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Published online by Cambridge University Press:  05 August 2016

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Flow Measurement Handbook
Industrial Designs, Operating Principles, Performance, and Applications
, pp. 643 - 734
Publisher: Cambridge University Press
Print publication year: 2016

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References

Abe, J. and Yoshinaga, A. (1991) Flow measurement by using fluidic resistor. FLUCOME ’91 3rd Triennial International Symposium on Fluid Control, Measurement and Visualization, San Francisco, USA: 559–564.
Abe, T., Hayashi, T., Kikawa, N., Tsuruta, D., Kobayashi, Y., Takamoto, M., Shimada, T., Doihara, R. and Terao, Y. (2013) Development of a new clamp-on ultrasonic flowmeter. FLOMEKO 2013, 16th International Flow Measurement Conference, Paris, France.
Abernathy, F. H. and Kronauer, R. E. (1962) The formation of vortex streets. Journal of Fluid Mechanics, 13: 1–20.Google Scholar
Abro, E., Kleppe, K. and Vikshåland, J. (2009) Recent field experiences using multiphase meters for fiscal allocation. 27th International North Sea Flow Measurement Workshop, Tonsberg, Norway, 20–23 October, pp. 67–93.
Adejuyigba, B., Uvwo, I., Liu, J., Ekpecham, O., Scott, S. L., Lansangan, R. and Dutton, R. (2004) Investigation of three-phase flow measurement capabilities of a Coriolis flow meter. 4th North American Conference on Multiphase Technology, pp. 161–176.Google Scholar
Adiletta, G., Cascetta, F., della Valle, S., Pagano, S. and Vigo, P. (1993) Twin rigid straight pipe Coriolis mass flowmeter. Measurement, 11: 289–308.Google Scholar
Advisory Committee on Aeronautics (1916–1917) Reports and Memoranda, No 295: 675.
AGA-8 (1992) Compressibility and supercompressibility for natural gas and other hydrocarbon gases, Transmission Measurement Committee Report No 8 AGA Catalog No XQ 1285, Arlington, Virginia, USA.
AGA-9 (2007) Measurement of gas by multipath ultrasonic meters, AGA Report no. 9, American Gas Association, Transmission Measurement Committee (April).
Agarwal, A. K. and Turgeon, M. (1984) New MicroMotion mass flowmeters. Energy Progress, 4: 221–224.Google Scholar
Agricola, J. B. (1997) Gas well flowline measurement by ultrasonic flow meter. North Sea Flow Measurement Workshop Kristiansand, Norway, Paper 16.
Ahmad, K., Baker, R. C. and Goulas, A. (1986) Computation and experimental results of wear in a slurry pump impeller. Proceedings of the Institution of Mechanical Engineers, Part C, 200: 439–445.Google Scholar
Ahn, Y.-C., Do Oh, B. and Kim, M. H. (2003) A current-sensing electromagnetic flowmeter for two-phase flow and numerical simulation of the three-dimensional virtual potential distribution: I. Fundamentals and Annular Flow. Measurement Science and Technology, 14(3): 239–250.Google Scholar
Akashi, K., Watanabe, H. and Koga, K. (1978) Flow rate measurement in pipe line with many bends. Technical Review, June.
Akresh, M., Reindl, L. and Vasic, M. (2010) Extended measurement range of vortex flow meter in high turbulent range. 15th Flow Measurement Conference (FLOMEKO), 13–15 October, Taipei, Taiwan, Paper B2-1.
Al-Asmi, K. and Castro, I. P. (1992) Vortex shedding in oscillatory flow: geometrical effects. Journal of Flow Measurement & Instrumentation, 3: 187–202.Google Scholar
Al-Bouri, H. A., Samizo, N., Bakhteyar, Z. and Alvi, A. (2005) Application of new multiphase flow measurement systems with satellite-based monitoring in offshore Khafji Field. International Petroleum Technology Conference Proceedings, pp. 431–440.Google Scholar
Al-Khamis, M. N., Al-Nojaim, A. A. and Al-Marhoun, M. A. (2002) Performance evaluation of Coriolis mass flowmeters. Journal of Energy Resources Technology, Transactions of the ASME, 124(2): 90–94.Google Scholar
Al-Khazraji, Y. A. and Baker, R. C. (1979) Analysis of the performance of three large-electrode electromagnetic flowmeters. Journal of Physics D, 12: 1423–1434.Google Scholar
Al-Khazraji, Y. A. and Hemp, J. (1980) Electromagnetic flowmeters and methods of measuring flow. Patent application No. 8011624.
Al-Khazraji, Y. A., Al-Rabeh, R. H., Baker, R. C. and Hemp, J. (1978) Comparison of the effect of a distorted profile on electromagnetic, ultrasonic and differential pressure flowmeters. FLOMEKO 1978 – Proceedings of the Conference on Flow Measurement of Fluids, Groningen, The Netherlands, (Amsterdam North-Holland Publishing Company): 215–222.
Al-lababidi, S. and Sanderson, M. L. (2004) Transit time ultrasonic modelling in gas/liquid intermittent flow using slug existence conditions and void fraction analysis. 12th International Conference on Flow Measurement FLOMEKO, Guilin, China.
Al-Mubarak, A. M. (1997) A new method in calculating water cut and oil and water volumes using Coriolis meters. SPE 38785 SPE Conference, 5–8 October, San Antonio, Texas, USA.
Al-Rabeh, R. H. (1981) The design and performance of electromagnetic flowmeters. PhD Thesis, Imperial College, University of London, England.
Al-Rabeh, R. H. and Baker, R. C. (1979) Optimisation of conventional electromagnetic flowmeters. Fluid Mechanics Silver Jubilee Conference, National Engineering Laboratory, Glasgow, Scotland, Paper 6.1.
Al-Rabeh, R. H. and Baker, R. C. (1986) On the ability to dry calibrate an electromagnetic flowmeter. Journal of Physics E: Scientific Instruments, 19: 203–206.Google Scholar
Al-Rabeh, R. H. and Hemp, J. (1981) A new method for measuring the flow rate of insulating fluids. International Conference on Advances in Flow Measurement Techniques, BHRA, Paper K3: 267–278.
Al-Rabeh, R. H., Baker, R. C. and Hemp, J. (1978) Induced flow measurement theory for poorly conducting fluids. Proceedings of the Royal Society A, 361: 93–107.Google Scholar
Al-Taweel, A. B., Barlow, S. G. and Aggour, M. A. (1997) Development and testing of multiphase metering unit utilizing Coriolis meters. Proceedings SPE (38785) Annual Technical Conference and Exhibition, San Antonio, TX, USA, 365–376.
Ali, M., Bohari, M., de Leeuw, H. and Nilsson, C. (2003) Multiphase flow measurement using tracer technology at Dulang Oil Field, Malaysia. SPE – Asia Pacific Oil and Gas Conference, 351–359.Google Scholar
Altendorf, M. (1998) Coriolis technique in the pulp and paper industry. Chemical Engineering World, 33(5): 87–89.Google Scholar
Altfeld, K. (2002) Custody transfer metering in the liberalised European market. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Alvarado, J., MirelesJr., J. and Soriano, G. (2009) Development and characterization of a capacitance-based microscale flowmeter. Flow Measurement and Instrumentation, 20(2): 81–84.Google Scholar
Amabili, M. and Garziera, R. (2004) Coriolis mass flow meter having a thin-walled measuring tube. US Patent 6,805,013 B2.
Amadi-Echendu, J. E. and Zhu, H. (1992) Signal analysis applied to vortex flowmeters. IEEE Transactions on Instrumentation and Measurement, 41.6: 1001–1004.Google Scholar
Amadi-Echendu, J. E., Zhu, H. and Higham, E. H. (1993) Analysis of signals from vortex flowmeters. Journal of Flow Measurement & Instrumentation, 4: 225–232.Google Scholar
Amare, T. (1995) Electromagnetic flowmeter for dielectric liquids. PhD thesis, Cranfield University, UK.
Amare, T. (1999) Design of an electromagnetic flowmeter for insulating liquids. Measurement Science and Technology, 10: 755.Google Scholar
Amata, Y. (1986) Electromagnetic flowmeter of the residual magnetism type. US Patent 4,601,209.
Amini, A. and Owen, I. (1995) The use of critical flow Venturi nozzles with saturated wet steam. Journal of Flow Measurement and Instrumentation, 6: 41–47.Google Scholar
Anabtawi, A. L. and Howlett, R. J. (2000) Detection of blade contamination in turbine flowmeters using neural networks. Proceedings of the International Conference on Knowledge-based Intelligent Electronic Systems, KES 2: 635–639.Google Scholar
Andersen, O., Miller, G., Harvey, R. and Stewart, D. (2004) Two-component Coriolis measurement of oil and water at low velocities. In: 22nd North Sea flow metering workshop.
Anklin, M., Drahm, W. and Rieder, A. (2006) Coriolis mass flowmeters: overview of the current state of the art and latest research. Journal of Flow Measurement and Instrumentation, 17(6): 317–323.Google Scholar
Anklin, M., Eckert, G., Sorokin, S. and Wenger, A. (2000) Effect of finite medium speed of sound on Coriolis mass flowmeters. FLOMEKO '2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper C11.
Anon, . (1966a) Measuring beefeater gin. Control, 10(96): 292.Google Scholar
Anon, . (1966b) Positive displacement flowmeter for low rates. Control, 10(98): 437.Google Scholar
Anon, . (1988) NEL launches offshore multiphase flowmeter project. Process Engineering, October: 33.Google Scholar
Anon, . (1993) Non-intrusive multiphase flow meter. Offshore Research Focus, No. 98: 9.Google Scholar
Anon, . (1994) Multiphase flow meter. Offshore Research Focus, No. 103: 2.Google Scholar
Anon, . (1999) New fuel meter particle filter system from Pierburg. Diesel Progress – North American Edition, 65(2): 32.Google Scholar
Anon, . (2002) A consumers’ guide to full-bore magnetic flowmeters. World Pumps, (428): 46–49.Google Scholar
Anon, . (2003) Reincarnation of 2-wire flowmeter. PACE – Process and Control Engineering, 56(9): 27–30.Google Scholar
ANSI/API 2530. (1985) Manual of Petroleum Measurement Standards, Chapter 14. Natural Gas Fluids Measurement Section 3 – Orifice Metering of Natural Gas and Other Related Hydrocarbon Fuels.
Ao, S. and Freeke, J. (2003) GE-Panametrics clamp-on flow meter, results in industrial gas applications. 21st North Sea Flow Metering Workshop 2003, Paper 14.
Ao, X. S., Martson, J., Kucmas, P., Khrakovsky, O. and Li, X. S. (2002) Ultrasonic clamp-on flow measurement of natural gas, steam and compressed air. 5th International Symposium of Fluid Flow Measurement, Arlington, VA, USA.
Ao, X. S., Caravana, R., Furlong, E. R., Khrakovsky, O. A., McDonald, B. E., Mollo, N. J. and Shen, L. (2011) Method and system for multi-path ultrasonic flow rate measurement. US Patent 7,942,068.
Ao, X. S. Khrakovsky, O. A., Frail, C. A. and Ma, A. Y. (2014) Ultrasonic coupler assembly. US Patent 8635913B2. 28 January 2014.
Aoki, T., Nukui, K., Okamura, S. and Kimura, Y. (1996) Development of fluidic gas meter (improvement of sensitivity at lower flow rate using U-shaped target sensor). FLOMEKO '96 Proceedings of the 8th International Conference on Flow Measurement, Beijing, China: 138–143.
API (2005) Measurement of liquid hydrocarbons by displacement meter systems. American Petroleum Institute (API). Manual of Petroleum Measurement Standards, Chapter 5.2.
API (2011) Measurement of liquid hydrocarbons by ultrasonic flow meters. American Petroleum Institute (API). Manual of Petroleum Measurement Standards, Chapter 5.8.
Araimi, N. M., Jha, N. K. and Al-Zakwani, S. (2005) Exploration well testing with a Venturi/dual energy gamma ray multiphase flow meter – A case study from Oman. SPE Asia Pacific Oil and Gas Conference and Exhibition – Proceedings, pp. 505–512.
Arasi, J. A. (1989) Coriolis mass flowmeter passes NGL line field trials. Oil & Gas Journal, January: 59–61.Google Scholar
Arnberg, B. and Ishibashi, M. (2001) Review of flow nozzle and Venturi designs and discharge coefficient. Proc. 47th Intern. Instrumentation Symposium, paper no. 1200.
Arnberg, B. T., Britton, C. L. and Seidl, W. F. (1973) Discharge coefficient correlations for circular-arc Venturi flowmeters at critical (sonic) flow. ASME Paper No 73-WA/FM-8.
Arnold, K. B. and Molz, F. J. (2000) In-well hydraulics of the electromagnetic borehole flowmeter: further studies. Ground Water Monitoring and Remediation, 20(1): 52–55.Google Scholar
Arnold, R. M. and Pitts, R. W. (1981) Fluid flow meters for mixed liquid and gas. US Patent 4,272,982, 16 June.
Arvoh, B. K., Asdahl, S., Rabe, K., Ergon, R. and Halstensen, M. (2012) Online estimation of reject gas and liquid flow rates in compact flotation units for produced water treatment. Flow Measurement and Instrumentation, 24: 63–70.Google Scholar
Ashauer, M., Glosch, H., Hedrich, F., Hey, N., Sandmaier, H. and Lang, W. (1999) Thermal flow sensor for liquids and gases based on combinations of two principles. Sensors and Actuators, 73: 7–13.Google Scholar
Asher, R. C. (1983) Ultrasonic transducers for chemical and process plant. Physics Technology, 14: 19–23.Google Scholar
ASME/ANSI MFC-7M (1987) Measurement of gas flow by means of critical flow Venturi nozzles. New York: ASME.
Aston, N. A. J. and Evans, G. V. (1975) The integrated pulse velocity method applied to the calibration of flowmeters in high pressure natural gas systems. Conference on Fluid Flow Measurement in the Mid 1970s, Paper D-2: Scotland: National Engineering Laboratory.
Athane, B. (1994) Implications of legal metrology in flow measurement for the utilities. Journal of Flow Measurement and Instrumentation, 5(2): 67–69.Google Scholar
Atkinson, D. I., Berard, M. and Segeral, G. (2000) Qualification of a nonintrusive multiphase flow meter in viscous flows. Proceedings 2000 SPE Annual Technical Conference and Exhibition – Production Operations and Engineering General, P1: 533–544.
Atkinson, K. N. (1992) A software tool to calculate the over-registration error of a turbine meter in pulsating flow. Journal of Flow Measurement and Instrumentation, 3: 167–172.Google Scholar
Awbery, J. H. and Griffiths, E. (1926–1927) Further experiments with the Ewing ball-and-tube flowmeter. Proceedings of the Royal Society, 47: 1.Google Scholar
Baird, , J. (1993) Innovations in magnetic flowmetering. Advances in Instrum. & Control: International Conf. & Exhibition (ISA), Chicago, USA, 48: 879–884.Google Scholar
Baker, P. D. (1983) Positive displacement liquid meters. International School of Hydrocarbon Measurement (ISHM), University of Oklahoma, 12–14 April.
Baker, R. C. (1968a) On the potential distribution resulting from flow across a magnetic field projecting from a plane wall. Journal of Fluid Mechanics, 33: 73–86.Google Scholar
Baker, R. C. (1968b) Solutions of the electromagnetic flowmeter equation for cylindrical geometries. British Journal of Applied Physics, 1, Ser. 2: 895–899.Google Scholar
Baker, R. C. (1969) Flow measurement with motion induced magnetic field at low magnetic Reynolds number. Magnetohydrodynamics, No. 3: 69–73 (in Russian).Google Scholar
Baker, R. C. (1970a) Effects of non-uniform conductivity fluids in electromagnetic flowmeters. Journal of Physics D, 3: 637–639.Google Scholar
Baker, R. C. (1970b) Linearity of motion-induced-magnetic-field flowmeter. Proc. I.E.E., 117: 629–633.Google Scholar
Baker, R. C. (1973) Numerical analysis of the electromagnetic flowmeter. Proc. I.E.E., 120: 1039–1043.Google Scholar
Baker, R. C. (1976) Some recent developments in ultrasonic and electromagnetic pipe flow measurement at Imperial College. ACTA IMEKO: 339–348.Google Scholar
Baker, R. C. (1977) Electromagnetic flowmeters for fast reactors. Progress in Nuclear Energy, 1: 41–61.Google Scholar
Baker, R. C. (1982) Electromagnetic flowmeters. Developments in Flow Measurement – 1, ed. Scott, R. W. W., Applied Science Publishers Ltd, Chapter 7: 209–251.
Baker, R. C. (1983) A review of recent developments in electromagnetic flow measurement. Third Beer-Sheva Seminar on MHD – Flows and Turbulence, Ben-Gurion University of the Negev, Beer-Sheva, Israel, 23–27 March 1981. See also in Prog. in Astro. & Aero. AIAA Inc, 84: 225–259.
Baker, R. C. (1985) Principles and practice of electromagnetic flow measurement. Technisches Messen, tm 52 Jahrgang, Heft 1: 4–12 (in German).
Baker, R. C. (1988a/1989) An introductory guide to flow measurement. Mechanical Engineering Publications Limited.
Baker, R. C. (1988b) Measuring multiphase flow. Chemical Engineer, October: 39–45.Google Scholar
Baker, R. C. (1989) Multi-phase flow moves on. Control and Instrumentation, February: 35 and 37.Google Scholar
Baker, R. C. (1991a) Response of bulk flowmeters to multiphase flow. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 205: 217–229.Google Scholar
Baker, R. C. (1991b) Turbine and related flowmeters: Part I – Industrial practice. Journal of Flow Measurement and Instrumentation, 2: 147–162.Google Scholar
Baker, R. C. (1993) Turbine flowmeters: Part II – Theoretical and experimental published information. Journal of Flow Measurement and Instrumentation, 4: 123–144.Google Scholar
Baker, R. C. (1994) Coriolis flowmeters: industrial practice and published information. Flow Measurement and Instrumentation, 5(4): 229–246.Google Scholar
Baker, R. C. (1996) An introductory guide to industrial flow. London: Mechanical Engineering Publications Limited.
Baker, R. C. (1998) Flowmeter. Instruments of science, an historical encyclopedia, Eds. Bud, R. and Warner, D. J.. New York and London: Garland Publishing Inc., 245–247.
Baker, R. C. (2000) Flow measurement handbook. 1st Edition. New York: Cambridge University Press.
Baker, R. C. (2002b) An introductory guide to flow measurement. 2nd Edition. Professional Engineering Press (now available from John Wiley & Sons).
Baker, R. C. (2003) An introductory guide to flow measurement (ASME Edition). ASME Press.
Baker, R. C. (2004a) The impact of component variation in the manufacturing process on variable area (VA) flowmeter performance. Journal of Flow Measurement and Instrumentation, 15(4): 207–213.Google Scholar
Baker, R. C. (2004b) Variation in flowmeter manufacture: some observations and lessons. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 218: 961–975.Google Scholar
Baker, R. C. (2005) In-situ calibration verification device and method for electromagnetic flowmeters, International Patent Application number PCT/GB2005/04399 dated 15 November 2005 (taking priority from UK Patent Application number GB0425186.4 dated 15 November 2004).
Baker, R. C. (2011) On the concept of virtual current as a means to enhance verification of electromagnetic flowmeters. Measurement Science and Technology, 22: 105403.Google Scholar
Baker, R. C. and Deacon, J. E. (1983) Tests on turbine, vortex and electromagnetic flowmeters in 2-phase air-water upward flow. International. Conference. on Physical Modelling of Multi-Phase Flow, Coventry, England, BHRA Fluid Engineering: paper H1, 337–352.
Baker, R. C. and Gimson, C. (2001) The effects of manufacturing methods on the precision of insertion and in-line thermal mass flowmeters. Journal of Flow Measurement and Instrumentation, 12(2): 113–121.Google Scholar
Baker, R. C. and Gregory, M. J. (2001) Editorial: special issue of the journal focusing on flowmeter manufacture. Journal of Flow Measurement and Instrumentation, 12(2): 85–87.Google Scholar
Baker, R. C. and Gregory, M. J. (2002) Flowmeter manufacture: some observations on variation and robustness. 5th International Symposium on Fluid Flow Measurement (ISFFM), Washington, DC, USA.
Baker, R. C. and Hayes, E. R. (1985) Multiphase measurement problems and techniques for crude oil production systems. Petroleum Review, November.Google Scholar
Baker, R. C. and Higham, E. H. (1992) Flowmeters. UK Patent No. 2 231 669 B.
Baker, R. C. and Morris, M. V. (1985) Positive-displacement meters for liquids. Transactions of the Institute of Measurement and Control, 7: 209–220.
Baker, R. C. and Saunders, P. M. (1977) Tests on flux distortion flowmeters using an analogue rig to simulate flow with a boundary layer. Annals of Nuclear Energy, 4: 457–464.Google Scholar
Baker, R. C. and Smith, D. J. M. (1990) Flowmeter specification guidelines. Cranfield, England: FLOMIC Report No 14.
Baker, R. C. and Sorbie, I. (2001) A review of the impact of component variation in the manufacturing process on variable area (VA) flowmeter performance. Journal of Flow Measurement and Instrumentation, 12(2): 101–112.Google Scholar
Baker, R. C. and Tarabad, M. (1978) The performance of electromagnetic flowmeters with magnetic slurries. Journal of Physics D Applied Physics, 11: 167–175.Google Scholar
Baker, R. C. and Thompson, E. J. (1975) A two beam ultrasonic phase-shift flowmeter. Conference on Fluid Flow Measurement in the Mid 1970s, National Engineering Laboratory, East Kilbride Glasgow, Scotland.
Baker, R. C. and Thompson, E. J. (1978) Measurement of fluid flow. US Patent 4,078,428, 14 March.Google Scholar
Baker, R. C., Moore, P. I. and Thomas, A. L. (2004a) Verification for electromagnetic flowmeters – its current state and its potential. Presented at FLOMEKO 2004, Guilin, China.
Baker, R. C., Moore, P. I. and Thomas, A. L. (2006a) Electronic verification of electromagnetic flowmeters in the water industry. Water Management 159 (WM4): 245–251.Google Scholar
Baker, R. C., Moore, P. I. and Wang, T. (2004b) Rethinking dry calibration. Presented at FLOMEKO 2004, Guilin.
Baker, R. C., Moore, P. I. and Wang, T. (2005) In situ calibration. Sensor Review, 25(3): 197–201.Google Scholar
Baker, R. C., Deacon, J. E., Lenn, C. P. and Smart, M. D. (1985) The effect on electromagnetic flowmeters of a change in fluid. Measurement and Control, 8: 5–10.Google Scholar
Baker, R. C., Wang, T., Moore, P. I. and Nurse, A. (2006b) Observations on the design and development of a water flow rig related to calibration in the manufacturing process. Journal of Flow Measurement and Instrumentation, 17: 171–178.Google Scholar
Baker, R. C., Wang, T., Hussain, Y. A. and Woodhouse, J. (2009) Method for testing a mass flow rate meter. US Patent 7,603,885 B2, 20 October.
Baker, R. C., Gautrey, D. P., Mahadeva, D. V., Sennitt, S. D. and Thorne, A. J. (2013) Case study of the electrical hardware and software for a flowmeter calibration facility. Journal of Flow Measurement and Instrumentation, 29: 9–18. http://dx.doi.org/10.1016/j.flowmeasinst.2012.09.001 Google Scholar
Baldwin, P. and Rivera, I. (2012) Ultrasonic clamp-on flow metering – 50 years and counting. 8th International Symposium on Fluid Flow Measurement – June.
Ball, J. M. (1977) Viscosity effects on the turbine flowmeter. Proceedings of the Symposium on Flow Measurement in Open Channels and Closed Conduits. NBS, Gaithersburg, MD, USA: 847–869.
Balla, J. and Takáras, F. (2003) Long term operational experience of turbine meters. 21st North Sea Flow Metering Workshop 2003, Paper 16.
Balls, B. W. and Brown, K. J. (1959) The magnetic flowmeter. Symposium on Flow Measurement: Trans. Soc. Instrument Technology, June: 123–130.Google Scholar
Barbe, J., Dijoux, F., Yardin, C. and Mace, T. (2010) Measurement of helium micro flowrates with high accuracy for gas chromatography. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A8-5.
Barnes, R. G. (1982) Positive displacement liquid meters. Advances in Instrumentation, 37, Part 3, Proc ISA Int Conf and Exhibit (Philadelphia USA, 18–21 October 1982), Research Triangle Park, USA, Instrum Soc Am: 1197–1204.
Barry, J. J., Sheikoleslami, M. Z. and Patel, B. R. (1992) Numerical simulation of flow through orifice meters, Gas Research Institute, GRI-92/0060.1.
Barton, N. A. and Boam, D. (2002) In-service performance of ultrasonic flowmeters – Application and validation of CFD modeling methods, Report No. 2002/72, National Engineering Laboratory.
Barton, N. A. and Brown, G. (1999) Velocity distribution effects on ultrasonic flowmeters – Part 2 Determination by computational and experimental methods, Report No. 348/99, National Engineering Laboratory.
Barton, N. and Parry, A. (2012) Using CFD to understand multiphase and wet-gas measurement. North Sea Flow Metering Workshop. Paper 9.2.
Barton, N. and Peebles, B. (2005) Redesign of the ETAP gas export system. FLOMEKO 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 6.3.
Barton, N., Reader-Harris, M., Hodges, D. and Coull, C. (2002) The effect of varying Reynolds number on a Zanker flow conditioner plate. 20th North Sea Flow Measurement Workshop 22–25 October 2002, St Andrews, Scotland, Paper 6.2.
Barton, N. A., Gibson, J. G. and Reader-Harris, M. J. (2004) Overview of CFD modelling of orifice-plate flowmeters. 22nd North Sea Flow Metering Workshop, St Andrews, Scotland, 26–28 October 2004, Paper 6.3.
Barton, N., Hodgkinson, E. and Reader-Harris, M. (2005) Estimation of the measurement error of eccentrically installed orifice plates. 23rd North Sea Flow Metering Workshop 2005, Paper 4, pp. 35–44.
Bartstra, R. W. (2006) Clamp-on Coriolis mass flow meter using in-situ calibration. EP 1623192.
Basil, M., Stobie, G. and Letton, W. (2007) A new approach to MPFM performance assessment in heavy oil. 25th International North Sea Flow Measurement Workshop, Energy Institute, Oslo, Norway, 311–326.
Basrawi, Y. F. (2003a) Coriolis force mass flow measurement devices. Proceedings of the International Instrumentation Symposium, 49: 237–247.Google Scholar
Basrawi, Y. F. (2003b) Coriolis force mass flow measurement devices. Annual ISA Analysis Division Symposium – Proceedings, 444: 161–172.Google Scholar
Basse, N. T. (2014) A review of the theory of Coriolis flowmeter measurement errors due to entrained particles. Journal of Flow Measurement and Instrumentation, 37: 107–118.Google Scholar
Batchelor, G. K. (1967) An introduction to fluid dynamics. Cambridge University Press.
Bates, C. J. (1981) Laser Doppler anemometry measurements of the flow through an orifice plate. Flow: Its Measurement and Control in Science and Industry, 2: 59–68.Google Scholar
Bates, C. J. (1999) Upstream installation and misalignment effects on the performance of a modified electromagnetic flowmeter. Journal of Flow Measurement and Instrumentation, 10: 79–89.Google Scholar
Bates, C. J. (2000a) The performance of a modified electromagnetic flowmeter when abutted to a smaller misaligned upstream diameter pipe. FLOMEKO '2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper B6.
Bates, C. J. (2000b) Performance of two electromagnetic flowmeters mounted downstream of a 90° mitre bend/reducer combination. Measurement: Journal of the International Measurement Confederation, 27: 197–206.Google Scholar
Bates, C. J. and Turner, R. B. (2003) Fluid flow studies associated with a new electromagnetic flowmeter. Measurement: Journal of the International Measurement Confederation, 33(1): 85–94.Google Scholar
Bates, I. P. (1991) Field use of K-lab flow conditioner. Proceedings of the North Sea Flow Measurement Workshop 1991 (two volumes), Norwegian Society of Chartered Engineers, 22–24 October 1991 (9th in the series).
Battye, J. S. (1993) The correlation flowmeter – a detailed investigation of an attempt to improve its performance. FLOMEKO '93 Proceedings of the 6th International Conference on Flow Measurement, Korea: 492–499.
Battye, J. S. (2001) Acoustic considerations effecting the design of demodulators for the ultrasonic correlation flow meter. Sensors and Actuators, A88(1): 29–40.Google Scholar
Baucom, W. E. (1979) Evaluation of a Coriolis mass flow meter for pulverized coal flows. Prepared by The Energy Conservation Division, The University of Tennessee Space Institute, Tullahoma, Tennessee 37388, for the U.S. Dept. of Energy (Contract No DE-AC02 – 79ET10815, December).
Baumann, S. and Vaterlaus, H.-P. (2002) Hot-tapping for the ultrasonic flowmeters at North Umpqua, USA. International Journal on Hydropower and Dams, 9(3): 102–104.Google Scholar
Baumgartner, M. (2001) Heat metering by ultrasound (in German). Euroheart and Power/Femwarme International, 30(3): 53–55.Google Scholar
Baumoel, J. (1994) Use of clamp-on transit-time ultrasonic flowmeters in aircraft mass fuel flow, hydraulic fluid leak detection, & ground support applications. Instrumentation in the Aerospace Industry: Proceedings of the International Symposium ISA, Research Triangle Pk, NC, USA: 243–260.
Baumoel, J. (1996) Pipeline management using networked clamp-on transit-time flowmeters. Proceedings of the International Pipeline Conference, Calgary, Canada, ASME, NY, USA, 2: 1123–1128.
Baumoel, J. (2002) Performance of wide beam clamp-on ultrasonic flowmeters in API proving tests (clamp-on custody transfer by API method). 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Bean, H. S. (1971) Fluid meters, their theory and application. 6th Edition. New York: ASME.
Beaulieu, A., Faucault, E., Braud, P., Micheau, P. and Szeger, P. (2011) A flowmeter for unsteady liquid flow measurements. Journal of Flow Measurement and Instrumentation, 22(2): 131–137.Google Scholar
Beck, M. S. and Plaskowski, A. (1987) Cross correlation flowmeters – their design and application. Bristol, UK: Adam Hilger.
Beeson, J. (1995) Ultrasonics meters improve NorAm's custody transfer. Pipeline & Gas Journal, 222(7): 21–24.Google Scholar
Beg, N. and Toral, H. (1993) Off-site calibration of a two-phase pattern recognition flowmeter. Int. J. Mult. Flow, 19: 999–1012.Google Scholar
Belhadj, A., Cheesewright, R. and Clark, C. (2000) The simulation of Coriolis meter response to pulsating flow using a general purpose FE code. Journal of Fluids and Structures, 14: 613–634.Google Scholar
Bell, M. J. and MacLeod, M. (2012) Assessment of particle erosion in Coriolis meters. North Sea Flow Metering Workshop, Paper 2.1.
Bellinga, H. and Delhez, F. J. (1993) Experience with a high-capacity piston prover as a primary standard for high-pressure gas flow measurement. Journal of Flow Measurement and Instrumentation, 4: 85–90.Google Scholar
Bellinga, H. et al. (1981) Using a piston prover as a primary standard in high-pressure gas metering. Flow, Its Measurement and Control in Science and Industry, Flow 81 Conference, St Louis, USA.
Benabdelkarim, M. and Galiana, C. (1991) Nonradioactive densitometer for continuous monitoring of cement mixing process. Proceedings of the First International Conference on Health, Safety and Environment in Oil and Gas Exploration and Production, Society of Petroleum Engineers of AIME, Texas, USA: 539–545.
Benard, C. J. (1988) Handbook of fluid flowmetering. Morden, England: The Trade & Technical Press Limited.
Benes, P. and Zehnula, K. (2000) New design of the two-phase flowmeters. Sensors and Actuators A: Physical, 86: 220–225.Google Scholar
Benhadj, R. and Ouazzane, A. K. (2002) Flow conditioners design and their effects in reducing flow metering errors. Sensor Review, 22(3): 223–231.Google Scholar
Benkova, M., Makovnik, S., Mikulecky, I. and Zamecnik, V. (2010) Bell prover – calibration and monitoring of time stability. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A1-3.
Bennett, R. (1996) Positive displacement diaphragm gas meter is industry workhorse, Pipe Line & Gas Industry, June: 51–53.
Bentley, J. P. and Benson, R. A. (1993) Design conditions for optimal dual bluff body vortex flowmeters. Journal of Flow Measurement and Instrumentation, 4: 205–214.Google Scholar
Bentley, J. P. and Nichols, A. R. (1990) The mapping of vortex fields around single and dual bluff bodies. Journal of Flow Measurement and Instrumentation, 1: 278–286.Google Scholar
Bentley, J. P., Benson, R. A. and Shanks, A. J. (1996) The development of dual bluff body flowmeters. Journal of Flow Measurement and Instrumentation, 7: 85–90.Google Scholar
Bera, S. C. and Kumar Ray, J. (2001) An approach to the design and fabrication of a microprocessor based flow meter using resistance and semiconductor probe. IETE Technical Review (Institution of Electronics and Telecommunication Engineers, India), 18(5): 355–360.Google Scholar
Bera, S. C., Kumar Ray, J. and Chattopadhyay, S. (2004) A modified inductive pick-up type technique of measurement in a vortex flowmeter. Measurement: Journal of the International Measurement Confederation, 35(1): 19–24.
Berg, R. F. (2004) Quartz capillary flow meter for gases. Review of Scientific Instruments, 75(3): 772–779.Google Scholar
Berg, R. F. (2005) Simple flow meter and viscometer of high accuracy for gases. Metrologia, 42(1): 11–23.Google Scholar
Berg, R. F. (2008) Capillary flow meter for calibrating spinning rotor gauges. Journal of Vacuum Science and Technology A: Vacuum, Surfaces and Films, 26(5): 1161–1165.Google Scholar
Berg, R. F. and Tison, S. A. (2002) Two primary standards for low flows of gases. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Bernier, R. N. and Brennen, C. E. (1983) Use of the electromagnetic flowmeter in a two-phase flow. Int. J. Multiphase Flow, 9: 251–257.Google Scholar
Berrebi, J.; Van Deventer, J. and Delsing, J. (2002) Detection of the error generated by a single elbow on an ultrasonic flow meter. ISA TECH/EXPO Technology Update Conference Proceedings, 424–425: 1268–1279.Google Scholar
Berrebi, J., Martinsson, P.-E., Willatzen, M. and Delsing, J. (2004a) Ultrasonic flow metering errors due to pulsating flow. Flow Measurement and Instrumentation, 15(3): 179–185.Google Scholar
Berrebi, J., van Deventer, J. and Delsing, J. (2004b) Reducing the flow measurement error caused by pulsations in flows. Flow Measurement and Instrumentation, 15(5–6): 311–315.Google Scholar
Betts, K. S. (1990) Mass flow sensors. Measuring up to new applications. Mechanical Engineering, 112: 72–75.Google Scholar
Bevir, M. K. (1970) The theory of induced voltage electromagnetic flowmeters. Journal of Fluid Mechanics, 43: 577.Google Scholar
Bevir, M. K. (1972) The effect of conducting pipe connections and surrounding liquid on the sensitivity of electromagnetic flowmeters. Journal of Physics D, 5: 717.Google Scholar
Bevir, M. K., O'Sullivan, V. T. and Wyatt, D. G. (1981) Computation of electromagnetic flowmeter characteristics from magnetic field data. Journal of Physics D, 14: 376.Google Scholar
Bezděk, M., Rieder, A., Landes, H., Lerch, R. and Drahm, W. (2003) Numerical analysis of wave propagation in an ultrasonic flowmeter. Paper presented at First Congress, Alps Adria Acoustic Associtrion, 573–80.
Bezděk, M., Rieder, A., Landes, H., Strunz, T. and Lerch, R. (2004) A novel numerical method for simulating wave propagation in moving media. Paper presented at IEEE Ultrasonics Symposium, 2, 934–937.
Bezděk, M., Landes, H., Rieder, A. and Lerch, R. (2007) A coupled finite-element boundary-integral method for simulating ultrasonic flowmeters. IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control, 54(3): 636–646.Google Scholar
Bignell, N. (1994) A secondary standard ultrasonic gas flowmeter. FLOMEKO '94 Flow Measurement in the Mid-90s, NEL, Glasgow, Scotland: Paper 7.2.
Bignell, N. (1996a) Comparison techniques for small sonic nozzles. Journal of Flow Measurement and Instrumentation, 7: 109–114.Google Scholar
Bignell, N. (2000) Ultrasonic domestic gas meters – a review. FLOMEKO'2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper A1.
Bignell, N. and Takamoto, M. (2000) Editorial of a special issue on Sonic Nozzles. Journal of. Flow Measurement and Instrumentation, 11(4): 255.Google Scholar
Bignell, N., Collings, A. F., Taylor, K. J. H., Martin, B. J., Braathen, C. W., Peterson, M. and Welsh, C. (1993a) An ultrasonic domestic gas meter. FLOMEKO '93 Proceedings of the 6th International Conference on Flow Measurement, Korea: 403–409.
Bignell, N., Collings, A. F., Taylor, K. J. H., Martin, B. J., Braathen, C. W., Peterson, M. and Welsh, C. (1993b) Calibration of ultrasonic domestic gas meter. FLOMEKO '93 Proceedings of the 6th International Conference on Flow Measurement, Korea: 410–415.
BIPM/IEC/IFCC/ISO/IUPAC/IUPAP/OIML (1993) Guide to the expression of uncertainty in measurement, 1st ed., ISO. See updated version at BIPM (JCGM 100: 2008).
BIPM [Internet]. The BIPM key comparison database calibration and measurement capabilities — CMCs (Appendix C). Available from: http://kcdb.bipm.org/AppendixC/default.asp.
Birch, J. R. and Lemon, D. D. (1995) Non-intrusive flow measurement techniques for hydroelectric applications. ASCE Waterpower – Proceedings of the Int Conf on Hydropower, 3: 2049–2058.Google Scholar
Birker, B. (1989) Theory, design and performance of the straight tube mass flowmeter. Mass Flow Measurement Direct and Indirect, London, England.
Birkhofer, B. H., Jeelani, S. A. K., Windhab, E. J., Ouriev, B., Lisner, K.-J., Braun, P. and Zeng, Y. (2008) Monitoring of fat crystallization process using UVP-PD technique. Flow Measurement and Instrumentation, 19(3–4): 163–169.Google Scholar
Blackett, P. M. S. and Henry, P. S. H. (1930) A flow method for comparing specific heats of gases. Part II – the Theory of the Method. Proc. R. Soc. London Series A, 126: 333–354.Google Scholar
Blickley, G. J. (1995) Coriolis for the masses. Control Engineering, 42(7): 40–41.Google Scholar
Blows, L. G. (1981) Towards a better turbine flowmeter. International Conference on Advances in Flow Measurement Techniques, Warwick, England (Publ by BHRA Fluid Eng, Cranfield, England): 307–318.
Blumenthal, I. (1984) Improving productivity through mass flow measurement and control. Enhancing Productivity, Proceedings of the Pacific Cascade Instrumentation ’84 Exhibition and Symposium, ISA: 163–168.
Blumenthal, I. (1985) Direct mass flow rate and density monitoring using a Coriolis/gyroscopic sensor base. Tappi Journal (USA), 68(11): 82–84.Google Scholar
, Ø. L., Nyfors, E., Løland, T. and Couput, J.-P. (2002) New compact wet gas meter based on a microwave water detection technique and differential pressure flow measurement. 20th North Sea Flow Measurement Workshop, 22–25 October 2002, St Andrews, Scotland, Paper 4.1.
Bobovnik, G., Kutin, J. and Bajsić, I. (2005) Estimation of velocity profile effects in the shell-type Coriolis flowmeters using CFD simulations. Flow Measurement and Instrumentation, 16(6): 365–373.Google Scholar
Bobovnik, G., Kutin, J., Mole, N., Štok, B. and Bajsić, I. (2013) Numerical analysis of installation effects in Coriolis flowmeters: A case study of a short straight tube full-bore design. Flow Measurement and Instrumentation, 34: 142–150.Google Scholar
Boer, A. H. and Volmer, W. (1997) Test results Krohne 8” ultrasonic flowmeter. North Sea Flow Measurement Workshop Kristiansand, Norway: Paper 32.
Bonfig, K. W., Hofman, F., Reinhoold, I. and Feuerstein, M. (1975) A new method of magnetic inductive flow measurement. Conference on Flow Measurement in the Mid-1970s: Paper E-3.
Bonner, J. A. (1977) Pulsating effects in turbine meter. Pipe Line Industry, March: 57–62.Google Scholar
Bonner, J. A. (1993) A new international standard, ISO 9951: the measurement of gas flow in closed conduits – turbine meters. Journal of Flow Measurement and Instrumentation, 4: 99–100.Google Scholar
Bonner, J. A. and Lee, W. F. Z. (1992) The history of the gas turbine meter. AGA Distribution and Transmission Conference , Kansas City, Missouri.
Borkar, K., Venugopal, A. and Prabhu, S. V. (2013) Pressure measurement technique and installation effects on the performance of wafer cone design. Flow Measurement and Instrumentation, 30: 52–59.
Bosio, J., Wilcox, P. L., Erdal, A. and Sinding, H. (1990) Gas flowmeters repeatability and accuracy might be impeded by elemental sulphur deposition. North Sea Flow Measurement Workshop, National Engineering Laboratory, Scotland, 23–25.
Botros, K. K., Jungowski, W. M. and Petela, G. (1992) Gauge line effects and DP transmitter response to flow pulsation through orifice plate. Journal of Flow Measurement and Instrumentation, 3: 130–144.Google Scholar
Boucher, R. F. (1995) Minimum flow optimization of fluidic flowmeters. Measurement Science and Technology, 16: 872–879.Google Scholar
Boucher, R. F. and Mazharoglu, C. (1988) Low Reynolds number fluidic flowmetering. Journal of Physics E: Scientific Instruments, 21: 977–989.Google Scholar
Boucher, R. F., Churchill, D., Mazharoglu, C. and Parkinson, G. J. (1991) A fluidic by-pass Venturi meter. FLUCOME ’91 3rd Triennial International Symposium on Fluid Control, Measurement and Visualization, San Francisco, USA: 565–569.
Bowden, K. F. and Fairbairn, L. A. (1956) Measurement of turbulent fluctuations and Reynolds stresses in a tidal current. Proceedings of the Royal Society, 237: 422.Google Scholar
Boyer, C. and Lemonnier, H. (1996) Design of a flow metering process for two-phase dispersed flows. International Journal of Multiphase Flow, 22(4): 713–732.Google Scholar
Boyle, K. C. (2002) Accurate measurement for gypsum. Global Gypsum, 2002: 28–31.Google Scholar
Bragg, M. I. and Lynnworth, L. C. (1994) Internally-nonprotruding one-port ultrasonic flow sensors for air and some other gases. Control '94, Conference Publication No. 389, IEE: 1241–1247.
Brain, T. J. S. (1978) The calibration of meters with gases. Short Course notes on The Principles and Practice of Flow Measurement, Lecture No 7, National Engineering Laboratory, East Kilbride.
Brain, T. J. S. and MacDonald, L. M. (1975) Evaluation of the performance of small-scale critical flow Venturis using the NEL gravimetric gas flow standard test facility. Fluid Flow Measurement in the Mid ’70s, Edinburgh, Scotland: 103–125.
Brain, T. J. S. and Reid, J. (1978) Primary calibrations of critical flow Venturi nozzles in high-pressure gas. FLOMEKO 1978 Flow Measurement of Fluids, Groningen, The Netherlands: 55–64.
Brain, T. J. S. (1980) Primary calibrations of critical flow Venturi nozzles in high-pressure gas. NEL Report No 666.
Brain, T. J. S., Reid, J. and MacDonald, C. (1975) Further development of the NEL pulsed gas-ionization flowmeter. Conference on Fluid Flow Measurement in the Mid 1970's, Paper D-4.
Branch, J. C. (1995) The effect of an upstream short radius elbow and pressure tap location on orifice discharge coefficients. Journal of Flow Measurement and Instrumentation, 6: 157–162.Google Scholar
Brassier, P. and Hosten, B. (2000) An ultrasonic gas flowmeter using high frequency transducers and correlation technique. FLOMEKO'2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper B4.
Brassier, P., Hosten, B. and Vulovic, F. (2001) High-frequency transducers and correlation method to enhance ultrasonic gas flow metering. Journal of Flow Measurement and Instrumentation, 12(3): 201–211.Google Scholar
Bremser, W., Hässelbarth, W., Hirlehei, U., Hotze, H.-J. and Wendt, G. (2002) Traceability and uncertainty of the German national flow rate measurement standard pigsar . 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Brennan, J. A., McFaddin, S. E., Sindt, C. F. and Kothari, K. M. (1989) The influence of swirling flow on orifice and turbine flowmeter performance. Journal of Flow Measurement and Instrumentation, 1: 5–8.Google Scholar
Brennan, J. A., Sindt, C. F., Lewis, M. A. and Scott, J. L. (1991) Choosing flow conditioners and their location for orifice flow measurement. Journal of Flow Measurement and Instrumentation, 2: 40–44.Google Scholar
Brewer, H. (2005) Why your lab should be ISO/IEC 17025-Accredited. Quality Digest, May 2005, 49–52.
Brignell, J. and White, N. (1994) Intelligent sensor systems. Institute of Physics Publishing, Bristol and Philadelphia.
Britton, C. L. and Caron, R. W. (1997) Unchoking pressure ratio for critical flow Venturis. ASME Fluids Engineering Division Summer Meeting FEDSM'97, Paper 3004.
Britton, C. and Mesnard, D. (1982) A performance survey of round- and diamond-shaped averaging pitot-type primaries. Measurement & Control, 15: 341–350.Google Scholar
Britton, C., Seidl, W. and Kinney, J. (2002) Experimental wet gas data for a Herschel style Venturi. 5th International Symposium of Fluid Flow Measurement, Arlington, VA, USA.
Britton, C. L., Kinney, J. and Savidge, J. L. (2004) Wet gas flow measurements with mixtures of natural gas, hydrocarbon liquids and water. 22nd North Sea Flow Metering Workshop 2004, Paper 8.3
Brobeil, W., Frohlich, R., Schafer, R. and Schulz, K. H. (1993) Flow measurements in slurry applications with switched DC-fields magflowmeters. FLOMEKO'93 Proceedings of the 6th International Conference on Flow Measurement, Korea Research Institute of Standards and Science: 635–641.
Brockhaus, H. (2005) Magnetisch Induktiver Durchflussmesser mit erweiterter Selbstu berwachung. VDI Berichte, No 1883:723–731 (in German).
Brockhaus, H., van der Pol, R., Schoth, U. and Klein, J. W. (1996) Capacitive electro magnetic flowmeter (EMF) using microsystems technology. FLOMEKO'96 Proceedings of the 8th International Conference on Flow Measurement, Beijing, China: 635–641.
Brown, A. F. and Kronberger, H. (1947) A sensitive recording calorimetric mass flowmeter. Journal of Scientific Instruments, 24: 151–155.Google Scholar
Brown, G. J. (1997) Factors affecting the performance of ultrasonic flowmeters. North Sea Flow Measurement Workshop Kristiansand, Norway: Paper 33.
Brown, G., Augenstein, D., Estrada, H., Laird, C. and Cousins, T. (2010) Thermal gradient effects on ultrasonic flowmeters in the laminar regime. 28th International North Sea Flow Metering Workshop, Paper 6.1.
Brown, G. J. and Coull, G. J. (2001) Benefits and limitations of ultrasonic meters for upstream oil and gas production. 19th North Sea Flow Measurement Workshop, Kristiansand, Norway, 22–25 October 2001, Paper 19.
Brown, G. J. and Griffith, B. (2012) the effects of flow conditioning on the performance of multipath ultrasonic meters. 8th International Symposium in Fluid Flow Measurement, June 20–22, 2012.
Brown, G. J. and Griffith, B. (2013) A new flow conditioner for 4-path ultrasonic flowmeters. FLOMEKO 2013, 16th International Flow Measurement Conference, Paris, France.
Brown, G. J., Reader-Harris, M. J., Gibson, J. and Stobie, G. J. (2000) Correction of the readings of an orifice-plate installed in reverse orientation. 18th North Sea Flow Measurement Workshop. Gleneagles, Scotland, 2000.
Brown, G., Augenstein, D. and Cousins, T. (2006) Velocity profile effects on multipath ultrasonic meters . Proc. 6th International Symposium on Fluid Flow Measurement (ISFFM), Querétero, Mexico.
Brown, G., Estrada, H., Augenstein, D. and Cousins, T. (2007) LNG metering using 8-path ultrasonic meters . 25th International North Sea Flow Measurement Workshop, Energy Institute, Oslo, Norway, pp. 327–349.
Brown, G. J., Cousins, T., Griffith, B. and Augenstein, D. R. (2009a) Comparison of multipath ultrasonic meter calibration data from two liquid hydrocarbon facilities and one water facility. 27th International North Sea Flow Measurement Workshop, Tonsberg, Norway, 20–23 October 2009, pp. 325–340.
Brown, G. J., Cousins, T., Augenstein, D. A. and Estrada, H. (2009b) A multipath ultrasonic meter with reducing nozzle for improved performance in the laminar/turbulent transition region. 27th International North Sea Flow Measurement Workshop, Tonsberg, Norway, 20–23 October 2009, pp. 361–385.
Bruschi, P., Nizza, N. and Piotto, M. (2006) Measurement and modelling of pulsed mode flow meter for liquids based on a single chip probe. Sensors and Actuators, A: Physical, 132(1 SPEC. ISS): 188–194.
Buchanan, R. K. (2003) Non-invasive cryogenic flow measurement. Proceedings of the International Instrumentation Symposium, 49: 257–265.Google Scholar
Buckle, U., Durst, F., Howe, B. and Melling, A. (1992) Investigation of a floating element flowmeter. Flow Measurement and Instrumentation, 3: 215–225.Google Scholar
Buckle, U., Durst, F., Kochner, H. and Melling, A. (1995) Further investigation of a floating element flowmeter. Flow Measurement and Instrumentation, 6: 75–78.Google Scholar
Bucknell, R. L. (1963) Calibration systems and turbine type flow transducers for cryogenic flow measurements. Advances in cryogenic Engineering, Plenum Press, New York, USA, 8: 360–370.
Buhidma, A. and Pal, R. (1996) Flow measurement of two-phase oil-in-water emulsions using wedge meters and segmental orifice meters. Chemical Engineering Journal, 63(1): 59–64.Google Scholar
Buonanno, G. (2000) On the field characterization of static domestic gas flowmeters. Measurement: Journal of the International Measurement Confederation, 27: 277–285.Google Scholar
Butterworth, D. and Hewitt, G. F. (1977) Two-phase flow and heat transfer. Harwell Series, Oxford University Press.
Buttle, R. S. and Kimpton, A. (1989) ESKOM's flow calibration facility. FLOMEKO 5th Internaitonal Conference on Flow Measurement: 1–10.
Caetano, E., Pinheiro, J. A. and Moreira, C. C. (1997) MMS 1200: cooperation on a subsea mutliphase flowmeter application. Offshore Technology Conference, Houston, TX, USA, 4:115–123.
Caetano, E., Pinheiro, J. A., da Costa e Silva, C. B., Kuchpil, C. and Dykesteen, E. (2000) Subsea multiphase flowmetering offshore Brazil. FLOMEKO'2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper D5.
Cai, S., Toral, H., Sinta, D. and Tajak, M. (2004) Experience in field tuning and operation of a multiphase meter based on neural net characterization of flow conditions. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Cairney, W. D. (1991) Typical flow measurement problems and their solution in the electricity supply industry. Journal of Flow Measurement and Instrumentation, 2: 217–224.Google Scholar
Calamante, F., Thomas, D. L., Pell, G. S., Wiersma, J. and Turner, R. (1999) Measuring cerebral blood flow using magnetic resonance imaging techniques. Journal of Cerebral Blood Flow & Metabolism, 19: 701–735.Google Scholar
Calcatelli, A., Raiteri, G. and Rumiano, G. (2003) The IMGC-CNR flowmeter for automatic measurements of low-range gas flows. Measurement: Journal of the International Measurement Confederation, 34(2): 121–132.
Calogirou, A., Boekhoven, J. and Henkes, R. A. W. M. (2001) Effect of wall roughness changes on ultrasonic gas flowmeters. Journal of Flow Measurement and Instrumentation, 12(3): 219–229.Google Scholar
Campion, P. J., Burns, J. E. and Williams, A. (1973) A code of practice for the statement of accuracy. London: HMSO.
Carlander, C. and Delsing, J. (2000) Installation effects on an ultrasonic flowmeter with implications for self diagnostics. Journal of Flow Measurement and Instrumentation, 11(2): 109–122.Google Scholar
Caron, R. W. (1995) Use of sonic nozzles in a manufacturing environment. Proceedings of the Int Instrumentation Symposium, ISA: 543–558.
Caron, R. W. (2001) Realistic gas flow measurement traceability. Proceedings of the International Instrumentation Symposium 47: 477–491.Google Scholar
Caron, R. W., Britton, C. L., Connolly, T., Hodges, C. and Kegel, T. (2002) A novel primary flow standard for compressible flow calibration: initial testing and calibration. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Carpenter, B. (1990) Choose the right material for mass flow meters. Chemical Engineering Progress, 86, No. 10: 55–60.Google Scholar
Carter, R. M., Yan, Y. and Cameron, S. D. (2005) On-line measurement of particle size distribution and mass flow rate of particles in a pneumatic suspension using combined imaging and electrostatic sensors. Flow Measurement and Instrumentation, 16(5): 309–314.Google Scholar
Cascetta, F. (1994) Application of a portable clamp-on ultrasonic flowmeter in the water industry. Journal of Flow Measurement and Instrumentation, 5: 191–194.Google Scholar
Cascetta, F. (1996) Effect of fluid pressure on Coriolis mass flowmeter's performance. ISA Transactions, 35: 365–370.Google Scholar
Cascetta, F. and Vigo, P. (1988) Flowmeters – a comprehensive survey and guide to selection. ISA Publ, Research Triangle Park, NC, USA.
Cascetta, F., della Valle, S., Guido, A. R. and Vigo, P. (1989a) A new type of Coriolis acceleration mass flowmeter. Proc IMEKO XI, Houston: 511–521.
Cascetta, F., della Valle, S., Guido, A. R. and Vigo, P. (1989b) A Coriolis mass flowmeter based on a new type of elastic suspension. Measurement, 7: 182–191.Google Scholar
Cascetta, F., Cignolo, G., Goria, R., Martini, G., Rivetta, A. and Vigo, P. (1992) Experimental intercomparison of Coriolis mass flowmeters. Trans Institute of Measurement & Control, 14: 99–107. (Also International Conference on Flow Measurement of Commercially Important Fluids, IBC Technical Services Ltd, London, Feb/Mar 1990.)Google Scholar
Cascetta, F., Palombo, A. and Scalabrini, G. (2003) Water flow measurement in large bore pipes: An experimental comparison between two different types of insertion flowmeters. ISA Transactions, 42(2): 171–179.Google Scholar
Casperson, C. (1975) The vortex flowmeter. Conference on Fluid Flow Measurement in the Mid 1970's, National Engineering Laboratory, Glasgow, Scotland: Paper C-1.
Casperson, C. (1993) A new flowmeter for measurement of gas flow at very low rates. FLOMEKO'93 Proceedings of the 6th International Conference on Flow Measurement, Korea: 306–312.
Catherine, L. (2002) Dynamic measurement of volumes in hydrocarbons pipelines . 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Cazin, J., Couput, J-P., Dudézert, C., Escande, J., Gajan, P., Lepeau, A. and Strzelecki, A. (2005) Lessons from wet gas flow metering systems using differential measurement devices: testing and flow modelling results. 23rd North Sea Flow Metering Workshop 2005, Paper 12, pp. 185–197.
Cha, J-E., Ahn, Y-C. and Kim, M-H. (2001) Flow measurement with an electromagnetic flowmeter in two-phase bubbly and slug flow regimes. Flow Measurement and Instrumentation, 12(5–6): 329–339.Google Scholar
Cha, J-E., Ahn, Y-C., Seo, K-W., Nam, H-Y., Choi, J-H. and Kim, M-H. (2003a) An experimental study on the characteristics of electromagnetic flowmeters in the liquid metal two-phase flow. Flow Measurement and Instrumentation, 14(4–5): 201–209.Google Scholar
Cha, J-E., Ahn, Y-C., Seo, K-W., Nam, H. Y., Choi, J. H. and Kim, M. H. (2003b) The performance of electromagnetic flowmeters in a liquid metal two-phase flow (F34). Journal of Nuclear Science and Technology, 40(10): 744–753.Google Scholar
Chahine, K. (2005) Comparison of low pressure gas flow standards. Flomeko 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 8.3.
Chahine, K. C. and Ballico, M. (2010) Assessment of reproducibility and linearity of the NMIA bell prover using a high flowrate sonic nozzle array. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A1-2.
Chambers, J. (1994) The EMC test house – before and after. Engineering, May 1994: 39–42.
Chanaud, R. C. (1965) Observations of oscillatory motion in certain swirling flows. Journal of Fluid Mechanics, 21: 111–127.Google Scholar
Chapman, N. R. and Etheridge, D. W. (1993) A step change in domestic metering technology from leather diaphragms to ultrasonics. Flow Measurement for the Utilities, Amsterdam, The Netherlands.
Chateau, F. (1991) Mass delivery meters using the Coriolis effect for batching hydrocarbon binders. Bulletin de Liaison des Laboratoires des Ponts et Chaussees, No. 175: 13–19.
Cheesewright, R. and Clark, C. (1998) The effect of flow pulsations on Coriolis mass flow meters. Journal of Fluids and Structures, 12: 1025–1039.Google Scholar
Cheesewright, R. and Clark, C. (2002) Experimental investigation of the influence of external vibrations on Coriolis mass flow meters. American Society of Mechanical Engineers, Applied Mechanics Division, AMD, 253(2): 1109–1117.Google Scholar
Cheesewright, R. and Shaw, S. (2006) Uncertainties associated with finite element modelling of Coriolis mass flow meters. Flow Measurement and Instrumentation, 17(6): 335–347.Google Scholar
Cheesewright, R. and Tombs, M. S. (2006) Editorial. Flow Measurement and Instrumentation, 17(6): 315–316.Google Scholar
Cheesewright, R., Atkinson, K. N., Clark, C., ter Horst, G. J. P., Mottram, R. C. and Viljeer, J. (1996) Field tests of correction procedures for turbine flowmeters in pulsatile flows. Journal of Flow Measurement and Instrumentation, 7: 7–17.Google Scholar
Cheesewright, R., Bisset, D. and Clark, C. (1998) Factors which influence the variability of turbine flowmeter signal characteristics. Journal of Flow Measurement and Instrumentation, 9: 83–89.Google Scholar
Cheesewright, R., Clark, C. and Bisset, D. (1999) Understanding the experimental response of Coriolis mass flowmeters to flow pulsations. Journal of Flow Measurement and Instrumentation, 10: 207–215.Google Scholar
Cheesewright, R., Clark, C. and Bisset, D. (2000) The identification of external factors which influence the calibration of Coriolis mass flowmeters. Journal of Flow Measurement and Instrumentation, 11: 1–10.Google Scholar
Cheesewright, R., Belhadj, A. and Clark, C. (2003a) Effect of mechanical vibrations on Coriolis mass flow meters. Journal of Dynamic Systems, Measurement and Control, Transactions of the ASME, 125(1): 103–113.Google Scholar
Cheesewright, R., Clark, C., Belhadj, A. and Hou, Y. Y. (2003b) The dynamic response of Coriolis mass flow meters. Journal of Fluids and Structures, 18(2): 165–178.Google Scholar
Chen, J., Karras, M., Tahkola, E. and Tombery, J. (1993) Flow measurement of medium consistency pulp suspension by cross-correlation flowmeter. FLOMEKO '93 Proceedings of the 6th International Conference on Flow Measurement, Korea: 506–508.
Chen, J.-L., Lin, J.-W., Chen, P., Wei, C.-Y. and Huang, Y.-C. (2010) Numerical simulation on the flow field of a vortex flowmeter with various upstream conditions. 15th Flow Measurement Conference (FLOMEKO), October 13–15, 2010, Taipei, Taiwan, Paper B2-5.
Chesnoy, A. B. (1993) Sonic nozzles meter natural gas at K-Lab. Journal of Flow Measurement and Instrumentation, 4: 73–76.Google Scholar
Cheung, W.-S., Kwon, H.-S., Park, K.-A. and Paik, J.-S. (2001) Acoustic flowmeter for the measurement of the mean flow velocity in pipes. Journal of the Acoustical Society of America, 110(5 I): 2308–2314.Google Scholar
Chien, S.-F. and Schrodt, J. L. G. (1995) Determination of steam quality and flow rate using pressure data from an orifice meter and a critical flowmeter. SPE Production & Facilities, 10(2): 76–81.Google Scholar
Chisholm, D. (1967) Flow of incompressible two-phase mixtures through sharp-edged orifices. Journal of Mechanical Engineering Science, 9: 72–78.Google Scholar
Chisholm, D. (1977) Two-phase flow through sharp-edged orifices. Journal of Mechanical Engineering Science, 19: 128–130.Google Scholar
Chisholm, D. and Leishman, J. M. (1969) Metering of wet steam. Chemical and Process Engineering, 50: 103–106.Google Scholar
Chisholm, D. and Watson, G. C. (1966) The flow of steam/water mixtures through sharp-edged orifices. NEL Report No 213, East Kilbride, Glasgow.
Choi, H. M., Park, K.-A., Oh, Y. K. and Choi, Y. M. (2009) Improvement and uncertainty evaluation of mercury sealed piston prover using laser interferometer. Journal of Flow Measurement and Instrumentation, 20(4–5): 200–205.
Choi, H. M. (2010) Uncertainty evaluation procedure and intercomparison of bell provers as a calibration system for gas flow meters. Journal of Flow Measurement and Instrumentation, 21(4): 488–496.
Choi, Y. M., Park, K. A. and Park, S. O. (1997) Interference effect between sonic nozzles. Journal of Flow Measurement and Instrumentation, 8(2): 113–119.Google Scholar
Choi, Y. M., Park, K. A., Park, J. T., Choi, H. M. and Park, S. O. (1999) Interference effects of three sonic nozzles of different throat diameters in the same meter tube. Journal of Flow Measurement and Instrumentation, 10: 175–181.Google Scholar
Christensen, T. A. and Willatzen, M. (2010) Investigating the effect of magnetic pipes connected to electromagnetic flowmeters using experimentally validated finite element models. Journal of Flow Measurement and Instrumentation, 21(1): 62–69.Google Scholar
Chun, S., Yoon, B.-R., Kang, W. and Kwon, H.-S. (2013) Accuracy enhancement of a combined V/Z clamp-on ultrasonic flow meter. FLOMEKO 2013, 16th International Flow Measurement Conference, Paris, France.
Chung, J., Grigoropoulos, C. P. and Greif, R. (2003) Infrared thermal velocimetry for nonintrusive flow measurement in silicon microfluidic devices. Review of Scientific Instruments, 74(5): 2911–2917.
Chunhui Li, C. and Johnson, A. (2010) Bilateral comparison confirms NIM's and NIST's gas flow capabilities. 15th International Flow Measurement Conference FLOMEKO 2010, Taiwan, Paper A1-1.
Cignolo, G., Alasia, F., Capelli, A., Goria, R. and La Piana, G. (2002) A primary standard piston prover for measurement of very small gas flows. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Clarijs, M. C., Bom, V. R., Van Eijk, C. W. E., Kolar, Z. I. and Scheers, L. M. (2003) X-ray spectrum generation for a multiphase flow meter. IEEE Transactions on Nuclear Science, 50 III(4): 713–717.Google Scholar
Clark, C. (1992) The measurement of dynamic differential pressure with reference to the determination of pulsating flows using DP devices. Journal of Flow Measurement and Instrumentation, 3: 145–150.Google Scholar
Clark, C. and Cheesewright, R. (2003a) Coriolis flow meters/the potential for outstanding dynamic performance. Measurement and Control, 36(9): 275–277+281.Google Scholar
Clark, C. and Cheesewright, R. (2003b) The influence upon Coriolis mass flow meters of external vibrations at selected frequencies. Flow Measurement and Instrumentation, 14(1–2): 33–42.
Clark, C. and Cheesewright, R. (2006) Experimental determination of the dynamic response of Coriolis mass flow meters. Flow Measurement and Instrumentation, 17(1): 39–47.Google Scholar
Clark, C., Cheesewright, R. and Hou, Y. Y. (2003) The dynamic response of Coriolis flowmeters. IEE Computing and Control Engineering, 14(4): 37.Google Scholar
Clark, C., Wang, S. and Cheesewright, R. (2006a) The dynamic performance of a micro-machined Coriolis flow meter. 2006 NSTI Nanotechnology Conference and Trade Show – NSTI Nanotech 2006 Technical Proceedings, 3: 336–339.Google Scholar
Clark, C., Wang, S. and Cheesewright, R. (2006b) The performance characteristics of a micro-machined Coriolis flow meter: An evaluation by simulation. Flow Measurement and Instrumentation, 17(6): 325–333.Google Scholar
Clark, C., Zamora, M., Cheesewright, R. and Henry, M. (2006c) The dynamic performance of a new ultra-fast response Coriolis flow meter. Flow Measurement and Instrumentation, 17(6): 391–398.Google Scholar
Clarke, D. W. (1998) Non-linear control of the oscillation amplitude of a Coriolis mass-flowmeter. European Journal of Control, 4: 196–207.Google Scholar
Clarke, D. W. and Ghaoud, T. (2002) Validation of vortex flowmeters. Computing and Control Engineering Journal, 13(5): 237–241.Google Scholar
Clarke, D. W. and Ghaoud, T. (2003) A dual phase-locked loop for vortex flow metering. Flow Measurement and Instrumentation, 14(1–2): 1–11.Google Scholar
Clarke, D. W. and Hemp, J. (2009) Eddy-current effects in an electromagnetic flowmeter. Flow Measurement and Instrumentation, 20(1): 22–37.Google Scholar
Clayton, C. G., Ball, A. M., Clark, W. E. and Spencer, E. A. (1962a) The accurate measurement of turbulent flow in pipes – using radioactive isotopes – the isotope dilution method. Proc. Symp. on Flow Measurement in Closed Conduits, HMSO, 2: Paper E-3.
Clayton, C. G., Clark, W. E. and Ball, A. M. (1962b) The accurate measurement of turbulent flow in pipes – using radioactive isotopes – using the isotope velocity method and the effect of some restriction on optimum operation. Proc. Symp. on Flow Measurement in Closed Conduits, HMSO, 2: Paper E-4.
Cloy, J. K. (2002) Ultrasonic, transit time flow measurement technology. Proceedings of the Annual Symposium on Instrumentation for the Process Industries, 57: 235.Google Scholar
Cobu, T., Berg, R. F., Wright, J. D. and Moldover, M. R. (2010) Modeling Laminar Flow Meters for Process Gases. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A2-1.
Cochran, T. B., Feiveson, H. A., Patterson, W., Pshakin, G., Ramana, M. V., Schneider, M., Suzuki, T. and von Hippel, F. (2010) Fast breeder reactor programs: history and status. A research report of the International Panel on Fissile Materials February 2010.
Cole, J. H. (1985) Drag turbine mass flowmeter development . Flow, Its Measurement and Control in Science and Industry, ISA Conf, St Louis, USA, 2: 441–451.
Cole, K. D. (2006) Flush-mounted steady-periodic heated film with application to fluid-flow measurement . American Society of Mechanical Engineers, Heat Transfer Division, (Publication) HTD, International Mechanical Engineering Congress and Exposition, IMECE2006 – Heat Transfer, Chicago, IL, United States.
Coleman, H. W. and Steele, W. G. (1999) Experimentation and uncertainty analysis. 2nd ed. Wiley Inter Science.
Coleman, M. C. (1956) Variable area flow meters. Transactions of the Institution of Chemical Engineers, 34: 339.Google Scholar
Collings, A. F., Bignell, N., Hews Taylor, K. J. and Marting, B. J. (1993) Ultrasonic metering of gas flows . Proceedings of the Ultrasonic International Conference, Vienna, Austria, Butterworth Heinemann: 205–208.
Collins, D. B. and Gacesa, M. (1970) Measurement of steam quality in two-phase up flow with Venturi meters. ASME Paper No 70-FE-6.
Collis, D. C. and Williams, M. J. (1959) Two-dimensional convection from heated wires at low Reynolds numbers. Journal of Fluid Mechanics, 6: 357.Google Scholar
Conrad, F. and Trostmann, E. (1981) A servo controlled volume rate flowmeter. BHRA Int. Conf. on Advances in Flow Measurement Techniques, Warwick, UK: Paper H3.
Cook, C. E. and Bernfeld, , (1967) Radar signals. Academic Press, New York.
Cooley, C., Couput, J.-P., Letton, C. and Hall, J. (2003) Wet Gas allocation on the canyon express project. 21st North Sea Flow Metering Workshop 2003, Paper 7.
Corneliussen, S. co-ordinated by Dahl, E. (2005) Handbook of multiphase flow metering 3rd Revision. Norwegian Society for oil and gas measurement & The Norwegian Society of Chartered Technical and Scientific Professionals ISBN 82-91341-89-3.
Coull, C. J. and Barton, N. A. (2002) Investigation of the installation effect on ultrasonic flowmeters and evaluation of computational fluid dynamics prediction methods. 20th North Sea Flow Measurement Workshop, 22–25 October 2002, St Andrews, Scotland, Paper 6.4
Coull, C. J. and Boam, D. (2002) In-Service performance of ultrasonic flowmeters—Investigation of installation effect, Report No. 2002/55, National Engineering Laboratory, 2002.
Coull, C. and Miller, G. (2005) Multiphase measurement using ultrasonic technology – testing a conceptual design. Flomeko 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 3.1.
Coulthard, J. and Yan, Y. (1993a) Vortex wake transit time measurements for flow metering. Journal of Flow Measurement & Instrumentation, 4: 269–272.Google Scholar
Coulthard, J. and Yan, Y. (1993b) Comparisons of different bluff bodies in vortex wake transit time measurements. Journal of Flow Measurement & Instrumentation, 4: 273–276.Google Scholar
Cousins, T. (1971) The performance of long bore orifices at low Reynolds numbers. Modern Developments in Flow Measurement, Paper 4.1: 160–179.Google Scholar
Cousins, T. (1975) An experimental investigation into the design parameters of the Dall tube. Conference on Fluid Flow Measurement in the Mid-1970s, National Engineering Laboratory, Glasgow, Scotland: Paper J2.
Cousins, T. (1977) Vortex meters. Transducer 77 Conference.
Cousins, T. et al. (1973) A linear and accurate flowmeter using vortex shedding. Symposium Power Fluidics for Process Control, University of Surrey, Guildford, England: 45–56.
Cousins, T. and Hayward, A. T. J. (1993) Development of the T-ring vortex meter. Journal of Flow Measurement & Instrumentation, 4: 197–204.
Cousins, T., Hayward, A. T. J. and Scott, R. (1989) Design and performance of a new vortex shedding flowmeter. FLOMEKO '89 Proceedings of the 5th International Conference on Flow Measurement, Dusseldorf, Germany: 151–167.
Cousins, T., Augenstein, D. and Eagle, S. (2005) The effect of water in oil on the performance of a four path chordal ultrasonic flow meter in horizontal flow lines. 23rd North Sea Flow Metering Workshop 2005, Paper 14, pp. 209–223.
Cowley, M. D. (1965) Flowmetering by a motion-induced magnetic field. Journal of Scientific Instruments, 42: 406–409.Google Scholar
Cox, T. J. and Wyatt, D. G. (1984) An electromagnetic flowmeter with insulated electrodes of large surface area. Journal of Physics E: Scientific Instruments, 17: 488–503.Google Scholar
Crainic, M. S., Cornel, M. and Ilie, D. (2000) Ferrofluids flow transducer for liquids. Journal of Flow Measurement & Instrumentation, 11(2): 101–108.Google Scholar
Cramer, A., Zhang, C. and Eckert, S. (2004) Local flow structures in liquid metals measured by ultrasonic Doppler velocimetry. Flow Measurement and Instrumentation, 15: 145–153.Google Scholar
Crawshaw, J. and Chambers, J. (1984) A concise course in A-level statistics. Stanley Thornes (Publishers) Ltd.
Cristancho, D. E., Coy, L. A. Hall, K. R. and Iglesias-Silva, G. A. (2010) An alternative formulation of the standard orifice equation for natural gas. Journal of Flow Measurement and Instrumentation, 21(3): 299–301.Google Scholar
Cruz-Maya, J. A., Sánchez-Silva, F. and Quinto-Diez, P. (2006) A new correlation to determine the discharge coefficient of a critical Venturi nozzle with turbulent boundary layer. Journal of Flow Measurement and Instrumentation, 17(5): 258–266.Google Scholar
Cui, L., (2010) A kind of New Calibration Method for the Volume of Bell Prover….15th Flow Measurement Conference (FLOMEKO), October 13–15, 2010 Taipei, Taiwan, Paper A1-4.
Cunningham, T. J. (2009) An in-situ verification technology for Coriolis flowmeters. 7th ISSFM, Alaska, USA.
Cunningham, T. J. and Hensley, D. P. (2001) Using IMAT and Matlab for Coriolis flowmeter design . Proceedings of the International Modal Analysis Conference (IMAC), Kissimmee, USA, 1: 165–71.
Cunningham, W. J. and Astami, K. (1993) The effect of ultrasonic frequency on the accuracy of gas flowmeters. Measurement Science and Technology, 4: 1476–1478.Google Scholar
Cushing, V. (1958) Induction flowmeter (for use with dielectrics). Review of Scientific Instruments, 29: 692.Google Scholar
Cushing, V.(1965) Electromagnetic flowmeter. Review of Scientific Instruments, 36: 1142.Google Scholar
Cushing, V.(1971) Electromagnetic flowmeters. Symposium on Flow – Its Measurement and Control in Science and Industry, Pittsburgh, PA, Paper 2-4-38.
Cushing, V.(2001) Electromagnetic flowmeter for all fluids. ISA TECH/EXPO Technology Update Conference Proceedings, 416: 309–319.Google Scholar
Cushing, V. (2002) Electromagnetic flowmeter for insulating liquids. Conference Record – IEEE Instrumentation and Measurement Technology Conference, 1: 103–108.Google Scholar
Cutler, G. D. (September 1982) Averaging Pitot-type primaries. Measurement & Control, 15: 436–437.Google Scholar
Dahlström, M. J. (2000) Effortless oil ultrasonic fiscal meter operation: Krohne Altosonic-V, with master meter approach. Vignis-Snorre Crossover and the Snorre B Export Station . North Sea Flow Measurement Workshop, National Engineering Laboratory, East Kilbride, Scotland.
Dahlström, M. J. (2003) Flare Meter Monitoring Method, and Flare Meter High Velocity Extender Experience from Snorre TLP high pressure flare estimator pilot. 21st North Sea Flow Metering Workshop 2003, Paper 27.
Dakić, B. M., Bajić, J. S., Stupar, D. Z., Slankamenac, M. P. and Živanov, M. B. (2013) A novel fiber-optic mass flow sensor. Key Engineering Materials, 543: 231–234.
Dall, H. E. (1962) Flow tubes and non-standard devices for flow measurement with some coefficient considerations. Proceedings of a Symposium on Flow Measurement in Closed Conduits, HMSO, Edinburgh: Paper D-1: 385–394.
Dane, H. J. and Wilsack, R. (1999) Upstream pipe wall roughness influence on ultrasonic flow measurement. 17th North Sea Flow Measurement Workshop, Paper 9, pp. 106–116.
Danen, G. W. A. (ed.) (1985) Shell flowmeter engineering handbook. 2nd ed. McGraw Hill.
David, C. (2012) Evaluation of water flow measurement performance of portable ultrasonic flowmeter technology. International Symposium on Fluid Flow Measurement .Google Scholar
Davis, R. W. and Mattingly, G. B. (1997) Numerical modelling of turbulent flow through thin orifice plates . Symposium on Flow in Open Channels and Closed Conduits, Gaithersburg, USA.
Davis, R. W., Moore, E. F. and Purtell, L. P. (1984) A numerical-experimental study of confined flow around rectangular cylinders. Physics of Fluids, 27: 46–59.Google Scholar
Davis, T. C. E. (1990) Fiscal measurement and proving experience with Coriolis meters . North Sea Flow Measurement Workshop, National Engineering Laboratory, Scotland.
de Boer, G. and Lansing, J. (1997) Dry calibration of ultrasonic gas flow meters. North Sea Flow Measurement Workshop, Kristiansand, Norway: Paper 18.
De Boom, R. J. (1996) Flowmeter lifecycle costs, Advances in Instrumentation and Control, Chicago, 621–630.
de Carvalho, J. G. and Antunes, B. de C. (2000) Multi-phase flowmetering using twin helicoidal rotors – the ‘multi-stream’ meter. FLOMEKO'2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper B4.
de Jager, P. A., Hemminga, M. A. and Sonneveld, A. (1978) Novel method for determination of flow velocities with pulsed nuclear magnetic resonance. Review of Scientific Instruments, 49: 1217.Google Scholar
de Jong, J. (1978) Comparison of some 500 mm diameter flowmeters. FLOMEKO 1978 – Proceedings of the Conference on Flow Measurement of Fluids, Groningen, The Netherlands: 565.
de Jong, S. and van der Kam, P. M. A. (1993) High pressure recalibration of turbine meters. FLOMEKO '93 Proceedings of the 6th International Conference on Flow Measurement: 121–128.
de Kraker, F. (1989) The performance of a Coriolis meter when used to measure density . Mass Flow Measurement Direct and Indirect, London, England.
de Leeuw, H. (1994) Wet gas flow measurement by means of a Venturi meter and a tracer technique . North Sea Flow Measurement Workshop, Peebles, Scotland.
de Leeuw, H. and Dybdahl, B. (2002) Field installation of smartvent wet gas flow meters at Bintang, Malaysia. 20th North Sea Flow Measurement Workshop, 22–25 October 2002, St Andrews, Scotland, Paper 4.3.
de Leeuw, H.R. (1997) Liquid correction of Venturi meter readings in wet gas flow. North Sea Flow Measurement Workshop Kristiansand, Norway: Paper 21.
de Leeuw, R., Kamal, M. and Dybdahl, B. (2005) Operational Experience of Smartvent Wet Gas Metering in SE-Asia. 4th South East Asia Hydrocarbon Flow Measurement Workshop, 7–11 March 2005. http://www.gbv.de/dms/tib-ub-hannover/493689834.pdf
de Leeuw, R., Steven, R. and van Maanen, H. (2011) Venturi Meters and Wet Gas Flow. North Sea Flow Measurement Workshop, 25–28 October 2011, Page 1 of 23.
de Vries, H., Loogmann, L. L., van Dellen, K. and Broekgaarden, G. J. (1989) Ultrasonic gas flow measurements with reflection mode in underground pipelines. FLOMEKO '89 Proceedings of the 5th International Conference on Flow Measurement, Dusseldorf, Germany: 325–332.
Deacon, J. E. (1983) Electromagnetic flowmeter installation tests. IMEKO Budapest, Paper E3: 85–91.
Dean, R. W. (1988a) Field experience using Coriolis mass meters II . North Sea Metering Workshop, National Engineering Laboratory, East Kilbride, Scotland.
Dean, R. W. (1988b) Advantages of mass measurement for petroleum liquids. Petroleum Review, 42: 32–33.Google Scholar
Dean, T. L., Dowty, E. L. and Jiskoot, M. A. (1990a) The design manufacture and testing of the Texaco subsea three phase metering system. North Sea Flow Measurement Workshop, National Engineering Laboratory, 23–25 October.
Dean, T. L., Dowty, E. L. and Jiskoot, R. J. J. (1990b) The development of a subsea three phase metering system. European Oil and Gas Conference, Palermo, October.
Decker, M. M. (1960) The gyroscopic mass flowmeter. Engineers Digest, 21(7).Google Scholar
Decker, H., Leenhoven, T. and Danen, H. (2001) Multibeam ultrasonic flowmeter-for custody transfer at a tank farm: a long term trial project. ISA TECH/EXPO Technology Update Conference Proceedings, 413 I:815–25.Google Scholar
Del Grosso, V. A. and Spurlock, E. M. (1957) The feasibility of using wholly external ultrasonics to measure fluid flow within thick walled metal pipes. NRL Report 4967.
Delajoud, P., Girard, M. and Blair, M. (2005) The implementation of toroidal throat Venturi nozzles to maximize precision in gas flow transfer standards. FLOMEKO 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 5.2.
Delenne, B., Mouton, G., Pritchard, M., Huppertz, M., Ciok, K., van den Heuvel, A., Folkestad, T., Vieth, D., Lezuan, F. and Marini, G. (2004) Evaluation of flow conditioners – ultrasonic meters combinations. 22nd North Sea Flow Metering Workshop 2004, Paper 3.2.
Deloughry, R., Young, M., Pickup, E. and Barratt, L. (2001) Variable density flowmeter for loading road tankers using process tomography. Proceedings of SPIE – The International Society for Optical Engineering, 4188: 273–283.Google Scholar
Delsing, J. (1991) The zero-flow performance of a sing-around ultrasonic flowmeter. Journal of Flow Measurement and Instrumentation, 2: 205–208.Google Scholar
Delsing, J. (2004) The prospect of self-diagnosing flow meters. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Delsing, J. (2006) Flow measurement facilities. Flow Measurement and Instrumentation, 17(3): 139.Google Scholar
Démolis, J., Escande, J., Gajan, P. and Strzelecki, A. (1998) The use of ultrasonic tomography to characterise internal flows in pipes. FLOMEKO '98 Proceedings of the 9th International Conference on Flow Measurement, Lund, Sweden, 369–373.
Deng, W., Jiang, S., Liu, R., Huang, L., Zhao, P., Lei, L. and Jin, K. (2010) Calibration and verification of MEMS mass flow meters for custody transfer. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A8-1.
Denison, A. B. and Spencer, M. P. (1956) Factors involved in intact vessel electromagnetic flow recording. Federation Proceedings, 15: 46.Google Scholar
Dijstelbergen, H. H. (1964) Rotameter dynamics. Chemical Engineering Science, 19: 853.Google Scholar
Dijstelbergen, H. H. (1970) The performance of a swirl meter. Journal of Physics E: Scientific Instruments, 3: 886–888.Google Scholar
Dijstelbergen, H. H. (1982) Gas meters. Developments in Flow Measurement – 1, Ed. R. W. W. Scott, Applied Science Publishers: Chapter 5.
Dijstelbergen, H. and Richards, R. (2012) A novel concept of an old idea: electronic twin turbine meters for custody transfer. 8th ISFFM.
Dijstelbergen, H. H. and van der Beek, M. P. (1998) A new reference meter for gasmeter calibrations. FLOMEKO '98 Proceedings of the 9th International Conference on Flow Measurement, Lund, Sweden, 37–42.
Dilthey, U., Scheller, W. and Brandenburg, A. (1996) Flow measuring systems for automated adhesive application. Welding & Cutting, 48(7): 137–138.Google Scholar
Dimaczek, G., Fassbinder, H-G., Emmel, A. and Kupfer, R. (1994) High-precision Coriolis mass flowmeter for bulk material two-phase flows. Journal of Flow Measurement and Instrumentation, 5: 295–202.Google Scholar
Dixey, M. (1993) Putting reliability at the centre of maintenance. Professional Engineering June 1993: 23–25.Google Scholar
Dobrowolski, B., Kabaciński, M. and Pospolita, J. (2005) A mathematical model of the self-averaging Pitot tube. Flow Measurement and Instrumentation, 16(4): 251–265.Google Scholar
Doihara, R., Shimada, T., Terao, Y. and Takamoto, M. (2004) Development of diverting system employing a rotating double wing method. 12th International Conference on Flow Measurement FLOMEKO, Guilin, China.
Doihara, R., Shimada, T., Terao, Y. and Takamoto, M. (2006) Development of weighing tank system employing rotating double wing diverter. Flow Measurement and Instrumentation, 17(3): 141–152.Google Scholar
Dominick, J., Durst, F., Raszillier, H. and Zeisel, H. (1987) A method to measure mass and volume flow rates of two-phase flows. International Journal ofMultiphase Flow, 13: 685–698.Google Scholar
Doney, B. (1999a) EMF flow measurement in partially filled pipes. Sensors (Peterborough, NH), 16(10): 65–66, 68.Google Scholar
Doney, B. (1999b) Electromagnetic flow measurement in partially filled pipes. Water/Engineering and Management, 146(11): 32–34.Google Scholar
Dong, F., Xu, Y. B., Xu, L. J., Hua, L. and Qiao, X. T. (2005) Application of dual-plane ERT system and cross-correlation technique to measure gas-liquid flows in vertical upward pipe. Flow Measurement and Instrumentation, 16(2–3): 191–197.
Dong, W. and Zong Hu, L. (2002) Gas-liquid two-phase flow measurement using ESM. Experimental Thermal and Fluid Science, 26(6–7): 827–832.Google Scholar
Dongwei, W. (2004) Technical reformation of gas flow primary standard with pVTt method. 12th International Conference on Flow Measurement FLOMEKO Guilin, China.
dos Reis, E. and GoldsteinJr., L. (2008) On the measurement of mass flow rate of horizontal two-phase flows in the proximity of the transition lines which separates two different flow patterns. Flow Measurement and Instrumentation, 19(5): 269–282.
Dou, J., Guo, J. and Gokulnath, R. (2005) Is it a MUST to add upstream devices for high GVF multiphase? 23rd North Sea Flow Metering Workshop 2005, Paper 19, pp. 289–303.
Drahm, W. (1998) New single straight tube Coriolis mass flowmeter without installation restrictions. FLOMEKO '98 Proceedings of the 9th International Conference on Flow Measurement, Lund, Sweden, 243–248.
Drahm, W. and Bjønnes, H. (2003) A Coriolis mass flowmeter with direct viscosity measurement. IEEE Computing and Control Engineering, 14(4): 42–43.Google Scholar
Drahm, W. and Staudt, W. (2004) Coriolis mass flowmeters: state of the art review and innovations. 12th International Conference on Flow Measurement FLOMEKO, Guilin, China.
Drahm, W., Reider, A., Wenger, A. and Koudal, O. (2002)Method and corresponding sensors for measuring mass flow rate. US Patent 6360614, 26 March 2002.
Drenthen, J. G. (1989) Device for determining the flow Velocity of a medium in a cylindrical conduit. US Patent 4,831,884.
Drenthen, J. (1996) Method and device for determining characteristics of the flow of a medium. US Patent 5,546,812.
Drenthen, J. G. and de Boer, G. (2001) The manufacturing of ultrasonic gas flow meters. Journal of Flow Measurement and Instrumentation, 12(2): 89–99.Google Scholar
Drenthen, J. G. and Huijsmans, F. J. J. (1993) Gassonic-400 & P Sonic & Q Sonic ultrasonic gas flow meters. FLOMEKO '93 Proceedings of the 6th International Conference on Flow Measurement, Korea: 285–298.
Drenthen, J. G., Kurth, M. van Kooster, J. and Vermeulen, M. (2009) Reducing installation effects on ultrasonic flow meters. 27th International North Sea Flow Measurement Workshop, Tonsberg, Norway, 20–23 October 2009, pp. 187–204.
Drenthen, J. G., Kurth, M. and Vermeulen, M. (2009) A novel design of a 12-chord ultrasonic gas flow meter. Canadian School of Hydrocarbon Measurement CSHM Calgary 4/2009 Paper 9030.
Drenthen, J. G., Vermeulen, M., Kurth, M. and den Hollander, H. (2010) Ultrasonic flow meter diagnostics and the impact of fouling. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A4-3.
Drenthen, J. G., Vermeulen, M., Kurth, M. and den Hollander, H. (2011) The detection of corrosion and fouling and the operational influence on ultrasonic flow meters using reflecting paths. North Sea Flow Metering Workshop.
Drysdale, A., Frederiksen, J. and Rasmussen, M. (2005) New on-site calibration technique for large flow meters using laser Doppler velocimetry. Flomeko 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 8.1.
DTI (1993) Product standards – electromagnetic compatibility. Department of Trade and Industry UK Regulations.
Dunn, Donald G., Hoge, K., Liolios, G. and Klein, M. (2003) Alkylation unit optimization using Coriolis mass flow meters. Proceedings of the Annual Symposium on Instrumentation for the Process Industries, pp. 15–21.
Durcan, L. P. (1998) Development of Baseline Stability in an Electromagnetic Flowmeter for Dielectric Liquids. Cranfield University Press.
Durst, F. and Raszillier, H. (1990) Flow in a rotating straight pipe, with a view on Coriolis mass flow meters. Journal of Fluids Engineering, Transactions of ASME, 112: 149–154.Google Scholar
Dyakowski, T. (1996) Process tomography applied to multi-phase flow measurement. Measurement Science and Technology, 7: 343–353.Google Scholar
Dykesteen, E. (1992) Multiphase metering. Chemical Engineering Research & Design, 70.1: 32–7.Google Scholar
Dykesteen, E. (2000) Multiphase meters offshore Malaysia. Journal of Offshore Technology, 8.Google Scholar
Dykesteen, E. (2001) Status and trends in technology and applications. Keynote paper 19th North Sea Flow Measurement Workshop, Kristiansand, Norway, 22–25 October 2001, Keynote paper. ISBN: 978-1-61567-868-6.
Dykesteen, E., Hallanger, A., Hammer, E., Samnoy, E. and Thorn, R. (1985) Non-intrusive three-component ratio measurement using an impedance sensor. Journal of Physics E: Scientific Instruments, 18: 1985.Google Scholar
Eccles, A., Green, N. and Porkess, R. (1993a) MEI structured mathematics – statistics 2. Hodder & Stoughton.
Eccles, A., Green, N., and Porkess, R. (1993b) MEI structured mathematics – statistics 3. Hodder & Stoughton.
Eide, J. M. (1991) Operational experience, compact prover as a portable calibration unit. Proceedings of the North Sea Flow Measurement Workshop, Norwegian Society of Chartered Engineers.
Eide, J. M. and Gwaspari, S. C. (1996) Comparison test and calibration of Coriolis meters. North Sea Flow Measurement Workshop, Peebles, Scotland.
Einhellig, R.F., Schmitt, C. and Fitzwater, J. (2002) Flow measurement opportunities using irrigation pipe elbows. Hydraulic Measurements and Experimental Methods, 1111–1118.Google Scholar
Elkins, C. J. and Alley, M. T. (2007) Magnetic resonance velocimetry: applications of magnetic resonance imaging in the measurement of fluid motion. Experiments in Fluids (2007) 43: 823–858.
Elliott, K. (2004) API's microprocessor based flowmeter testing programme. 22nd North Sea Flow Metering Workshop 2004, Paper 5.4.
Elperin, T., Fominykh, A. and Klochko, M. (2002) Performance of a Venturi meter in gas-liquid flow in the presence of dissolved gases. Flow Measurement and Instrumentation, 13(1–2): 13–16.Google Scholar
El-Wahed, A. K. and Sproston, J. L. (1991) The influence of shedder shape on the performance of the electrostatic vortex flowmeter. Journal of Flow Measurement & Instrumentation, 2: 169–179.Google Scholar
El-Wahed, A. K., Johnson, M. W. and Sproston, J. L. (1993) Numerical study of vortex shedding from different shaped bluff bodies. Journal of Flow Measurement & Instrumentation, 4: 233–240.Google Scholar
Endress, U., et al. (1989) Flow handbook. Reinach, Switzerland: Flowtec AG (English edition).
Endress+Hauser (2006) Flow handbook 3rd Edition. Endress+Hauser Flowtec AG.
Engel, R. (2002) Dynamic weighing – improvements in gravimetric liquid flowmeter calibration. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Engel, R. (2010) Water density determination in high-accuracy flowmeter calibration – measurement uncertainties and practical aspects. 15th Flow Measurement Conference (FLOMEKO), October 13–15, 2010 Taipei, Taiwan, Paper B3-1.
Engel, R. and Baade, H.-J. (2012) Water density determination in high-accuracy flowmeter calibration – measurement uncertainties and practical aspects. Flow Measurement and Instrumentation, 25: 40–53.Google Scholar
Engelbert, C., Scheulen, R. and Incontri, J. (2007) Successful flow measurement in varnish production. World Pumps, (488): 24–25.Google Scholar
Enoksson, P., Stemme, G. and Stemme, E. (1997) A silicon resonant sensor structure for Coriolis mass-flow measurements. Journal of Microelectromechanical Systems, 6(2): 119–125.Google Scholar
Enz, S. (2010) Effect of asymmetric actuator and detector position on Coriolis flowmeter and measured phase shift. Journal of Flow Measurement and Instrumentation, 21(4):497–503.Google Scholar
Enz, S., Thomsen, J. J. and Neumeyer, S. (2011) Experimental investigation of zero phase shift effects for Coriolis flowmeter due to pipe imperfections. Journal of Flow Measurement and Instrumentation, 22(1): 1–9.Google Scholar
Erdal, A. (1997) A numerical investigation of different parameters that affect the performance of a flow conditioner. Journal of Flow Measurement and Instrumentation, 8(2): 93–102.Google Scholar
Erdal, A. and Cabrol, J. F. (1991) Comparison of repeatability, reproducibility and linearity for turbine, Coriolis and ultrasonic meters tested at 100 bars on natural gas. Proceedings of the North Sea Flow Measurement Workshop, Norwegian Society of Chartered Engineers, October 22–24.Google Scholar
Erdal, A. and Andersson, H. I. (1997) Numerical aspects of flow computation through orifices. Journal of Flow Measurement and Instrumentation, 8: 27–37.Google Scholar
Erdal, A., Lindholm, D. and Thomassen, D. (1994) Development of a flow conditioner. North Sea Flow Measurement Workshop, Peebles, Scotland.
Eren, H. (1995) Particle concentration characteristics and density measurements of slurries using electromagnetic flowmeters. IEEE Transactions on Instrumentation and Measurement, 44, No. 3: 783–786.Google Scholar
Eren, H., Lowe, A. M. and Basharan, B. (2002) Processing ultrasonic signals to identify fluid contents in transit-time flowmeters. Conference Record – IEEE Instrumentation and Measurement Technology Conference, 2:1491–5.Google Scholar
Erickson, G. P. and Graber, J. C. (1983) Ultrasonic flowmeters for hydroelectric plants. Mechanical Engineering, November: 84–88.Google Scholar
Esbensen, K. H., Halstensen, M., Lied, T. T., Saudland, A., Svalestuen, J., de Silva, S. and Hope, B. (1998) Acoustic chemometrics — from noise to information. Chemometrics and Intelligent Laboratory Systems, 44: 61–76.Google Scholar
Esbensen, K. H., Hope, B., Lied, T. T., Halstensen, M., Gravermoen, T. and Sundberg, K. (1999) Acoustic chemometrics for fluid flow quantifications-II: a small constriction will go a long way. Journal of Chemometrics, 13: 209–236.Google Scholar
Espina, P. (2005) Results of the North American natural gas flow calibration laboratory comparison: CEESI – SwRI – TCC. Flomeko 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 2.3.
Espina, P. G. and Baumoel, D. (2003) Latest advances in ultrasonic flow measurement of natural gas using externally mounted, non-intrusive sensors. 21st North Sea Flow Metering Workshop 2003, Paper 13.
Estrada, H. (2002) The effect of in-service velocity profiles on flow measurement systems of several types . 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Estrada, H., Cousins, T. and Augenstein, D. (2004) Installation effects and diagnostic interpretation using the Caldon ultrasonic meter. 22nd North Sea Flow Metering Workshop 2004, Paper 4.1.
Evans, R. P. and Blotter, J. (2002) Mass Flow measurement using flow induced pipe vibration. Proceedings of the International Instrumentation Symposium, 48: 231–240.Google Scholar
Evans, R. P., Blotter, J. D. and Stephens, A. G. (2004) Flow rate measurements using flow-induced pipe vibration. Journal of Fluids Engineering, 126: 280–285.Google Scholar
Evans, R., Ifft, S. and Hodges, D. (2007) Wet gas performance of differential pressure flowmeters. 25th International North Sea Flow Measurement Workshop, Energy Institute, Oslo, Norway, 138–151.
Ewing, J. A. (1924–25) A ball-and-tube flowmeter. Proceedings of the Royal Society, 45: 308.
Fage, A. and Johansen, F. C. (1928) The structure of vortex sheets. Philosophical Magazine, 5.Google Scholar
Fahlenbock, T. D. (2005) Coriolis mass flow meter: high accuracy for high flow rates. Powder and Bulk Engineering, 19(9): 29–33.Google Scholar
Fairclough, A. M. (2000) Wet gas well testing. FLOMEKO'2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper D9.
Fakouhi, A. (1977) The influence of viscosity on turbine flow meter calibration curves. PhD thesis, University of Southampton.
Falcone, G., Hewitt, G. F., Alimonti, C. and Harrison, B. (2001) multiphase flow metering: current trends and future developments. SPE Annual Technical Conference and Exhibition, 30 September-3 October 2001, New Orleans, Louisiana.
Falcone, G., Hewitt, G. F., Alimonti, C. and Harrison, B. (2002) Multiphase flow metering: current trends and future developments. JPT, Journal of Petroleum Technology, 54(4): 77–84.Google Scholar
Falcone, G., Hewitt, G. F., Alimonti, C. and Harrison, B. (2005) Multiphase flow metering: 4 years on. 23rd North Sea Flow Metering Workshop 2005, Paper 18, pp. 277–288.
Falcone, G., Hewitt, G. F. and Alimonti, C. (2009) Multiphase flow metering: principles and applications. Developments in Petroleum Science, Volume 54, Elsevier Science ISBN: 0-444-52991-8. http://www.elsevier.com/wps/find/bookdescription.cws_ home/714238/description#description
Falvey, H. T. (1983) Effect of gradients on acoustic velocity meter. Journal of Hydraulic Engineering, 109: 1441–1453.Google Scholar
Fan, S. and Song, M. (2003) Analysis on response of straight tube Coriolis mass-flow meter under pulsating flow. Beijing Hangkong Hangtian Daxue Xuebao/Journal of Beijing University of Aeronautics and Astronautics, 29: 67–71 (in Chinese)Google Scholar
Fang, T., Xie, D. and Liang, G. (2008) Studies on the flow characteristic of fluidic flow meter. Yi Qi Yi Biao Xue Bao/Chinese Journal of Scientific Instrument, 29(SUPPL. 2): 617–620. (in Chinese)Google Scholar
Faraday, M. (1832) Experimental researches in electricity. Philosophical Transactions of the Royal Society, 15: 175–177.Google Scholar
Fathimani, A., Marko, P. E., , T., Tominaga, , , K., Hauser, E., Yee, F. and Malcolm, S. (2007) Power uprates through ultrasonic feed water flow measurement – CANDU-specific opportunities and challenges. Canadian Nuclear Society – 28th Annual Conference of the Canadian Nuclear Society and 31st CNS/CNA Student Conference 2007: “Embracing the Future: Canada's Nuclear Renewal and Growth”, Saint John, N.B., Canada, 995–1006.
Feng, C.-C., Lin, W.-T. and Yang, C.-T. (2010) Laminar flow element type flow meter with straight glass capillary. 15th Flow Measurement Conference (FLOMEKO), October 13–15, 2010 Taipei, Taiwan, Paper A2-5.
Fenwick, J. S. and Jepson, P. (1975) The problems and needs in large volume gas measurement. Transducer ’75 Conference.
Ferreira, V. C. S. (1988) Flow patterns inside a turbine type flowmeter. PhD thesis, Cranfield Institute of Technology, England.
Ferron, A.G. (1962) Velocity profile effects on the discharge coefficient of pressure differential meters. Journal of Basic Engineering, 85(3): 338–342.Google Scholar
Finlayson, A. J. (1992) Industrial review: selection of flowmeters for nuclear fuel processing. Journal of Flow Measurement and Instrumentation, 3(1): 3–8.Google Scholar
Finnof, C., Stainton, D., Saenz, C. P. and Smith, J. E. (1976) Apparatus and method for measuring fluid mass flow. British Patent 1,535,817.
Fischbacker, R. E. (1959) The ultrasonic flowmeter. Trans. Soc. Inst. Tech., 11: 114.Google Scholar
Fischer, C. (1994) Development of a metering system for total mass flow and compositional measurements of multiphase/multicomponent flows such as oil/water/air mixtures. Journal of Flow Measurement and Instrumentation, 5: 31–42.Google Scholar
Fischer, R. (1995) Calculation of the discharge characteristic of an orifice for gas-liquid annular-mist flow. International Journal of Multiphase Flow, 21.5: 817–835.Google Scholar
Fischer, S., Schmitt, P., Ensminger, D., Abda, F. and Pallares, A. (2008) A new velocity estimation method using spectral identification of noise. Flow Measurement and Instrumentation, 19(3–4): 197–203.Google Scholar
Fischer, S., Rebattet, C. and Dufour, D. (2013) Applicability of ultrasonic pulsed doppler for fast flow-metering. FLOMEKO 2013, 16th International Flow Measurement Conference, Paris.
Fish, D. J. (2007) The importance of discerning the impact of new measurement technology. 25th International North Sea Flow Measurement Workshop, Energy Institute, Oslo, Norway, 1–8.
Fletcher, S. I., Nicholson, I. G. and Smith, D. J. M. (2000) An investigation into the effects of installation on the performance of insertion flowmeters. Journal of Flow Measurement and Instrumentation, 11: 19–39.Google Scholar
Fling, W. A. and Whetstone, J. R. (1985) Development of basic orifice discharge coefficients. 64th Annual GPA Convention, Houston, Texas.
Folkestad, T. (2001) Testing a 12˝ Krohne 5-path Altosonic V ultrasonic liquid flow meter on Osenberg crude oil and on heavy crude oil. 19th North Sea Flow Measurement Workshop, Kristiansand, Norway, 22–25 October 2001, Paper 15.
Fosså, Ø., Stobie, G. and Wee, A. (2009) Successful implementation and use of multiphase meters. 27th International North Sea Flow Measurement Workshop, Tonsberg, Norway, 20–23 October 2009, pp. 107–130.
Fosse, S., Ullebust, B. and Ekerhovd, H. (2008) The importance of proper internal surface and alignment of upstream metering tubes, when metering light hydrocarbons with turbine meter. 26th International North Sea Flow Measurement Workshop, 21–24 October 2008, St Andrews, Scotland, Paper 1.1.
Frail, C. (2005) Clamp-on gas flow measurement using ultrasonic flow pattern recognition. Technical Papers of ISA, 459: 851–859.Google Scholar
Frank, R., Mazars, J. and Rique, R. (1977) Determination of mass flowrate and quality using a Venturi and turbine meter. Proceedings of the Institution of Mechanical Engineers, Part C, 200.Google Scholar
Franke, S., Büttner, L., Czaskre, J., Räbiger, D. and Eckert, S. (2010) Ultrasound Doppler system for two-dimensional flow mapping in liquid metals. Journal of Flow Measurement and Instrumentation, 21(3): 402–409.Google Scholar
Frankvoort, W. (1989) Results of the evaluation of the performance of mass flow meters using a prover loop. Mass Flow Measurement Direct and Indirect, Proc Int Conf Mass Flow Measurement, IBC Pbl, London, England.
Frantzen, K. H. and Dykesteen, E. (1990) Field experience with CMI multiphase fraction meter. North Sea Flow Measurement Workshop, National Engineering Laboratory, Scotland.
Fridjonsson, E. O., Stanwix, P. L. and Johns, M. L. (2014) Earth's field NMR flow meter: preliminary quantitative measurements. Journal of Magnetic Resonance, 245: 110–115.Google Scholar
Frøysa, K.-E. and Lunde, P. (2004) Mass and energy measurement of natural gas using ultrasonic flow meters. Recent results. Proc. of the 27th Scandinavian Symposium on Physical Acoustics, Norway, 25–28 January 2004.
Frøysa, K.-E. and Lunde, P. (2005) Density and calorific value measurement in natural gas using ultrasonic flow meters. 23rd North Sea Flow Metering Workshop 2005, Paper 5, pp. 45–67.
Frøysa, K.-E., Lunde, P. and Vestrheim, M. (2001) A ray theory approach to investigate the influence of flow velocity profiles on transit times in ultrasonic flow meters for gas and liquid. Proc. 19th International North Sea Flow Measurement Workshop, Kristiansand, Norway, 22–25 October 2001, Paper 21.
Frøysa, K.-E., Lunde, P. Paulsen, A. and Jacobsen, E. (2006a) Density and calorific value measurement in natural gas using ultrasonic flow meters. Results from testing on various North Sea gas field data. 24th International North Sea Flow Measurement Workshop, 24–27 October 2006.
Frøysa, K.-E., Lunde, P., Hallanger, A. and Sand, I. Ø. (2006b) Mass and energy measurement of natural gas using ultrasonic flow meters. Results from testing on various North Sea gas field data. Proc. of the 29th Scandinavian Symposium on Physical Acoustics, Norway, 29 January–1st February 2006.
Frøysa, K.-E., Vågenes, A. L. H., Sørli, B. and Jørgenvik, H. (2007) Uncertainty analysis of emissions from the Statoil Mongstad oil refinery. 25th International North Sea Flow Measurement Workshop, Energy Institute, Oslo, Norway, pp. 386–400.
Frøysa, K.-E., Hallanger, A. and Paulsen, A. (2008) Installation effects on the Easington ultrasonic fiscal metering station. 26th International North Sea Flow Measurement Workshop, 21–24 October 2008, St Andrews, Scotland, Paper 6.3.
Frøystein, T., Kvandal, H. and Aakre, H. (2005) Dual energy gamma tomography system for high pressure multiphase flow. Flow Measurement and Instrumentation, 16(2–3): 99–112.Google Scholar
Fu, X. and Yang, H. (2001) Study on hydrodynamic vibration in dual bluff body vortex flowmeter. Chinese Journal of Chemical Engineering, 9(2): 123–128.Google Scholar
Fueki, M., Tanaka, Y., Nishi, T. and Yamazaki, D. (1998) Development of a multiphase flowmeter without radioactive source. 30th Offshore Technology Conference, Houston, TX, USA: 463–470.
Fulton, J., Hammer, E. A. and Haugs, A. (1987) Deflection of orifice plates at high differential pressure . North Sea Flow Metering Workshop, Stavanger.
Funck, B. and Mitzkus, A. (1996). Acoustic transfer function of the clamp-on flowmeter. IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control, 43(4): 569–575.Google Scholar
Furness, R. A. (1982) Turbine flowmeters. Developments in Flow Measurement – 1, Ed. R. W. W. Scott, Applied Science Publishers: 171–207.
Furness, R. A. (1989) The application, standardisation and future use of Coriolis type mass meters in the oil and process industries . Mass Flow Measurement Direct and Indirect, Proc Int Conf Mass Flow Measurement, IBC Pbl, London, England.
Furness, R. A. (1991) BS 7405: The principles of flowmeter selection. Journal of Flow Measurement and Instrumentation, 2(4): 233–242.Google Scholar
Furness, R. A. (2001) Review of “Flow measurement handbook” by R. C. Baker. Journal of Flow Measurement and Instrumentation, 12(3): 233–234.Google Scholar
Furness, R. A. (2003) Assessing leakage in water supply networks using flowmeters. Water Engineering and Management, 150(3): 26-29-36.Google Scholar
Furness, R. A. and Jelffs, P. A. M. (1991) Flowmeters – their role in loss reduction in refining. Petroleum Review, 45: 544–549.Google Scholar
Furuichi, N., Sato, H., Terao, Y. and Takamoto, M. (2009) A new calibration facility for water flowrate at high Reynolds number. Flow Measurement and Instrumentation, 20(1): 38–47.Google Scholar
Fyrippi, I., Owen, I. and Escudier, M. P. (2004) Flowmetering of non-Newtonian liquids. Flow Measurement and Instrumentation, 15(3): 131–138.Google Scholar
Gadshiev, E. M., Grigor'yants, S. E., Gusein-zade, K. P. and Smirnov, V. P. (1988) Metrological support to hot-water meters in use and during production. Measurement Techniques, 151–154.Google Scholar
Gainsford, S. (1990) Tested performance of the Hitec/Multi-Fluid water fraction meter . North Sea Flow Measurement Workshop, National Engineering Laboratory, Scotland.
Gajan, P., Mottram, R. C., Hebrard, P., Andriamihafy, H. and Platet, B. (1992) The influence of pulsating flows on orifice plate flowmeters. Journal of Flow Measurement and Instrumentation, 3: 118–129.Google Scholar
Gallagher, J. E. (1990a) The A.G.A. Report No.3 Orifice Plate Discharge Coefficient Equation. Second International Symposium on Fluid Flow Measurement, Calgary, 6–8 June 1990.
Gallagher, J. E. (1990b) The A.G.A. Report No.3 Orifice Plate Discharge Coefficient Equation. North Sea Flow Metering Workshop, 23-25 October 1990. National Engineering Laboratory, East Kilbride, Scotland.
Gallagher, J. E. and Saunders, M. P. (2002) Intelligent ultrasonic flowmeters. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Gallagher, J. E., LaNasa, P. J. and Beaty, R. E. (1994) The Gallagher flow conditioner . North Sea Flow Measurement Workshop, Peebles, Scotland.
Gallagher, J. E., Saunders, P.E. and Saunders, M. P. (2002) High performance flow conditioners bring unparalleled accuracy to metering stations. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Geach, D. and Jamieson, A. W. (2005) Wet gas measurement in the Southern North Sea. 23rd North Sea Flow Metering Workshop 2005, Paper 11, pp. 163–183.
Geng, Y., Zheng, J. and Shi, T. (2006) Study on the metering characteristics of a slotted nozzle for wet gas flow. Flow Measurement and Instrumentation, 17(2): 123–128.Google Scholar
Genthe, W. K. (1974) The nuclear magnetic resonance flowmeter process flow measurement experiences. Flow Measurement and Control in Science and Industry, ISA pp849–856.Google Scholar
George, D. L. (2002) Turbine meter research in support of the revision of AGA Report No. 7. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Geropp, D. (1971) Laminare Grenzschichten in ebenen und rotationssymmetrischen Lavalduesen . Deutsche Luft- und Raumfahrt Forschungsbericht, 71–90.
Geropp, D. and Odenthal, H.-J. (2001) Flow rate measurements in turbulent pipe flows with minimal loss of pressure using a defect-law. Journal of Flow Measurement and Instrumentation, 12(1): 1–7.Google Scholar
Gerrard, D. (1979) Measure viscous flows over 150:1 turndown by PD meter techniques. Control and Instrumentation, 11(4): 39–41.Google Scholar
Gerrard, J. H. (1966) The mechanics of the formation region of vortices behind bluff bodies. Journal of Fluid Mechanics, 25: 401–413.Google Scholar
Ghaoud, T. and Clarke, D. W. (2002) Modelling and tracking a vortex flow-meter signal. Flow Measurement and Instrumentation, 13(3): 103–117.Google Scholar
Gibson, J. (2009) Validation of the CFD method for determining the measurement error in flare gas ultrasonic meter installations. 27th International North Sea Flow Measurement Workshop, Tonsberg, Norway 20–23 October 2009, pp. 292–308.
Ginesi, D. (1990) Flow measurement solved with Venturi-cone meter. Intech, February: 30–32.
Ginesi, D. (1991) Choosing the best flowmeter. Chemical Engineering, NY, 98.4: 88–100.Google Scholar
Ginesi, D. and Annarummo, C. (1994) Application and installation guidelines for volumetric and mass flowmeters. ISA Transactions, 33.1: 61–72.Google Scholar
Gold, R. C., Miller, J. S. S. and Priddy, W. J. (1991) Measurement of multiphase well fluids by positive displacement meter . Offshore Europe Conference, Aberdeen, Scotland: SPE Paper 23065.
Gol'dgammer, K. A., Terent'ev, A. T. and Zalaliev, M. I. (1990) Effect of magnetic properties of a medium on the metrological characteristics of an NMR meter for measurement of gas-liquid flows. Measurement Techniques, 33.7: 676–9.Google Scholar
Goldstein, S. (1936) A note on the measurement of total head and static pressure. Proceedings of the Royal Society, Series A, 155: 570–575.Google Scholar
Goldstein, S. (1965) Modern developments in fluid dynamics. Dover Publications Inc.
Goodrich, L. D. (1979) Design and performance of the drag disc turbine transducer. International Colloquium, Idaho Falls, USA, June.
Gopal, M. and Jepson, P. (1996) Development of a novel non-intrusive, ultrasonic flowmeter for wet gas pipelines. Proceedings of the ASME Fluids Engineering Division Summer Meeting, San Diego, CA, USA, 236(1): 647–652.Google Scholar
Gorny, L. J., Gillis, K. A. and Moldover, M. R. (2012) Testing long-wavelength acoustic flowmeter concepts for flue gas flows. 8th International Symposium on Fluid Flow Measurement.
Goujon-Durand, S. (1995) Linearity of the vortex meter as a function of fluid viscosity. Journal of Flow Measurement and Instrumentation, 6: 235–238.Google Scholar
Gralenski, N. (2004) Creating a better mass flow meter. Solid State Technology, 47(5): 26–28.Google Scholar
Grattan, E., Rooney, D. H. and Simpson, H. C. (1981) Two-phase flow through gate valves and orifice plates. NEL, East Kilbride, Scotland, Report No 678.
Gray, D. E., Benjamin, N. M. P. and Chapman, B. N. (1991) Effects of environmental and installation specific factors on process gas delivery via mass flow controller with an emphasis on real time behaviour. Proceedings of SPIE, Int Soc Optical Eng, 1392: 402–410.Google Scholar
Gray, J. O. and Sanderson, M. L. (1970) Electromagnetic differential flowmeter. Electronic Letters, 6(7): 194.Google Scholar
Grego, G. and Muciaccia, F. (2008) Choice of the best position of 4 path acoustic systems in circular sections downstream curves or with inadequate straight pipes and disturbed speed profiles. Proceeding of 7th International Conference on Hydraulic Efficiency Measurements, IGHEM (International Group for Hydraulic Efficiency Measure), Milan, Italy.
Gregor, J., Norman, R. S., Bass, R. L. and Spark, C. R. (1993) Establishment of a new natural gas metering research facility for improving flow measurement accuracy under field conditions. FLOMEKO '93 Proceedings of the 6th International Conference on Flow Measurement: 27–41.
Gregory, D., West, M., Paton, R., Casimiro, R., Boo, S., Low, Y. K., Henry, M., Tombs, M., Duta, M., Zhou, F., Zamora, M., Mercado, R. and Machacek, M. (2008) Two-phase flow metering using a large Coriolis mass flow meter applied to ship fuel bunkering. Measurement and Control, 41(7): 208–212.Google Scholar
Grendstad, J., Eide, J. and Salvesen, P. (1991) Testing of Coriolis meters for metering of oil, condensate and gas. Proceedings of the North Sea Flow Measurement Workshop.Google Scholar
Grenier, P. (1991) Effects of unsteady phenomena on flow metering. Journal of Flow Measurement and Instrumentation, 2: 74–80.Google Scholar
Grey, J. (1956) Transient response of the turbine flowmeter. Jet Propulsion, February: 98–100.
Gribok, A. V., Attieh, I. K., Hines, J. W. and Uhrig, R. E. (2001) Regularization of feedwater flow rate evaluation for Venturi meter fouling problem in nuclear power plants. Nuclear Technology, 134(1): 3–14.Google Scholar
Griffin, D. (2009) New challenges in oil & gas measurement. 27th International North Sea Flow Measurement Workshop, Tonsberg, Norway, 20–23 October 2009, pp. 1–12.
Griffith, B., Cousins, T. and Augenstein, C. (2005) The effect of flow conditioners on the performance of multi-path ultrasonic flowmeters. Flomeko 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 7.2.
Griffiths, A. and Newcombe, J. (1970) Large-volume gas measurement. 36th Autumn Research Meeting of the Institution of Gas Engineers.
Griffiths, C. and Silverwood, P. A. (1986) Selection and application of flow measurement instrumentation. HYDRIL Production Technology Division, Bulletin 5126-A.Google Scholar
Grimley, T. A. (1996) Multipath ultrasonic flow meter performance . North Sea Flow Measurement Workshop, Peebles, Scotland.
Grimley, T. A. (1997) Performance testing of ultrasonic flow meters. North Sea Flow Measurement Workshop, Kristiansand, Norway: Paper 19.
Grimley, T. A. (2002) Installation effects testing of Coriolis flow meters with natural gas. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Grini, P. G., Maehlum, H. S. and Brendeng, E. (1994) In situ calibration of Coriolis flowmeters for high-pressure gas flow calorimetry. Journal of Flow Measurement and Instrumentation, 5: 285–288.Google Scholar
Grumski, J. T. and Bajura, R. A. (1984) Performance of a Coriolis-type mass flowmeter in the measurement of two-phase (air-liquid) mixtures. Mass Flow Measurements ASME Winter Annual Meeting, New Orleans, USA.
Guan, J., Zhang, H. and Hu, C. (2002) Multi-electrode electromagnetic flowmeter. Proceedings of the Second International Symposium on Instrumentation Science and Technology, 1:1/325-1/330.Google Scholar
Guilbert, A. R. and Sanderson, M. L. (1996a) Novel ultrasonic mass flowmeter for liquids. IEE Colloq. (Dig.), No. 092:8/1–8/4.Google Scholar
Guilbert, A. R. and Sanderson, M. L. (1996b) The development of curved reflective surfaces for ultrasonic beam redirection in high speed gas flow measurement. Ultrasonics, 34: 441–445.Google Scholar
Guilbert, A. R., Law, M. and Sanderson, M. L. (1996) A novel ultrasonic/thermal clamp-on flowmeter for low liquid flowrates in small diameter pipes. Ultrasonics, 34: 435–439.Google Scholar
Guizot, J. L. (2003) 18 Ultrasonic paths for liquid flow measurement. 21st North Sea Flow Metering Workshop 2003, Paper 28.
Guo, J. and Heslop, M. J. (2004) Diffusion problems of soap-film flowmeter when measuring very low-rate gas flow. Flow Measurement and Instrumentation, 15(5–6): 331–334.
Gurevich, Y, Lopez, A., Askari, V., Safavi-Ardibili, V. and Zobin, D. (2002) Performance evaluation and field application of clamp-on ultrasonic cross-correlation flow meter, CROSSFLOWTM. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Gwaspari, S. C. (1990) Multiple regression footprinting of meter factors . North Sea Flow Measurement Workshop, National Engineering Laboratory, Scotland.
Gysling, D. L. (2007) An aeroelastic model of Coriolis mass and density meters operating on aerated mixtures. Flow Measurement and Instrumentation, 18(2): 69–77.Google Scholar
Gysling, D. L. and Loose, D. H. (2003) Sonar-based, clamp-on flow meter for gas and liquid applications. BI0036 Rev. B – ISA EXPO 2003 http://www.cidra.com/sites/default/files/document_library/BI0036_Final_ISA_Houston_June172003_October_event.pdf
Gysling, D. and Mueller, E. (2004) Application of sonar-based, clamp-on flow meter in oil sand processing, ISA 2004 Exhibit and Conference.
Gysling, D. L., Loose, D. H. and van der Spek, A. (2005) Clamp-on sonar-based volumetric flow rate and gas volume fraction measurement for industrial applications. Flomeko 2005 13th International Flow Measurement Conference, Peebles, Scotland, Poster Session.
Gysling, D. L., Loose, D. H., Morlino, N. and van der Spek, A. (2007) Wet gas metering using sonar-based flow meters and piping pressure loss gradients. 25th International North Sea Flow Measurement Workshop, Energy Institute, Oslo, Norway, 79–96.
H. M. Customs and Excise (1995) Mineral (hydrocarbon) oils: Duty and VAT: Warehousing and related procedures. Notice 179.
Hafner, P. (1985) New developments in magflowmeters. International Conference on Flow Measurement in the Mid-1980s, National Engineering Laboratory, Glasgow, Scotland: Paper 9.1.
Haga, J., Sotono, Y. and Hanai, J. (1995) Development of a fuel vapor flow meter. Japan Society of Automotive Engineers, JSAE Review, 16.2: 185–187.Google Scholar
Hagenmeyer, H., Schulz, K-H., Wenger, A. and Keita, M. (1994) Design of an advanced Coriolis mass flowmeter using hoop mode. FLOMEKO'94 Conference on Flowmeasurement in the Mid 90s, NEL, Scotland.
Hahn, B. V. (1968) Theory of the sliding-vane meter, Siemens Review XXXV (9): 362–366.Google Scholar
Hakansson, E. and Delsing, J. (1992) Effects of flow disturbance on an ultrasonic gas flowmeter. Journal of Flow Measurement and Instrumentation, 3: 227–234.Google Scholar
Hakansson, E. and Delsing, J. (1994) Effects of pulsating flow on an ultrasonic gas flowmeter. Journal of Flow Measurement and Instrumentation, 5(2): 93–101.Google Scholar
Hall, A.R.W. (2001) Performance of Venturi meters in multiphase flow. Proceedings of the Engineering Technology Conference on Energy, B: 975–994.Google Scholar
Hall, A. and Shaw, C. (1988) Field experience of two phase flow measurement. North Sea Flow Metering Workshop, paper 2.3.
Hall, A. R. W., Whitaker, T. S. and Millington, B. C. (1997) Multiphase flowmetering: current status and future developments. 29th Offshore Technology Conference, Houston, TX, USA, 4:545–552.
Hall, A., Griffin, D. and Steven, R. (2007) A discussion on wet gas flow parameter definitions. 25th International North Sea Flow Measurement Workshop, Energy Institute, Oslo, Norway, 113–137.
Hall, J., Letton, C. and Webb, R. A. (2008) Deepwater measurement verification – a deepstar-RPSEA mandate. 26th International North Sea Flow Measurement Workshop 21–24 October 2008, St Andrews, Scotland, Paper 3.3.
Hall, J., Zanker, K. and Kelner, E. (2010) When should a gas ultrasonic flow meter be recalibrated? 28th International North Sea Flow Metering Workshop, Paper 5.1.
Hall, R. (1990) Measuring mass flow and density with Coriolis meters. InTech, 37(4): 45–46.Google Scholar
Hallanger, A. (2002) CFD Analyses of the influence of flow conditioners on liquid ultrasonic flow metering. Oseberg Sør – A Case Study. 20th North Sea Flow Measurement Workshop 22–25 October 2002, St Andrews, Scotland, Paper 6.3.
Hallanger, A., Frøysa, K.-E. and Lunde, P. (2002) CFD simulation and installation effects for ultrasonic flow meters in pipes with bends. International Journal of Applied Mechanics and Engineering, 7(1): 33–64.Google Scholar
Halttunen, J. (1990) Installation effects on ultrasonic and electromagnetic flowmeters: a model-based approach. Journal of Flow Measurement and Instrumentation, 1: 287–292.Google Scholar
Hamblett, L. S. J. (1970) Flowmeters. Displacement and inferential types. Glenfield Gazette, No. 231: 24–27.
Hamid, A. and Stuchly, S. S. (1975) Microwave Doppler effect flow monitor. IEE Transactions in Industrial Electronics and Control Instrumentation, IECI-22(2): 224–228.Google Scholar
Hamidullin, V., Malakhanov, R. and Khamidoullina, E. (2001) Statics and dynamics of ultrasonic flowmeters as sensing elements for power control systems. IEEE Conference on Control Applications – Proceedings, 680–685.Google Scholar
Hampel, U., Speck, M., Koch, D., Menz, H.-J., Mayer, H.-G., Fietz, J., Hoppe, D., Schleicher, E., Zippe, C. and, H.-M. (2005) Experimental ultra fast X-ray computed tomography with linearly scanned electron beam source. Flow Measurement and Instrumentation, 16(2–3):65–72.Google Scholar
Han, I. Y., Kim, D-K. and Kim, S. J. (2005) Study on the transient characteristics of the sensor tube of a thermal mass flow meter. International Journal of Heat and Mass Transfer, 48(13): 2583–2592.Google Scholar
Haneef, I., Ali, S. Z., Udrea, F., Coull, J. D. and Hodson, H. P. (2007) High performance SOI-CMOS wall shear stress sensors. IEEE Sensors Conference, 28–31 October 2007, Atlanta, USA.
Hannisdal, N-E. (1991) Metering study to reduce topsides weight. Proceedings of the North Sea Flow Measurement Workshop, Norwegian Society of Chartered Engineers: 22–24.
Hans, V. (2002a) State and research results of ultrasonic gas flow measurement. Proceedings of the Second International Symposium on Instrumentation Science and Technology, 1:1/054-1/066.Google Scholar
Hans, V. H. (2002b) New aspects of the arrangement and geometry of bluff bodies in ultrasonic vortex flow meters. Conference Record – IEEE Instrumentation and Measurement Technology Conference, 2: 1661–1664.Google Scholar
Hans, V. (2003a) Ultrasonic gas flow measurement. Proceedings of the ASME/JSME Joint Fluids Engineering Conference, 1 A: 31–35.Google Scholar
Hans, V. (2003b) Digital processing of complex modulated ultrasonic signals in flow measurement. Proceedings of SPIE – The International Society for Optical Engineering, 5253: 334–338.Google Scholar
Hans, V. and Lin, Y. (2005) Self – Monitoring ultrasonic vortex and correlation gas flow meter. Conference Record – IEEE Instrumentation and Measurement Technology Conference, 3: 2276–2280.Google Scholar
Hans, V. and Windorfer, H. (2003) Comparison of pressure and ultrasound measurements in vortex flow meters. Measurement: Journal of the International Measurement Confederation, 33(2): 121–133.Google Scholar
Hans, V., Poppen, G., von Lavante, E. and Perpéet, S. (1998a) Vortex flowmeters and ultrasound detection: signal processing and influence of bluff body geometry. Journal of Flow Measurement and Instrumentation, 9(2): 79–82.Google Scholar
Hans, V., Windorfer, H., von Lavante, E. and Perpéet, S. (1998b) Experimental and numerical optimization of acoustic signals associated with ultrasound measurement of vortex frequencies: signal processing and influence of bluff body geometry. FLOMEKO '98 Proceedings of the 9th International Conference on Flow Measurement, Lund, Sweden, 363–367.
Harmuth, B. and Erbe, V. (2002) Time of flight flow meters as a reliable and cost effective monitoring alternative in sewer systems. Water Science and Technology, 46(6–7): 397–402.Google Scholar
Harper, K., Lansing, J. and Dietz, T. (2009) Field experience of ultrasonic flow meter use in CO2-rich applications. 27th International North Sea Flow Measurement Workshop, Tonsberg, Norway, 20–23 October 2009, pp. 220–234.
Harper, K., Lansing, J. and Dietz, T. (2012) Field experience of ultrasonic flow meter use in CO2-rich applications. 8th International Symposium on Fluid Flow Measurement.
Harrie, P. M. (1991) Mass flow and density. Measurement & Control, April.
Harriger, J. W. (1966) High-pressure measurement. 32nd Autumn Research Meeting of the Institution of Gas Engineers.
Harrison, P. (1978a) The calibration of flowmeters with liquids. Short Course notes on The Principles and Practice of Flow Measurement, Lecture No 6, National Engineering Laboratory, East Kilbride.
Harrison, P. (1978b) National standards, transfer standards, traceability and the BCS. Short Course notes on The Principles and Practice of Flow Measurement, Lecture No 8, National Engineering Laboratory, East Kilbride.
Harrison, P. and Williamson, J. (1985) Accuracy of flowmeters used in a survey of domestic water consumption in Scotland in October 1982. Proc Flow Measurement for Water Supply, London.
Harrold, D. (2001) Coriolis flowmeters. New and improved: What's that mean? Control Engineering, 48(11): 24–33.Google Scholar
Hartley, P. E., Roach, G. J., Stewart, D., Watt, J. S., Zastawny, H. W. and Ellis, W. K. (1995) Trial of a gamma-ray multiphase flowmeter on the West Kingfish oil platform. Nuclear Geophysics, 9(6): 533–552.Google Scholar
Hastings, C. R. (1968) LE flowmeter – a new device for measuring liquid flow rates. Westinghouse Engineer, 28(6): 183.Google Scholar
Hastings, C. R. (1970) The LE acoustic flowmeter: an application to discharge measurement. New England Water Works Association, 84: 127.Google Scholar
Hauser, E., Estrada, H. and Regan, Jennifer (2004) Impact of flow velocity profile on nuclear plant feed water flow measurement accuracy; results of recent laboratory testing. Instrumentation, Control, and Automation in the Power Industry, Proceedings, 45(ISA 421): 109–118.Google Scholar
Hayes, E. R. (1988) The prediction of droplet motion and breakup using a vortex model for turbulent flows. PhD thesis, Cranfield Institute of Technology.
Hayward, A. T. J. (1977a) Flowmeters: a basic guide and source-book for users. The Macmillan Press Ltd, London, England.
Hayward, A. T. J. (1977b) Measuring the repeatability of flowmeters. NEL Report No. 636, Dept. of Industry, UK.
Hayward, A. T. J. (1977c) Repeatability and accuracy. Mechanical Engineering Publications Limited, London.
Hayward, A. T. J. (1979) Flowmeters: A basic guide and source-book for users. The Macmillan Press, London.
Hayward, A. T. J. and Furness, R. A. (1989) A portable gravimeter prover for the in-line proving of direct mass flowmeters. Mass Flow Measurement Direct and Indirect, Proc Int Conf Mass Flow Measurement, IBC Pbl, London, England.
Haywood, R. W. (1968) Thermodynamic tables in SI units. Cambridge University Press.
He, D. and Bai, B. (2012) Numerical investigation of wet gas flow in Venturi meter. Flow Measurement and Instrumentation, 28: 2–6.Google Scholar
Head, V. P. (1946–1947) An extension of rotameter theory and its application in new practical fields. Instrument Practice. Dec 1946: 64–71, and Feb 1947: 135–141.Google Scholar
Head, V. P. (1956) A practical pulsation threshold for flowmeters. Transactions on ASME, 78: 1471–1479.Google Scholar
Hebrard, P., Malard, L. and Strzelecki, A. (1992) Experimental study of a vortex flowmeter in pulsatile flow conditions. Journal of Flow Measurement & Instrumentation, 3: 173–186.Google Scholar
Heinrichs, K. (1991) Flow measurement by a new push-pull swirlmeter. Sensors & Actuators, A: Physics, 27: 809–813.Google Scholar
Hemp, J. (1975) Improved magnetic field for an electromagnetic flowmeter with point electrodes. Journal of Physics D Applied Physics, 8: 983–1002.Google Scholar
Hemp, J. (1979) British Patent Specification No 2017914A.
Hemp, J. (1982) Theory of transit time ultrasonic flowmeters. Journal of Sound Vibration, 84(1): 1133–1147.Google Scholar
Hemp, J. (1988) Flowmeters and reciprocity. QJMAM, 41(4): 503–520.Google Scholar
Hemp, J. (1991) Theory of eddy currents in electromagnetic flowmeters. Journal of Physics D Applied Physics, 24: 244–251.Google Scholar
Hemp, J. (1994a) Weight vector for thermal diffusion flowmeters, Part 1: General theory. Journal of Flow Measurement and Instrumentation, 5(3): 217–222.Google Scholar
Hemp, J. (1994b) The weight vector theory of Coriolis mass flowmeters. Journal of Flow Measurement and Instrumentation, 5(4): 247–253.Google Scholar
Hemp, J. (1994c) Error in potential measurements due to nonuniform contact impedence of electrodes. Quarterly Journal of Mechanics and Applied Mathematics, 47(1): 175–182.Google Scholar
Hemp, J. (1995a) Weight vector for thermal diffusion flowmeters, Part 2: Application to a particular configuration. Journal of Flow Measurement and Instrumentation, 6: 149–156.Google Scholar
Hemp, J. (1995b) Theory of a simple electromagnetic velocity probe with prediction of the effect on sensitivity of a nearby wall. Measurement Science and Technology, 6: 376–382.Google Scholar
Hemp, J. (1996) A theoretical investigation into the feasibility of Coriolis mass flowmeters for low density fluids. FLOMEKO'96 Proceedings of the 8th International Conference on Flow Measurement, Beijing, China: 265–270.
Hemp, J. (1998) A review of the weight vector theory of transit time ultrasonic flowmeters. FLOMEKO'98 9th International Conference on Flow Measurement, Lund, Sweden.
Hemp, J. (2001a) A technique for low cost calibration of large electromagnetic flowmeters. Journal of Flow Measurement and Instrumentation, 12(2): 123–134.Google Scholar
Hemp, J. (2001b) Calculation of the sensitivity of a straight tube Coriolis mass flowmeter with free ends. Flow Measurement and Instrumentation, 12(5–6): 411–420.Google Scholar
Hemp, J. and Hendry, L. A. (1995) The weight vector theory of Coriolis mass flowmeters – Part 2. Boundary source of secondary vibration. Journal of Flow Measurement and Instrumentation, 6: 259–264.Google Scholar
Hemp, J. and Kutin, J. (2006) Theory of errors in Coriolis flowmeter readings due to compressibility of the fluid being metered. Flow Measurement and Instrumentation, 17(6): 359–369.Google Scholar
Hemp, J. and Sanderson, M. L. (1981) Electromagnetic flowmeters – a state of the art review. BHRA International Conference on Advances in Flow Measurement Techniques, Coventry, England, Paper E1: 319–340.
Hemp, J. and Sultan, G. (1989) On the theory and performance of Coriolis mass flowmeters. Mass Flow Measurement Direct and Indirect, Proc Int Conf Mass Flow Measurement, IBC Pbl, London, England.
Hemp, J. and Versteeg, H. K. (1986) Prediction of electromagnetic flowmeter characteristics. Journal of Physics D: Applied Physics 19: 1459–1476.Google Scholar
Hemp, J. and Wyatt, D. G. (1981) A basis for comparing the sensitivity of different electromagnetic flowmeters to velocity distribution. Journal of Fluid Mechanics, 112: 189–201.Google Scholar
Hemp, J. and Yeung, H. (2003) Coriolis meters in two phase conditions. IEE Computing and Control Engineering, 14(4): 36.Google Scholar
Hemp, J. and Youngs, I. (2003) Problems in the theory and design of electromagnetic flowmeters for dielectric liquids. Part 3a. Modelling of zero drift due to flux linkage between coil and electrode cables. Flow Measurement and Instrumentation, 14(3): 65–78.Google Scholar
Hemp, J., Sanderson, M. L., Koptioug, A. V., Liang, B., Sweetland, D. J. and Al-Rabeh, R. H. (2002) Problems in the theory and design of electromagnetic flowmeters for dielectric liquids. Part 1: Experimental assessment of static charge noise levels and signal-to-noise ratios. Flow Measurement and Instrumentation, 13(4): 143–153.Google Scholar
Hemp, J., Yeung, H. and Kassi, L. (2003) Coriolis meters in two phase conditions. IEE One-day Seminar on Advanced Coriolis Mass Flow Metering, 8 July 2003.
Hendrix, A. R. (1982) Positive displacement flowmeters: high performance -with a little care. In Tech: 47–49.Google Scholar
Henke, R. W. (1955) Positive displacement meters. Control Engineering, 2(5): 56–64.Google Scholar
Henry, M. P. (1995) Self-validation improves Coriolis flowmeter. Control Engineering, 42(6 May).Google Scholar
Henry, M. (2000) Self-validating digital Coriolis mass flow meter. Computing and Control Engineering Journal, 11(5): 219–227.Google Scholar
Henry, M. (2001) On-line compensation in a digital Coriolis mass flow meter. Flow Measurement and Instrumentation, 12(2): 147–161.
Henry, M. (2003a) Coriolis meter digital transmitter technology. IEE Computing and Control Engineering, 14(4): 34–35.Google Scholar
Henry, M. (2003b) Coriolis flow transmitter and dynamic response performance – digital transmitter. Measurement & Control, 36(9): 278–281.Google Scholar
Henry, M. P., Clarke, D. W., Archer, N., Bowles, J., Leahy, M. J., Liu, R. P., Vignos, J. and Zhou, F. B. (2000) A self-validating digital Coriolis mass-flowmeter: an overview. Control Engineering Practice, 8: 487–506.Google Scholar
Henry, M., Clark, C. and Cheesewright, B. (2003a) Pushing Coriolis mass flowmeters to the limit. IEE Computing and Control Engineering, 14(3): 24–28.Google Scholar
Henry, M. P., Clark, C., Duta, M., Cheesewright, R. and Tombs, M. (2003b) Response of a Coriolis mass flow meter to step changes in flow rate. Flow Measurement and Instrumentation, 14(3): 109–118.Google Scholar
Henry, M., Duta, M., Tombs, M., Yeung, H. and Mattar, W. (2004) How a Coriolis mass flow meter can operate in two-phase (gas/liquid) flow. Technical Papers of ISA, 454: 17–30.Google Scholar
Henry, M., Tombs, M., Duta, M., Zhou, F., Mercado, R., Kenyery, F., Shen, J., Morles, M., Garcia, C. and Lansangan, R. M. (2006) Two-phase flow metering of heavy oil using a Coriolis mass flow meter: a case study. Flow Measurement and Instrumentation, 17(6): 399–413.Google Scholar
Henry, M., Tombs, M., Zamora, M. and Zhou, F. (2013) Coriolis mass flow metering for three-phase flow: A case study. Flow Measurement and Instrumentation, 30: 112–122 http://dx.doi.org/10.1016/j.flowmeasinst.2013.01.003.Google Scholar
Heritage, J. E. (1989) The performance of transit time ultrasonic flowmeters under good and disturbed flow conditions. Journal of Flow Measurement and Instrumentation, 1: 24–30.Google Scholar
Hermant, C. (1962) Application of flow measurement by the comparative salt-dilution to the determination of turbine efficiency. Proc. Symp. on Flow Measurement in Closed Conduits, HMSO, 2 Paper E-2.
Herremans, P., Hoogendijk, C. J., Boer, A. H. and van Bekkum, A. J. (1989) Ultrasonic flowmeter. US Patent 4838127A.
Herschy, R. W. (1995) Streamflow measurement. Second edition, E & F N Spon.
Herzl, P. J. (1982) A vortex flowmeter with 2 active vortex generators. Advances in Instrumentation, 37: 1205–1216.Google Scholar
Herzog, J. P. (1992) An optical fibre vortex sensor for flow rate measurements. Sensors & Actuators, A: Phys., 32: 696–700.Google Scholar
Herzog, M. W., Brobeil, W., Schafer, R. and Meyre, S. (1993) Breakthroughs in the design of the next generation of electromagnetic water meters. Flow Measurement for the utilities, Amsterdam, The Netherlands.
Hetsroni, G. (1981) Handbook of multiphase systems. McGraw Hill.
Higham, E. H. and Johnston, J. S. (1992) A review of ‘smart’ and ‘intelligent’ flowmetering systems. FLOMIC Report No 18.
Higham, E. H., Fell, R. and Ajaya, A. (1986) Signal analysis and intelligent flowmeters. Measurement and Control: 47–50.Google Scholar
Higson, D. J. (1964) The transient performance of turbine flowmeters in water. Journal of Scientific Instruments, 42: 337–342.Google Scholar
Hilgenstock, A. and Ernst, R. (1996) Analysis of installation effects by means of computational fluid dynamics – CFD vs experiments? Journal of Flow Measurement and Instrumentation, 7(3/4): 161–171.Google Scholar
Himpe, U., Gotte, B. and Schatz, M. (1994) Influence of upstream bends on the discharge coefficients of classical Venturi tubes and orifice plates. Journal of Flow Measurement and Instrumentation, 5: 209–216.Google Scholar
Hirnschrodt, M., von Jena, A., Vontz, T., Fischer, B., Lerch, R. and Meixner, H. (2000) Time domain evaluation of resonance antireflection (RAR) signals for ultrasonic density measurement. IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, 47(6): 1530–1539.
Ho, Y. L., Chen, J. Y., Shaw, J. H. and Yang, C. T. (2005) Design, CFD investigation and implementation of a novel diverter mechanism for water flow measurement. Key Engineering Materials, 295–296: 521–526.Google Scholar
Hobbs, J. M. and Humphreys, J. S. (1990) The effect of orifice plate geometry upon discharge coefficient. Journal of Flow Measurement and Instrumentation, 1: 133–140.Google Scholar
Hochreiter, H. M. (1958) Dimensionless correlation of coefficients of turbine type flowmeters. Trans. ASME: 1363–1368.Google Scholar
Hodges, C., Britton, C., Johansen, W. and Steven, R. (2010) Cone DP meter calibration issues. 15th Flow Measurement Conference (FLOMEKO), 13–15 October Taipei, Taiwan, Paper B4-2.
Hofman, F. (1993) Magnetic flowmeter with flowshaping flowtube. FLOMEKO'93 Proceedings of the 6th International Conference on Flow Measurement, Korea Research Institute of Standards and Science: 445–451.
Hofstede, H., Hogendoorn, J., Danen, H. and Tetzner, R. (2004) ALTOSONIC III –dedicated three beam liquid ultrasonic flowmeter for custody transfer and pipeline leak detection. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Hogendoorn, J., Laan, D., Hofstede, H. and Danen, H. (2004) ALTOSONIC III – a dedicated three-beam ultrasonic flowmeter for custody transfer of liquid hydrocarbons. 22nd North Sea Flow Metering Workshop 2004, Paper 4.2.
Hogendoorn, J., Boer, A., Hofstede, D. L. H. and Danen, H. (2005) Flow disturbances and flow conditioners: the effect on multi-beam ultrasonic flowmeters. 23rd North Sea Flow Metering Workshop 2005, Paper 16, pages 241–252.
Hogendoorn, J., Boer, A. and Danen, H. (2007) An ultrasonic flowmeter for custody transfer measurement of LNG: a challenge for design and calibration. 25th International North Sea Flow Measurement Workshop, Energy Institute, Oslo, Norway, 350–365.
Hogendoorn, J. Tawackolian, K., van Brakel, P., van Klooster, J. and Drenthen, J. (2009) High viscosity hydrocarbon flow measurement, a challenge for ultrasonic flow meters? 27th International North Sea Flow Measurement Workshop, Tonsberg, Norway, 20–23 October 2009, pp. 341–360.
Hogendoorn, J., Boer, A., Appel, M., de Jong, H. and de Leeuw, R. (2013) Magnetic resonance technology: a new concept for multiphase flow measurement. 31st International North Sea Flow Measurement Workshop, 22-25 October 2013, Tønsberg, Norway
Hogendoorn, J., Boer, A., Zoeteweij, M., Bousché, O., Tromp, R., de Leeuw, R., Moeleker, P., Appel, M. and de Jong, H. (2015) Magnetic resonance multiphase flowmeter: measuring principle and broad range test results. South East Asia Flow Measurement Conference 3–4 March 2015.
Hogrefe, W., Kirchhof, U., Mannherz, E., Marchewka, W., Mecke, U., Otto, F., Rakebrandt, K.-H., Thone, A. and Wegener, H.-J. (1995) Guide to flowmeasurements. Bailey-Fischer & Porter GmbH Gottingen.
Holden, J. L. and Peters, R. J. W. (1990) Practical experiences using ultrasonic flowmeters on high pressure gas . North Sea Flow Measurement Workshop, National Engineering Laboratory, Scotland.
Holden, J. L. and Peters, R. J. W. (1991) Practical experiences using ultrasonic flowmeters on high pressure gas. Journal of Flow Measurement and Instrumentation, 2: 69–73.Google Scholar
Holm, M., Stang, J. and Delsing, J. (1995) Simulation of flowmeter calibration factors for various installation effects. Measurement: 15(4): 235–244.Google Scholar
Hooper, L. J. (1962) Discharge measurements by the Allen salt-velocity method. Proc. Symp. on Flow Measurement in Closed Conduits, HMSO, 2: Paper E-1.
Hopkins, D., Savage, P. F. and Fox, E. (1995) Problems encountered during research into flow rate, pattern of water consumption and unaccounted-for water losses in urban areas. Journal of Flow Measurement and Instrumentation 6: 173–179.Google Scholar
Hornak, J. P. (1997–1999) The basics of NMR. http://www.cis.rit.edu/htbooks/nmr/inside.htm
Horner, B., Mesch, F. and Trachtler, A. (1996) A multi-sensor induction flowmeter reducing errors due to non-axisymmetric flow profiles. Measurement Science and Technology, 7: 354–360.Google Scholar
Hoshikawa, S., Ishikawa, H., Nakao, S. and Takamoto, M. (2005) Development of an ultrasonic flowmeter for hydrogen gas. Flomeko 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 7.1.
House, R. K. and Johnson, R. T. (1986) Practical application of hydrostatic fluid bearing design principles to a turbine flow meter. Instrumentation in the Aerospace Industry, Proceedings of the 32nd International Instrumentation Symposium, Seattle, Washington, USA. (Also in ISA Transactions 26, No 3, pp. 59–63, 1987.)
Howarth, M. (1994) HART – Standard for 4–20mA digital communications. Measurement & Control, 27(1): 5–8.Google Scholar
Hrin, G. P. and Tuma, D. T. (1977) Doppler microwave cavity resonator for particulate loading. IEEE Trans Instrument Measurement, IM26 13–17.Google Scholar
Hu, C.-C. and Lin, W.-T. (2009) Performance test of KOH-etched silicon sonic nozzles. Flow Measurement and Instrumentation, 20(3): 122–126.Google Scholar
Hu, C.-C., Lin, W.-T., Su, C.-M. and Liu, W.-J. (2010a) Discharge characteristics of small sonic nozzles in the shape of pyramidal convergent and conical divergent. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A6-5.
Hu, C.-C., Lin, W.-T. and Su, C.-M. (2011) Flow characteristics of pyramidal shaped small sonic nozzles. Journal of Flow Measurement and Instrumentation, 22(1): 64–70.Google Scholar
Hu, C.-C., Lin, W.-T., Su, C.-M. and Liu, W.-J. (2012) Discharge characteristics of small sonic nozzles in the shape of pyramidal convergent and conical divergent. Journal of Flow Measurement and Instrumentation, 25: 26–31.Google Scholar
Hu, H.-M., Wang, C. and Meng, T. (2010b) Numerical approach to estimate the accuracy of ultrasonic flowmeter under disturbed flow condition. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A10-1.
Hu, H., Zhang, L., Meng, T. and Wang, C. (2015) Mechanism analysis and estimation tool of installation effect on multipath ultrasonic flowmeter. 9th International symposium of Fluid Flow Measurement , Arlington, VA, USA.Google Scholar
Hu, L., Zou, J., Zhu, Z. C., Fu, X., Ruyan, X. D. and Wang, C. Y. (2010c) Analytical calculation of the measuring error of an electromagnetic velocity probe caused by a side channel wall. Flow Measurement and Instrumentation, 21(4): 435–442.Google Scholar
Huang, L., Chen, C. C., Yao, Y., Wang, G., Feng, Y., Wei, K., Deng, W., Jiang, C., Ruan, J. and Jiang, S. (2010) All Electronic MEMS flow meters for city gas applications. 15th Flow Measurement Conference (FLOMEKO), October 13–15, 2010 Taipei, Taiwan, Paper A8-2.
Huang, Z., Xie, D., Zhang, H. and Li, H. (2005) Gas-oil two-phase flow measurement using an electrical capacitance tomography system and a Venturi meter. Flow Measurement and Instrumentation, 16(2–3): 177–182.Google Scholar
Huijsing, J. H., van Dorp, A. L. C. and Loos, P. J. G. (1988) Thermal mass-flow meter. Journal of Physics E: Scientific Instruments, 21: 994–997.Google Scholar
Hulbert, G. M., Darnell, I. and Brereton, G. J. (1995) Numerical and experimental analysis of Coriolis mass flowmeters. AIAA/ASME/ASCE/AHS Structures, Structural Dynamics and Materials Conference – Collection of Technical Papers, 3: (AIAA-95-1384-CP), pp. 1889–1893.
Hulin, J-P. and Foussat, A. J. M. (1983) Vortex flowmeter behaviour in liquid-liquid two-phase flow. International Conference on Physical Modelling of Multi-Phase Flow, Coventry, England, BHRA Fluid Engineering, Paper H3: 377–390.
Hulin, J- P., Fierfort, C. and Condol, R. (1982) Experimental study of vortex emission behind bluff obstacles in a gas liquid vertical two-phase flow. International Journal of Multiphase Flow, 8: 475–490.Google Scholar
Hunter, J. J. and Green, W. L. (1975) Blockage and its effect on a drag plate flowmeter. Conference on Fluid Flow Measurement in the Mid 1970's, National Engineering Laboratory, East Kilbride, Scotland: Paper C-2.
Hussain, Y. A. (2000a) Mass flowmeter which operates according to the Coriolis principle. US Patent 6,041,665.
Hussain, Y. A. (2000b) Mass flow rate measuring instrument. US Patent 6,082,202.
Hussain, Y. A. (2003) Single straight tube mass flowmeter using ‘adaptive sensor technology. IEE Computing and Control Engineering, 14(4): 40–41.Google Scholar
Hussain, Y. A. and Baker, R. C. (1985) Optimised non-contact electromagnetic flowmeter. Journal of Physics E: Scientific Instruments, 18: 210–213.Google Scholar
Hussain, Y. A. and Farrant, D. (1994) Coriolis mass flow measurement using single straight tube . Proceedings of a Study Day on Massflow at RAI (Studiedag ‘Massflow’), MRBT, Amsterdam.
Hussain, Y. A. and Rolph, C. N. (1994) Mass flowmeter. US Patent 5, 365, 794.
Hussain, Y.A., and Rolph, C.N. (2002) Mass flow meter. US Patent 2002020227, 21 February 2002.
Hussain, Y., Rolph, C. and Wang, T. (2010) Mass flowmeter.US2010050783.
Hussein, I. B. and Owen, I. (1991) Calibration of flowmeters in superheated and wet steam. Journal of Flow Measurement and Instrumentation, 2: 209–216.Google Scholar
Hussein, I. B., Owen, I. and Amin, A. M. (1992) Energy metering system for high quality saturated steam. Journal of Flow Measurement and Instrumentation, 3: 235–240.Google Scholar
Hutchings, I. M. (1992) Tribology: friction and wear of engineering materials. Arnold 1992, reprinted by Butterworth-Heineman 2001.
Hutton, S. P. (1974) The effect of inlet flow conditions on the accuracy of flowmeters. Int. Mech. E Conf. Publ. 4: 1–8.Google Scholar
Hutton, S. P. (1986) The effects of fluid viscosity on turbine meter calibration. Flow Measurement in the Mid 80s, NEL, Scotland: Paper 1.1.
Hwang, S.-Y., Lee, H.-J. and Kim, H.-D. (2004) Application of multi-path ultarsonic oil flowmeter using a new weighting factor method. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Ibarz, A., Bauer, G., Casas, R., Marco, A. and Lukowicz, P. (2008) Design and evaluation of a sound based water flow measurement system. 3rd European Conference on Smart Sensing and Context, EuroSSC: 41–54.
Ibrahim, S., Green, R. G. and Dutton, K. (2000) Optical fibre sensors for flow measurement. Proceedings of SPIE – The International Society for Optical Engineering, 4074: 372–376.
Ifft, S. A. (1996) Partially closed valve effects on the V-cone flowmeter. FLOMEKO '96 Proceedings of the 8th International Conference on Flow Measurement, Beijing, China: 49–54.
Ifft, S. A. and Mikklesen, E. D. (1993) Pipe elbow effects on V-cone flow meter FED. Fluid Meas Instrum ASME, 161.Google Scholar
Igarashi, T. (1986) Fluid flow around a bluff body used for a Karman vortex flowmeter. Fluid Control and Measurement, 2: 1003–1008.Google Scholar
Ilha, A., Doria, M. M. and Aibe, V. Y. (2010) Treatment of the time dependent residual layer and its effects on the calibration procedures of liquids and gases inside a volume prover. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper B3-3.
Imrie, A. (1994) Communication options in the water industry. 27(7): 221–224.
Incontri, J. (2005) Recent advances in electromagnetic flow measurement technology. Technical Papers of ISA, 459: 163–168.Google Scholar
Inkley, F. A., Walden, D. C. and Scott, D. J. (1980) Flow characteristics of vortex shedding meters. Measurement & Control, 13: 166–170.Google Scholar
Iooss, B., Lhuillier, C. and Jeanneau, H. (2002) Numerical simulation of transit-time ultrasonic flowmeters: Uncertainties due to flow profile and fluid turbulence. Ultrasonics, 40(9): 1009–1015.Google Scholar
ISA (1959) Terminology, dimensions and safety practices for indicating variable area meters (Rotameters): RP16.1 Glass tube, RP16.2 Metal tube, RP16.3 Extension type glass tube. Instrument Society of America, Report (recommended practice) RP 16.1.2.3.
ISA (1960) Nomenclature and terminology for extension type variable area meters (Rotameters). Instrument Society of America, Report (tentative recommended practice) RP 16.4.
ISA (1961a) Installation, operation, maintenance instructions for glass tube variable area meters (Rotameters). Instrument Society of America, Report (recommended practice) RP 16.5.
ISA (1961b) Methods and equipment for calibration of variable area meters (Rotameters). Instrument Society of America, Report (tentative recommended practice) RP 16.6.
Ishibashi, M. (2002) Proposal of fluid dynamical standard (FDS) for gas flow-rate. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Ishibashi, M. and Funaki, T. (2013) Boundary layer transition in high precision critical nozzles of various shapes. Proceedings of FLOMEKO2013 Small nozzles
Ishibashi, M. and Morioka, T. (2006) The renewed airflow standard system in Japan for 5–1000 m3/h. Flow Measurement and Instrumentation, 17(3): 153–161.Google Scholar
Ishibashi, M. and Morioka, T. (2010) Dependence of the flow velocity field in critical nozzles on the pressure ratio. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A6-4.
Ishibashi, M. and Morioka, T. (2012) Velocity field measurements in critical nozzles using Recovery Temperature Anemometry (RTA). Flow Measurement and Instrumentation, 25: 15–25.Google Scholar
Ishibashi, M. and Takamoto, M. (1997) Very accurate analytical calculation of the discharge coefficients of critical Venturi nozzles with laminar boundary layer. Proceedings of FLUCOME
Ishibashi, M. and Takamoto, M. (2000a) Methods to calibrate a critical nozzle and flowmeter using reference critical nozzles. Flow Measurement and Instrumentation, 11(4): 293–303.Google Scholar
Ishibashi, M. and Takamoto, M. (2000b) Theoretical discharge coefficient of a critical circular-arc nozzle with laminar boundary layer and its verification by measurements using super-accurate nozzles. Flow Measurement and Instrumentation, 11(4): 305–313.Google Scholar
Ishibashi, M. and Takamoto, M. (2001)Discharge coefficient of super-accurate critical nozzles accompanied with the boundary layer transition measured by reference super-accurate critical nozzles connected in series. Proc. ASME FEDSM01 paper No. 18036.
Ishikawa, H., Takamoto, M., Shimizu, K., Monji, H. and Matsui, G. (2000) Development of a new ultrasonic liquid flowmeter for very low flow rate applicable to a thin pipe. IEEE International Symposium on Semiconductor Manufacturing Conference, Proceedings, (1): 383–386.Google Scholar
Islam, M., Seshadri, V., Singh, S. N. and Hasan, M. M. (2003) Skewed velocity profile effect on turbine flowmeter performance. Proceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering, 217(1): 25–32.Google Scholar
ISO Standards – the reader is referred to the ISO website on the internet.
Ito, D., Kikura, H. and Antomi, M. (2011) Micro wire-mesh sensor for two-phase flow measurement in a rectangular narrow channel. Flow Measurement and Instrumentation, 22(5): 377–382.Google Scholar
Ito, H., Watanabe, Y. and Shoji, Y. (1985) A long-radius inlet nozzle for flow measurement. Journal of Physics E: Scientific Instruments, 18: 88–91.Google Scholar
Itoh, I. and Ohki, S. (1993) Mass flowmeter detecting fluctuations in lift generated by vortex shedding. Journal of Flow Measurement & Instrumentation, 4: 215–224.Google Scholar
Jackson, G. A., Gibson, J. R. and Holmes, R. (1989) Three-path ultrasonic flowmeter for small-diameter pipelines. Journal of Physics E: Scientific Instruments, 22.8: 645–650.Google Scholar
Jackson, G. A., Gibson, J. R. and Holmes, R. (1991) Three-path ultrasonic flow meter with fluid velocity profile identification. Measurement Science & Technology, 2.7: 635–642.Google Scholar
Jacobsen, E., Denstad, H., Downing, A., Daniel, P. and Tudge, M. (2004) Validation and operational experience of a dualstream II wet gas meter in a subsea application on the Statoil Mikkel Field. 22nd North Sea Flow Metering Workshop 2004, Paper 8.2.
Jacobson, S. A., Lynnworth, L. C. and Korba, J. M. (1988) Differential correlation analyzer. US Patent 4,787,252 (Nov. 29, 1988).
Jae, H. H., Woo, H. J., Jung, Y. L., Ho, C. J. and Hang, B. K. (2006) Feed water flow measurement and experience using clamp-on transit-time ultrasonic flow meter in nuclear power plants. 5th International Topical Meeting on Nuclear Plant Instrumentation Controls, and Human Machine Interface Technology (NPIC and HMIT 2006), 2006: 284–291.
Jalbert, P. A. (1999) Evaluation of a dual rotor turbine fuel flow meter (G176). Instrumentation in the Aerospace Industry: Proceedings of the International Symposium, 427–437.Google Scholar
James, R. (1965/1966) Metering of steam/water two-phase flow by sharp-edged orifices. Proc I Mech E, 180: 549–572.Google Scholar
Jamieson, A. W. (2001) Wet gas metering – the unexpected challenge: Status and trends on technology and applications. Paper 5, 19th North Sea Flow Measurement Workshop, Kristiansand, Norway, 22–25 October 2001.
Jamieson, A. W., Johnson, P. A., Spearman, E. P. and Sattary, J. A. (1996) Unpredicted behaviour of Venturi flowmeter in gas at high Reynolds numbers. Proc. of 14th North Sea Flow Measurement Workshop, Peebles, Scotland, paper 1.5.
Jeanneau, H. and Piguet, M. (2000) Pipe flow modelling for ultrasonic flow measurement. FLOMEKO '2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper B9.
Jenkins, D. M., Lysak, P. D., Capone, D. E., Brown, W. L. and Askari, V. (2006) Ultrasonic cross-correlation flow measurement: Theory, noise contamination mechanisms, and a noise mitigation technique. International Conference on Nuclear Engineering, Proceedings, ICONE, 2006(14): 7p.Google Scholar
Jepson, P. (1964) Transient response of a helical flowmeter. Journal of Mechanical Engineering Science, 6: 317–320.Google Scholar
Jepson, P. (1967) Currentmeter errors under pulsating flow conditions. Journal of Mechanical Engineering Science, 9: 45–54.Google Scholar
Jepson, P. and Bean, P. G. (1969) Effect of upstream velocity profiles on turbine flowmeter registration. Journal of Mechanical Engineering Science, 11: 503–510.Google Scholar
Jepson, P. and Chamberlain, D. (1977) Operating high pressure orifice metering installations. FLO-CON 77 Proceedings of the Symposium – the Application of Flow Measuring Techniques, Brighton, UK: 285–319.
Jepson, P. and Chipchase, R. (1975) Effect of plate buckling on orifice meter accuracy. Journal of Mechanical Engineering Science, 17.Google Scholar
Jeronymo, C. E. and Aibe, V. Y. (2010) Implementation of quadruple-timing pulse interpolation applied to compact piston provers. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A5-1.
Jian, D. and Karcher, C. (2012) Electromagnetic flow measurements in liquid metals using time-of-flight Lorentz force velocimetry. Measurement Science & Technology, 23(7) 074021(14pp).
Jian, W. (2004) The middle range gas flow standard of SPRING Singapore. 12th International Conference on Flow Measurement FLOMEKO Guilin, China.
Jin, N., Miao, L. and Li, W. (2006) Symbolic sequence analysis method of gas/liquid two-phase flow measurement fluctuation signals. Proceedings of IEEE ICIA 2006–2006 IEEE International Conference on Information Acquisition, Weihai, Shandong, China, 1321–1326.
Jitschin, W. (2004) Gas flow measurement by the thin orifice and the classical Venturi tube. Vacuum, 76(1): 89–100.Google Scholar
Jitschin, W., Ronzheimer, M. and Khodabakhshi, S. (1999) Gas flow measurement by means of orifices and Venturi tubes. Vacuum 53(1–2): 181–185.Google Scholar
Johannessen, A. A. (1993) Evaluation of ultrasonic liquid flowmeters . North Sea Flow Measurement Workshop, Bergen, Norway.
Johannessen, A. A. (2001) Flare gas metering – measurement challenges at hand. 19th North Sea Flow Measurement Workshop, Kristiansand, Norway, 22–25 October 2001, Paper 14.
Johansen, E. S., Hall, A. R. W., Ünalmis, Ö. H., Rodriguez, D. J., Vera, A. and Ramakrishnan, V. (2007) A prototype wet-gas and multiphase flowmeter. 25th International North Sea Flow Measurement Workshop, Energy Institute, Oslo, Norway, 97–112.
Johansen, G. A. and Tjugum, S.-A. (2007) Fluid composition analysis by multiple gamma-ray beam and modality measurements. 25th International North Sea Flow Measurement Workshop, Energy Institute, Oslo, Norway, 69–78.
Johansen, W. R. (2010) The effect of using real gas absolute viscosity and isentropic exponent on orifice flow measurement: proposed adoption of REFPROP 8.0 as a standard for the natural gas industry. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper B8-1.
John, H., Hain, K., Bruderie, F., Reimann, J. and Vollmer, T. (1982) Tests of an advanced true mass flow meter (TMFM) in gas-liquid flow. Measurement in Polyphase Flows-1982, AIAA/ASME Joint Fluids, Plasma, Thermophysics and Heat Transfer Conference, St Louis, Missouri, USA: 55–60.
Johnson, A. and Wright, L. (2006) Evaluation of theoretical CFV flow models in the laminar, turbulent, and transition flow regimes. Proc. 6th International Symposium On Fluid Flow Measurement (ISFFM), Querétero, Mexico.
Johnson, A. and Wright, J. (2008) Comparison between theoretical CFV flow models and NIST's primary flow data in the laminar, turbulent, and transition flow regimes. ASME Journal of. Fluids Engineering, 130: 271202-1-11.Google Scholar
Johnson, A. N., Espina, , P. I., Mattingly, G. E., Wright, J. D. and Merkle, C. L. (1998) Numerical characterization of the discharge coefficient in critical nozzles. Proc. NCSL Workshop & Symposium, Session 4E: 407–442.Google Scholar
Johnson, A. N., Crowley, C. J. and Yeh, T. T. (2010) Uncertainty analysis of NIST's 20 liter hydrocarbon liquid flow standard. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper B5-4.
Johnson, A., Harman, E. and Boyd, J. (2013) Blow-down calibration of a large 8 path ultrasonic flow meter under quasi-steady flow conditions. FLOMEKO 2013, 16th International Flow Measurement Conference, Paris
Johnson, M. W. and Farroll, S. (1995) Development of a turbine meter for two-phase flow measurement in vertical pipes. Journal of Flow Measurement and Instrumentation, 6: 279–282.Google Scholar
Johnson, R. (2002) Keeping meters on line: accurately measuring drinking water and sewage. Water Engineering and Management, 149(9): 14–19.Google Scholar
Jones, F. E. (1992) Application of the equation to the treatment of laminar flowmeter calibration data. Industrial Metrology, 2: 91–96.
Jongerius, P. F. M., van der Beek, M. P. and van der Grinten, J. G. M. (1993) Calibration facilities for industrial gas flow meters in The Netherlands. Flow Measurement and Instrumentation, 4: 77–84.Google Scholar
Joshi, S. G. (1991) Surface-acoustic-wave (SAW) flow sensor. IEEE Trans on Ultrasonics, Ferroelectrics & Frequency Control, 38.2: 148–154.Google Scholar
Joslin, G. (1879) British Patent, No 2428.
Jousten, K., Menzer, H. and Niepraschk, R. (2002) A new fully automated gas flowmeter at the PTB for flow rates between 10–13 mol/s and 10–6 mol/s. Metrologia, 39(6): 519–529.Google Scholar
Jung, J. C. and Seong, P. H. (2005) Estimation of the flow profile correction factor of a transit-time ultrasonic flow meter for the feed water flow measurement in a nuclear power plant. IEEE Transactions on Nuclear Science, 52(3 II): 714–718.Google Scholar
Jungowski, W. M. and Weiss, M. H. (1996) Effects of flow pulsation on a single-rotor turbine meter. Journal of Fluids Engineering , Transactions ASME, 118: 198–201.Google Scholar
Kabaciński, M. and Pospolita, J. (2008) Numerical and experimental research on new cross-sections of averaging Pitot tubes. Flow Measurement and Instrumentation, 19(1): 17–27.Google Scholar
Kabacinński, M. (2011) Experimental research into a new design of flow-averaging tube. Flow Measurement and Instrumentation, 22(5): 421–427.
Kalivoda, R. J. and Lunde, P. (2005) Liquid ultrasonic flow meters for crude oil measurement. 23rd North Sea Flow Metering Workshop 2005, Paper 17, pages 253–275.
Kalotay, P. (1994) On-line viscosity measurement using Coriolis mass flowmeters. Journal of Flow Measurement and Instrumentation, 5: 303–308.Google Scholar
Kaltsas, G. and Nassiopoulou, A. G. (2004) Gas flow meter for application in medical equipment for respiratory control: Study of the housing. Sensors and Actuators, A: Physical, 110(1–3): 413–422.Google Scholar
Kaltsas, G., Katsikogiannis, P., Asimakopoulos, P. and Nassiopoulou, A.G. (2007) A smart flow measurement system for flow evaluation with multiple signals in different operation modes. Measurement Science and Technology, 18(11): 3617–3624.Google Scholar
Karlsson, K. and Delsing, J. (2013) The gap discharge transducer as a sound pulse emitter in an ultrasonic gas flow meter. FLOMEKO 2013, 16th International Flow Measurement Conference, Paris, France.
Karnik, U. (1995) A compact orifice meter/flow conditioner package, Proceedings of the American Gas Association Operating Section, Las Vegas, 95-OP-009:564–585.
Karnik, U. (2000) Centaur round robin test traceability of Transcanada calibrations facility. FLOMEKO'2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper A5.
Karnik, U. and Geerligs, J. (2002) Effect of steps and roughness on multi-path ultrasonic meters. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Karnik, U., Jungowski, W. M. and Botros, K. (1991) Effects of flow characteristics downstream of elbow/flow conditioner on orifice meter accuracy. Proceedings of the 9th North Sea Flow Measurement Workshop, Norwegian Society of Chartered Engineers.
Karnik, U., Jungowski, W. M. and Botros, K. (1994) Effect of turbulence on orifice meter performance. Journal of Offshore Mechanics and Arctic Engineering, 116.2: 77–85.Google Scholar
Katys, G. P. (1964) Continuous measurement of unsteady flow. Chapter 2: 37-?. Pergamon Press Ltd, London, England.
Katz, L. (1971) Improved flowmeter accuracy with electromechanical feedback. Proc. 1st Symp. on Flow – Its Measurement and Control in Science and Industry, Pittsburgh, Penn, USA. (Published by ISA 1, Pt. 2, 1974: 669–678.)
Kawaguchi, T., Aiba, T., Tsukada, K., Tsuzuki, N., Kikura, H., Sugita, K. and Umezawa, S. (2015) Non-intrusive measurement of steam flow rate in a steel pipe by means of a clamp-on ultrasound flowmeter. 9th international symposium of Fluid Flow Measurement, Arlington, VA, USA.
Kawano, T., Miyata, T., Shikuya, N., Takahashi, S., Handoh, M., Itoh, I. and Biles, B. (1992) Intelligent flowmeter. Proceedings of the Conference on Advances in Instrumentation and Control, (ISA) Houston, USA: 997–1009.
Kay, J. M. and Nedderman, R. M. (1974) An introduction to fluid mechanics and heat transfer. Cambridge University Press.
Kaye, G. W. C. and Laby, T. H. (1966) Tables of physical and chemical constants. Longmans.
Keech, R. P. (1982) The KPC multichannel correlation signal processor for velocity measurement. Transactions of the Institute of Measurement and Control, 4: 43-52Google Scholar
Kegel, T. (2002a) Uncertainty analysis of a volumetric primary standard. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Kegel, T. (2002b) Large scale calibration facility. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Kegel, T. and Cousins, T. (2012) Different requirements and methods for calibrating gas and liquid ultrasonic flow custody transfer meters . North Sea Flow Measurement Workshop, Scotland 2012.
Kegel, T. and English, S. (2011) A proposed ultrasonic meter recalibration interval. 29th North Sea Flow Metering Workshop, Paper 23.
Keita, N. M. (1989a) The zero drift effect in Coriolis mass flow meter. Mass Flow Measurement Direct and Indirect, Proc Int Conf Mass Flow Measurement, IBC Pbl, London, England.
Keita, N. M. (1989b) Contribution to the understanding of the zero shift effects in Coriolis mass flowmeters. Flow Measurement and Instrumentation, 1: 39–43.Google Scholar
Keita, N. M. (1990) Performance of Coriolis mass flowmeters in the metering of light fluids. Int Conf Flow Measurement of Commercially Important Fluids, London, England.
Keita, N. M. (1994) Behaviour of straight pipe Coriolis mass flowmeters in the metering of gas: theoretical predictions with experimental verification. Journal of Flow Measurement and Instrumentation, 5: 289–294.Google Scholar
Keita, N. M. (2000) Ab initio simulation of Coriolis mass flowmeter. FLOMEKO'2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper C9.
Kettle, R. J., Ross, D. and Deznan, D. (2002) The multiphase flowmeter, a tool for well performance diagnostics and production optimization. SPE – Asia Pacific Oil and Gas Conference, 591–598.
Keyser, D. R. (1973) The calibration correlation function for positive displacement liquid meters. Trans. ASME, 95, Series I, No. 2: 180–188.Google Scholar
Kiehl, W. (1991) Difference measurement using Coriolis mass flowmeters. Journal of Flow Measurement and Instrumentation, 2: 135–138.Google Scholar
Kiehl, W. and Gartner, U. (1989) Two Coriolis meters in one line. Mass Flow Measurement Direct and Indirect, Proc Int Conf Mass Flow Measurement, IBC Pbl, London, England.
Kikura, H., Yamanaka, G. and Aritomi, M. (2004) Effect of measurement volume size on turbulent flow measurement using ultrasonic Doppler method. Experiments in Fluids, 36(1): 187–196.Google Scholar
Kim, B.-C., Pak, B.-C., Cho, N.-H., Chi, D.-S., Choi, H.-M., Choi, Y.-M. and Park, K.-A. (1997) Effects of cavitation and plate thickness on small diameter ratio orifice meters. Journal of Flow Measurement and Instrumentation, 8(2): 85–92.Google Scholar
Kim, C. H., Lee, D. K. and Paik, J. S. (1993a) Mean velocity measurement of pipe flow by ultrasonic correlation. FLOMEKO '93 Proceedings of the 6th International Conference on Flow Measurement, Korea: 550–558.
Kim, D. K., Han, I. Y. and Kim, S. J. (2003) Study on the transient characteristics of the sensor tube of a thermal mass flow meter. American Society of Mechanical Engineers, Heat Transfer Division, (Publication) HTD, 374(3): 79–86.
Kim, D. K. (2007b) Study on the steady-state characteristics of the sensor tube of a thermal mass flow meter. International Journal of Heat and Mass Transfer, 50(5–6): 1206–1211.Google Scholar
Kim, D.-K., Majumdar, A. and Kim, S. J. (2007a) Electrokinetic flow meter. Sensors and Actuators, A: Physical, 136(1): 80–89.
Kim, H-M., Kim, K-Y., Her, J-Y. and Ha, Y-C. (2002) Three-dimensional flow analysis for estimation of measuring error of orifice flowmeter due to upstream flow distortion. American Society of Mechanical Engineers, Fluids Engineering Division (Publication) FED, 257(1 A): 121–126.
Kim, J., Ahn, Y.-C. and Kim, M. H. (2009) Measurement of void fraction and bubble speed on slug flow with three-ring conductance probes. Journal of Flow Measurement and Instrumentation, 20(3): 103–109.Google Scholar
Kim, J.-H., Kim, H.-D. and Park, K.-A. (2006) Computational/experimental study of a variable critical nozzle flow. 12th International Conference on Flow Measurement FLOMEKO Guilin China. Flow Measurement and Instrumentation 17(2): 81–86.Google Scholar
Kim, R. K., Swain, J. C., Kramer, G. S., Cooper, D. L., Schuluer, L. E. and Haubert, T. D. (1993b) Progress on development of a compact gas meter. FLOMEKO '93 Proceedings of the 6th International Conference on Flow Measurement, Korea Research Institute of Standards and Science: 393–402.
Kim, Y. and O'Neal, D. L. (1995) Comparison of critical flow models for estimating two-phase flow of HCFC22 and HFC134a through short tube orifices. International Journal of Refrigeration, 18.7: 447–455.Google Scholar
Kim, Y.-K. and Kim, Y.-H. (1996) A three accelerometer method for the measurement of flow rate in pipe. J. Acoust. Soc. Am., 100(2 Pt 1): 717–726. Advances in Instrumentation and Control: International Conference and Exhibition, New Orleans, LA, USA, 50(2): 643–651.Google Scholar
Kimpton, S. and Niazi, A. (2008) Thermal lagging – the impact on temperature measurement. 26th International North Sea Flow Measurement Workshop, 21–24 October 2008, St Andrews, Scotland, Paper 8.3.
King, D. C. (2004) Benefits of ISO 17025 accreditation for providers and users of calibration gases used in environmental testing. Air Waste Management Association, 97th Annual Conference, 2004, 127(2004), pp. 3651–62.
King, J. O. and Rollwitz, W. L. (1983) Magnetic resonance measurement of flowing coal. Trans ISA 22: 69–76.Google Scholar
King, L. V. (1914) On the convection of heat from small cylinders in a stream of fluid. Philosophical Transactions of the Royal Society, A214: 373–432.Google Scholar
King, N. W. (1988) Multi-phase flow measurement at NEL. Measurement & Control, 21.8.Google Scholar
King, N. W. (1990) Subsea multi-phase flow metering a challenge for the offshore industry? Subsea 90 International Conference, London.
King, N. W., Sidney, J. K. and Coulthard, J. (1988) Cross-correlation flow measurements in oil-air mixtures. 2nd Int Conf Flow Measurement, BHRA, London, UK.
Kinghorn, F. C. (1982) The analysis and assessment of data. Developments in Flow Measurement-1, ed Scott, R. W. W., London: Applied Science Publishers: 307–326.
Kinghorn, F. C. (1986) The expansibility correction for orifice plates: EEC data. International Conference on Flow Measurement in the Mid 80's Paper 5.2.
Kinghorn, F. C. (1988) Challenging areas in flow measurement. Meas. Control Measurement and Control, 21(8): 229–235.Google Scholar
Kinghorn, F. C. (1996) Industrial needs for cost-effective flow measurement. FLOMEKO'96 Proc. 8th Int. Conf. on Flow Measurement, Beijing, China: 741–50.
Kinghorn, F. C., McHugh, A. and Dyet, W. D. (1991) The use of etoile flow straighteners with orifice plates in swirling flow. Journal of Flow Measurement and Instrumentation, 2: 162–168.Google Scholar
Kivilis, S. S. and Reshetnikov, V. A. (1965) Effect of a stabilised flow profile on the error of ultrasonic flowmeters. Measurement Techniques, No. 3: 276.Google Scholar
Kjolberg, S. A. and Berentsen, H. (1997) The Porsgrunn 2 test programme of multiphase meters: general results and examples of different meter performance. North Sea Flow Measurement Workshop Kristiansand, Norway: Paper 2.
Kleppe, K. and Danielsen, H. B. (1993) Scaling problems in the oil metering system at the Veslefrikk Field . North Sea Flow Measurement Workshop, Bergen, Norway.
Kneisley, G., Lansing, J. and Dietz, T. (2009) Ultrasonic meter condition based monitoring – a fully automated solution. 27th International North Sea Flow Measurement Workshop, Tonsberg, Norway, 20–23 October 2009, pp. 253–274.
Kocbach, J. (2000) Finite element modeling of ultrasonic piezoelectric transducers: Influence of geometry and material parameters on vibration, response functions and radiated field. Doctoral dissertation, University of Bergen, Department of Physics, September 2000.
Koechner, H. and Melling, A. (2000) Numerical simulation of ultrasonic flowmeters. Acta Acustica (Stuttgart), 86(1): 39–48.Google Scholar
Koechner, H., Melling, A. and Baumgartner, M. (1996) Optical flow field investigation for design improvements of an ultrasonic gas meter. Journal of Flow Measurement and Instrumentation, 7: 133–140.Google Scholar
Koizumi, H. and Serizawa, M. (2008) A micro flowmeter based on the velocity measurement of a locally accelerated thermal flow in an upwardly directed Hagen-Poiseuille flow. Flow Measurement and Instrumentation, 19(6): 370–376.
Kolahi, K., Gast, Th. and Rock, H. (1994) Coriolis mass flowmeasurement of gas under normal conditions. Journal of Flow Measurement and Instrumentation, 5: 275–283.Google Scholar
Kolin, A. (1936) An electromagnetic flowmeter. The principle of the method and its application to blood flow measurement. Proc. Soc. Exp. Biol., NY, 35: 53.Google Scholar
Kolin, A. (1941) An AC flowmeter for measurement of blood flow in intact blood vessels. Proc. Soc. Exp. Biol., NY, 46: 235.Google Scholar
Komiya, K., Higuchi, F. and Ohtani, K. (1988) Characteristic of a thermal gas flowmeter. Review of Scientific Instruments, 59: 477–479.Google Scholar
Kondo, M. and Takahashi, M. (2005) Metallurgical study on electro-magnetic flow meter and pump for liquid lead-bismuth flow. Progress in Nuclear Energy, 47(1–4): 639–647.Google Scholar
Koning, H., Van Essen, G. J. and Smid, J. (1989) Time behaviour of turbine meters – statistical analysis of (re)calibration results of turbine meters. FLOMEKO'89 Proceedings of the 5th International Conference on Flow Measurement: 333–340.
Koschmieder, F. and Röck, H. (2010) Compensation method applied to Coriolis mass flow metering. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A9-5.
Koudal, O., Bitto, E. and Wenger, A. (1996) A solution to the problem of installation sensitivity of small Coriolis mass flowmeters. FLOMEKO'96 Proceedings of the 8th International Conference on Flow Measurement, Beijing, China: 256–259.
Krafft, R., Hemp, J. and Sanderson, M. L. (1996) Investigation into the use of the electromagnetic flowmeter for two-phase flow measurements. Advances in Sensors for Fluid Flow Measurement, IEE Colloquium (Digest) No. 092: 5/1–5/4.
Kragas, T. K., Mayeu, C., Gysling, D. L., van der Spek, A. and BostickIII, F. X. (2002) Downhole fibre-optic multiphase flowmeter. Journal of Petroleum Technology, 54(12): 59–61.Google Scholar
Kragas, T. K., Johansen, E. S., Hassanali, H. and Da Costa, S. L. (2003a) Installation and data analysis of a downhole, fibre optic flowmeter at Mahogany Field, offshore Trinidad. Proceedings of the SPE Latin American and Caribbean Petroleum Engineering Conference, pp. 163–176.
Kragas, T. K., Mayeu, C. W., Gysling, D. L., van der Spek, A. M. and BostickIII, F. X. (2003b) Downhole fibre-optic flowmeter: design, operating principle, testing, and field installations. SPE Production and Facilities, 18(4): 257–268.Google Scholar
Krajcin, I., Uhrig, M., Wrath, A., Dietz, T. and Herrmann, V. (2007) Impact of regulator noise on ultrasonic flow meters in natural gas. 25th International North Sea Flow Measurement Workshop, Energy Institute, Oslo, Norway, 206–224.
Kramer, R. and Mickan, B. (2012) The Application of small sonic nozzles in test rigs with natural gas. Proc. 8th International Symposium on Fluid Flow Measurement (ISFFM), Colorado, USA, 20–22 June.
Kramer, R., Mickan, B. and Schmidt, R. (2010) The application of critical nozzles in series for the determination of small flow rates and the generation of gas mixtures. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A6-3.
Krassow, H., Campabadal, F. and Lora-Tamayo, E. (1999) Smart-orifice meter: a mini head meter for volume flow measurement. Flow Measurement and Instrumentation, 10(2): 109–115.Google Scholar
Kratirov, V., Jamieson, A., Blaney, S. and Yeung, H. (2006) Neftemer – a versatile and cost effective multiphase meter, 24th International North Sea Flow Measurement Workshop, 24–27 October 2006.
Kratzer, W. and Kefer, V. (1988) Two phase flow instrumentation: a survey and operational experience with new and easy-to-handle devices. Cranfield Short Course Lecture.Google Scholar
Krautkramer, J. and Krautkramer, H. (1990) Ultrasonic testing of materials. Springer-Verlag.
Kristensen, B. D., Lofsei, C. and Frøysa, K-E. (1997) Testing of noise suppression system for multipath ultrasonic gas flow meters. North Sea Flow Measurement Workshop Kristiansand, Norway: Paper 17.
Kritz, J. (1955) An ultrasonic flowmeter for liquids. Proc. ISA, 10: 1-55-15-3.Google Scholar
Krokstad, A., Strøm, S. and Sørsdal, S. (1968) Calculating the acoustical room response by the use of a ray tracing technique. Journal of Sound and Vibration, 8(1): 118–125.Google Scholar
Kruger, G. J., Birke, A. and Weiss, R. (1996) Nuclear magnetic resonance (NMR) two-phase mass flow measurements. Journal of Flow Measurement and Instrumentation, 7: 25–37.Google Scholar
Kuchler, Heiko (1999) Special durchflussmessung. Mit volldampf sparen: Ultraschall- messsystem ermoghcht messung ohne druckverlust (Translation: Flow measurement special. Save with full steam: Ultrasound measurement system enables measurement without pressure drop). Chemie-Technik (Heidelberg), 28(8): S20–S21 (in German).
Kumar, P. and Ming Bing, M. W. (2011) A CFD study of low pressure wet gas metering using slotted orifice meters. Journal of Flow Measurement and Instrumentation, 22(1): 33–42.Google Scholar
Kumar, V., Anklin, M. and Schwenter, B. (2010) Fluid-structure interaction (fsi) simulations on the sensitivity of Coriolis flow meter under low Reynolds number flows. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A9-2.
Kunze, J. W., Storm, R. and Wang, T. (2014) Coriolis mass flow measurement with entrained gas. Proceedings of Sensors and Measuring Systems 2014 17 ITG/GMA Symposium
Kuo, C.-Y., Ho, Y.-L., Dietz, T., Wang, W.-B. Yang, F.-R., Su, C.-M. and Shaw, J.-H. (2012) Calibration of ultrasonic flow meter using blow-down type high pressure gas flow standard. International Symposium on Fluid Flow Measurement (2012).Google Scholar
Kuoppamäki, R. (2003) Guidelines for efficient improvement of accuracy in oil and gas flow measurements. 21st North Sea Flow Metering Workshop 2003, Paper 2.
Kupnik, M., O'Leary, P., Schröder, A. and Rungger, I.(2003) Numerical simulation of ultrasonic transit-time flowmeter performance in high temperature gas flows. IEEE Ultrasonics Symposium, 2: 1354–1359.Google Scholar
Kupnik, M., Schröder, A., O'Leary, P., Benes, E. and Gröschl, M. (2004) An Ultrasonic Transit-Time Gas Flowmeter for Automotive Applications IEEE Sensors 2004 Proceedings IEEE1: 451–454.Google Scholar
Kupnik, M., Schröder, A. and Gröschl, M. (2006a) PS-16 adaptive asymmetric double-path ultrasonic transit-time gas flowmeter. IEEE Ultrasonic Symposium, 2429–2432.Google Scholar
Kupnik, M., Schröder, A., O'Leary, P., Benes, E. and Gröschl, M.(2006b) Adaptive pulse repetition frequency tfor an ultrasonic transit-time gas flowmeter for hot pulsating gases. IEEE Sensors Journal, 6(4), August 2006: 906–915.Google Scholar
Kupyna, A., Rukke, E.-O. Schüller, R. B. and Isaksson, T. (2008) The effect of flow rate, accelerometer location and temperature in acoustic chemometrics on liquid flow: spectral changes and robustness of the prediction models. Chemometrics and Intelligent Laboratory Systems, 2008; 93: 87–97.Google Scholar
Kurnadi, D. and Trisnobudi, A. (2006) A multi-path ultrasonic transit time flow meter using a tomography method for gas flow velocity profile measurement. Particle and Particle Systems Characterization, 23(3–4): 330–338.Google Scholar
Kuromori, K. et al. (1988) ADMAG series magnetic flowmeters using dual frequency excitation. Yokogawa Technical Report, 32(3): 129–134 (In Japanese) cf 5th FLOMEKO 1989, pp 135–42.Google Scholar
Kuromori, K., Goro, Sh. and Matsunaga, Y. (1989) Advanced magnetic flowmeters with dual excitation. Proc. 5th International MEKQ Conference on Flow Measurement, Dusseldorf, VDI Ver1ag, pp. 135–142.
Kurz, J. L. (1992) Characteristics and applications of industrial thermal mass flow transmitters. Proceedings – Annual Symposium on Instrumentation for the Process Industries (TX, USA): 107–113.
Kutin, J. and Bajsić, I. (1999) Characteristics of the shell-type Coriolis flowmeter. Journal of Sound and Vibration, 228(2): 227–242.Google Scholar
Kutin, J. and Bajsić, I. (2001) Stability boundary effect in Coriolis meters. Journal of Flow Measurement and Instrumentation, 12 (1): 65–73.Google Scholar
Kutin, J., Hemp, J., Bobovnik, G. and Bajsić, I. (2005a) Weight vector study of velocity profile effects in straight-tube Coriolis flowmeters employing different circumferential modes. Flow Measurement and Instrumentation, 16(6): 375–385.Google Scholar
Kutin, J., Bajsić, I., Bobovnik, G. and Hemp, J. (2005b) Modelling and evaluation of velocity profile effects on Coriolis flowmeters. Flomeko 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 6.4.
Kutin, J., Bobovnik, G., Hemp, J. and Bajsić, I. (2006) Velocity profile effects in Coriolis mass flowmeters: recent findings and open questions. Flow Measurement and Instrumentation, 17(6): 349–358.Google Scholar
Kwietniewski, M. and Miszta-Kruk, K. (2005) Selected methods of flow measurement for the purposes of wastewater networks monitoring. Proceedings of SPIE – The International Society for Optical Engineering, 5775: 511–519.Google Scholar
Laan, D. (2012) Ultrasonic Flowmeters, latest developments now used in praxis. International Symposium on 8th International Symposium on Fluid Flow Measurement.
Lai, M-C., Lee, T., Xu, J. S. and Kwak, S. (1991) Inlet flow characterization of thermal mass air flow meters. SAE Transactions, 100: 813–819.Google Scholar
Laithier, B. E. and Paidoussis, M. P. (1981) The equations of motion of initially stressed Timoshenko tubular beams conveying fluid. Journal of Sound and Vibration, 79, (2): 175–195.Google Scholar
Lamb, H. (1925) The dynamical theory of sound. Edward Arnold Ltd (see also Dover Publications Inc, New York 1960).
Laneville, A., Strzelecki, A., Gajan, P. and Hebrard, P. (1993) Signal quality of a vortex flowmeter exposed to swirling flows. Journal of Flow Measurement & Instrumentation, 4: 151–154.Google Scholar
Lange, U., Levien, A., Pankratz, T. and Raszillier, H. (1994) Effect of detector masses on calibration of Coriolis flowmeters. Journal of Flow Measurement and Instrumentation, 5: 255–262.Google Scholar
Langsholt, M. and Thomassen, D. (1991) The computation of turbulent flow through pipe fittings and the decay of the disturbed flow in a downstream straight pipe. Journal of Flow Measurement and Instrumentation, 2: 45–55.Google Scholar
Lansing, J. (2000) Smart monitoring and diagnostics for ultrasonic meters, NSFMW 2000, Gleneagles, Scotland.
Lansing, J. (2002a) Dirty vs. clean ultrasonic gas flow meter performance. Proceedings of the Annual ACM-SIAM Symposium on Discrete Algorithms, 989–999.
Lansing, J. (2002b) Dirty vs. clean ultrasonic gas flow meters results. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Lansing, J. (2012) How today's gas ultrasonic meter handles compressor pulsations. 8th International Symposium On Fluid Flow Measurement.
Lansing, J. and Mooney, T. (2004) Dirty vs. clean ultrasonic gas flow meter performance. 22nd North Sea Flow Metering Workshop 2004, Paper 2.3.
Lansing, J., Herrmann, V. and Dietz, T. (2007) The relevance of two different path layouts for diagnostic purposes in one ultrasonic meter. 25th International North Sea Flow Measurement Workshop, Energy Institute, Oslo, Norway, 418–434.
Lansing, J., Ehrlich, A. and Dietz, T. (2009) Examination of ultrasonic flow meter in CO2-rich applications. Proc. 7th International Symposium on Fluid Flow Measurement (ISFFM), Anchorage, Alaska, USA.
Lapszewicz, J. A. (1991) Device for measurement of volumetric flow rates of gas mixtures. Measurement Science & Technology, 2.8: 815–817.Google Scholar
Laribi, B., Wauters, P. and Aichouni, M. (2003) Experimental study of the decay of swirling turbulent pipe flow and its effect on orifice meter performance. Proceedings of the ASME Fluids Engineering Division Summer Meeting, 1: 93–96.Google Scholar
Lashkari, S. and Kruczek, B. (2008) Development of a fully automated soap flowmeter for micro flow measurements. Flow Measurement and Instrumentation, 19(6): 397–403.Google Scholar
Laws, E. M. (1990) Flow conditioning – a new development. Journal of Flow Measurement and Instrumentation, 1: 165–170.Google Scholar
Laws, E. M. (1991) A further study of flow through tube bundles. FLUCOME ’91, 3rd Triennial International Symposium on Fluid Control, ASME, Measurement and Visualization, San Francisco, Cal USA: 635–641.
Laws, E. M. and Harris, R. (1993) Evaluation of a swirl-vor-tab flow conditioner. Journal of Flow Measurement and Instrumentation, 4: 101–108.Google Scholar
Laws, E. M. and Ouazzane, A. (1992) Effect of plate depth on the performance of a Zanker flow straightener. Journal of Flow Measurement and Instrumentation, 3: 257–269.Google Scholar
Laws, E. M. and Ouazzane, A. (1995a) A further investigation into flow conditioner design yielding compact installations for orifice plate flow metering. Journal of Flow Measurement and Instrumentation, 6: 187–199.Google Scholar
Laws, E. M. and Ouazzane, A. K. (1995b) A further study into the effect of length on the Zanker flow conditioner. Journal of Flow Measurement and Instrumentation, 6: 217–224.Google Scholar
Laws, E. M. and Ouazzane, A. K. (1995c) A preliminary study into the effect of length on the performance of the Etoile flow straightener. Journal of Flow Measurement and Instrumentation, 6: 225–233.Google Scholar
Lawson, B. (1988) Field experience using Coriolis mass meters I. North Sea Metering Workshop, National Engineering Laboratory, East Kilbride, Scotland.
Le Brusquet, L. and Oksman, J. (1999) Improving the accuracy of tracer flow-measurement techniques by using an inverse-problem approach. Measurement Science and Technology, 10: 559–563.Google Scholar
Leder, A. (1996) LDA-measurements in the near wake flow of floats for variable-area flowmeters. FLOMEKO '96 Proceedings of the 8th International Conference on Flow Measurement, Beijing, China: 468–473.
Lee, B., Cheesewright, R. and Clark, C. (2004) The dynamic response of small turbine flowmeters in liquid flows. Flow Measurement and Instrumentation, 15(5–6): 239–248.Google Scholar
Lee, W. F. Z. and Evans, H. J. (1965) Density effect and Reynolds number effect on gas turbine flowmeters. Journal of Basic Engineering, Trans. ASME: 1043–1057.Google Scholar
Lee, W. F. Z. and Evans, H. J. (1970) A field method of determining gas turbine meter performance. Journal of Basic Engineering, Trans. ASME: 724–731.Google Scholar
Lee, W. F. Z. and Karlby, H. (1960) A study of viscosity effect and its compensation on turbinetype flowmeters. Journal of Basic Engineering, 1960: 717–727.Google Scholar
Lee, W. F. Z., Kirik, M. J. and Bonner, J. A. (1975) Gas turbine flowmeter measurement of pulsating flow. Journal of Engineering for Power, Trans ASME: 531–539.Google Scholar
Lee, W. F. Z., Blakeslee, D. C. and White, R. V. (1982) A self-correcting and self-checking gas turbine meter. Journal of Fluids Engineering, 104: 143–148.Google Scholar
Leeungculsatien, T. and Lucas, G.P. (2013) Measurement of velocity profiles in multiphase flow using a multi-electrode electromagnetic flowmeter. Flow Measurement and Instrumentation, 31: 86–95.Google Scholar
Leggett, R. B., Borling, D. C., Powers, B. S., Shehata, K., Halvorsen, M. and AboElenain, A. (1996) Multiphase flowmeter successfully measures three-phase flow at extremely high gas column fractions – Gulf of Suez, Egypt, European Petroleum Conference, Milan, Society of Petroleum Engineers, SPE 36837: 215–226.
Legtenberg, R., Bouwstra, S. and Fluitman, J. H. J. (1991) Resonating microbridge mass flow sensor with low-temperature glass-bonded cap wafer. Sensors & Actuators, A: Physical, 27.1–3, 723–727.Google Scholar
Lehde, H. and Lang, W T. (1948) AC electromagnetic induction flow meter. US Patent 2,435,043.
Lemon, D. D. (1995) Measuring intake flows in hydroelectric plants with an acoustic scintillation flowmeter. ASCE Waterpower – Proceedings of the International Conference on Hydropower, 3: 2039–2048.
Lenn, C. P. and Oddie, G. M. (1990) The use of ultrasonic methods for monitoring secondary components (solid, liquid and gas) entrained in bulk liquid flows . International Conference on Basic Principles and industrial Applications of Multiphase Flow, IBC Technical Services Ltd, London.
Letton, W., Svaeren, J. A. and Conort, G. (1997) Topside and subsea experiences with the multiphase flowmeter, Proceedings SPE Annual Technical Conference, 345–357.
Levien, A. and Dudiak, A. (1995) How Coriolis meter design affects field performance. ISA TECH/EXPO Technology Update Conference Proceedings, 1995.
Lewis, D. C. G. (1975) Further development of a low-loss flowmetering device (Epiflo) based on the pressure difference principle. Conference on Fluid Flow Measurement in the Mid-1970s, National Engineering Laboratory, Glasgow, Scotland: Paper J3.
Li, B., Yao, J. and Li, X. (2003) The analysis and application of the rectangular electromagnetic flowmeter. Conference Record – IEEE Instrumentation and Measurement Technology Conference, 1: 490–499.Google Scholar
Li, C. and Mickan, B. (2012a) The investigation on the flow characteristic of small MEMS nozzle. Proc. 8th International Symposium on Fluid Flow Measurement (ISFFM).
Li, C. and Mickan, B. (2012b) The humidity effect on the calibration of discharge coefficient of sonic nozzle by means of pVTt facility. Proc. 8th International Symposium on Fluid Flow Measurement (ISFFM).
Li, C. H., Peng, X. F. and Wang, C. (2010) Influence of diffuser angle on discharge coefficient of sonic nozzles for flow-rate measurements. Flow Measurement and Instrumentation, 21(4): 531–537.Google Scholar
Li, X., Huang, Z.-Y., Wang, B.-L. and Li, H.-Q. (2008a) Using single-phase flowmeters in oil-water two-phase flow measurement. Kung Cheng Je Wu Li Hsueh Pao/Journal of Engineering Thermophysics, 29(11): 1872–1874. (in Chinese)Google Scholar
Li, Y., Meng, L., Wang, J. and Geng, Y. (2008b) A new type of wet gas online flow meter based on dual slotted orifice plate. Proceedings of SPIE – The International Society for Optical Engineering, 7127. 7th International Symposium on Instrumentation and Control Technology: Sensors and Instruments, Computer Simulation, and Artificial Intelligence, Beijing, China.
Li, Y., Wang, J. and Geng, Y. (2009) Study on wet gas online flow rate measurement based on dual slotted orifice plate. Flow Measurement and Instrumentation, 20(4–5): 168–173.Google Scholar
Li, Y. T. and Lee, S. Y. (1953) A fast-response true-mass-rate flowmeter. Transactions on ASME, 75: 835–841.Google Scholar
Li, Z. and Wang, C. (2004) On the standardization of elbow flow meters. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Lim, J. M., Yoon, B.H., Oh, Y. K. and Park, K-A. (2009) The humidity effect on air flow-rates in a critical flow Venturi nozzle. Proc. 7th International Symposium On Fluid Flow Measurement (ISFFM), Anchorage, Alaska, USA.
Lim, J.-M., Yoon, B.-H., Jpmg, S., Choi, H.-M. and Park, K.-A. (2010) Step-down procedure of sonic nozzle calibration at low Reynolds numbers. Journal of Flow Measurement and Instrumentation, 21(3): 340–346.Google Scholar
Lim, J. M., Yoon, B. H., Oh, Y. K. and Park, K.-A. (2011) The humidity effect on air flow rates in a critical flow Venturi nozzle. Flow Measurement and Instrumentation, 22(5): 402–405.Google Scholar
Lim, K. W. (2004) An experimental study on the characteristics of oval gear flowmeters. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Lim, K. W. (2005) Equipment stability effects on the uncertainty analysis of oil flow standard system. FLOMEKO 2005 13th International Flow Measurement Conference, Peebles, Scotland, Poster Session.
Lin, Y. and Hans, V. (2004) Influence of inclination of bluff body in flowmeters. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Lin, Y. and Hans, V. (2006) Improvement of ultrasonic cross-correlation measurement of gas flow by bluff body generated vortices. Metrology for a sustainable development: XVIII IMEKO World Congress, Rio de Janeiro, Brazil.
Lin, Y. and Hans, V. (2007) Self-monitoring ultrasonic gas flow meter based on vortex and correlation method. IEEE Transactions on Instrumentation and Measurement, 56(6): 2420–2424.Google Scholar
Lin, Z. H. (1982) Two-phase flow measurements with sharp-edged orifices. International Journal of Multiphase Flow, 8: 683–693.Google Scholar
Lisi, E.L. (1974) Mass flow meter. US Patent 3,785,204, Filed April 6th, 1972, Awarded January 15th, 1974.
Liu, C. Y., Lua, A. C., Chan, W. K. and Wong, Y. W. (1995) Theoretical and experimental investigations of capacitance variable area flowmeter. Transactions of the Institute of Measurement and Control, 17.2: 84–89.Google Scholar
Liu, J., Olsson, G. and Mattiasson, B. (2004) A volumetric meter for monitoring of low gas flow rate from laboratory-scale biogas reactors. Sensors and Actuators, B: Chemical, 97(2–3): 369–372.
Liu, K. T. and Revus, D. E. (1988) Net-oil computer improves water-cut determination. Oil and Gas Journal, Dec.Google Scholar
Liu, K. T., Canfield, D. R. and Conley, J. T. (1986) Application of a mass flow meter for allocation measurement of crude oil production. SPE Production Engineering, 3(4): 633–636.Google Scholar
Liu, R. P., Fuent, M. J., Henry, M. P. and Duta, M. D. (2001) A neural network to correct mass flow errors caused by two-phase flow in a digital Coriolis mass flowmeter. Journal of Flow Measurement and Instrumentation, 12(1): 53–63.Google Scholar
Liu, Y., Lynnworth, L. C. and Zimmerman, M. A. (1998) Buffer waveguides for flow measurement in hot fluids. Ultrasonics, 36: 305–315.Google Scholar
Livelli, G. (2002) DP flow measurement best practices for better plant safety, availability and efficiency. ISA Monterrey, 31–40.Google Scholar
Lloyd, K. E., Guthrie, B. D. and Peters, R. J. W. (2002) A flowmeter calibration facility developed at the University of Iowa to evaluate custody transfer steam flowmeters with a cone differential pressure meter used as the metering standard. Joint Power Generator Conference, Phoenix, Arizona, USA, No: IJPGC2002-26029. (See also ISA TECH/EXPO Technology Update Conference Proceedings, 422:383–95, and ISA TECH/EXPO Technology Update Conference Proceedings, 424–425:733–45.)
Løland, T., Sætran, L. R., Olsen, R., Gran, I. R. and Sakariassen, R. (1998) Cavity flow correction for the ultrasonic flowmeter. FLOMEKO '98 Proceedings of the 9th International Conference on Flow Measurement, Lund, Sweden, 127–131.
Lötters, J. C., Lammerink, T. S. J., Pap, M. G., Sanders, R. G. P., de Boer, M. J., Mouris, A. J. and Wiegerink, R. J. (2013) Integrated micro Wobbe index meter towards on-chip energy content measurement. IEEE 26th International Conference on Micro Electro Mechanical Systems, MEMS 2013, 20–24 January 2013, Taipei, Taiwan.
Lovelock, B. G. (2001) Steam flow measurement using alcohol tracers. Geothermics, 30(6): 641–654.Google Scholar
Lowell, F. C. and Walsh, J. J. (1991) Performance analysis of multipath acoustic flowmeters under various hydraulic conditions. Proceedings of the International Conference on Hydropower, Part 3: 2041–2050.Google Scholar
Lua, A. C. and Zheng, Z. (2003) Numerical simulations and experimental studies on a target fluidic flowmeter. Flow Measurement and Instrumentation, 14(1–2): 43–49.Google Scholar
Lucas, G. P. and Turner, J. T. (1985) Influence of cylinder geometry on the quality of its vortex shedding signal. FLOMEKO ’85, Paper C4: 81–83.
Lucas, G. P. and Jin, N. D. (2001) Measurement of the homogeneous velocity of inclined oil-in-water flows using a resistance cross correlation flow meter. Measurement Science and Technology, 12(9): 1529–1537.Google Scholar
Lunde, P. and Frøysa, K.-E. (2002) Mass and energy measurement of gas using ultrasonic flow meters. Proc. of the 25th Scandinavian Symposium on Physical Acoustics, Norway, 27–30 January 2002.
Lunde, P., Frøysa, K.-E. and Vestrheim, M. (2000) Challenges for improved accuracy and traceability in ultrasonic fiscal flow metering. Proc. of 18th Intern. North Sea Flow Measurem. Workshop, Gleneagles, Scotland.
Lunde, P., Frøysa, K. E. Kippersrud, R. A. and Vestrheim, M. (2003) Transient diffraction effects in ultrasonic meters for volumetric, mass and energy flow measurement of natural gas. 21st North Sea Flow Metering Workshop 2003, Paper 3.
Lunde, P., Vestrheim, M., , R., Smørgrav, S. and Abrahamsen, A. (2005) Reciprocity and its utilization in ultrasonic flowmeter. 23rd North Sea Flow Metering Workshop 2005, Paper 7, pp. 85–112.
Lunde, P., Frøysa, K.-E. and Folkestad, T. (2007) Pressure and temperature effects for Ormen Lange ultrasonic gas flow meters. 25th International North Sea Flow Measurement Workshop, Energy Institute, Oslo, Norway, 97–112.
Lunde, P., Frøysa, K-E., Martinez, V. and Torvanger, Ø. (2008) Pressure and temperature effects for Ormen Lange ultrasonic gas flow meters – results from a follow-up study. 26th International North Sea Flow Measurement Workshop 21–24 October 2008, St Andrews, Scotland, Paper 6.1.
Luntta, E. and Halttunen, J. (1989) Effect of velocity profile on electromagnetic flow measurement. Sensors & Actuators, 16.4: 335–344.Google Scholar
Luntta, E. and Halttunen, J. (1999) Neural network approach to ultrasonic flow measurements. Journal of Flow Measurement and Instrumentation, 10: 33–43.Google Scholar
Luo, S., Liu, Y. and Feng, G. (2002) Application of digital signal processing method in ultrasonic flowmeters for real-time monitoring. Proceedings of the Second International Symposium on Instrumentation Science and Technology, 3: 3/673-3/677.Google Scholar
Luo, S., Liu, Y. and Feng, G. (2003) Digital signal processing implementation of a novel ultrasonic Doppler flowmeter. Proceedings of the International Symposium on Test and Measurement, 1: 282–286.Google Scholar
Lupeau, A., Platet, B., Gajan, P., Strzelecki, A., Escande, J. and Couput, J.P. (2007) Influence of the presence of an upstream annular liquid film on the wet gas flow measured by a Venturi in a downward vertical configuration. Journal of Flow Measurement and Instrumentation, 18(1): 1–11.Google Scholar
Lüscher, B., Staubli, T., Tresch, T. and Gruber, B. (2007). Accuracy analysis of the acoustic discharge measurement using analytical, spatial velocity profiles. Hydro07, Granada.
Lygre, A., Vestrheim, M., Lunde, P. and Berge, V. (1987) Numerical simulation of ultrasonic flowmeters. Proc. of Ultrasonics International 1987, Butterworth Scientific Ltd., Guildford, UK (1987), pp. 196–201.
Lygre, A., Folkestad, T., Sakariassen, R. and Aldal, D. (1992) A new multi-path ultrasonic flow meter for gas . North Sea Flow Measurement Workshop, East Kilbride, Scotland.
Lynch, F. and Horciza, E. (1995) Flow measurement using low cost portable clamp-on ultrasonic flowmeters. ASCE Waterpower – Proceedings of the Int Conf on Hydropower, 1: 766–773.Google Scholar
Lynnworth, L. (1978) Ultrasonic measuring system for differing flow conditions. US Patent 4,103,551
Lynnworth, L. C. (1988) Buffer rod designs for ultrasonic flowmeters at cryogenic and high temperature, plus and minus 2000C. Proceedings of the 34th International Instrumentation Symposium, Albuquerque, USA, (ISA): 697–702.
Lynnworth, L. C. (1989) Ultrasonic Measurements for Process Control: Theory, Techniques, Applications. Academic Press ISBN 0-12-460585-0.
Lynnworth, L. C. (1990) Flexural wave externally-attached mass flowmeter for two-phase fluids in small-diameter tubing, 1-mm ID to 16-mm ID. Proceedings IEEE Ultrasonics Symposium, Honolulu: 1557–1562.
Lynnworth, L. C. (1994) Clamp-on transducers for measuring swirl, cross flow and axial flow. Proceedings IEEE Ultrasonics Symposium, Cannes, France : 1317–1321.Google Scholar
Lynnworth, L. (1999) High-temperature flow measurement with wetted and clamp-on ultrasonic sensors. Sensors (Peterborough, NH), 16(10): 36, 38, 40–42, 44–46, 48, 50–52.Google Scholar
Lynnworth, L. (2000) Ultrasonic buffer/waveguide. US Patent 6,047,602, issued April 11, 2000.
Lynnworth, L. (2001) Clamp-on flowmeters for fluids. Sensors (Peterborough, NH), 18(8): 50–59.Google Scholar
Lynnworth, L. C., Hallewell, G. D. and Bragg, M. I. (1994) One-port profiler. FLOMEKO '94 Flow Measurement in the Mid-90s, NEL, Glasgow, Scotland: Paper 7.3.
Lynnworth, L. C., Nguyen, T. H., Smart, C. D. and Khrakovsky, O. A. (1997) Acoustically isolated paired air transducers for 50-, 100-, 200-, or 500-kHz applications. IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, 44: 1087–1100.
Lynnworth, L. C., Cohen, R., Rose, J. L., Kim, J. O. and Furlong, E. R. (2006) Vortex shedder fluid flow sensor. IEEE Sensors Journal, 6(6): 1488–1496.Google Scholar
Lysak, P. D., Jenkins, D. M., Capone, D. E. and Brown, W. L. (2008a) Analytical model of an ultrasonic cross-correlation flow meter, part 1: Stochastic modelling of turbulence. Flow Measurement and Instrumentation, 19(1): 1–7.Google Scholar
Lysak, P. D., Jenkins, D. M., Capone, D. E. and Brown, W. L. (2008b) Analytical model of an ultrasonic cross-correlation flow meter, part 2: Application. Flow Measurement and Instrumentation, 19(1): 41–46.Google Scholar
Ma, Y. and Eidenschink, T. (2001) Motion induced signals of Coriolis flowmeters. Journal of Flow Measurement and Instrumentation, 12(3): 213–217.Google Scholar
Macdonald, G. A. (1983) A vibrating vane mass flowmeter . 1st European Conf on Sensors and their Applications, UMIST, Manchester: 58–59.
MacMillan, , (1954) Viscosity effects on Pitot tubes at low speeds. Journal of Royal Aeronautical Society,, 58: 570–572.Google Scholar
MacMillan, , (1957) Experiments on Pitot tubes in shear flow. Aero. Res. Council, Tech. Rpt., R&M 3028. 58: 570–572.Google Scholar
Maginnis, T. O. (2002) Dynamical effects in expanding volume flow calibrators. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Mahadeva, D. V. (2009) Studies of the accuracy of clamp-on ultrasonic flowmeters. PhD Thesis, University of Cambridge.
Mahadeva, D. V., Baker, R.C. and Woodhouse, J. (2008) Studies of the accuracy of clamp-on transit time ultrasonic flowmeters. I2MTC 2008 – IEEE International Instrumentation and Measurement Technology Conference, Victoria, Vancouver Island, Canada, 12–15 May.
Mahadeva, D. V., Baker, R.C. and Woodhouse, J. (2009) Further studies of the accuracy of clamp-on transit-time ultrasonic flowmeters for liquids. IEEE Transactions on Instrumentation and Measurement, 58(5): 1602–1609.Google Scholar
Mahadeva, D. V., Huang, S. M., Oddie, G. and Baker, R. C. (2010) Study of the effect of beam spreading on systemic Doppler flow measurement errors. IEEE International Ultrasonics Symposium (IUS), Sponsored by the IEEE Ultrasonics, Ferroelectrics, and Frequency Control SocietySan Diego, California, 11–14 October 2010.
Mahulikar, S. P. and Sane, S. K. (2005) Theoretical analysis of experimentally observed perplexing calibration characteristics of ball-in-vortex flow-meter. Journal of Fluids Engineering, Transactions of the ASME, 127(5): 1021–1028.Google Scholar
Mainardi, H., Barriol, R. and Panday, P. K. (1977) Pulsating duct flow in the presence of an orifice plate. International Journal of Mechanical Sciences, 19: 533–546.Google Scholar
Mair, W. A. (1965) The effect of a rear mounted disc on the drag of a blunt body of revolution. Aeronautical Quarterly, 16: 350–360.Google Scholar
Majeed, G. H. A. and Aswad, Z. A. A. (1989) A new approach for estimating the orifice discharge coefficient required in Ashford-Pierce correlations. Multiphase Flow – Proc 4th Int Conf, BHRA, Cranfield: 235–255.
Majumdar, A. S. and Gulek, M. (1981) Vortex shedding from single and compound prisms of various configurations. ASME Paper No. 81-WA/FE-6.
Malard, L., Wisnoe, W., Strzelecki, A., Gajan, P. and Hebrard, P. (1991) Air visualizations and flow measurements applied to the study of a vortex flowmeter: influence of grid turbulence and acoustical effects. FLUCOME ’91, 3rd Triennial International Symposium on Fluid Control, Measurement and Visualization, San Francisco, Cal, USA: 689–695.
Malinowski, L. and Rup, K. (2008) Measurement of the fluid flow rate with use of an elbow with oval cross section. Flow Measurement and Instrumentation, 19(6): 358–363.Google Scholar
Mandard, E., Kouam, D., Battault, R., Remenieras, J-P. and Patat, F. (2008) Methodology for developing a high-precision ultrasound flow meter and fluid velocity profile reconstruction. IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, 55(1): 161–171.Google Scholar
Mandrup-Jensen, L. (1990) Testing Coriolis mass flowmeters for pattern approval. North Sea Flow Measurement Workshop, National Engineering Laboratory, Scotland.
Mankin, P. A. (1955) Measurement of liquid flow by positive displacement meters. Journal of the Southern California Meter Association, Instruments and Automation: 453–457.Google Scholar
Manshoor, B., Nicolleau, F. C. G. A. and Beck, S. N. M. (2011) The fractal flow conditioner for orifice plate flow meters. Flow Measurement and Instrumentation, 22(3): 208–214.Google Scholar
Marfenko, I., Yeh, T. T. and Wright, J. (2006) Diverter uncertainty less than 0.01% for water flow calibrations. Proc. 6th International Symposium on Fluid Flow Measurement (ISFFM), Querétero, Mexico.
Marić, I. (2005) The Joule-Thomson effect in natural gas flow-rate measurement. Flow Measurement and Instrumentation, 16(6): 387–395.Google Scholar
Marić, I. (2007) A procedure for the calculation of the natural gas molar heat capacity, the isentropic exponent, and the Joule-Thomson coefficient. Journal of Flow Measurement and Instrumentation, 18(1): 18–26.Google Scholar
Marić, I. and Ivek, I. (2010) Compensation for Joule-Thomson effect in flowrate measurement by GMDH polynomial. Flow Measurement and Instrumentation, 21(2): 134–142.Google Scholar
Marić, I., Galović, A. and Šmuc, T. (2005) Calculation of natural gas isentropic exponent. Flow Measurement and Instrumentation, 16(1): 13–20.Google Scholar
Mark, P. A., Sproston, J. L. and Johnson, M. W. (1990a) Theoretical and experimental studies of two-phase flows in turbine meters. International Conference on Basic Principles and Industrial Applications of Multiphase Flow, IBC Technical Services Ltd, London.
Mark, P. A., Johnson, M. W., Sproston, J. L. and Millington, B. C. (1990b) The turbine meter applied to void fraction determination in two-phase flow. Flow Measurement and Instrumentation, 1: 246–252.Google Scholar
Markoja, B. (2011) CIDRA SONARtrac flow meters: an alternative flow measurement technology. Committee on Operation and Maintenance of Nuclear Power Plant / ISTOG Winter Meeting, 5–9 December 2011, Clearwater, Florida, USA.
Maron, R. and O'Keefe, C. (2007) Application of non-intrusive sonar technology in hydrotransport. FLUIMIN IV Taller de Concentaductos, Mineroductos Y Relaveductos, 18–19 October, Vina del Mar, Chile.
Marshad, A. H. and Irvine-Halliday, D. (1994) Intensity-modulated optical-fibre vortex-shedding flowmeter. Canadian Journal of Electrical and Computing Engineering, 119: 75–79.Google Scholar
Marshall, Rebekkah (2004) Accurate flow measurement, pure and simple. Chemical Engineering, 111(4): 19–22.Google Scholar
Martin, J. J. (1949) Calibration of rotameters. Chemical Engineering. Progress, 45: 338.Google Scholar
Martin, P. (2009) Realistic pipe prover volume uncertainty. 27th International North Sea Flow Measurement Workshop, Tonsberg, Norway, 20–23 October 2009, pp. 412–437.
Martinelli, M. and Viktorov, V. (2011) A mini fluidic oscillating flowmeter. Flow Measurement and Instrumentation, 22(6): 537–543.Google Scholar
Martinsson, E. and Delsing, J. (2009) Environmental tests of spark discharge emitter for use in ultrasonic gas flow measurements, Proc. 7th International Symposium on Fluid Flow Measurement (ISFFM), Anchorage, Alaska, USA.
Martinsson, E. and Delsing, J. (2010) Electric spark discharge as an ultrasonic generator in flow measurement situations. Journal of Flow Measurement and Instrumentation, 21(3): 394–401.Google Scholar
Masri, S., Lin, W.-T. and Su, C.-M. (2010) New primary low-pressure gas flow standard at NIMT. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A5-3.
Matson, J., Marioano, C. F., Khrakovsky, O. and Lynnworth, L. (2002) Ultrasonic mass flowmeters using clamp-on or wetted transducers. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Matsunaga, Y., Goto, S., Kuromori, K. and Ostling, H. (1988) New intelligent magnetic flowmeter with dual frequency excitation. Proceedings of the ISA/88 International Conference and Exhibition: Advances in Instrumentation, ISA, 43, Part 3: 1259–1267.
Matsunaga, Y., Takahashi, S. and Kuromori, K. (1990) Numerical analysis of a vortex flowmeter and comparison with experiment. Journal of Flow Measurement & Instrumentation, 1: 106–112.Google Scholar
Mattar, L., Nicholson, M., Aziz, K. and Gregory, G. A. (1979) Orifice metering of two-phase flow. Journal of Petroleum Technology, August:: 955–961.Google Scholar
Mattar, W. (2003) Coriolis metering in difficult industrial applications. IEE Computing and Control Engineering, 14(4): 44–45.Google Scholar
Mattar, W. M. (2005) Advances in Coriolis technology resolve tough pipeline flow measurement challenges. Pipeline and Gas Journal, 232(7): 35–36.Google Scholar
Matter, D., Kleiner, T., Kramer, B. and Sabbattini, B. (2003) Microsensor-based gas flow meter wins innovation prize. ABB Review, (3): 49–50.Google Scholar
Matthews, A. J. and Ayling, C. L. (1992) Compact large bore direct mass flow meters . North Sea Flow Measurement Workshop, East Kilbride, Scotland.
Mattingly, G. E. (1982) Primary calibrators, reference and transfer standards. Developments in Flow Measurement-1, ed. Scott, R. W. W., London: Applied Science Publishers: 31–71.
Mattingly, G. E. (1990/1991) Fluid flowrate metrology: Laboratory uncertainties and traceabilities. Advanced Techniques for Integrated Circuit Processing, Int Soc Optical Eng, Proceedings of SPIE, 1392: 386–401.Google Scholar
Mattingly, G. E. (2009) Improved meter performance characterizations for liquid and gas turbine meters. Proc. 7th International Symposium on Fluid Flow Measurement (ISFFM), Anchorage, Alaska, USA.
Mattingly, G. E. and Yeh, T. T. (1991) Effects of pipe elbows and tube bundles on selected types of flowmeters. Journal of Flow Measurement and Instrumentation, 2: 4–13.Google Scholar
Mattingly, G. E., Pontius, P. E., Allion, H. H. and Moore, E. F. (1977) Laboratory study of turbine meter uncertainty. Proceedings of the Symposium on Flow Measurement in Open Channels and Closed Conduits, NBS, Gaithersburg, Md, USA: 33–54.
Mattingly, G. E., Pursley, W. C., Paton, R. and Spencer, E. A. (1978) Steps towards an ideal transfer standard for flow measurement. FLOMEKO Symposioum on Flow, Groningen, The Netherlands, 543–552.
Mattingly, G. E., Yeh, T. T., Robertson, B. and Kothari, K. M. (1987) NBS research on ‘in situ’ flowmeter calibrations. AGA Distribution Transmission Congress, Las Vegas, USA.
McBrien, R. K. (1997) High pressure pulsation effects on orifice meters. ASME Fluids Engineering Division Summer Meeting FEDSM'97, Paper 3700.
McBrien, R. and Geerlings, J. (2005) The performance of a multipath, 8-inch ultrasonic meter in pulsating flow. FLOMEKO 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 1.4.
McCarthy, R. (1996) Five-path ultrasonic flowmeter completes one-year field trial. Pipe Line & Gas Industry, 79 (4): pp unknown.Google Scholar
McDonald, B. E. and Sui, L. (2013) Ultrasonic flow measurement with integrated temperature measurement compensation. FLOMEKO 2013, 16th International Flow Measurement Conference, Paris, France.
McFaddin, S. E., Sindt, C. F. and Brennan, J. A. (1989) The effect of the location of an in-line tube bundle on orifice flowmeter performance. Journal of Flow Measurement and Instrumentation , 1: 9–14.Google Scholar
McKee, R. J. (1992) Pulsation effects on single- and two-rotor turbine meters. Journal of Flow Measurement and Instrumentation, 3: 151–166.Google Scholar
McKenzie, G. (1989) The performance of direct mass flow coriolis meters used for fiscal measurement of high value fluids. Mass Flow Measurement Direct and Indirect, Proc Int Conf Mass Flow Measurement, IBC Pbl, London, England.Google Scholar
McQuien, G. E., Poplawski, J., O'Keefe, C., Maron, R. and Rothman, P. (2011) Passive sonar flow monitoring. 26th Annual Phosphate Conference, Lakeland Civic Center, Lakeland, Florida, 12–13 October 2011.
Medlock, R. S. (1976) The vortex flowmeter – its development and characteristics. Austral. J. Instrum. Control, 24: 24–32.Google Scholar
Medlock, R. S. (1986) The historical development of flow metering. Measurement & Control, 19: 11–22.Google Scholar
Medlock, R. (1989) A review of the techniques of mass flow measurement. Cranfield Short Course Lecture. See also Mass Flow Measurement Direct and Indirect, Proc Int Conf Mass Flow Measurement, IBC Pbl, London, England.
Medlock, R. and Furness, R. A. (1990) Mass flow measurement – a state of the art review. Measurement and Control, 23: 100–112.Google Scholar
Melick, T. and Robinson, A. D. (2006) The latest technology in air flow measurement for the cement industry. IEEE Cement Industry Technical Conference, Phoenix, AZ, United States, 255–267.
Mencke, D. (1989) Pattern approval of mass flowmeters. Mass Flow Measurement Direct and Indirect, Proc Int Conf Mass Flow Measurement, IBC Pbl, London, England.
Mencke, D. (1996) Use of Coriolis mass flowmeters in custody transfer. FLOMEKO'96 Proceedings of the 8th International Conference on Flow Measurement, Beijing, China: 232–237.
Menendez, A., Biscarri, F. and Gomez, A. (1998) Balance equations estimation with bad measurements detection in a water supply net. Journal of Flow Measurement and Instrumentation, 9: 193–198.Google Scholar
Meng, L., Li, Y., Zhang, J. and Dong, S. (2011) The development of a multiphase meter without separation based on sloped open channel dynamics. Journal of Flow Measurement and Instrumentation, 22(2): 120–125.Google Scholar
Meng, T. and Wang, C. (2004) Comparison of pVTt methods gas flow prover. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Meng, X-j., Li, S-f. and Li, Z. (2010a) The CFD simulation and experimental research of the V type elbow flowmeter. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper B9-5.
Meng, Z., Huang, Z., Wang, B., Ji, H., Li, H. and Yan, Y. (2010b) Air-water two-phase flow measurement using a Venturi meter and an electrical resistance tomography sensor. Journal of Flow Measurement and Instrumentation, 21(3): 268–276.Google Scholar
Meribout, M., Al-Rawahi, N., Al-Naamany, A., Al-Bimani, A., Al-Busaidi, K. and Meribout, A. (2010) Integration of impedance measurements with acoustic measurements for accurate two phase flow metering in case of high water-cut. Journal of Flow Measurement and Instrumentation, 21(1): 8–19.Google Scholar
Merritt, R. (2001) Turbine flowmeters vs. hydrogen sulphide. Control (Chicago, Ill), 14(7): 55–56.Google Scholar
Merzkirch, W. (1999) Special durchfiussmessung. Sinnvoll oder nicht? Stromungsgleichrichter fur die durchflussmessung (Translation: Flow measurement special. Worthwhile or not? Flow straightener for flow rate measurement). Chemie-Technik (Heidelberg), 28(8): S22–S23 (in German).
Merzkirch, W. (2005) (Ed.) Fluid mechanics of flow metering. Springer-Verlag.
Messer, M. and Aidun, C. K. (2009) Main effects on the accuracy of Pulsed-Ultrasound-Doppler-Velocimetry in the presence of rigid impermeable walls. Flow Measurement and Instrumentation, 20(2): 85–94.Google Scholar
Mi, Y., Ishii, M. and Tsoukalas, L. H. (2001a) Investigation of vertical slug flow with advanced two-phase flow instrumentation. Nuclear Engineering and Design, 204(1–3): 69–85.Google Scholar
Mi, Y., Ishii, M. and Tsoukalas, L. H. (2001b) Flow regime identification methodology with neural networks and two-phase flow models. Nuclear Engineering and Design, 204(1–3): 87–100.Google Scholar
Miau, J. J. and Hsu, M. T. (1992) Axisymmetric-type vortex shedders for vortex flowmeters. Journal of Flow Measurement & Instrumentation, 3: 73–80.Google Scholar
Miau, J. J., Yang, C. C., Chou, J. H. and Lee, K. R. (1993) A T-shaped vortex shedder for a vortex flowmeter. Journal of Flow Measurement & Instrumentation, 4: 259–268.Google Scholar
Miau, J. J., Chen, Y. S., Chou, J. H. and Hsieh, W. D. (1997) Effect of flow swirling on a vortex flowmeter, ASME Fluids Engineering Division Summer Meeting FEDSM'97, Paper 3018.
Miau, J. J., Hu, C. C. and Chou, J. H. (2000) Response of a vortex flowmeter to impulsive vibrations. Flow Measurement and Instrumentation, 11(1): 41–49.Google Scholar
Miau, J. J., Wu, C. W., Hu, C. C. and Chou, J. H. (2002) A study on signal quality of a vortex flowmeter downstream of two elbows out-of-plane. Flow Measurement and Instrumentation, 13(3): 75–85.Google Scholar
Miau, J. J., Yeh, C. F., Hu, C. C. and Chou, J. H. (2004) On measurement uncertainty of a vortex flowmeter. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Miau, J. J.; Yeh, C. F., Hu, C. C. and Chou, J. H. (2005) On measurement uncertainty of a vortex flowmeter. Flow Measurement and Instrumentation, 16(6): 397–404.Google Scholar
Mickan, B. and Kramer, R. (2009) Evaluation of two new volumetric primary standards for gas volume established by PTB. Proc. 7th International Symposium on Fluid Flow Measurement (ISFFM), Anchorage, Alaska, USA.
Mickan, B., Wendt, G., Kramer, R. and Dopheide, D. (1996a) Systematic investigation of flow profiles in pipes and their effects on gas meter behaviour. Measurement, 22: 1–14.Google Scholar
Mickan, B., Wendt, G., Kramer, R. and Dopheide, D. (1996b) Systematic investigation of pipe flows and installation effects using laser Doppler anemometry – Part II The effect of disturbed flow profiles on turbine gas meters – a describing empirical model. Flow Measurement and Instrumentation, 7(3/4): 151–160.Google Scholar
Mickan, B., Kramer, R., Hans-Hotze, J. and Dopheide, D. (2002) Pigsar – the extended test facility and new German national primary standard for high pressure natural gas. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Mickan, B., Kramer, R., Kiesewetter, P. and Dopheide, D. (2004) Determination of discharge coefficients of sonic nozzles obtaining low uncertainty without knowledge of throat diameter. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Mickan, B., Kramer, R. and Dopheide, D. (2006a) Determination of discharge coefficient of critical nozzles based on their geometry and the theory of laminar and turbulent boundary layers. Proc. 6th International Symposium On Fluid Flow Measurement (ISFFM), Querétero, Mexico.
Mickan, B., Kramer, R. and Dopheide, D. (2006b) The use of micro-nozzles under sonic and subsonic conditions with various gases. Proc. 6th International Symposium On Fluid Flow Measurement (ISFFM), Querétero, Mexico.
Mickan, B., Kramer, R. and Dopheide, D. (2006c) Comparisons by PTB, NIST and LNE-LADG in air and natural gas with critical Venturi nozzles agree within 0.05%. Proc. 6th ISFFM
Mickan., B., Kramer, R., Vieth, D. and Hinze, H. M. (2007) The use of sonic nozzles under high pressure conditions for scaling the traceability from high flow rates down to low flow rates and for the link of the volumetric primary references in low and high pressure at PTB. Proc. FLOMEKO 2007.
Mickan, B., Kramer, R., Müller, H., Strunck, V., Vieth, D. and Hinze, H.-M. (2009) Highest precision for gas meter calibration worldwide: the high pressure gas calibration facility pigsarTM with optimized uncertainty. Proc. 7th International Symposium On Fluid Flow Measurement (ISFFM), Anchorage, Alaska, USA.
Mickan, B., Kramer, K., Strunck, V. and Dietz, T. (2010) Transient response of turbine flow meters during the application at a high pressure piston prover. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A3-3.
Mickan, B., Kramer, R. and Li, C. (2012) The critical back pressure ratio of sonic nozzles – the correlation with diffuser geometry and gas composition. 8th International Symposium on Fluid Flow Measurement (ISFFM), Colorado, USA, 20–22 June 2012.
MID (2004) DIRECTIVE on measuring instruments. Directive 2004/22/EC of the European Parliament and of the Council of 31 March 2004.
Millen, M. J., Sowerby, B. D., Coghill, P. J., Ticker, J. R., Kingsley, R. and Grima, C. (2000) Plant tests of an on-line multiple-pipe pulverised coal mass flow measuring system. Journal of Flow Measurement and Instrumentation, 11(3): 153–158.Google Scholar
Miller, D. S. (1990) Internal flow systems. 2nd ed., Gulf Publishing Company, London.
Miller, G. and Belshaw, B, (2008) An investigation into the performance of Coriolis and ultrasonic meters at liquid viscosities up to 300 cSt. 26th International North Sea Flow Measurement Workshop, 21–24 October 2008, St Andrews, Scotland, Paper 1.4.
Miller, R. and Hanks, E (2015) Gas ultrasonic meter installation effects and diagnostic indicators “A history of NAFFMC installation effects testing including current testing”. 9th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Miller, R. W. (1996) Flow measurement engineering handbook. 3rd ed, McGraw-Hill: New York, USA.
Miller, R. W., DeCarlo, J. P. and Cullen, J. T. (1977) A vortex flowmeter – calibration results and application experiences. NBS Special Publication 484, 2: 549–570.Google Scholar
Millington, B. C. and King, N. W. (1988) Further developments of a jet mixer/turbine meter package for the measurement of gas-liquid mixtures. FLUCOME'88 2nd Int Symp on Fluid-Control Measurement Mechanics and Flow Visualization, Sheffield, UK: 474–478.
Millington, B. C., Adams, C. W. and King, N. W. (1986) The effect of upstream installation conditions on the performance of small liquid turbine meters. International Symposium on Fluid Flow Measurement, AGA, Washington.Google Scholar
Millington, B. C., Frantzen, K. and Marshall, M. (1993) The performance of the Fluenta MPFM 900 Phase Fraction Meter . North Sea Flow Measurement Workshop, Bergen, Norway.
Mills, C. J. (1966) Electromagnetic catheter-tip probe for blood flow measurement (approximate title). Phys. Med. Biol Physics in Medicine and Biology., 11: 323–324.Google Scholar
Minchenya, V., Karcher, C., Kolesnokov, Y. and Thess, A. (2011) Calibration of the Lorentz force flowmeter. Flow Measurement and Instrumentation, 22(3): 242–247.Google Scholar
Minemura, K., Egashira, K., Ihara, M., Furuta, H. and Yamamoto, K. (1996) Simultaneous measurement method for volumetric flow rates of both phases of air-water mixture using a turbine flowmeter. Transactions of the Japan Society of Mechanical Engineers, Part B, 62(593): 122–129.Google Scholar
Minkin, H. L., Hobart, H. F. and Warshawsky, I. (1966) Performance of turbine type flowmeter in liquid hydrocarbons, NASA TN D-3770.
Mohamed, P. G. and Al-Saif, K. H. (1998) Field trial of a multiphase flowmeter, Society of Petroleum Engineers Annual Technical Conference and Exhibition, New Orleans, SPE 49161 (also in synopsis in 1998 Journal of Petroleum Technology, 50: 74–75).
Mohamed, P. G., Al-Saif, K. H. and Mohamed, H. (1999) Field evaluations of different multiphase flow measurement systems, Society of Petroleum Engineers Annual Technical Conference and Exhibition, Houston, TX, USA, SPE 56643 1(P): 553–561.
Mokhtarzadeh-Dehghan, M. R. and Stephens, D. J. (1998) A numerical study of turbulent flow through a variable area orifice meter. International Journal of Computer Applications in Technology, 11: 271–280.Google Scholar
Moore, P. and Brown, G. J. (2000) Modelling of transit time ultrasonic flowmeters in theoretical asymmetric flow. FLOMEKO'2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper B11.
Moore, P. I., Brown, G. J. and Stimpson, B. P. (2000) Ultrasonic transit-time flowmeters modeled with theoretical velocity profiles: methodology. Measurement Science and Technology, 11(2000): 1802–1811.Google Scholar
Moore, P. I., Johnson, A. N. and Espina, P. I. (2002) Simulations of ultrasonic transit time in a fully developed turbulent flow using a ray-tracing method. In Proceeding of the 22nd North Sea Flow Measurement Workshop.
Moreau, J. (2000) Multiphase flow measurement. Journal of Offshore Technology, 8(1): 4 pp.Google Scholar
Morgan, D. V. and Aliyu, Y. H. (1993) An ionic flowmeter for measuring small rates of gas flow. Measurement Science and Technology, 4: 1479–1483.
Mori, M., Tezuka, K. and Takeda, Y. (2006) Effects of inner surface roughness and asymmetric pipe flow on accuracy of profile factor for ultrasonic flow meter. Fourteenth International Conference on Nuclear Engineering 2006, ICONE 14, Miami, FL, United States.
Morita, A. and Yoshimura, H. (1996) Method of measuring phase difference in Coriolis mass flowmeter. Proceedings of the International Conference on Advances in Instrumentation and Control, 51(1): 631–640.Google Scholar
Moriyama, T., Sukemura, N. and Morishita, K. (2001) Cross correlation mass flowmeter using pulse heating method. Proceedings of the SICE Annual Conference, 345–350.Google Scholar
Morris, S. C., Neal, D. R., Foss, J. F. and Cloud, G. L. (2001) A moment-of-momentum flux mass air flow measurement device. Measurement Science and Technology, 12(2): N9–N13.Google Scholar
Morrison, G. L. (1997) Flow field development downstream of two in plane elbows. ASME Fluids Engineering Division Summer Meeting FEDSM'97, Paper 3021.
Morrison, G. L. and Brar, P. (2005) Ambient temperature effects upon the flow in gas pipelines at low speeds. Paper no. FEDSM2005-77478 Volume 2 pp. 475–482 (8 pages) ASME 2005 Fluids Engineering Division Summer Meeting (FEDSM2005) ISBN: 0-7918-4199-5, 19–23 June 2005, Houston, Texas, USA.
Morrison, G. L. and Hall, K. R. (2000) Consider slotted orifice flowmeters. Hydrocarbon Processing, 79(12): 65–66, 68–72.Google Scholar
Morrison, G. L., DeOtte, R. E., Moen, M., Hall, K. R. and Holste, J. C. (1990a) Beta ratio, swirl and Reynolds number dependence of wall pressure in orifice flowmeters. Journal of Flow Measurement and Instrumentation, 1: 269–277.Google Scholar
Morrison, G. L., DeOtte, R. E., Panak, D. L. and Nail, G. H. (1990b) Flow field inside an orifice flow meter. Chemical Engineering Progress, 86.7: 75–80.Google Scholar
Morrison, G. L., DeOtte, R. E. and Beam, E. J. (1992) Installation effects upon orifice flowmeters. Journal of Flow Measurement and Instrumentation, 3: 89–94.Google Scholar
Morrison, G. L., Hall, K. R., Holste, J. C., DeOtteJr, R. E., Macek, M. L. and Ihfe, L. M. (Oct 1994a) Slotted orifice flowmeter. AIChE Journal. 40.10: 1757–1760.Google Scholar
Morrison, G. L., Hall, K., Holste, J. C., Macek, M., Ihfe, L. and DeOtte, R. E. (1994b) Comparison of orifice and slotted plate flow meters. Journal of Flow Measurement and Instrumentation, 5: 71–77.Google Scholar
Morrison, G. L., Hauglie, J. and DeOtte, R. E. (1995) Beta ratio, axisymmetric flow distortion and swirl effects upon orifice flow meters. Journal of Flow Measurement and Instrumentation, 6: 207–216.Google Scholar
Morrison, G. L., Hall, K. R., Holste, J. C., Ihfe, L., Gaharan, C. and DeOtte, Jr, R. E. (1997) Flow development downstream of a standard tube bundle and three different porous plate flow conditioners. Journal of Flow Measurement and Instrumentation, 8(2): 61–76.Google Scholar
Morrison, G. L., Terracina, D., Brewer, C. and Hall, K. R. (2001) Response of a slotted orifice meter to an air/water mixture. Journal of Flow Measurement and Instrumentation, 12(3): 175–180.Google Scholar
Morrison, G. L., Hall, K. R. and Flores, A. E. (2002a) Slotted orifice based two phase flow meter. Proceedings of the Annual Symposium on Instrumentation for the Process Industries, 57: 73–99.Google Scholar
Morrison, G. L., Hall, K. R., Brewer, C. and Flores, A. (2002b) Universal slotted orifice flow meter flow coefficient equation for single and two phase flow. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Morrow, T. B. (1996) Orifice meter installation effects: ten-inch sliding flow conditioner tests. GRI Report No. GRI-96/0391, Gas Research Institute, Chicago, Illinois, USA.
Morrow, T. B. (1997) Effects of flow conditioners on orifice meter installation errors, ASME Fluids Engineering Division Summer Meeting FEDSM'97, Paper 3006.
Morrow, T. B. (2004)Gravimetric calibration of critical flow Venturi nozzles. Proc. HT-FED04 Paper No. 56817.
Morrow, T. B. (2005) Multi-path gas ultrasonic flow meter performance at low velocity. Proceedings of 2005 ASME Fluids Engineering Division Summer Meeting, FEDSM2005, 2005: 2207–2211. (2:447–52).
Morrow, T. B., Park, J. T. and McKee, R. J. (1991) Determination of installation effects for a 100 mm orifice meter using a sliding vane technique. Journal of Flow Measurement and Instrumentation, 2: 14–20.Google Scholar
Morrow, T. D. and Behring, K. A. (1999) Energy flow measurement technology, and the promise of reduced operating costs. Proc. of 4th International. Symposium. on Fluid Flow Measurem., Denver, Colorado, 27–30 June 1999.
Morse, P. M. and Ingard, K. U. (1968) Theoretical acoustics. McGraw Hill Book Company, New York.
Morton, C. E. (2009) Performance and modelling of the oscillating piston flowmeter. PhD Thesis, Engineering Department, University of Cambridge.
Morton, C. E., Baker, R. C. and Hutchings, I. M. (2011) Measurement of liquid film thickness by optical fluorescence and its application to an oscillating piston positive displacement flowmeter. Measurement Science and Technology, 22: 125403 (11pp).Google Scholar
Morton, C. E., Hutchings, I. M. and Baker, R. C. (2014a) Experimental tests of a positive displacement flowmeter: I – piston movement and pressure losses. Flow Measurement and Instrumentation, 36(2014): 47–56. http://dx.doi.org/10.1016/j.flowmeasinst.2014.01.006 Google Scholar
Morton, C. E., Baker, R. C. and Hutchings, I. M. (2014b) Experimental tests of an oscillating circular piston positive displacement flowmeter: II – leakage flows and wear tests. Flow Measurement and Instrumentation, 36(2014): 57–63. http://dx.doi.org/10.1016/j.flowmeasinst.2014.01.007 Google Scholar
Motta, R. S. N., Schmedt, R. and Souza, L. E. (2011) Enhanced pulverized coal mass flow measurement. Flow Measurement and Instrumentation, 22(4): 303–308.Google Scholar
Mottram, R. C. (1981), Measuring pulsating flow with a differential pressure meter. Proc Conf Flow 81 – Its Measurement and Control in Science and Industry, St Louis, Mo, USA, ISA, 2: 347–361.
Mottram, R. C. (1989) Damping criteria for pulsating gas flow measurement. Journal of Flow Measurement and Instrumentation, 1: 15–23.Google Scholar
Mottram, R. C. (1991) Vortex flowmeters – installation effects. Journal of Flow Measurement & Instrumentation, 2: 56–60.Google Scholar
Mottram, R. C. (1992) Introduction: an overview of pulsating flow measurement. Journal of Flow Measurement and Instrumentation, 3: 114–117.Google Scholar
Mottram, R. C. and Hutton, S. P. (1987) Installation effects turbine and vortex flowmeters. FLOMIC Report No 3, Flow Measurement and Instrumentation Consortium.
Mottram, R. C. and Rawat, M. S. (1986) The swirl damping properties of pipe roughness and the implications for orifice meter installation. International Conference on Flow Measurement in the Mid 80's, 9–12 June. Glasgow, NEL.
Mottram, R. C. and Rawat, M. S. (1988) Installation effects on vortex flowmeters. Journal of Measurement & Control, 21: 241–246.Google Scholar
Mottram, R. C. and Ting, V. C. (1992) Presentation at 1992 AIChe Spring National Meeting , New Orleans, IA.
Mudd, J. and Bentley, J. (2002) The development of a multi-channel vortex flow-meter using a twelve-sensor array. Measurement and Control, 35(10): 296–298.Google Scholar
Müller, H., Strunck, V., Kramer, R., Mickan, B., Dopheide, D. and Hotze, H.-J. (2004) Germany's new optical primary national standard for natural gas of high pressure at pigsarTM 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Murakami, M., Maruo, K. and Yoshiki, T. (1990) Development of an electromagnetic flowmeter for studying gas-liquid, two-phase flow. International Chemical Engineering, 30.4: 699–702.Google Scholar
Murakawa, H., Kikura, H. and Aritomi, M. (2005) Application of ultrasonic Doppler method for bubbly flow measurement using two ultrasonic frequencies). Experimental Thermal and Fluid Science, 29(7 SPEC. ISS): 843–850.Google Scholar
Murakawa, H., Kikura, H. and Aritomi, M. (2008) Application of ultrasonic multi-wave method for two-phase bubbly and slug flows. Flow Measurement and Instrumentation, 19(3–4): 205–213.Google Scholar
Murakawa, H., Sugimoto, K. and Takenaka, N. (2014) Effects of the number of pulse repetitions and noise on the velocity data from the ultrasonic pulsed Doppler method with different algorithms. Flow Measurement and Instrumentation, 40: 9–18.Google Scholar
Murdock, J. W. (1961) Two-phase flow measurement with orifice. ASME Paper 61-GT-27.
Murugesan, K. (2002) Multiphase flow meter: Trends in well performance testing. Chemical Engineering World, 37(12): 151–153.Google Scholar
Mus, E. A., Toskey, E. D., Norris, R. J. and Bascoul, S. J. F. (2002) Added value of a multiphase flowmeter in exploration well testing. SPE Production and Facilities, 17(4): 197–203.Google Scholar
Music, M., Ahic-Djokic, M., Music, O. and Djemic, Z. (2004) An approximate mathematical model of ultrasound wave modulated by von Karman vortex street. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Myhr, S. (1991) Field experience with Coriolis mass meter on hydrocarbon liquid. Proceedings of the North Sea Flow Measurement Workshop.
Mylvaganam, K. S. (1989) High-rangeability ultrasonic gas flowmeter for monitoring flare gas. IEEE Transactions on. Ultrasonics, Ferroelectrics & Frequency Control, 36.2: 144–149.Google Scholar
Na, M. G., Shin, S. H. and Jung, D. W. (2005a) Design of a software sensor for feed water flow measurement using a fuzzy inference system. Nuclear Technology, 150(3): 293–302.Google Scholar
Na, M. G., Lee, Y. J. and Hwang, I. J. (2005b) A smart software sensor for feed water flow measurement monitoring. IEEE Transactions on Nuclear Science, 52(6): 3026–3034.Google Scholar
Nakano, K. and Tanaka, Y. (1990) Electrostatic flowsensor. Journal of Flow Measurement and Instrumentation, 1: 191–200.
Nakao, S. (2005) Development of the critical nozzle flow meter for high pressure hydrogen gas dispenser at a hydrogen gas station. Flomeko 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 5.1.
Nakao, S. (2006) Development of the PVTt system for very low gas flow rates. Flow Measurement and Instrumentation, 17(3): 193–200.Google Scholar
Nakao, S-I., Yokoi, Y. and Takamoto, M. (1996) Development of a calibration facility for small mass flow rates of gas and the uncertainty of a sonic Venturi transfer standard. Journal of Flow Measurement and Instrumentation, 7: 77–83.Google Scholar
Nakao, S-I(1997) Development of a calibration facility for small mass flow rates of gas and the uncertainty of a sonic Venturi transfer standard. Flow Measurement and Instrumentation,. 7(2): 77–83.Google Scholar
Nakao, S.-I., Terao, Y. and Takamoto, M. (2002) Development of the primary flow standard for very low gas flow rates. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Nath, B. and Löber, W. (1999) High sample rate ultrasonic gas flow meter for pulsating gas flow. Proceedings of the IMEKO-XV Conference, Osaka, Japan, 1999.
Neda, T., Saito, T. and Nukui, K. (1997) Simple flowmeter for undeveloped turbulent flow using multiple micro hot film flow sensors. FED-211, Fluid Measurement and Instrumentation, ASME, 211: 87–91.
Nederlof, A. J. (1994) Product certification of the future. Journal of Flow Measurement and Instrumentation, 5(2): 115–120.Google Scholar
NEL (1997b) Ultrasonic meters for oil flow measurement. Flow Measurement Guidance Note, No. 6.
Nesse, Ø. (2007) Experience with ultrasonic meters on high viscosity oil. 25th International North Sea Flow Measurement Workshop, Energy Institute, Oslo, Norway, 295–310.
Nesse, Ø. and Bratten, T. (2013) Qualification of fiscal liquid ultrasonic for operation on extended viscosity range. North Sea Flow Metering Workshop, Paper 3.8.
Nesse, Ø., Folkestad, T., Tunheim, H. and Flølo, D. (2003) Operating experience with two ultrasonic gas meters in series. 21st North Sea Flow Metering Workshop 2003, Paper 17.
Neuhaus, M., Looser, H., Burtscher, H., Schrag, D., Hahn, J. and Schoeb, R. (2007) Flow meter for high-purity and aggressive liquids. Sensors and Actuators, A: Physical, 134(2): 303–309.
Newcombe, J. and Griffiths, A. (1973) High throughput flowmeters for gas sales and grid control. 12th World Gas Congress, Nice, France, Paper IGU/D: 12–73.
Newcombe, J., Archbold, T. and Jepson, P. (1972) Errors in measuring gas flows at high pressure – recent developments in correcting methods. 38th Autumn Research Meeting of the Institution of Gas Engineers.
Nguyen, N. T. (1997) Micromachined flow sensors – a review. Journal of Flow Measurement and Instrumentation, 8: 7–16.
Nguyen, N. T. and Kiehnscherf, R. (1995) Low-cost silicon sensors for mass flow measurement of liquids and gases. Sensors & Actuators, A: Physical, A49.1–2: 17–20.Google Scholar
Niazi, A. and Gaskell, M. (2000) Building confidence with multi-path ultrasonic meters . North Sea Flow Measurement Workshop, National Engineering Laboratory, East Kilbride, Scotland.
Nicholson, S. (1994) Coriolis mass flow measurement. FLOMEKO'94 Conference on Flowmeasurement in the Mid 90s, NEL, Scotland.
Nilsson, U. R. C. (1998) A new method for finding inaccurate gas flowmeters using billing data: Finding faulty meters using billing data. Journal of Flow Measurement and Instrumentation, 9: 237–242.Google Scholar
Nilsson, U. R. C. and Delsing, D. (1998) In situ detection of inaccurate gas flowmeters using a fingerprint technique. Journal of Flow Measurement and Instrumentation, 9: 143–152.Google Scholar
Ningde, J., Hua, Z., Shuying, Z. and Xingbin, L. (2005) Turbine meters for measuring oil-gas-water three phase flow in vertical upward pipes. FLOMEKO 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 3.3.
Nishigaki, M., Ippommatsu, M., Ikeda, Y. and Nakajima, T. (1995) Measurement principle of the fluidic gas flowmeter. Measurement Science & Technology, 6.6: 833–842.Google Scholar
Nishimura, F. R., Kawashima, S. K. and Kagawa, T. T. (2008) Analysis of laminar flow meter with flute-type cross section laminar elements. 2008 Asia Simulation Conference – 7th International Conference on System Simulation and Scientific Computing, ICSC, Beijing, China: 1110–1114.
Nolan, M. E., Gaskell, M. C. and Cheung, W. S. (1985) Further developments of the British Gas ultrasonic flowmeter. Flowmeasurement in the Mid'80s, Paper 11.2.
Noltingk, B. E. ed. (1988) Instrumentation reference book. London: Butterworths.
Norman, D. F. (2003) Calibration of a Coriolis mass flow meter using normal modal analysis. International Publication Number WO 2003021205 A1.
Norman, R., Rawat, M. S. and Jepson, P. (1983) Buckling and eccentricity effects on orifice metering accuracy. International Gas Research Conference, London.
Norman, R., Rawat, M. S. and Jepson, P. (1984) An experimental investigation into the effects of plate eccentricity effects and elastic deformation on orifice metering accuracy. International Conference on the Metering of Natural Gas and Liquefied Hydrocarbon Gases, London.
Norman, R., Graham, P. and Drew, A. W. (1995) Effects of acoustic noise on orifice meters. Proceedings of the 3rd International Symposium on Fluid Flow Measurement, Electronic Flow Measurement Section, San Antonio, Texas, USA.
Nygaard, G., Mylvaganam, S. and Engan, H. E. (2000) Integration of impedance measurements with transit time measurements for ultrasonic gas mass flow metering – Model and experiments with transducers in different vibration modes. Proceedings of the IEEE Ultrasonics Symposium, 1: 475–482.Google Scholar
O'Keefe, C. V., Maron, R., Rothman, P. and Poplawski, J. (2008a) Application of passive sonar technology to minerals processing flow measurement situations. Society for Mining, Metallurgy and Exploration – SME Annual Meeting and Exhibit 2008: “New Horizons – New Challenges”, Salt Lake City, UT, United States: 277–284.
O'Keefe, C., Maron, R., Rothman, P. and Poplawski, J. (2008b) Description of non-intrusive sonar array-based technology and its application to unique and difficult slurry and paste flow measurements presented at Paste 2008, Kaskane, Botswana, May 2008.
O'Keefe, C. V., Poplawski, J. and Maron, R. (2008c) Accuracy of non-intrusive sonar array-based technology to solve unique and difficult measurement situations. CMP 2008.
O'Keefe, C.V., Maron, R. and Rothman, P. (2009a) Improved flow and flotation monitoring for process efficiency improvements through new technology utilizing non-invasive passive arrays. COM2009 (Conference of Metallurgists).
O'Keefe, C. V., Maron, R. J., Fernald, M., Bailey, T. and Van der Spek, A. (2009b) New developments in velocity profile measurement and pipe wall wear monitoring for hydrotransport lines. Canadian Mineral Operators Conference (CMP) 2009.
O'Keefe, C. V., Maron, R., Fernald, M. R., Bailey, T, J., van der Spek, A., M., Davis, M. A. and Viega, J. V. (2011) Flow and pipe management using velocity profile measurement and/or pipe wall thickness and wear monitoring. US Patent Application No. US2011/0056298 March 2011.
O'Keefe, C. V., Felix, J., Peacock, R., Huysamen, T. and Thwaites, P. (2012) The impact of entrained air and enhanced flow measurements at Eland Platinum concentrator. The South African Institute of Mining and Metallurgy, Platinum.
O'Sullivan, I. J. and Wright, W. M. D. (2002) Ultrasonic measurement of gas flow using electrostatic transducers. Ultrasonics, 40(1–8): 407–411.Google Scholar
O'Sullivan, V. T. and Wyatt, D. G. (1983) Computation of electromagnetic flowmeter characteristics from magnetic field data: III rectilinear weight functions. Journal of Physics D: Applied Physics, 16: 461–476.Google Scholar
Obayashi, H., Tasaka, Y., Kon, S. and Takeda, Y. (2008) Velocity vector profile measurement using multiple ultrasonic transducers. Flow Measurement and Instrumentation, 19(3–4): 189–195.Google Scholar
Oddie, G. and Pearson, J. A. R. (2004) Flow-rate measurement in two-phase flow. Annual Reviews in Fluid Mechanics, 36: 149–172.Google Scholar
Oddie, G., Stephenson, K. E. and Fitzgerald, J. B. (2005) Flow characteristic measuring apparatus and method. US Patent 6,854,341 B2 Feb 15 2005.
Ogawa, Y. (2006) Nagare waza no siruku rodo (means Silk road of flow technology or History of flowmeters). Published by Japan Industry Publishing Co.Ltd.
Oguri, Y. (1988) Wedge flowmeters for measuring bi-directional pipe flows. In Mass Flow Measurement, presented at ASME Winter Annual Meeting (Chicago, Illinois, 27 November-2 December 1988) (Eds G E Mattingly and T R Hendrick), FED 73, pp. 1–5 (ASME, New York).
Ohira, K., Nakamichi, K. and Kihara, Y. (2003) Study on the development of a capacitance-type flowmeter for slush hydrogen. Cryogenics, 43(10–11): 607–613.
Ohlmer, E. and Schulze, W. (1985) Experience with CENG full-flow turbinemeters for transient two-phase flow measurements under loss-of-coolant experiment conditions. BHRA 2nd International Conference on Multi-phase Flow, London, England, Paper H1: 381–395.
Ohnuki, A. and Akimoto, H. (1995) Application of electromagnetic velocity meter for measuring liquid velocity distribution in air-water two-phase flow along a large vertical pipe, Proceedings of ASME Heat Transfer and Fluids Engineering Divisions (HYD-321/FED-233, ASME, 473–478.
OIML (2004) The International Organization for Legal Metrology, International Recommendation, Weights of Classes E1, E2, F1, F2, M1, M1-2, M2 and M3, Part 1: Metrological and technical requirements, OIML R111-1, 1–78.
Okabayashi, M. and Yamasaki, H. (1991) Feasibility study of new fluidic gas meters. FLUCOME ’91, 3rd Triennial International Symposium on Fluid Control, Measurement and Visualization, San Francisco, Cal, USA: 313–318.
Okada, T. and Nishimura, J. (2000) The effects of electromagnetic flowmeter on continuous digester. TAPPI Pulping/Process and Product Quality Conference , pp. 305–323.Google Scholar
Okada, T., Nishimura, J. and Tanabe, S. (2003) The stable flow measurement for stock flow by capacitance magnetic flowmeter. Kami Pa Gikyoshi/Japan Tappi Journal, 57(6): 82–89 (in Japanese).Google Scholar
Okland, O. and Berentsen, H. (1994) Using the MFI multiphase meter for well testing at Gullfaks B . North Sea Flow Measurement Workshop, Peebles, Scotland.
Okland, O., Kleppe, K., Berentsen, and Klemp, H. (1997) Applications of multiphase meters at the Gullfaks Field in the North Sea. Offshore Technology Conference, Houston, TX, USA, 4: 533–544.
Olivier, P. D. (1997) The effects of line pressure on the performance of thermal mass meters, International Instrumentation Symposium, Instrument Society of America, Aerospace Division, Orlando, Florida, 43: 669–680.
Olivier, P. D. (2002) A turbine flow meter that is insensitive to changes in fluid viscosity. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Olsen, E. (1991) An investigation of sonic and ultrasonic flowmeters with transducers in free stream. Journal of Flow Measurement and Instrumentation, 2: 185–187.Google Scholar
Olsen, L. F. (1974) Introduction to liquid flowmetering and the calibration of liquid flowmeters. National Bureau of Standards TN 831.
Ong, J. T., Oyeneyin, M. B., Coutts, E. J. and MacLean, I. M. (2004) In well nuclear magnetic resonance (NMR) multiphase flowmeter in the oil and gas industry. SPE Annual Technical Conference and Exhibition, 26–29 September 2004, Houston, Texas.
Ong, J. T., Aymond, M., Albarado, T., Majid, J., Daniels, P., Jordy, D. and Lafleur, L. (2007) Inverted Venturi: Optimizing recovery through flow measurement. SPE Annual Technical Conference and Exhibition 2007, ATCE 2007, Anaheim, CA, United States: 2490–2503.
Opara, U. and Bajsiae, I. (2001) Concurrent two-phase downflow measurement with an induced electromagnetic flowmeter. Journal of Hydraulic Research, 39(1): 93–98.Google Scholar
Oppenheim, A. K. and Chilton, E. G. (1955) Pulsating flow measurement – a literature survey. Transactions of ASME, 77: 231–248.Google Scholar
Orlando, V. A. and Jennings, F. B. (1954) The momentum principle measures true mass flow rate. Transactions of ASME, 76: 961–965.Google Scholar
O'Rourke, E. L. (1993) The MTI compact electronic gas meter. FLOMEKO '93 Proceedings of the 6th International Conference on Flow Measurement, Korea Research Institute of Standards and Science: 424–433.
O'Rourke, E. L. (1996) Results of the MTI compact electronic meter test program. FLOMEKO'96 Proceedings of the 8th International Conference on Flow Measurement, Beijing, China: 313–318.
Ostling, H. and Oki, S. (2001) Spectral Signal Processing (SSP) enhances vibration immunity for vortex flowmeters. ISA TECH/EXPO Technology Update Conference Proceedings, 416: 411–417.Google Scholar
Owen, I. and Hussein, I. B. (1991) Wet steam flowmeter correction factors. Journal of Flow Measurement and Instrumentation, 2: 139–140.Google Scholar
Owen, I., Hussein, I. B. and Amini, A. M. (1991) The impact of water slugs on wet steam flowmeters. Journal of Flow Measurement and Instrumentation, 2: 98–104.Google Scholar
Owen, I., Fyrippi, I. and Escudier, M.P. (2003) Flowmetering of shear-thinning non-Newtonian liquids. Proceedings of the ASME/JSME Joint Fluids Engineering Conference, 1 A:3–14.Google Scholar
Ower, E. (1937) On the response of a vane anemometer to an air-stream of pulsating speed. Philosophical Magazine, Series 7, 23, No. 157.Google Scholar
Ower, E. and Pankhurst, R. C. (1966) The measurement of air flow. Pergamon Press.
Ozgoren, M. (2006) Flow structure in the downstream of square and circular cylinders. Flow Measurement and Instrumentation, 17(4): 225–235.Google Scholar
Padden, H. (2002) Uncertainty analysis of a high-speed dry piston flow prover. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Padden, H. (2004) Uncertainties and inter-laboratory comparisons of dry piston gas flow provers. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Paik, J. S., Lim, K. W. and Lee, K. B. (1990) Calibration of Coriolis mass flowmeters using a dynamic weighing method. Journal of Flow Measurement and Instrumentation, 1: 171–175.Google Scholar
Paik, J. S., Mim, C. H. and Lee, D. K. (1994) Effect of variation of pipe velocity profile on the ultrasonic cross-correlation flowmeters. FLOMEKO '94 Flow Measurement in the Mid-90s, NEL, Glasgow, Scotland: Paper 7.1.
Paik, J. S., Park, K. A. and Park, J. T. (1998) Inter-laboratory comparison of sonic nozzles at KRISS. FLOMEKO '98 Proceedings of the 9th International Conference on Flow Measurement, Lund, Sweden, 95–99.
Paik, J., Lee, K. B. and Mattingly, G. (2005) Uncertainties for an inter-comparison of water flow calibration facilities. FLOMEKO 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 2.2.
Pal, R. (1993) Flow of oil-in-water emulsions through orifice and Venturi meters. Industrial & Engineering Chemistry Research, 32: 1212–1217.Google Scholar
Pal, R. and Rhodes, E. (1985) Methods for metering oil and water production of wells. BHRA 2nd International Conference on Multi-phase Flow, London, Paper H2, 397–411.
Paladino, E. E. and Maliska, C. R. (2002) The effect of the slip velocity on the differential pressure in multiphase Venturi flow meters. Proceedings of the International Pipeline Conference, IPC, A: 965–972.Google Scholar
Paladino, E. E. and Maliska, C. R. (2011) Computational modelling of bubbly flows in differential pressure flow meters. Flow Measurement and Instrumentation, 22(4): 309–318.Google Scholar
Palau, C. V., Arregui, F. J., Palau, G. and Espert, V. (2004) Velocity profile effects on Woltman water meters performance. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Panicke, M. and Huebel, C. (2009) Measurement & diagnostic capabilities of clamp-on ultrasonic flow meters. 7th International Symposium on Fluid Flow Measurement (ISFFM), Anchorage, Alaska, USA.
Pannell, C. N., Evans, W. A. B. and Jackson, D. A. (1990) A new integration technique for flowmeters with chordal paths. Journal of Flow Measurement and Instrumentation, 1: 216–224.Google Scholar
Panneman, H. J. (2001) On-line comparison of the speed of sound at four Dutch metering stations equipped with ultrasonic gas flow meters. 19th North Sea Flow Measurement Workshop, Kristiansand, Norway, 22–25 October 2001, Paper 10.
Parchen, R. R. and Steenbergen, W. (1998) An experimental and numerical study of turbulent swirling pipe flow. Transactions of ASME, 120, March 1998.Google Scholar
Park, K., Kim, J., Kauh, S. K., Ro, S. T. and Lee, J. (1997) Measurement of air flow rate by using an integration type ultrasonic flowmeter applicable for spark ignition engine control. Proceedings of the Institution of Mechanical Engineers, 211D: 129–135.Google Scholar
Park, K-A. (1995) Effects of inlet shapes of critical Venturi nozzles on discharge coefficients. Journal of Flow Measurement and Instrumentation, 6: 15–19.
Park, K. A., Choi, Y. M., Choi, H. M., Cha, T. S. and Yoon, B. H. (2001) The evaluation of critical pressure ratios of sonic nozzles at low Reynolds numbers. Journal of Flow Measurement and Instrumentation, 12(1): 37–41.Google Scholar
Park, K-A., Oh, Y., Choi, H. and Lee, D. (2002) Performance enhancement of wet gas flow meter. American Society of Mechanical Engineers, Fluids Engineering Division (Publication) FED, 257(1 A): 149–153.Google Scholar
Parker, M. (September 1990) Improving the performance of a glass tube variable area flowmeter. Measurement & Control, 23: 211–215.Google Scholar
Parkinson, G. J. (1991) Fluidic flow sensors for industrial applications. Measurement & Control, 24: 4–10.Google Scholar
Patel, B. R. and Sheikholeslami, Z. (1986) Numerical modelling of turbulent flow through orifice meters. International Symposium on Fluid Flow Measurement, Washington, DC.
Paton, R. (1988) Calibration techniques for mass flowmeters. Petroleum Review, 42.502, Nov: 40–42.Google Scholar
Paton, R. (1998) Calibration techniques for Coriolis mass flowmeters. FLOMEKO '98 Proceedings of the 9th International Conference on Flow Measurement, Lund, Sweden, pp. 505–508.
Patten, T. and Dunphy, K. (2006) Flow measurement in bitter cold: How to use Coriolis meters in cryogenic service. Chemical Engineering, 113(7): 48–49.Google Scholar
Paulsen, F. (1991) Prover ball material problems. Proceedings of the North Sea Flow Measurement Workshop, Norwegian Society of Chartered Engineers.
Pavlovic, V., Dimitrijevic, B., Stojcev, M., Golubovic, L. J., Zivkovic, M. and Stamenkovic, L. J. (1997) Realization of the ultrasonic liquid flowmeter based on the pulse-phase method. Ultrasonics, 35: 87–102.Google Scholar
Pawlas, G. E. and Pankratz, T. (1994) Fluid mechanics effects in Coriolis mass flowmeters. FLOMEKO'94 Conference on Flowmeasurement in the Mid 90s, NEL, Scotland.
Pawlas, G. and Patten, T. (1995) Gas measurement using Coriolis mass flowmeters. ISA Advances in Instrumentation and Control: International Conference and Exhibition, 50.3: 781–790.Google Scholar
Peng, B. H., Miau, J. J., Bao, F., Weng, L. D., Chao, C. C. and Hsu, C. C. (2010) Performance of Vortex Shedding from a Circular Cylinder with a Slit. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper B2-4.
Peng, B. H., Miau, J. J., Bao, F., Weng, L. D., Chao, C. C. and Hsu, C. C. (2012a) Performance of vortex shedding from a circular cylinder with a slit normal to the stream. Flow Measurement and Instrumentation, 25: 54–62.Google Scholar
Peng, J., Fu, X. and Chen, Y. (2004) Flow measurement by a new type vortex flowmeter of dual triangulate bluff body. Sensors and Actuators, A: Physical, 115(1): 53–59.Google Scholar
Peng, J., Fu, X. and Chen, Y. (2008a) Response of a swirlmeter to oscillatory flow. Flow Measurement and Instrumentation, 19(2): 107–115.Google Scholar
Peng, J., Fu, X. and Chen, Y. (2008b) Experimental investigation of Strouhal number for flows past dual triangulate bluff bodies. Flow Measurement and Instrumentation, 19(6): 350–357.Google Scholar
Peng, J., Wang, W. and Fang, M. (2012b) Hilbert-Huang transform (HHT) based analysis of signal characteristics of vortex flowmeter in oscillatory flow. Flow Measurement and Instrumentation, 26: 37–45.Google Scholar
Peng, L., Zhang, Y. and Yan, Y. (2008c) Characterization of electrostatic sensors for flow measurement of particulate solids in square-shaped pneumatic conveying pipelines. Sensors and Actuators, A Physical, 141(1): 59–67.
Pereira, M. T. and Nunes, M. (1993) Nozzle chamber to measure flow rates up to 5000m3/h. FLOMEKO Proc 6th Int Conf on Flow Measurement, Korea: 380–386.
Pereira, M. T., de Pimenta, M. and Taira, N. M. (1993) Flow metering with a modified sonic nozzle. FLOMEKO '93 Proceedings of the 6th International Conference on Flow Measurement: 372–379.
Perovic, S. and Higham, E.H. (2002) Electromagnetic flowmeters as a source of diagnostic information. Flow Measurement and Instrumentation, 13(3): 87–93.Google Scholar
Perovic, S., Higham, E. H. and Unsworth, P. J. (2001) Fault detection and flow regime identification based on analysis of signal noise from electromagnetic flowmeters. Proceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering, 215(4): 283–293.Google Scholar
Peters, F. and Kuralt, T. (1995) A gas flowmeter of high linearity. Journal of Flow Measurement and Instrumentation, 6: 29–32.Google Scholar
Peters, J. and Schook, C. A. (1981) Electromagnetic sensing of slurry concentration. The Canadian Journal of Chemical Engineering, 59: 430–437.Google Scholar
Peters, M. C. A. M., Braal, F. M., Limpens, C. H. L. and van Bokhorst, E. (2000) Installation effects on vortex flowmeters – the impact of piping and flow dynamics on the sensor signal. FLOMEKO'2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper E9.
Peters, R. J., Reader-Harris, M. and Stewart, D. (2001) An experimental derivation of an expansibility factor for the V-cone and wafer cone meters. 19th North Sea Flow Measurement Workshop, Kristiansand, Norway, 22–25 October 2001, Paper 23.
Peters, R. J. W., Steven, R., Caldwell, S. and Johansen, B. (2004b) Testing the Wafer V-Cone flowmeters in accordance with API 5.7 “Testing Protocol for Differential Pressure Flow Measurement Devices” in the CEESI Colorado test facility. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Peters, R. J. W., Steven, R., Caldwell, S. and Johansen, B. (2006) Testing the Wafer V-Cone flowmeters in accordance with API 5.7 “Testing Protocol for Differential Pressure Flow Measurement Devices” in the CEESI Colorado test facility. Flow Measurement and Instrumentation, 17(4): 247–254.Google Scholar
Peterson, S., Lightbody, C., Trail, J. and Coughlan, L. (2008) On line condition based monitoring of gas USM's. 26th International North Sea Flow Measurement Workshop, 21–24 October 2008, St Andrews, Scotland, Paper 2.1.
Peyvan, D., Gurevich, Y. and French, C. T. (2002) In-situ calibration for feed water flow measurement. International Conference on Nuclear Engineering, Proceedings, ICONE, 1: 137–142.Google Scholar
Pfrehm, R. H. (1981) Improved turbine-meter system measures ethylene accurately. Oil and Gas Journal, 79(16): 73–76.Google Scholar
Philip-Chandy, R., Scully, P. J. and Morgan, R. (2000) The design, development and performance characteristics of a fibre optic drag-force flow sensor. Measurement Science and Technology, 11: N31–N35.Google Scholar
Place, J. D. and Maurer, R. (1986) Non-invasive fibre optic pick-up for a turbine flowmeter. Conference Fibre Optics 86, London England.
Plache, K. O. (1977) Coriolis/gyroscopic flow meters. ASME 77-WA/FM-4, 1977. (Also Australian Process Engineering, 6, No 9: 47–51, Sept 1978.) (Also Mechanical Engineering March 1979).
Plank, N. (1951) Slippage errors in positive displacement liquid meters. Proc Third World Petroleum Congress, The Hague, Netherlands (Published by E J Brill, Leiden, Netherlands), Section IX: 100–124.
Poiseuille, J. L. M. (1842) Recueil des savants etrangers. Academie des Sciences, Paris.
Polo, J., Pallas-Areny, R. and Martin-Vide, J. P. (2001) Analog signal processing in an AC electromagnetic flowmeter. Conference Record – IEEE Instrumentation and Measurement Technology Conference, 3: 2136–2139.Google Scholar
Peng, J., Fu, X. and Chen, Y. (2002) Analog signal processing in an AC electromagnetic flowmeter. IEEE Transactions on Instrumentation and Measurement, 51(4): 793–797.Google Scholar
Poornapushpakala, S., Gomathy, C., Sylvia, J. I. and Babu, B. (2014) Design, development and performance testing of fast response electronics for eddy current flowmeter in monitoring sodium flow. Flow Measurement and Instrumentation, 38: 98–107.Google Scholar
Pope, J. G. and Wright, J. D. (2014) Performance of Coriolis meters in transient gas flows. Flow Measurement and Instrumentation, 37: 42–53.Google Scholar
Pope, J. G., Wright, J. D., Johnson, A. N. and Moldover, M. R. (2012) Extended Lee model for the turbine meter & calibrations with surrogate fluids. Flow Measurement and Instrumentation, 24: 71–82.Google Scholar
Pöschel, W. and Engel, R. (1998) The concept of a new primary standard for liquid flow measurement at PTB Braunschweig, FLOMEKO '98 Proceedings of the 9th International Conference on Flow Measurement, Lund, Sweden, 7–12.
Potter, D. M. (1959) Improvements in or relating to mass flow meters. British Patent 860 657, Filed 12th June 1959.Google Scholar
Potter, D. M. (1961) UK Patent Specification No. 986,831.
Prahu, S. V., Mascomani, R., Balakrishnan, K. and Konnur, M. S. (1996) Effects of upstream pipe fittings on the performance of orifice and conical flowmeters. Journal of Flow Measurement and Instrumentation, 7: 49–54.Google Scholar
Prasser, H.-M., Misawa, M. and Tiseanu, I. (2005) Comparison between wire mesh sensor and ultra-fast X-ray tomograph for an air-water flow in a vertical pipe. Flow Measurement and Instrumentation, 16(2–3): 73–83.Google Scholar
Priddy, W. J. (1994) Field trials of multiphase metering systems at Prudhoe Bay, Alaska. SPE 69th Annual Technical Conference and Exhibition, New Orleans, USA: 531–543.
Priede, J., Buchenau, D. and Gerbeth, G. (2011a) Contactless electromagnetic phase-shift flowmeter for liquid metals. Measurement Science and Technology, 22 (2011): 055402 (11 pp).Google Scholar
Priede, J., Buchenau, D. and Gerbeth, G. (2011b) Single-magnet rotary flowmeter for liquid metals. Journal of Applied Physics 110: 034512.Google Scholar
Pritchard, M., Marshall, D. and Wilson, J. (2004) An assessment of the impact of contamination on orifice plate metering accuracy. 22nd North Sea Flow Metering Workshop 2004, Paper 2.2.
Pursley, W. C. (1986) The calibration of flowmeters. Measurement & Control, 19(5): 37–45.Google Scholar
Raišutis, R. (2006) Investigation of the flow velocity profile in a metering section of an invasive ultrasonic flowmeter. Flow Measurement and Instrumentation, 17(4): 201–206.Google Scholar
Raszillier, H. and Durst, F. (1991) Coriolis-effect in mass flow metering. Archive of Applied Mechanics, 61: 192–214.Google Scholar
Raszillier, H. and Raszillier, V. (1991) Dimensional and symmetry analysis of Coriolis mass flowmeters. Flow Measurement and Instrumentation, 2: 180–184.Google Scholar
Raszillier, H., Allenborn, N. and Durst, F. (1993) Mode mixing in Coriolis flowmeters. Archive of Applied Mechanics, 63(4–5): 219–227.Google Scholar
Raszillier, H., Allenborn, N. and Durst, F. (1994) Effect of a concentrated mass on Coriolis flowmetering. Archive of Applied Mechanics, 64.6: 373–382.Google Scholar
Raustein, O. and Fosse, S. (1991) Measurement of fuel and flare as basis for the CO2 – tax. Proceedings of the North Sea Flow Measurement Workshop, Norwegian Society of Chartered Engineers.
Rawes, W. and Sanderson, M. L. (1997) An ultrasonic insertion flowmeter for in-situ calibration, Ultrasonics in Flow Measurement. Cranfield University, Bedford, England.
Rawes, W. and Sanderson, M. L. (1998) Improvements to an ultrasonic insertion flowmeter for in-situ calibration. FLOMEKO '98 Proceedings of the 9th International Conference on Flow Measurement, Lund, Sweden, pp. 143–147.
Reader-Harris, M. J. (1986) Computation of flow through orifice-plates downstream of rough pipework. Proceedings of International Conference on Flow Measurement in the mid 80's, National Engineering Laboratory, 9–12 June 1986.
Reader-Harris, M. J. (1989) Computation of flow through orifice plates. Numerical Methods in Laminar and Turbulent Flow, 6: 1907–1917.Google Scholar
Reader-Harris, M. J. (1994) The decay of swirl in a pipe. International Journal of Heat and Fluid Flow, 15(3): 212–217.Google Scholar
Reader-Harris, M. J. (1998) The equation for the expansibility factor for orifice plates. FLOMEKO'98 International Conference on Flow Measurement, Lund, Sweden: 209–214.
Reader-Harris, M. (2012) Wet-gas measurement: ISO/TR 11583. North Sea Flow Metering Workshop
Reader-Harris, M. (2015) Orifice plates and Venturi tubes. Springer-Verlag GmbH.
Reader-Harris, M. and Addison, D. (2013) Orifice plates with drain holes. FLOMEKO 2013, Paris, or IMEKO- TC9-2013–088.
Reader-Harris, M. and Addison, D. (2014) Orifice plates with drain holes. North Sea Flow Metering Workshop.
Reader-Harris, M. J. and Brunton, W. C. (2002) The effect of diameter steps in upstream pipework on orifice plate discharge coefficients. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Reader-Harris, M. and Graham, E. (2009) An improved model for Venturi-tube over-reading in wet gas. 27th International North Sea Flow Measurement Workshop, Tonsberg, Norway, 20–23 October 2009, pp. 131–153. Also at https://www.tekna.no/ikbViewer/Content/783839/Paper%207%20-%20%20E%20Graham.pdf.
Reader-Harris, M. J. and Keegans, W. (1986) Comparison of computation and LDV measurement of flow through orifice and perforated plates, and computation of the effect of rough pipework on orifice plates. Proceedings of the International Symposium on Fluid Flow Measurement, Washington, DC, USA.
Reader-Harris, M. J. and Sattary, J. A. (1990) The orifice plate discharge coefficient equation. Journal of Flow Measurement and Instrumentation, 1: 67–76.Google Scholar
Reader-Harris, M. J. and Sattary, J. A. (1996) The orifice plate discharge coefficient equation – the equation for ISO5167-1, 1996. Flow Measurement Memo FL/462, September 1996, Equation 11 (National Engineering Laboratory, East Kilbride, Scotland).
Reader-Harris, M. J., Sattary, J. A. and Spearman, E. P. (1995) The orifice plate discharge coefficient equation – further work. Journal of Flow Measurement and Instrumentation, 6: 101–114.Google Scholar
Reader-Harris, M. J., Brunton, W. C. and Sattary, J. A. (1997) Installation effects on Venturi tubes. ASME Fluids Engineering Division Summer Meeting FEDSM'97, Paper 3016.
Reader-Harris, M. J., Brunton, W. C., Gibson, J. J., Hodges, D. and Nicholson, I. G. (1999) Venturi tube discharge coefficients. In Proc. 4th Int. Symposium on Fluid Flow Measurement, Denver, Colorado.
Reader-Harris, M. J., Brunton, W. C., Gibson, J. J. and Hodges, D. (2000a) Discharge coefficients of Venturi tubes with non-standard convergent angles. FLOMEKO 2000, Salvador, Brazil.
Reader-Harris, M. J., Brunton, W. C., Gibson, J. J., Hodges, D. and Nicholson, I. G. (2000b) Discharge coefficients of Venturi tubes in gas: increasing our understanding. Proceedings of Flow Metering for Next Millennium, FCRI, Palghat, India .Google Scholar
Reader-Harris, M. J., Barton, N., Brunton, W. C., Gibson, J. J., Hodges, D., Nicholson, I. G. and Johnson, P. (2000c) The discharge coefficient and through-life performance of Venturi tubes. 18th North Sea Flow Measurement Workshop, Gleneagles, pp. 5.2, October 2000. East Kilbride, Glasgow, National Engineering Laboratory.
Reader-Harris, M. J., Brunton, W. C., Gibson, J. J., Hodges, D. and Nicholson, I. G. (2001) Discharge coefficients of Venturi tubes with standard and non-standard convergent angles. Journal of Flow Measurement and Instrumentation, 12(2): 135–145.Google Scholar
Reader-Harris, M. J., Brunton, W. C., Hodges, D. and Nicholson, I. G. (2002) Venturi tubes: improved shape. 20th International. North Sea Flow Measurement Workshop, St Andrews, Scotland, Paper 7.3.
Reader-Harris, M., Brunton, W., Nicholson, I. and Rushworth, R. (2003) Ageing effects on orifice metering. 21st North Sea Flow Metering Workshop 2003, Paper 12.
Reader-Harris, M., Rushworth, R. and Gibson, J. (2004) Installation effects on Venturi tubes of convergent angle 10.5º. 22nd North Sea Flow Metering Workshop 2004, Paper 6.1.
Reader-Harris, M. J., Gibson, J., Hodges, D., Nicholson, I. and Rushworth, R. (2005) Venturi tubes with a 10.5° convergent angle: development of a discharge coefficient equation. FLOMEKO 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 5.4.
Reader-Harris, M., Hodges, D. and Rushworth, R. (2008) The effect of drain holes in orifice plates on the discharge coefficient. 26th International North Sea Flow Measurement Workshop, 21–24 October 2008, St Andrews, Scotland, Paper 4.2.
Reader-Harris, M., Barton, N. and Hodges, D. (2010) The effect of contaminated orifice plates on the discharge coefficient. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper B4-5.
Reader-Harris, M., Barton, N. and Hodges, D. (2012) The effect of contaminated orifice plates on the discharge coefficient. Flow Measurement and Instrumentation, 25: 2–7.Google Scholar
Reeb, B. and Joachim, O. (2002) Development of a diagnostics tool for gas turbine meters: the “Acculert G – II”. 20th North Sea Flow Measurement Workshop, 22–25 October 2002, St Andrews, Scotland, Paper 7.2.
Reid, J. and Pursley, W. C. (1986) An on line prover for the calibration of flowmeters in high pressure gas. International Conference on Flow Measurement in the Mid-80s: Paper 8.3.
Reimann, J., John, H. and Muller, U. (1982) Measurement of two-phase flowrate: a comparison of different techniques. International Journal of Multiphase Flow, 8: 33–46.Google Scholar
Reitz, W. C. (1979) Positive displacement meters maintenance. Proc ISA Conf and Exhibit, Advances in Instrumentation. 34, Pt. 2 (Chicago, 22–25 October 1979), Pittsburgh USA, ISA: 259–261.
Reizner, J. R. (2003) Coriolis – the almost perfect flow meter. IEE Computing and Control Engineering, 14(4): 28–33.Google Scholar
Rensing, M. and Cunningham, T. J. (2010) Coriolis flowmeter verification via embedded modal analysis. IMAC XXVIII, Jacksonville, FL, USA.
Rezende, V. A. and Apple, C. (1997) Coriolis meter for LPG custody transfer at Petrobras. North Sea Flow Measurement Workshop, Kristiansand, Norway, Paper 30.
Rice, J. A. (1988) Mathematical statistics and data analysis. Wadsworth & Brooks/Cole Advanced Books & Software, Pacific Grove, California.
Ricken, M. (1989) The swirlmeter – an universal flow measuring instrument. FLOMEKO '89 Proceedings of the 5th International Conference on Flow Measurement, Dusseldorf, Germany: 295–303.
Ricken, O. and Hans, V. (2004) Influence of the variation of the angle of incidence in vortex-shedding metering. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Riddle, W. H. (2004) My mass flow meter has gas. Control (Chicago, Ill), 17(2): 14.Google Scholar
Rieder, A. and Drahm, W. (1996) A new type of single straight tube Coriolis mass flowmeter. FLOMEKO'96 Proceedings of the 8th International Conference on Flow Measurement, Beijing, China: 250–254.
Rieder, A., Drahm, W. and Zhu, H. (2005) Coriolis mass flowmeters: on measurement errors in two-phase conditions. FLOMEKO 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 3.4.
Riezebos, H. J., Mulder, J. P., Sloet, G. H. and Zwart, R. (2000) Whistling flow straighteners and their influence on US flow meter accuracy. North Sea Flow Measurement Workshop, National Engineering Laboratory, East Kilbride, Scotland.
Rivetti, A., Martini, G., Goria, R., Cignolo, G., Capelli, A. and Alasia, F. (1989) Oil, kerosene and water flowmeter calibration: the integrated IMGC gravimetric/volumetric primary facility. FLOMEKO'89 Proceedings of 5th International Conference on Flow Measurement, Dusseldorf, Germany.
Rivetti, A., Martini, G. and Birello, G. (1994) LHe Venturi flowmeters: practical design criteria and calibration method. Cryogenics, 34 Suppl.: 449–452.Google Scholar
Rivkin, I. Y. (1978) Method and apparatus for measuring mass flow rate of individual components of two-phase gas-liquid medium. US Pat. 4 096 745, June.
Robinson, A. C. and Saffman, P. G. (1982) Three-dimensional stability of vortex arrays. Journal of Fluid Mechanics, 125: 411–427.Google Scholar
Robinson, C. (1986) Obstructionless flowmeters: smooth sailing for some, rough passage for others. InTech, 33(12): 33–36.Google Scholar
Robøle, B., Kvandal, H. K. and Schüller, R. B. (2006) The Norsk hydro multi phase flow loop. A high pressure flow loop for real three-phase hydrocarbon systems Flow Measurement and Instrumentation, 17(3): 163–170.Google Scholar
Rogers, J. (1995) Validity of calibration and test data: application of ISO/IEC Guide 25 (EN45001) or the ISO9000 series. Engineering Science and Education Journal, 37 Pt. 2: 109–112. See also INSIGHT 37 No 2, February 1995.
Rooney, D. H. (1973) Steam flow through orifices. Report of a meeting at NEL on Two-Phase Flow Through Orifices and Nozzles, Report No 549: 1–17.
Roosnek, N. (2000) Novel digital signal processing techniques for ultrasonic gas flow measurements. Journal of Flow Measurement and Instrumentation, 11(2): 89–99.Google Scholar
Rosa, E. S. and Morales, R. E. M. (2004) Experimental and numerical development of a two-phase Venturi flow meter. Journal of Fluids Engineering, Transactions of the ASME, 126(3): 457–467.Google Scholar
Rosales, C. and Sanderson, M. L. (2003) Streaming current noise generation in electromagnetic flowmeters measuring conducting fluids. Flow Measurement and Instrumentation, 14(3): 97–108.Google Scholar
Rosales, C., Sanderson, M. L. and Hemp, J. (2002a) Problems in the theory and design of electromagnetic flowmeters for dielectric liquids. Part 2a: Theory of noise generation by turbulence modulation of the diffuse ionic charge layer near the pipe wall. Flow Measurement and Instrumentation, 13(4): 155–163.Google Scholar
Rosales, C., Sanderson, M.L. and Hemp, J. (2002b) Problems in the theory and design of electromagnetic flowmeters for dielectric liquids. Part 2b: Theory of noise generation by charged particles. Flow Measurement and Instrumentation, 13(4): 165–171.Google Scholar
Rose, C. and Vass, G. (1995) New developments in flow measurement technology provide solutions to difficult process applications. ISA Advances in Inst and Control: Int Conf and Exhibition, 50.3: 791–809.Google Scholar
Roshko, A. (1954) On the development of turbulent wakes from vortex streets. NACA Report 1191.
Rothman, P., O'Keefe, C. and Thomas, A. (2009) Application of unique sonar array based process monitoring measurement equipment for minerals processing applications. BI0407 Rev. A, 10th Mill Operations Conference, Adelaide, Australia, 12–14 October 2009, pp. 365–374.
Roverso, D. and Ruan, D. (2004) Enhancing cross-correlation analysis with artificial neural networks for nuclear power plant feed water flow measurement. Real-Time Systems, 27(1): 85–96.Google Scholar
Roverso, D., Ruan, D. and Fantoni, P. F. (2002) Improving feedwater cross-correlation flow measurements in nuclear power plants with artificial neural networks. 5th International FLINS (Fuzzy Logic and Intelligent Techniques in Nuclear Science) Conference on computational intelligent systems for applied research, Ghent, Belgium, 16–18 September 2002, pp. 572–579.
Rowland, J. E. (1989) Acceleration torque devices . Cranfield Short Course Lecture, Cranfield Institute of Technology, England.
Ruan, D., Roverso, D., Fantoni, P. F., Sanabrias, J. I., Carrasco, J. A. and Fernandez, L. (2003) Integrating cross-correlation techniques and neural networks for feed water flow measurement. Progress in Nuclear Energy, 43(1–4 SPEC): 267–274.Google Scholar
Rubio, E., Solano, J., Torres, F. and Garcia-Nocetti, F. (2006) A proposed warped wigner-ville time frequency distribution applied to Doppler blood flow measurement. Proceedings of the Fourth IASTED International Conference on Biomedical Engineering, 2006: 384–389.
Ruoff, J., Hodapp, M. and Kück, H. (2014) Finite element modelling of Coriolis mass flowmeters with arbitrary pipe geometry and unsteady flow conditions. 37: 119–126.
Rychagov, M. N. and Tereshchenko, S. A. (2002) Ultrasonic flow measurements by multipath measuring spoolpieces: quadrature integration and tomographic reconstruction. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Rychagov, M. N., Tereshchenko, S., Masloboev, Y., Simon, M. and Lynnworth, L. C. (2002) Mass flowmeters for fluids with density gradient. Proceedings of the IEEE Ultrasonics Symposium, 1: 465–470.Google Scholar
Saito, S., Hashimoto, M. and Wada, T. (1993) Development of Karman vortex flowmeter by use of laser diode: measurement of flowrate in a pipe with small cross section. FLOMEKO '93 Proceedings of the 6th International Conference on Flow Measurement, Korea: 335–340.
Sakai, K., Okabayasi, M. and Yasuda, K. (1989) The fluidic flowmeter – a gas flowmeter based on fluidic dynamic oscillation. Journal of Flow Measurement & Instrumentation, 1: 44–50.Google Scholar
Sakariassen, R. (1997) On-line quality control of ultrasonic gas flow meters. North Sea Flow Measurement Workshop, Kristiansand, Norway: Paper 15.
Salami, L. A. (1971) Errors in the velocity-area method of measuring asymmetric flows in circular pipes. Proceedings of the International Conference on Modern Developments in Flow Measurement, England: Harwell (Published 1972 by Peter Peregrinus Ltd).
Salami, L. A. (1984a) Application of a computer to asymmetric flow measurement in circular pipes. Transactions of the Institute of Measurement and Control, 6: 197–206.Google Scholar
Salami, L. A. (1984b) Effect of upstream velocity profile and integral flow straighteners on turbine flowmeters. International Journal of Heat and Fluid Flow, 5: 155–165.Google Scholar
Salami, L. A. (1985) Analysis of swirl, viscosity and temperature effects on turbine flowmeters. Transactions of the Institute of Measurement and Control, 7: 183–202.Google Scholar
Salmasi, Z. Z., Jin, W., Gregg, R. D., MacManus, G. and Howarth, C. T. (2001) Electromagnetic flowmeter having low power consumption. US Patent 6,237,424.
Salque, G., Couput, J.-P., Gajan, P., Strzelecki, A. and Fabre, J.-L. (2008) New correction method for wet gas flow metering based on two phase flow modelling: validation on industrial air/oil/water tests at low and high pressure. 26th International North Sea Flow Measurement Workshop, 21–24 October 2008, St Andrews, Scotland, Paper 7.1.
Samer, G. and Fan, S-C. (2010) Modelling of Coriolis mass flow meter of a general plane-shape pipe. Journal of Flow Measurement and Instrumentation, 21(1): 8–19.Google Scholar
Sanderson, M. L. (1994) Domestic water metering technology. Journal of Flow Measurement and Instrumentation, 5: 107–113.Google Scholar
Sanderson, M. L. (1999) Industrial flow measurement by ultrasonics. Non-Destructive Testing and Condition Monitoring, 41(1): 16–19.Google Scholar
Sanderson, M. L. (2003) Factors affecting the dynamic performance of electromagnetic flowmeters. Measurement and Control, 36(9): 270–274.Google Scholar
Sanderson, M. L. (2004) Special issue: ultrasonic flowmetering, Editorial. Flow Measurement and Instrumentation, 15(3): 128.Google Scholar
Sanderson, M. L. and Al-Rabeh, R. H. (2005) A novel ultrasonic flowmeter for low flowrates in small tubes. Flomeko 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 1.1.
Sanderson, M. L. and Hemp, J. (1981) Ultrasonic flowmeters – a review of the state of the art. International Conference on Advances in Flow Measurement Techniques, Coventry, England, Paper G1: 157–178.
Sanderson, M. L. and Sweetland, D. (1991) The effect of four designs of flow conditioner on flowmeter performance. Flow Measurement and Instrumentation Consortium, Category 2A Report No. 1. Cranfield, Bedford: Cranfield Institute of Technology, July 1991.
Sanderson, M. L. and Torley, B. (1985) Error assessment for an intelligent clamp-on transit time ultrasonic flowmeter. International Conference on Flow Measurement in the Mid 80's, NEL Glasgow, Scotland: Paper 11.3.
Sanderson, M. L. and Yeung, H. (2002) Guidelines for the use of ultrasonic non-invasive metering techniques. Flow Measurement and Instrumentation, 13: 125–142.Google Scholar
Sanderson, M. L., Hemp, J., Coulthard, J. and Henry, R. M. (1988) Non-intrusive flow metering. FLOMIC Report No 4.
Sapra, M. K., Bajaj, M., Kundu, S. M. and Sharma, B. S. V. G. (2011) Experimental and CFD investigation of 100 mm size cone flow elements. Flow Measurement and Instrumentation, 22(5): 469–474.Google Scholar
Sato, H. and Watanabe, K. (2000) Experimental study on the use of a vortex whistle as a flowmeter. IEEE Transactions on Instrumentation and Measurement, 49: 200–205.Google Scholar
Sato, H., Furuichi, N., Terao, Y. and Takamoto, M. (2005) Basic design of a very large water flow calibration facility for nuclear power application. FLOMEKO 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 8.2.
Sato, S., Nukui, K., Ito, S. and Kimura, Y. (1996) Numerical analysis of fluidic oscillation applied to the fluidic gas meter. FLOMEKO'96 Proceedings of the 8th International Conference on Flow Measurement, Beijing, China: 138–143.
Sattary, J. A. (1991) EEC orifice plate programme – installation effects. Journal of Flow Measurement and Instrumentation, 2: 21–33.Google Scholar
Sattary, J. A. and Reader-Harris, J. (1997) Computation of flow through Venturi meters. North Sea Flow Measurement Workshop, Kristiansand, Norway: Paper 26.
Sazhin, O. (2013) Novel mass air flow meter for automobile industry base on thermal flow microsensor. I. Analytical Model and microprocessor. Flow Measurement and Instrumentation 2013, 30: 60–65.Google Scholar
Scanes, E. P. (1974) A domestic oil flowmeter. Kent Technical Review, 11: 31–33.Google Scholar
Scelzo, M. J. A. (2001) Clamp-on ultrasonic flowmeter for gases. Flow Control, VII(9): 34–37.Google Scholar
Scheers, A. M. and Wolff, C. J. M. (2002) Production measurement management. 20th North Sea Flow Measurement Workshop, 22–25 October 2002, St Andrews, Scotland, Paper 1.2.
Schieber, W. (1998) The Accutest: a turbine meter with a built-in transfer standard. FLOMEKO '98 Proceedings of the 9th International Conference on Flow Measurement, Lund, Sweden, pp. 509–516.
Schlichting, H. (1979) Boundary Layer Theory, McGraw-Hill, New York, ISBN 0-07-055334-3.
Schlumberger, (2010) Fundamentals of multiphase metering. Schlumberger.
Schluter, Th. and Merzkirch, W. (1996) PIV measurements of the time-averaged flow velocity downstream of flow conditioners in a pipeline. Journal of Flow Measurement and Instrumentation, 7(3/4): 173–179.Google Scholar
Schneider, F., Peters, F. and Merzkirch, W. (2003) Quantitative analysis of the cross-correlation ultrasonic flow meter by means of system theory. Measurement Science and Technology, 14(5): 573–582.Google Scholar
Schoenborn, E. M. Jr. and Colburn, A. P. (1939) The flow mechanism and performance of the rotameter. Transactions of the American Institute of Chemical Engineers, 35: 359–389.Google Scholar
Scott, C. (1984) Sounding out ultrasonic flowmeters. Control & Instrumentation, August: 27 and 29.Google Scholar
Scott, R. W. W. (1975a) The use and maintenance of weighing machines in high accuracy liquid flow calibration systems. Conference on Fluid Flow Measurement in the Mid 1970's, Paper B-1: Scotland: National Engineering Laboratory.
Scott, R. W. W. (1975b) A practical assessment of the performance of electromagnetic flowmeters. Conference on Fluid Flow Measurement in the mid 1970s, NEL, Scotland: Paper E1.
Scott, R. W. W. (1982) Liquid flow measurement – a general appraisal. Developments in Flow Measurement-1, ed. Scott, R. W. W., London: Applied Science Publishers: 73–100.
Selvikvag, O. (1997) The Norwegian regulations relating to fiscals measurements of oil and gas – 1997 update. North Sea Flow Measurement Workshop, Kristiansand, Norway: Paper 8.
Shafer, M. R. (1962) Performance characteristics of turbine flowmeters. Journal of Basic Engineering,: 471–485.Google Scholar
Shakouchi, T. (1989) New fluidic oscillator, flowmeter, without control port and feedback loop. Journal of Dynamic Systems, Trans ASME, 111.3: 535–539.Google Scholar
Sharma, P., Kumar, S. S., Nashine, B. K., Veerasamy, R., Krishnakumar, B., Kalyanasundaram, P. and Vaidyanathan, G. (2010) Development, computer simulation and performance testing in sodium of an eddy current flowmeter. Annals of Nuclear Energy 37: 332–338.Google Scholar
Sharma, V., Kumar, G. V., Dash, S. K., Nashine, B. K. and Rajan, K. K. (2012) Modelling of permanent magnet flowmeter for voltage signal estimation and its experimental verification. Flow Measurement and Instrumentation, 28: 22–27.Google Scholar
Sheikholeslami, M. Z., Patel, B. R. and Kothari, K. (1988) Numerical modelling of turbulent flow through orifice meters – a parametric study. 2nd International Conference on Flow Measurement, London.
Shen, J. J. S., Vierkandt, S. J. and Ogden, K. A. (2003) Operation and evaluation of a roxar (MFI model) multiphase meter in sour field environment. 21st North Sea Flow Metering Workshop 2003, Paper 23.
Shen, X., Saito, Y., Mishima, K. and Nakamura, H. (2005) Methodological improvement of an intrusive four-sensor probe for the multi-dimensional two-phase flow measurement. International Journal of Multiphase Flow, 31(5): 593–617.Google Scholar
Sheppard, T. J. (1994) Solid state gas metering: the future. Journal of Flow Measurement and Instrumentation, 5: 103–106.Google Scholar
Shercliff, J. A. (1955) Experiments on the dependence of sensitivity on velocity profile in electromagnetic flowmeters. Journal of Scientific Instruments, 32: 441–442.Google Scholar
Shercliff, J. A. (1962) The theory of electromagnetic flow-measurement. Cambridge University Press (2nd Ed. 1987), Cambridge.
Shields, C. A., Dollard, M., Sridhar, S., Dragnea, G. and Illingworth, M. (2013) Use of SONAR Metering to Optimize Production in Liquid Loading Prone Gas Wells. SPE 166652-MS.
Shim, W. J., Dougherty, T. J. and Cheh, H. Y. (1996) Turbine flowmeter response in two-phase flow. International Conference on Nuclear Engineering Volume 1 – Part B, ASME, 943–953.
Shimada, T., Terao, Y., Takamoto, M., Ono, S. and Gomi, S. (2002) Development of a servo pd oil flowmeter for a transfer standard. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Shimada, T., Oda, S., Terao, Y. and Takamoto, M. (2003) Development of a new diverter system for liquid flow calibration facilities. Journal of Flow Measurement and Instrumentation, 14(3): 89–96.Google Scholar
Shimada, T., Doihara, R., Terao, Y. and Takamoto, M. (2004) Uncertainty analysis of primary standard for hydrocarbon flow at NMIJ FLOMEKO 2004 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Shimada, T., Doihara, R., Terao, Y. and Takamoto, M. (2007) Development of hydrocarbon flow facility as a national standard Journal of Fluid Science and Technology, 2(1): 23–34.Google Scholar
Shimada, T., Doihara, R., Terao, Y. and Takamoto, M. (2010a) Establishment of Traceability System for Hydrocarbon Flow in Japan. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper B5-3.
Shimada, T., Mahadeva, D. V. and Baker, R.C. (2010b) Further investigation into a water flow rig related to calibration. Journal of Flow Measurement and Instrumentation, 21(4): 462–475.Google Scholar
Shimada, T., Doihara, R. and Terao, Y. (2015) Investigation into calibration performance of small volume prover for hydrocarbon flow. Flow Measurement and Instrumentation, 41: 174–180.Google Scholar
Shimizu, T. and Takeshima, N. (2001) Numerical study on Faraday-type electromagnetic flowmeter in liquid metal system, (II) analysis of end effect due to saddle-shaped small-sized magnets with FALCON code. Journal of Nuclear Science and Technology, 38(1): 19–29.Google Scholar
Shimizu, T., Takeshima, N. and Jimbo, N. (2000) Numerical study on Faraday-type Electromagnetic Flowmeter in liquid metal system, (I) A numerical method based on magnetic field and electric potential field: FALCON code. Journal of Nuclear Science and Technology, 37(12): 1038–1048.Google Scholar
Shinder, I. I. and Moldover, M. R. (2009) Dynamic gravitational standard for liquid flow: model and measurements. 7th International Symposium of Fluid Flow Measurement Anchorage, Alaska, USA.
Shinder, I. I, Moldover, M. R and Lingan, X. (2010) Feasibility of an accurate dynamic standard for water flow. Journal of Flow Measurement and Instrumentation, 21(2): 128–133.
Shufang, H., Yongtao, H. and Lingan, X. (1996) The practice on DN 1400MM Venturi tubes. Proceedings of the 8th International Conference on Flow Measurement, China: Beijing: 37–42.
Shuoping, Z., Zhijie, X. and Baofen, Z. (1996) Flow with differential pressure noise of orifice. FLOMEKO '96 Proceedings of the 8th International Conference on Flow Measurement, Beijing, China: 605–611.
Sidney, J. K., King, N. W. and Coulthard, J. (1988a) Cross-correlation flow measurements in oil-air mixtures. 2nd Int Conf Flow Measurement, BHRA, London.
Sidney, J. K., King, N. W. and Coulthard, J. (1988b) The measurement of individual phase-flowrates using an ultrasonic cross-correlation flowmeter in air-kerosene mixtures. Flucome '88, H S Stephens & Associates, Sheffield, September.
Siegwarth, J. D. (1989) Vortex shedding flowmeters for high velocity liquids. International Journal of Heat & Fluid Flow, 10.3: 232–244.Google Scholar
Silva, F. S., Velazquez, M. T. and Ruiz, J. H. (1997) Experimental study for the use of elbows as flowmeters. ASME Fluids Engineering Division Summer Meeting FEDSM'97, Paper 3010.
Simões, E. W., Furlan, R. and Pereira, M. T. (2002) Flow measurement with microfluidic oscillators. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Simões, E. W., Furlan, R., Brusetti Leminski, R. E., Gongora-Rubio, M. R., Pereira, M. T. and Morimoto, N. I. (2004) Microfluidic oscillator for gas flow control and measurement. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Simões, E. W., Furlan, R., Brusetti Leminski, R. E., Gongora-Rubio, M. R., Pereira, M. T., Morimoto, N. I. and Santiago-Avilés, J. J. (2005) Microfluidic oscillator for gas flow control and measurement. Flow Measurement and Instrumentation, 16(1): 7–12.Google Scholar
Simpson, R. J. (1984) Flexible orifice plates. Measurement & Control, 17.Google Scholar
Sims, L. and Rabalais, R. A. (2002) Ultrasonic flow measurement: technology and applications in process and multiple vent stream situations. Proceedings of the Annual Symposium on Instrumentation for the Process Industries, 57: 135.Google Scholar
Sims, P. (1992) Mass flowmeter technology benefits blending. Process & Control Engineering, 45(5): 32–33.Google Scholar
Sindt, Ch. F., Brennan, J. A., McFaddin, S. E. and Wilson, R. W. (1989) Effect of pipe surface finish on the orifice discharge coefficient. FLOMEKO'89 International Conference on Flow Measurement, Dusseldorf, Germany: 49–56.
Singh, R. K., Singh, S. N. and Seshadri, V. (2009) Study of the effect of vertex angle and upstream swirl on the performance characteristics of cone flowmeter using CFD. Flow Measurement and Instrumentation, 20(2): 69–74.Google Scholar
Singh, R. K., Singh, S. N. and Seshadri, V. (2010) CFD prediction of the effects of the upstream elbow fittings on the performance of cone flowmeters. Flow Measurement and Instrumentation, 21(2): 88–97.Google Scholar
Singh, S. N., Seshadri, V., Singh, R. K. and Gawhade, R. (2006) Effect of upstream flow disturbances on the performance characteristics of a V-cone flowmeter. Flow Measurement and Instrumentation, 17(5): 291–297.Google Scholar
Skaardalsmo, K. and Moksnes, P. O. (2003) Phase watcher VX multiphase flowmeter Heidrun experience and analysis. 21st North Sea Flow Metering Workshop 2003, Paper 25.
Skea, A. F. and Hall, A. R. W. (1999a) Effects of gas leaks in oil flow on single-phase flowmeters. Journal of Flow Measurement and Instrumentation, 10: 145–150.Google Scholar
Shimada, T., Doihara, R., Terao, Y. and Takamoto, M. (1999b) Effects of water in oil and oil in water on single-phase flowmeters. Journal of Flow Measurement and Instrumentation, 10: 151–157.Google Scholar
Skwarek, V. and Hans, V. (2000) The ultrasonic cross-correlation flowmeter – new insights into the physical background. FLOMEKO'2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper B3.
Skwarek, V., Windorfer, H. and Hans, V. (2001) Measuring pulsating flow with ultrasound. Measurement J. Int. Measurement Confederation, 29(3): 225–236.Google Scholar
Slater, S. G., Paterson, A. McK. and Marshall, M. F. (1997) Offshore Technology Conference, Houston, TX, USA, 4: 523–532.
Sloet, G. and de Nobel, G. (1997) Experiences with ultrasonic meters at the Gasunie export stations. North Sea Flow Measurement Workshop, Kristiansand, Norway: Paper 14.
Sluše, J. and Geršl, J. (2013) Cavitation of lng in ultrasonic flowmeters – CFD modelling. FLOMEKO 2013, 16th International Flow Measurement Conference, Paris, France.
Smalling, J. W., Braswell, L. D., Lynnworth, L. C. and Russell Wallace, D. (1984) Flare gas ultrasonic flow meter. Proc. of 39th Annual Symp. on Instrum. for the Process Industries, 17–20 January 1984, pp. 27–38.
Smalling, J. W., Braswell, L. D. and Lynnworth, L. C. (1986) Apparatus and methods for measuring fluid flow parameters. US Patent 4,596,133, 24 June 1986 (filed 29 July 1983).
Smith, C. R., Greco, J. J. and Hopper, P. B. (1989) Low-loss conditioner for flow distortion/swirl using passive vortex generation devices. FLOMEKO 5th International Flow Measurement Conference, Dusseldorf, Germany: 57–64.
Smith, J. E. (1978) Gyroscopic/Coriolis mass flow meter. Canadian Controls & Instruments, 117: 29–31, (follows Willer's (1978) note).Google Scholar
Smith, J. E. and Cage, D. R. (1985) Parallel path Coriolis mass flow rate meter. US Patent 4,491,025, 1st Jan.
Smith, M. and Morfey, C. (1997) The effect of developing flow on the accuracy of an ultrasonic gas meter. Ultrasonics in Flow Measurement, Cranfield University, Bedford, UK.
Smith, R. E. and Matz, R. J. (1962) A theoretical method of determining discharge coefficients for Venturis operating at critical flow conditions. Journal of Basic Engineering, 84: 434–446.Google Scholar
Smith, R. V. and Leang, J. T. (1975) Evaluations of correlations for two-phase flowmeters, three current – one new. ASME Paper No 74-WA/FM-5, 1974, and ASME J Eng Power, 1975.
Smith, W. C. and Kowalski, R. R. (1998) Adaptation of commercial Coriolis flowmeters for non-intrusive pressure measurement. Instrumentation in the Aerospace Industry: Proceedings of the 44th International Symposium, 44: 87–96.Google Scholar
Smorgrav, A. E. (1990) Multiphase flow meter KO 300 MFM. North Sea Flow Measurement Workshop, National Engineering Laboratory, Scotland.
Smørgrav, S. and Abrahamsen, A. K. (2009) OIML R 137-1, the first ultrasonic meter to be tested to accuracy class 0.5?. 27th International North Sea Flow Measurement Workshop, Tonsberg, Norway, 20–23 October 2009, pp. 235–252.
Soderholm, A. (1999) Bulk solid mass flowmeter using the Coriolis principle. Powder Handling and Processing, 11(3): 297–300.Google Scholar
Sofialidis, D. and Prinos, P. (March 1996) Wall suction effects on the structure of fully developed turbulent pipe flow. Journal of Fluid Engineering, 118: 33–39.Google Scholar
Sparks, C. R., Durke, R. D. and McKee, R. J. (1989) Pulsation-induced errors in the primary and secondary systems of orifice meters. FLOMEKO'89 International Conference on Flow Measurement, Dusseldorf, Germany: 31–38.
Sparks, D., Smith, R., Cripe, J., Schneider, R. and Najafi, N. (2003) A portable MEMS Coriolis mass flow sensor. IEEEE Sensors Conference, 2003.
Sparreboom, W., van de Geest, J., Katerberg, M., Postma, F., Haneveld, J., Groenesteijn, J., et al. (2013) Compact mass flow meter based on a micro Coriolis flow sensor. Micromachines, 4: 22–33.Google Scholar
Spazzini, P. G., Callegaro, L., Pennecchi, F. and Mickan, B. (2010) Comparison of Calibration Curves: an Application Example. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper B6-1.
Spearman, E. P., Sattary, J. A. and Reader-Harris, M. J. (1991) A study of flow through a perforated-plate/orifice-meter package in two different pipe configurations using laser Doppler velocimetry. Journal of Flow Measurement and Instrumentation, 2: 83–88.Google Scholar
Spearman, E. P., Sattary, J. A. and Reader-Harris, M. J. (1996) Comparison of velocity and turbulence profiles downstream of perforated plate flow conditioners. Journal of Flow Measurement and Instrumentation, 7(3/4): 181–199.Google Scholar
Spencer, E. A. (1993) Bibliography of the EEC orifice plate project. Report EUR 14885 EN, Commission of the European Communities, Brussels, Belgium.
Spencer, E. A., Heitor, M. V. and Castro, I. P. (1995) Intercomparison of measurements and computations of flow through a contraction and a diffuser. Journal of Flow Measurement and Instrumentation, 6: 3–14.Google Scholar
Spink, L. K. (1978) Principles and practice of flow meter engineering. 9th ed., Foxboro, MA: The Foxboro Company.
Spitzer, D. W. ed. (1991) Flow measurement. Instrument Society of America.
Spragg, W. T. and Seatonberry, B. W. (1975) A radioisotope dilution method for the precise absolute determination of the flowrate of gas under industrial conditions. Conference on Fluid Flow Measurement in the Mid 1970's, Paper D-1: Scotland: National Engineering Laboratory.
Sproston, J. L., Johnson, M. W. and Pursley, W. C. (1987) Mass flow measurement. FLOMIC Report.
Sproston, J. L., El-Wahed, A. and Johnson, M. W. (1990) An electrostatic vortex-shedding meter. Journal of Flow Measurement & Instrumentation, 1: 183–190.Google Scholar
Squirrell, B. (1994) Profibus: a working standard fieldbus. Measurement & Control, 27 (1): 9–14.Google Scholar
Stack, C. P. and Cunningham, T. J. (1993) Design and analysis of Coriolis mass flowmeters using MSC/NASTRAN. Presented at Conference on MSC World Users, 1993.
Stack, C. P., Barnett, R. B. and Pawlas, G. E. (1993) A finite-element for the vibration analysis of a fluid-conveying Timoshenko beam AIAA Technical Paper (AIAA-93-1552-CP)’, pp. 2120–2129.
Standiford, D. M. and Lee, M. (2010) Inter-laboratory comparison results for coriolis mass flow meter calibration facilities. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A9-3.
Stansfeld, J., Atkinson, I. and Washington, G. (1988) A new mass flow meter and its application to crude oil metering. North Sea Metering Workshop, National Engineering Laboratory, Scotland.
Starling, K. E. and Luongo, J. F. (1997) Electronic implementations of A.G.A. Report No. 8. ASME Fluids Engineering Division Summer Meeting FEDSM'97, Paper 3015.
Staubli, T., Luescher, B., Gruber, P. and Widmer, M. (2008) Optimization of acoustic discharge measurement using CFD. International Journal on Hydropower & Dams, 15(2): 109–113.Google Scholar
Steenbergen, W. and Voskamp, W. (1998) The rate of decay of swirl in turbulent pipe flow. Flow Measurement and Instrumentation, 9: 67–78.Google Scholar
Stelian, C. (2013) Calibration of a Lorentz force flowmeter by using numerical modeling. Flow Measurement and Instrumentation. 33: 36–44.Google Scholar
Steven, R. (2000) Wet gas metering with a horizontally installed Venturi meter. FLOMEKO '2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper D7.
Steven, R. (2007) V-cone wet gas metering. 25th International North Sea Flow Measurement Workshop, Energy Institute, Oslo, Norway, 152–180.
Steven, R. (2008a) A dimensional analysis of two phase flow though a horizontally installed Venturi flow meter. Flow Measurement and Instrumentation, 19(6): 342–349.Google Scholar
Steven, R. (2008b) Diagnostic methodologies for generic differential pressure flow meters. 26th International North Sea Flow Measurement Workshop, 21–24 October 2008, St Andrews, Scotland, Paper 4.1.
Steven, R. (2009) Horizontally installed cone differential pressure meter wet gas flow performance. Flow Measurement and Instrumentation, 20(4–5): 152–167.Google Scholar
Steven, R. (2009a) Diagnostic capabilities of Δ P cone meter. 7th International Symposium of Fluid Flow Measurement, Anchorage, Alaska, USA.
Steven, R. (2009b) Significantly improved capabilities of DP meter diagnostic methodologies. 27th International North Sea Flow Measurement Workshop, Tonsberg, Norway, 20–23 October 2009, pp. 13–41.
Steven, R. (2010) Diagnostic system for Venturi meters. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010 Taipei, Taiwan, Paper B10-4.
Steven, R. and Hall, A. (2009) Orifice plate meter wet gas flow performance. Flow Measurement and Instrumentation, 20(4–5): 141–151.Google Scholar
Steven, R. and Hodges, C. (2012) Orifice meter diagnostics – a discussion on theory, laboratory tests, system interface and field results. 8th ISFFM (2012).
Steven, R. and Lawrence, P. A. (2003) Research developments in wet gas metering with V-cone meters. 21st North Sea Flow Metering Workshop 2003, Paper 11.
Steven, R., Kegel, T. and Britton, C. (2005) An update on V-cone meter wet gas flow metering research. FLOMEKO 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 3.2.
Steven, R., Britton, C., Kinney, J. and Pagano, S. (2009) Wedge meters with wet natural gas flows. Proc. 7th International Symposium on Fluid Flow Measurement (ISFFM), Anchorage, Alaska, USA.
Steven, R., Britton, C. and Kinney, J. (2010) 4˝, 0.63 beta ratio cone DP meter wet gas performance. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper B4-4.
Stewart, D. G. (2002) Performance of Coriolis meters in gas flow. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Stewart, D. G. and Hodges, D. (2003) Suitability of dry gas metering technology for wet gas metering. 21st North Sea Flow Metering Workshop 2003, Paper 6.
Stewart, D. G., Hodges, D., Steven, R. and Peters, R. J. W. (2002) Wet gas metering with V-cone meters. 20th North Sea Flow Measurement Workshop, 22–25 October 2002, St Andrews, Scotland, Paper 4.2.
Stewart, D. G., Hodges, D. and Brown, G. (2003) Venturi meters in wet gas flow. 21st North Sea Flow Metering Workshop 2003, Paper 4.
Stewart, D. G., Watson, J. T. R. and Vaidya, A. M. (2000) A new correlation for the critical mass flux of natural gas mixtures. Flow Measurement and Instrumentation, 11(4): 265–272.
Stidger, Ruth W. (2003) Measurement and instrumentation: flow meter advances push utilities to make changes. Gas Utility Manager, 47(7): 12–13.Google Scholar
Stobie, G. J. (1993) Metering in the real world . North Sea Flow Measurement Workshop, Bergen, Norway.
Stobie, G. J., Zanker, K. J., Brown, C. and Letton, W. (2001) Flow testing a USM outside its performance envelope. 19th North Sea Flow Measurement Workshop, Kristiansand, Norway, 22–25 October 2001, Paper 8.
Stobie, G., Hart, R., Svedeman, S. and Zanker, K. (2007) Erosion of a Venturi meter with laminar and turbulent flow and low Reynolds number discharge coefficient measurements. 25th International North Sea Flow Measurement Workshop, Energy Institute, Oslo, Norway, 274–294.
Stoll, H. W. (1978) Current trends in flow measurement technology. Proc ISA Pacific Northwest Instrum ’78 Symp, Portland Oreg: 89–91.
Stoltenkamp, P. W., Araujo, S. B., Riezebos, H. J., Mulder, J. P. and Hirschberg, A. (2003) Spurious counts in gas volume flow measurements by means of turbine meters. Journal of Fluids and Structures, 18(6): 771–781.Google Scholar
Stolz, J. (1978) A universal equation for the calculation of discharge coefficients of orifice plates. Flow Measurement of Fluids (ed. H. H. Dijstelbergen and E. A. Spencer), North Holland, Amsterdam: 519–534.
Stolz, J. (1988) The first revision of ISO 5167. North Sea Metering Workshop, NEL, East Kilbride, Scotland: Paper 3.1.
Stone, C. R. and Wright, S. D. (1994) Non-linear and unsteady flow analysis of flow in a viscous flowmeter. Transactions of the Institute of Measurement and Control, 16: 128–141.Google Scholar
Storer, J. and Steven, R. (2010) A mass flow meter concept with diagnostic capabilities. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper B7-3.
Storer, J., Schroeder, E. and Steven, R. (2009) Advances in vortex shedding flow metering. Proc. 7th International Symposium on Fluid Flow Measurement, Anchorage, Alaska, USA.
Storm, R., Kolahi, K. and Rock, R. (2001) Model based correction of Coriolis mass flowmeters. Conference Record – IEEE Instrumentation and Measurement Technology Conference, 2: 1231–1236.Google Scholar
Storm, R., Kolahi, K. and Rock, R. (2002) Model-based correction of Coriolis mass flowmeters. IEEE Transactions on Instrumentation and Measurement, 51(4): 605–610.Google Scholar
Stratford, B. S. (1964) The calculation of the discharge coefficient of profiled choked nozzles and the optimum profile for absolute air flow measurement. Journal of Royal Aeronautical Society, 68(640): 237–245.Google Scholar
Strawn, C. (1991) Mass meters for liquid measurement. Methods of proving Coriolis mass flowmeters. Proc International School of Hydrocarbon Measurement, University of Oklahoma, Continuing Engineering Education, Norman, USA: 148–150.
Strohrmann, M., Lembke, M., Huftle, G., Konzelmann, U., Lenzing, T., Opitz, B. and Bruckner, J. (2004) Heissfilmluftmassenmesser HFM6 – Prazise Luftmassenmessung fur Kraftfahrzeuganwendungen (Hot film mass air flow meter HFM6 – High precision mass air flow metering for automotive applications). VDI Berichte, (1829): 535–542+921 (in German).Google Scholar
Strom, G. R. and Livelli, G. (2001 date uncertain) Direct mounting allows differential pressure (dp) based flow measurement optimization . Rosemount, Inc. http://www2.emersonprocess.com/siteadmincenter/PM%20Rosemount%20Documents/ISA-DirectMountingPaper.pdf
Strzelecki, A., Gajan, P., Couput, J. P. and De Laharpe, V. (2000) Behaviour of Venturi meters in two-phase flows. FLOMEKO '2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper D6.
Studzinski, W. and Karnik, U. (1997) Installation effects on orifice meter with no flow conditioner, ASME Fluids Engineering Division Summer Meeting FEDSM '97, Paper 3014.
Sui, L., Nguyen, T. H., Matson, J. E., Espina, P. and Tew, I. (2010) Ultrasonic flowmeter for accurately measuring flare gas over a wide velocity range. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A4-5.
Sui, L., Pfenninger, R. S., Nguyen, T. H., Hobbs, N. A., Sadovnik, I., Su, L. and Matson, J. E. (2013) Ultrasonic flowmeter for coal seam gas application. FLOMEKO 2013, 24-26th September 2013, Paris
Sullivan, J. J., Ewing, J. H. and Jacobs, R. P. (no date) Calibration techniques for thermal-mass flowmeters. (possibly published in Solid State Technology) MKS Instruments Inc, Burlington, MA 01803, USA.
Sultan, G. (1992) Single straight tube Coriolis mass flowmeter. Journal of Flow Measurement and Instrumentation, 3: 241–246.Google Scholar
Sultan, G. and Hemp, J. (1989) Modelling of the Coriolis mass flowmeter. Journal of Sound and Vibration, 132(3): 473–489.Google Scholar
Summers-Smith, J. D. (1994) An introductory guide to industrial tribology. Mechanical Engineering Press, London.
Sun, L. and Zhang, T. (2004) Study on the mathematical model of the turbine flowmeters. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Sun, L.-J., Qi, L.-X. and Zhang, T. (2010) Numerical simulation and experiment on averaging pitot tube with flow conditioning wing. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper B10-2. Possibly cf paper in JFMI).
Sun, M., Liu, S., Lei, J. and Li, Z. (2008) Mass flow measurement of pneumatically conveyed solids using electrical capacitance tomography. Measurement Science and Technology, 19(4): 045503.Google Scholar
Sun, Y., Xiong, H., Zhu, R. and Bi, l. (1996) Research and development on wear-resistant orifice plates. Proceedings of the 8th International Conference on Flow Measurement, Beijing, China: 27–31.
Sun, Zhengnai; Li, P., Qiang, X. and Zhao, Y. (2000) Optical fiber interference target flowmeter (II): damper design. Proceedings of SPIE – The International Society for Optical Engineering, 4222: 198–201.Google Scholar
Suzuki, N., Nakabori, H. and Yamamoto, M. (1972) Ultrasonic method of flow measurement in large conduits and open channels. Modern Developments in Flow Measurement, Peter Peregrinus Ltd: 115–138.
Suzuki, N., Nakabori, H. and Kitajima, A. (1975) New applications of ultrasonic flowmeters. Flowmeasurement in the Mid ’70s, NEL, Glasgow, Scotland: Paper H-3.
Svedin, N., Stemme, E. and Stemme, G. (2001) A static turbine flow meter with a micromachined silicon torque sensor. Proceedings of the 14th IEEE International Conference on Micro Electro Mechanical Systems (MEMS 2001), Interlaken, Switzerland, pp. 208–211.
Svedin, N. (2003) A static turbine flow meter with a micro machined silicon torque sensor. Journal of Microelectromechanical Systems, 12(6): 937–946.
Svensson, B. and Delsing, J. (1998) Application of ultrasonic clamp-on flowmeters for in situ tests of billing meters in district heating systems. Journal of Flow Measurement and Instrumentation, 9(1): 33–41.Google Scholar
Svete, A., Kutin, J. and Bajsić, I. (2009) Static and dynamic characteristics of a hydraulic Wheatstone Bridge. Flow Measurement and Instrumentation, 20(6): 264–270.
Svete, A. (2013) Dynamic characteristics of a hydraulic Wheatstone bridge mass flowmeter. 16th International Flow Measurement Conference, FLOMEKO 2013, 24–26 September 2013, Paris.
Svete, A., Kutin, J., Bajsic, I. and Slavic, J. (2012) Development of a liquid flow pulsator. Flow Measurement and Instrumentation, 23(1): 1–8.
Swanson, K. (1988) New developments in the measurement of slurries and emulsions using Coriolis effect mass flowmeters. Proc Pacific Cascade Instrum '88 Symposium, ISA, USA.
Szebeszcyk, J. M. (1994) Application of clamp-on ultrasonic flowmeter for industrial flow measurements. Journal of Flow Measurement and Instrumentation, 5: 127–131.Google Scholar
Taha, S. M. R. (1994) Digital measurement of the mass-flow rate. Sensors & Actuators, A: Phys, 45.2: 139–143.Google Scholar
Tai, S. W., Miau, J. J., Shaw, J. H. and Chen, Z. L. (1993) Signal-quality study of ring-type vortex flowmeters. FLOMEKO '93 Proceedings of the 6th International Conference on Flow Measurement, Korea: 320–326.
Takahashi, S. and Itoh, I. (1993) Intelligent vortex flowmeter. FLOMEKO '93 Proceedings of the 6th International Conference on Flow Measurement, Korea: 313–319.
Takamoto, M. (1996) New flowmeter technology for the next century. FLOMEKO '96 Proceedings of the 8th International Conference on Flow Measurement, China: Beijing: 7–12.
Takamoto, M. and Komiya, K. (1981) Application of a ring to a bluff body of a vortex shedding flowmeter. Transactions of the Society of Instrument and Control Engineers, Japan,. 17: 506–510, (in Japanese).Google Scholar
Takamoto, M. and Terao, Y. (1994) Development of a standard vortex shedding flowmeter. FLOMEKO '94 Flow Measurement in the Mid 90's, NEL, Glasgow, Scotland.
Takamoto, M., Ishiashi, M., Watanabe, N., Aschenbrenner, A. and Caldwell, S. (1993a) Intercompariosn tests of gas flowrate standards. FLOMEKO '93 Proceedings of the 6th International Conference on Flow Measurement, Korea: 75–84.
Takamoto, M., Utsumi, H., Watanabe, N. and Terao, Y. (1993b) Installation effects on vortex shedding flowmeters. Journal of Flow Measurement & Instrumentation, 4: 277–285.Google Scholar
Takeda, Y. and Shaik, J. (2008) Editorial, Special Issue: ISUD 5: The 5th International Symposium on Ultrasonic Doppler Methods for Fluid Mechanics and Fluid Engineering. Flow Measurement and Instrumentation, 19(3–4): 129.Google Scholar
Tan, C. and Dong, F. (2006) Two-phase flow measurement by dual-plane ERT system with drift-flux model and cross correlation technique. Proceedings of the 2006 International Conference on Machine Learning and Cybernetics, ICMLC 2006, 20061443-8.
Tan, P. A. K. (1973) Theoretical and experimental studies of turbine flowmeter. PhD Thesis, University of Southampton.
Svete, A. (1976) Effect of upstream disturbances and velocity profiles on turbine meter performance. I Mech E Conference Paper C77.
Tan, P. A. K. and Hutton, S. P. (1971) Experimental, analytical and tip clearance loss studies in turbine-type flowmeters. Proc. International Conference on Flow Measurements, Harwell PPL Conference Publication 10: 321–346.
Tang, S. P. (1969) Theoretical determination of the discharge coefficients of axisymmetric nozzles under critical flows. Project SQUID Technical report PR-118-PU.
Tarabad, M. and Baker, R. C. (1979) Electromagnetic flowmeters for sodium-cooled nuclear reactors, Paper 6b-6, IMEKO Japan, November 1979.
Tarabad, M. and Baker, R. C. (1982) Integrating electromagnetic flowmeter for high magnetic Reynolds numbers. Journal of Physics D Applied Physics, 15: 739–745.Google Scholar
Tarabad, M. and Baker, R. C. (1983) Computation of pulsed field electromagnetic flowmeter response to profile change. Journal of Physics D Applied Physics, 16: 2103–2111.Google Scholar
Taylor, J. W. and Cassidy, H. P. (1994) Acoustic flowmeter comparison tests at BC Hydro, Canada. FLOMEKO '94 Flow Measurement in the Mid-90s, NEL, Glasgow, Scotland: Paper 7.4.
Taylor, R. D. H. and Nuttall, R. C. H. (1993) On-line well monitoring and its application in a South Oman oil field. Proc Middle East Oil Show, AIME, 2: 229–234.Google Scholar
Temperley, N. C., Behnia, M. and Collings, A. F. (2000) Flow patterns in an ultrasonic liquid flowmeter. Journal of Flow Measurement and Instrumentation, 11: 11–18.Google Scholar
Temperley, N. C., Behnia, M. and Collings, A. F. (2004) Application of computational fluid dynamics and laser Doppler velocimetry to liquid ultrasonic flow meter design. Flow Measurement and Instrumentation, 15(3): 155–165.Google Scholar
Terao, Y., Choi, H. M., Edra, R. B. and Chen, Z. L. (1993) An experimental study on flow struucture in vortex flowmeters. FLOMEKO '93 Proceedings of the 6th International Conference on Flow Measurement, Korea: 327–334.
Teufel, M., Trimis, D., Lohmuller, A., Takeda, Y. and Durst, F. (1992) Determination of velocity profiles in oscillating pipe-flows by using laser Doppler velocimetry and ultrasonic measuring devices. Journal of Flow Measurement and Instrumentation, 3: 95–102.Google Scholar
Tezuka, K., Mori, M., Suzuki, T. and Kanamine, T. (2008a) Ultrasonic pulse-Doppler flow meter application for hydraulic power plants. Flow Measurement and Instrumentation, 19(3–4): 155–162.Google Scholar
Tezuka, K., Mori, M., Suzuki, T. and Takeda, Y. (2008b) Calibration tests of pulse-Doppler flow meter at national standard loops. Flow Measurement and Instrumentation, 19(3–4): 181–187.Google Scholar
Thatcher, G., Bentley, P. G. and McGonigal, G. (1970) Sodium flow measurement in PFR. Nuclear Engineering International, 15: 822–825.Google Scholar
Theuveny, B. and Walker, J. (2001) Flow meters enhance well test data. Hart's E and P, 74(11): 55–56.Google Scholar
Theuveny, B. C., Pithon, J. F., Loicq, O. and Segeral, G. (2002a) Worldwide field experience of mobile well testing services with multiphase flowmeters. American Society of Mechanical Engineers, Petroleum Division (Publication) PD, 2: 771–85.Google Scholar
Theuveny, B., Pinguet, B., Pittman, D., Ségéral, G. and Hanssen, B. V. (2002b) Field performance of dual energy spectral gamma ray/Venturi multiphase flowmeters. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Thinh, N. D. and Evangelisti, J. (1997) Flow modelling and experimental investigation of a vortex shedding flowmeter. ASME Fluids Engineering Division Summer Meeting FEDSM'97, Paper 3011.
Thomas, A., Keech, R., Burt, A. and Yeung, H. (2001) Applying low powered EM metering in the UK water industry—field and lab performance aspects. Flow Measurement 2001, NEL International Conference, Scotland.
Thomas, A., Sheldon, R., Fray, M. K. and Kobryn, P. (2004a) Advances in on-site verification of water flow meters. The intelligent application of electromagnetic insertion probes. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Thomas, A., Kobryn, P. and Franklin, B. (2004b) Electromagnetic insertion probe calibration. Advances towards a standard. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Thomas, N. H., Auton, T. R., Sene, K. and Hunt, J. C. R. (1983) Entrapment and transport of bubbles by transient large eddies in multiphase turbulent shear flow. International conference on Physical modelling of multi-phase flow, Coventry, England, BHRA Fluid Engineering, Cranfield, Paper E1: 169–184.
Thomasson, J. A., Pennington, D. A., Pringle, H. C., Columbus, E. P., Thomson, S. J. and Byler, R. K. (1999) Cotton mass flow measurement: experiments with two optical devices. Applied Engineering in Agriculture, 15(1):11–7.Google Scholar
Thompson, E. J. (1978) Two beam ultrasonic flow measurement. PhD thesis, University of London.
Thompson, R. E. and Grey, J. (1970) Turbine flowmeter performance model. Journal of Basic Engineering, Transactions onASME: 712–723.Google Scholar
Thorn, R., Johansen, G. A. and Hammer, E. A. (1997) Recent developments in three-phase flow measurement. Measurement Science and Technology, 8: 691–701.Google Scholar
Thorn, R., Johansen, G. A. and Hjertaker, B. T. (2013) Three-phase flow measurement in the petroleum industry. Measurement Science and Technology, 24: 012003 (17pp) http://dx.doi.org/10.1088/0957-0233/24/1/012003.Google Scholar
Thornton, A. C. (1999a) Mathematical framework for the key characteristic process. Research in Engineering Design, 11: 145–157.Google Scholar
Thornton, A. C. (1999b) Variation risk management using modelling and simulation. Transactions on ASME, Journal of Mechanical Design, 121: 297–304.Google Scholar
Thornton, A. C. (2000) Quantitative selection of variation reduction plans. Journal of Mechanical Design, 122(2): 185–193.Google Scholar
Thürlemann, B. (1955) On the electromagnetic speed measurement of fluid. Helvetica Physica Acta, 28: 483.Google Scholar
Timothy, J. and Cunningham, P. E. (1997) Zero shifts due to non-proportional damping. Proceedings of the 15th International Modal Analysis Conference IMAC, Orlando, FL, USA, 1:237–243.
Ting, V. C. and Ao, X. S, (2002) Evaluation of clamp-on ultrasonic gas transit time flowmeters for natural gas applications. 20th North Sea Flow Measurement Workshop 22–25 October 2002, St Andrews, Scotland, Paper 3.1.
Ting, V. C. and Shen, J. J. S. (1989) Field calibration of orifice meters for natural gas flow. Journal of Energy Resources Technology, Transactions of ASME, 111.1: 22–33.Google Scholar
Tison, S. A. and Berndt, L. (1997) High-differential-pressure laminar flowmeter. ASME Fluids Engineering Division Summer Meeting FEDSM'97, Paper 3207.
Tobi, N. V. (1953) British Patent 726 271, 27th May 1953.
Tokarczuk, P. F., Sanderson, M. L. and High, G. (1998) The application of nuclear magnetic resonance (NMR) to multiphase flow metering. FLOMEKO '98 Proceedings of the 9th International Conference on Flow Measurement, Lund, Sweden, 291–296.
Tombs, M. (2003) Coriolis special issue. IEE Computing and Control Engineering, 14(4): 27.Google Scholar
Tombs, M., Henry, M., Yeung, H. and Lansangan, R. (2004) Coriolis mass flow meter developments: increasing the range of applications in oil & gas production and processing. 22nd North Sea Flow Metering Workshop 2004, Paper 7.1
Tombs, M., Henry, M., Zhou, F., Lansangan, R. M. and Reese, M. (2006) High precision Coriolis mass flow measurement applied to small volume proving. Flow Measurement and Instrumentation, 17(6): 371–82.Google Scholar
Tominaga, K., Yudate, T. and Cormier, M. A. (2005) Reactor power uprate by ultrasonic flow meter. 26th Annual Canadian Nuclear Society Conference and 29th CNS/CNA Student Conference, pp. 1369–1378.
Toral, H., Beg, N. and Archer, J. S. (1990) Multiphase flow metering by software. International Conference on Basic Principles and Industrial Applications of Multiphase Flow, IBC Technical Services Ltd, London, April.
Toral, H., Cai, S., Peters, R. and Steven, R. (2004a) A method for characterization of the turbulence properties of wet gas flow across a V-Cone. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Toral, H., Cai, S., Steven, R. and Peters, R. (2004b) Characterization of the turbulence properties of wet gas flow in a V-cone meter with neural nets. 22nd North Sea Flow Metering Workshop 2004, Paper 8.4.
Torkildsen, B. H. and Hanssen, B. V. (1996) Practical considerations related to multiphase metering of a well stream. North Sea Flow Measurement Workshop, Peebles, Scotland.
Torkildsen, B. H., Helmers, P. B. and Kanstad, S. K. (1997) Topside and subsea experience with the FRAMO multiphase meters. North Sea Flow Measurement Workshop, Kristiansand, Norway: Paper 3.
Tresch, T., Gruber, P. and Staubli, T. (2006) Comparison of integration methods for multi-path acoustic discharge measurements. 6th International Conference on IGHEM, Portland, USA, 2006.
Trigas, A. and Hope, S. H. (1991) A comparison of the accuracy and process control capability of turbine and Coriolis flowmeters. International Conference on Flow Measurement In Industry and Science, London.
Tritton, D. J. (1988) Physical fluid dynamics. 2nd ed., Oxford University Press.
Trostel, B., Clancy, J. and Kegel, T. (2010) Ultrasonic flowmeter calibration intervals. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A4-1.
Trung, M. C., Nishiyama, S. and Anyoji, H. (2007) Application of a 45° bend pipe with a bypass flow meter without changing the flow direction or the system construction. Transactions of the ASABE, 50(6): 2051–2057.Google Scholar
Tsuchida, T., Terashima, Y. and Machiyama, T. (1982) The effects of flow velocity profile on the electromagnetic flowmeters. Report of Researches, Nippon Institute of Technology: 101–111.
Tsuchiya, , et al. (1970) Karman vortex flow meter. Bulletin Japanese Society of Mechanical Engineers, 13: 573–578.Google Scholar
Tsukamoto, H. and Hutton, S. P. (1985) Theoretical prediction of meter factor for a helical turbine flowmeter. Conference on Fluid Control and Measurement, Tokyo, Japan.
Tsutsui, H. and Yamikawa, Y. (1993) Coriolis force mass-flowmeter composed of a straight pipe and an additional resonance vibrator. Japanese Journal of Applied Physics. 1, 32(58): 2369–2371.Google Scholar
Tucker, H. G. and Hayes, W. F. (1982) Error analysis of a vibrating pendulum two phase flowmeter for oil well application. Measurement in Polyphase Flows – 1982, AIAA/ASME Joint Fluids, Plasma, Thermophysics and Heat Transfer Conference, St Louis, Missouri: 45–53.
Tullis, P. and Smith, J. (1979) Coriolis flowmeter. NEL Fluid Mechanics Silver Jubilee Conference, East Kilbride, Glasgow: Paper 6.3.
Turkowski, M. (2003) Progress towards the optimisation of a mechanical oscillator flowmeter. Flow Measurement and Instrumentation, 14(1–2): 13–21.Google Scholar
Turkowski, M. (2004) Influence of fluid properties on the characteristics of a mechanical oscillator flowmeter. Measurement: Journal of the International Measurement Confederation, 35(1): 11–18.Google Scholar
Turner, D. (1971) A differential pressure flowmeter with linear response. Modern Developments in Flow Measurement, Paper 4.3: 191–199.
Turner, J., Wynne, R. and Hurren, P. (1989) Computation and techniques in flow measurement and their applications to flowmeter diagnostics. FLOMIC, Rept. No. 6.
Turner, J. T., Popiel, C. O. and Robinson, D. I. (1993) Evolution of an improved vortex generator. Journal of Flow Measurement & Instrumentation, 4: 249–258.Google Scholar
Tuss, B. (1996) Production evaluation and testing of a high viscosity and high gas volume fraction multiphase meter. North Sea Flow Measurement Workshop, Peebles, Scotland.
Tuss, B. (1997) Wet gas multi-phase measurement . Offshore Technology Conference, Houston, TX, USA, 4: 517–522.
UKAS(2012) The expression of uncertainty and confidence in measurement. 3rd ed., United Kingdom Accreditation Service.
Urner, G. (1997) Pressure loss of orifice plates according to ISO 5167-1. Journal of Flow Measurement and Instrumentation, 8: 39–41.Google Scholar
van Bloemendaal, K. and van der Kam, P. M. A. (1994) Installation effects on multi-path ultrasonic flow meters: the ‘Ultraflow’ project. North Sea Flow Measurement Workshop, Peebles, Scotland.
van Bokhorst, E. and Peters, M. C. A. M. (2000) Impact of pulsation sources in pipe systems on multi-path ultrasonic flowmeters. North Sea Flow Measurement Workshop, National Engineering Laboratory, East Kilbride, Scotland.
van Bokhorst, E. and Peters, M. C. A. M. (2002) A test certificate on the impact of piping and flow dynamic effects on flowmeter accuracy in gas and liquid flows. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
van Cleve, C., Lanham, G., Ollila, C. and Stack, C. (2000) Development and validation of a new single straight tube Coriolis meter. FLOMEKO'2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper D11.
van Dellen, K. (1991) Ultrasonic gas flow meters continue their rise. Proceedings of the North Sea Flow Measurement Workshop, Norwegian Society of Chartered Engineers.
van Deventer, J. (2005) Introduction of a 2 transducer ultrasonic mass flow meter. Conference Record – IEEE Instrumentation and Measurement Technology Conference, 2: 1369–1372.Google Scholar
van Deventer, J. and Delsing, J. (2002) Apparent transducer non-reciprocity in an ultrasonic flow meter. Ultrasonics, 40(1–8): 403–405.Google Scholar
van Dijk, G. J. A. and Huijsing, J. H. (1995) Bridge-output-to-frequency converter for smart thermal air-flow sensors. IEEE Transactions on Instrumentation and Measurement, 44: 881–886.Google Scholar
van Essen, G. J. (2010) Testing the performance of an ultrasonic clamp-on flowmeter. 9th Spith East Asia Hydrocarbon Flow Measurement Workshop, 2nd–4th March.
van Luijk, L. and Riezebos, H. (2014) In situ flow verification by means of US clamp-on technology. US and Coriolis Metering Workshop, Lisbon, Portugal, 27th March 2014. http://www.vsl.nl/sites/default/files/rtf/Lennart_van_Luijk_In_Situ_Flow_Verification_by_Means_of_USM_Clamp_on_Technology%20%281%29.pdf
van Mannen, H. (1999) Cost reduction for wet-gas measurement using the tracer-venturi combination, NEL Natural Gas Metering one day seminar.
van Santen, H., Kolar, Z. I. and Scheers, A. M. (1995) Photon energy selection for dual energy γ - and/or X-ray absorption composition measurements in oil-water-gas mixtures. Nuclear Geophysics, 9(3): 193–202.Google Scholar
van Weers, T., van der Beek, M. P. and Landheer, I. J. (1998) Cd – factor of Classical Venturi's: Gaming Technology? 9th Int. Conf. on Flow Measurement, FLOMEKO, Lund, Sweden, June, pp. 203–207.
van Werven, M., Drenthen, J., de Boer, G. and Kurth, M. (2006) Wet gas flow measurement with ultrasonic and differential pressure metering technology. Proc. 6th International Symposium On Fluid Flow Measurement (ISFFM), Querétero, Mexico.
van den Heuvel, A. and Kemmoun, H. F. (2005) Flow measurement errors due to stratified flow conditions. FLOMEKO 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 1.3.
van den Heuvel, A., Doorman, F., van den Herik, P., Stehouwer, A. and Kruithof, R. (2009) Calibration errors of ultrasonic meters in the Bernoulli laboratory due to non-isothermal flow conditions. 27th International North Sea Flow Measurement Workshop, Tonsberg, Norway, 20–23 October 2009, pp. 205–219.
van der Grinten, J. G. M. (1990) Error curves of turbine gas meters. Netherlands Metrology Institute.
van der Grinten, J. G. M. (1994) A comparison of the methods for uncertainty analysis based on ISO 5168 and the Guide prepared by ISO/TAG4/WG3. FLOMEKO'94 Flow Measurement in the mid 90's, East Kilbride, Scotland.
van der Grinten, J. G. M. (1997) Recent developments in the uncertainty analysis of flow measurement processes. North Sea Flow Measurement Workshop, Kristiansand, Norway: Paper 11.
van der Grinten, J. (2005) The Reynolds interpolation method for calibrations of turbine gas meters and application to intercomparisons. FLOMEKO 2005 13th International Flow Measurement Conference, Peebles, Scotland, Poster Session.
van der Kam, P. M. A. and Dam, A. M. (1993) Large turbine meters for custody transfer measurement: the renovation of the Gasunie export stations. Journal of Flow Measurement and Instrumentation, 4: 91–98.Google Scholar
van der Kam, P. M. A. and De Jong, S. (1994) Gas turbine meters: standardization and operational experiences. Journal of Flow Measurement and Instrumentation, 5: 121–126.Google Scholar
van der Kam, P. M. A. and van Dellen, K. (1991) The effect of double bends out of plane on turbine meters. Journal of Flow Measurement and Instrumentation, 2: 61–68.Google Scholar
van der Kam, P. M. A., Dam, M. A. and van Dellen, K. (1990) Gasunie selects turbine meters for renovated export metering stations. Oil and Gas Journal, 88: 39–44.Google Scholar
Vass, G. E. (1996) Users benefit from newer electronics in today's smarter magnetic flowmeters. Advances in Instrumentation and Control: International Conference and Exhibition, (ISA), 51(1): 641–656.Google Scholar
Vaterlaus, H-P. (1995) A new intelligent ultrasonic flowmeter for closed conduits and open channels. ASCE Waterpower – Proceedings of the Int Conf on Hydropower, 2: 999–1008.Google Scholar
VDI/VDE (December 1978) Variable area flowmeters – accuracy. VDI/VDE 3513, Page 2, (In German). Updated edition VDI/VDE 7513-2: 2008.
Vermeulen, M., de Boer, G., van Weelde, A. B., Botte, E. and Dijkmans, R. (2004) Coded Multiple Burst (CMB) signal processing applied to ultrasonic flow meters in applications with high noise levels. 22nd North Sea Flow Metering Workshop 2004, Paper 3.3.
Vermeulen, M. J. M., Drenthen, J. G. and Den Hollander, H. (2012) Expert systems in ultrasonic flow meters. 8th International Symposium on Fluid Flow Measurement.
Vervik, S. (2000) Methods for characterization of gas-coupled ultrasonic sender-receiver measurement systems. Doctoral dissertation, University of Bergen, Department of Physics.
Vestrheim, M. and Vervik, S. (1996) Transit time determination in a measurement system, with effects of transducers. Proc. of 1996 IEEE Intern. Ultrason. Symp.
Vetter, G. and Notzon, S. (1994) Effect of pulsating flow on Coriolis mass flowmeters. Journal of Flow Measurement and Instrumentation, 5: 263–273.Google Scholar
Vieth, D., de Boer, G., Buijen van Welden, A. and Huijsman, F. (2001) Test results of a new design ultrasonic gas flow meter. 19th North Sea Flow Measurement Workshop, Kristiansand, Norway, 22–25 October 2001, Paper 7.
Viswanathan, M., Kandaswamy, A., Sreekala, S. K. and Sajna, K. V. (2001) Development, modelling and certain investigations on thermal mass flow meters. Flow Measurement and Instrumentation, 12(5–6): 353–360.Google Scholar
Viswanathan, M., Rajesh, R. and Kandaswamy, A. (2002) Design and development of thermal mass flowmeters for high pressure applications. Flow Measurement and Instrumentation, 13(3): 95–102.Google Scholar
Vogtlin, B. and Tschabold, P. (undated) Direct measurement of mass flow using the Coriolis force. E&H Flowtec publication.
von Lavante, E. and Mickan, B. (2005) Unsteady transition in critical Venturi nozzles. FLOMEKO 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 5.3.
von Lavante, E. and Yao, J. (2010) Numerical investigation of turbulent swirling flows in flow metering configurations. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper B9-4.
von Lavante, E. and Yao, J. (2012) Numerical investigation of turbulent swirling flows in axisymmetric internal flow configurations. Flow Measurement and Instrumentation, 25: 63–68.Google Scholar
von Lavante, E., Zachcial, A., Nath, B. and Dietrich, H. (2000) Numerical and experimental investigation of unsteady effects in critical Venturi nozzles. Flow Measurement and Instrumentation, 11(4): 257–264.Google Scholar
von Lavante, E., Zachcial, A., Nath, B. and Dietrich, H. (2001) Unsteady effects in critical nozzles used for flow metering. Measurement: Journal of the International Measurement Confederation, 29(1): 1–10.Google Scholar
von Lavante, E., Mickan, B. and Kramer, R. (2004a) Numerical investigation of transition as effects in critical Venturi nozzles. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
von Lavante, E., Banaszak, U. and Lefebvre, M. (2004b) Effect of shape change due to wear on the accuracy of vortex-shedding flow meters. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
von Lavante, E., Banaszak, U., Kettner, T. and Lötz-Dauer, V. (2004c) Numerical simulation of Reynolds number effects in a turbine flow meter. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
von Lavante, E., Banaszak, U., Lötz-Dauer, V., Enste, K., Bergervoet, J. and Dietrich, H. (2006) Theoretical and experimental investigations of rotary piston flow meters. Proc. 6th International Symposium on Fluid Flow Measurement (ISFFM), Querétero, Mexico.
von Lavante, E., Banaszak, U., Yilmaz, M. G. and Ricken, O. (2007) Effects of shape change due to wear on the accuracy of vortex-shedding flow meters. 14th International Flow Measurement Conference 2007 (FLOMEKO 2007) Proceedings of a meeting held 18–21 September 2007, Sandton, Gauteng, South Africa.
von Lavante, E., Gedikli, A., Thibaut, A., Tournillon, S. and Krisch, H. (2010) Effects of upstream butterfly valve on the accuracy of a vortex flow meter. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper B2-3.
von Lavante, E., Brinkhorst, S., Gedikli, A. and Krisch, H. (2013) Fluid mechanical optimization of a dn25 vortex flow meter with novel vortex detection. FLOMEKO (2013) The 16th International Flow Measurement Conference – 24–26th September 2013 – Paris, France.
Vontz, T. and Magori, V. (1996) Ultrasonic flowmeter for industrial applications using a helical sound path. Proceedings of the IEEE Ultrasonics Symposium, San Antonio, TX, USA, 2: 1047–1050.
Nauchno-Issledovatelsky, Vsesojuzny (1976) Method of and apparatus for measuring the mass flowrate of individual components of a gas-liquid medium. British Patent 1,528,232.Google Scholar
Vulovic, F., Vallet, J. P. and Windenberger, C. (2002) The advantages of critical flow Venturi nozzles for the high pressure gas metering. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Wada, S., Kikura, H. and Aritomi, M. (2006) Pattern recognition and signal processing of ultrasonic echo signal on two-phase flow. Flow Measurement and Instrumentation, 17(4): 207–224.Google Scholar
Wagner, J. J. (1988) Effects of sensor design and application characteristics on Coriolis mass meter performance: an overview . 2nd Int Conf on Flow Measurement, London, UK.
Walker, J. T. (1992) Advances in Coriolis technology for precision flow and density measurements of industrial fluids. Proc 47th American Symposium on Instrumentation for the Process Industries, Publ. Texas A&M Univ: 69–73.
Walker, J.R. (2001) Diagnostics advance in electromagnetic flow metering. ISA TECH/EXPO Technology Update Conference Proceedings, 413 I: 501–510.Google Scholar
Walles, K. F. A. (1975) The long term repeatability of positive displacement liquid flowmeters. Conference on Fluid Flow Measurement in the mid 1970s, National Engineering Laboratory, Scotland: Paper B-4.
Walles, K. F. A. and James, J. H. P. (1985) Performance of a fuel flow calibration system. Int. Conf. on the Metering of Petroleum and its Products, OYEZ, London.
Wallis, R. A. (1961) Axial flow fans design and practice. George Newnes Limited, London.
Walsh, J. T. (2004) A report of acoustic transit time accuracy field work performed in North America, 5th International Conference on Hydraulic Efficiency Measurements, Lucerne, 2004.
Walus, S. (2000) Decreasing of volume flow rate measurement error in modified averaging impact tubes. FLOMEKO'2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper B2.
Wang, C., Li, F., Meng, T., Xu, Y., Yang, Y., Jiang, N., Wu, W., Sang, X., Chen, M., Zhou, B., Zang, J., Shen, W. and Xu, L. (2004) Intercomparison tests of gas flow by bell prover. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Wang, G., Chen, C., Yao, Y. and Huang, L. (2009a) Micromachined mass flow sensor and insertion type flow meters and manufacture methods. US Patent 7536908, 26 May 2009.
Wang, H., Priestman, G. H., Beck, S. B. M. and Boucher, R. F. (1996) Development of fluidic flowmeters for monitoring crude oil production. Journal of Flow Measurement and Instrumentation, 7: 91–98.Google Scholar
Wang, H., Priestman, G. H., Beck, S. B. M. and Boucher, R. F. (1998) A remote measuring flow meter for petroleum and other industrial applications. Measurement Science and Technology, 9: 779–789.Google Scholar
Wang, J. (2009) Numerical simulation and verification of weight function of electromagnetic flow meter. Chinese Journal of Scientific Instrument, 30(1): 132–137 (in Chinese).Google Scholar
Wang, J. and Gong, C. (2006) Sensing induced voltage of electromagnetic flow meter with multi-electrodes. Proceedings of IEEE ICIA 2006–2006 IEEE International Conference on Information Acquisition, 1031–1036, Weihai, Shandong, China
Wang, J. and Lu, R. (2006) Numerical simulation on weight function of electromagnetic flow meter. Proceedings of SPIE – The International Society for Optical Engineering, 6280 II: 628033.Google Scholar
Wang, J. Z., Tian, G. Y. and Lucas, G. P. (2007a) Relationship between velocity profile and distribution of induced potential for an electromagnetic flow meter. Flow Measurement and Instrumentation, 18(2): 99–105.Google Scholar
Wang, J. Z., Lucas, G. P. and Tian, G. Y. (2007b) A numerical approach to the determination of electromagnetic flow meter weight functions. Measurement Science and Technology, 18(3): 548–554.Google Scholar
Wang, J. Z., Tian, G. Y., Simm, A. and Lucas, G. P. (2009b) Uniform magnetic flux density simulation and verification for a new electromagnetic flow meter. Nondestructive Testing and Evaluation, 24(1–2): 143–151.Google Scholar
Wang, L.-J., Hu, L., Fu, X. and Ye, P. (2010) Experimental investigation on zero drift effect in Coriolis mass flowmeters. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A9-1.
Wang, S., Clark, C. and Cheesewright, R. (2006a) Virtual Coriolis flow meter: a tool for simulation and design. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 220(6): 817–835.Google Scholar
Wang, T. and Baker, R. C. (2003/4) Manufacturing variation of the measuring tube in a Coriolis flowmeter. IEE Computing and Control Engineering, 14(4): 38–39 and in IEE Proceedings, Sci. Meas. Technol. 151(3): 201–204, 2004. (Also in IEE Advanced Coriolis Mass Flow Metering Seminar, Oxford University 2003 in summary.)Google Scholar
Wang, T. and Baker, R. C. (2014) Coriolis flowmeters: a review of developments over the past 20 years, and an assessment of the state of the art and likely future directions. Flow Measurement and Instrumentation, 40(2014): 99–123.Google Scholar
Wang, T. and Hussain, Y. A. (2006) Investigation of the batch measurement errors for single-straight tube Coriolis mass flowmeters. Flow Measurement and Instrumentation, 17(6): 383–390.Google Scholar
Wang, T. and Hussain, Y. A. (2007) Latest research and development of twin-straight tube Coriolis mass flowmeters. Sensor Review, 27(1): 43–47.Google Scholar
Wang, T. and Hussain, Y. A. (2009) Coriolis mass flow measurement at cryogenic temperatures. Journal of Flow Measurement and Instrumentation, 20(3): 110–115.Google Scholar
Wang, T. and Hussain, Y. (2010a) Extending flow measurement capacity with the straight tube Coriolis technology. 15th Flow Measurement Conference (FLOMEKO), October 13–15, 2010 Taipei, Taiwan, Paper A9-4.
Wang, T. and Hussain, Y. (2010b) Pressure effects on Coriolis mass flowmeters. Journal of Flow Measurement and Instrumentation, 21(4): 504–510.Google Scholar
Wang, T., Baker, R. C. and Hussain, Y. A. (2006b) An advanced numerical model for single straight tube Coriolis flowmeters. Transactions of ASME Journal of Fluids Engineering, 128: 1346–1350, 2006. (Also presented as A practical numerical model for single straight tube Coriolis meters, at FLOMEKO 2004, Guilin.)Google Scholar
Wangsa, S., Latief, R., Kaura, J., Finley, D. and Ogilvie, A. (2005) Successful field surveillance using portable multi-phase flow meter in a high gas-volume fraction and high water-cut application in east Kalimantan, Indonesia. 67th European Association of Geoscientists and Engineers, EAGE Conference and Exhibition, incorporating SPE EUROPE2005, pp. 2503–2514.
Ward-Smith, A. J. (1980) Internal fluid flow. Clarendon Press, Oxford.
Warren, P. B., Al-Dusari, K. H., Zabihi, M. and Al-Abduljabbar, J. M. (2003) field-testing a compact multiphase flow meter – offshore Saudi Arabia. Proceedings of the Middle East Oil Show, 13: 993–998.Google Scholar
Washington, G. (1989) Measuring the flow of wet gas . North Sea Flow Metering Workshop, Haugesund, Norway.
Watkins, D., Lucchini, F., Weaver, P., Feltresi, E. and Genolini, M. (2014) In line multiphase flow measurement Permian Basin, Texas Field Trial. North Sea Flow Measurement Workshop 2014.
Watson, G. A. and Furness, R. A. (1977) Development and application of the turbine meter. Proc Transducer 77 Conf Flow Measurement Session, Wembley, London.
Watson, G. G., Vaughan, V. E. and McFarlane, M. W. (1967) Two-phase pressure drop with a sharp-edged orifice. NEL Report No 290, East Kilbride, Glasgow.
Watt, J. S. (1993) Platform trial of a multiphase flow meter . North Sea Flow Measurement Workshop, Bergen, Norway.
Watt, R. M. (1990) Computational modelling of Coriolis mass flowmeters. North Sea Flow Measurement Workshop, National Engineering Laboratory, Scotland.
Watt, R. M. (1991) Modelling of Coriolis mass flowmeters using ANSYS . ANSYS Users Conf, Pittsburgh, USA.
Way, J. and Wood, I. (2002) Kerr-McGee North Sea (UK) Limited – Gryphon Alpha FPSO Monetary Application for Multiphase Meters. 20th North Sea Flow Measurement Workshop, 22–25 October 2002, St Andrews, Scotland, Discussion session 5.1 (Paper 5.4).
Weager, B. (1993/4) NAMAS-approved flowmetering. Measurement and Control, 26(10): 298–301.Google Scholar
Węcel, D., Chmielniak, T. and Kotowicz, J. (2008) Experimental and numerical investigations of the averaging Pitot tube and analysis of installation effects on the flow coefficient. Flow Measurement and Instrumentation, 19(5): 301–306.Google Scholar
Wee, A. and Scheers, L. (2009) Measurement of water in a wet gas. 27th International North Sea Flow Measurement Workshop, Tonsberg, Norway, 20–23 October 2009, pp. 154–179.
Wee, A., Berentsen, H., Midttveit, V. R., Moestue, H. and Hide, H. O. (2007) Tomography powered multiphase and wet-gas meter providing measurements used for fiscal metering. 25th International North Sea Flow Measurement Workshop, Energy Institute, Oslo, Norway, 40–63.
Wee, A., Fosså, Ø. and Midttveit, V. R. (2013) Multiphase meter capable of detecting scale on the pipe wall and correcting flow rate measurements. North Sea Flow Metering Workshop, Paper 21.
Weigand, D. E (1972) Magnetometer flow sensor. Argonne National Laboratory, Argonne, Ill., Report ANL-7874.
Weigand, J. (1994) Gas flow measurement using laminar flow elements. ASHRAE Trans. 100: 973–979.Google Scholar
Weinig, F. (1932) Stromung durch Profilgitter und einige Anwendungen auf die Stromung in Propellern. Hydromechanische Probleme des Schiffsantriebs: 171.Google Scholar
Weiss, M., Studzinski, W. and Attia, J. (2002) Performance evaluation of orifice meter standards for selected T-junction and elbow installations. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Wemyss, W. A. and Wemyss, A. C. (1975) Development of the Hoverflo: a turbine flowmeter without bearings. NEL Conference on Fluid Flow Measurement in the Mid 1970's, 2, Paper H1.
Dong-xu, Wen (1990) Smart fiber optics flowmeter. Proceedings of SPIE, Int Soc Optical Eng, 1230: 557–558.Google Scholar
Wendoloski, J. C. (2001) On the theory of acoustic flow measurement. Journal of the Acoustical Society of America, 110(2): 724–737.Google Scholar
Wendt, G. and von Lavante, E. (2000)Influence of surface roughness on the flowrate behaviour of small critical Venturi nozzles. Proc. FLOMEKO.
Wendt, G., Mickan, B., Kramer, R. and Dopheide, D. (1996) Systematic investigation of pipe flows and installation effects using laser Doppler anemometry – Part I, Profile Measurements Downstreaqm of Several Pipe Configurations and Flow Conditioners. 7(3/4): 141–149.Google Scholar
Wenran, W. and Yunxian, T. (1995) A new method of two-phase flow measurement by orifice plate differential pressure noise. Journal of Flow Measurement and Instrumentation, 6: 265–270.Google Scholar
Whitaker, T. S. (1993) A review of multiphase flowmeters and future development potential. FLOMEKO '93 Proceedings of the 6th International Conference on Flow Measurement, Korea: 628–634.
Whitaker, T. S. (1996) Assessment of multiphase flowmeter performance . North Sea Flow Measurement Workshop, Peebles, Scotland.
Whitaker, T. S. and Millington, B. C. (1993) Review of multiphase flowmeter projects . North Sea Flow Measurement Workshop, Bergen, Norway.
Whitaker, T. and Owen, I. (1990) Experience with two designs of differential pressure flowmeters in two-phase flow. International Conference on Basic Principles and Industrial Applications of Multiphase Flow, April 1990 (IBC Technical Services, London).
White, D. F., Rodely, A. E. and McMurtie, C. L. (1974) The vortex shedding flowmeter. Flow, Its Measurement and Control in Science and Industry, Pittsburgh, PA, USA, Instrument Society of America, 1, Pt 2: 967–974.
Whitson, R. J. (2008) A general methodology for geometry related pressure and temperature corrections in ultrasonic time for flight flowmeters. 26th International North Sea Flow Metering Workshop 2008, Paper 6.2.
Widmer, A. E., Fehlmann, R. and Rehwald, W. (1982) A calibration system for calorimetric mass flow devices. Journal of Physics E: Scientific Instruments, 15: 213–220.Google Scholar
Wiegerink, R. J. Lammerink, T. S. Groenesteijn, J., Dijkstra, M. and Lotters, J. C. (2012) Micro Coriolis Mass Flow Sensor For Chemical Micropropulsion Systems, in: Micromachines, Enschede, The Netherlands, 2012.
Wiklund, D. and Peluso, M. (2002a) Quantifying and specifying the dynamic response of flowmeter. ISA TECH/EXPO Technology Update Conference Proceedings, 422: 463–75. see also ISA TECH/EXPO Technology Update Conference Proceedings, 424–425: 810–22).Google Scholar
Wiklund, D. and Peluso, M. (2002b) Flowmeter dynamic response characteristics Part 1: Quantifying dynamic response. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Wiklund, D. and Peluso, M. (2002c) Flowmeter dynamic response characteristics Part 2: Effects in various flow applications. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Wilcox, P., Barton, N. and Laing, K. (2001) Using computational fluid dynamics to investigate the flow through an offshore gas metering station. 19th North Sea Flow Measurement Workshop, Kristiansand, Norway, 22–25 October 2001, Paper 22.
Willatzen, M. (2001) Temperature gradients and flow-meter performance. Ultrasonics, 39(5): 383–389.Google Scholar
Willatzen, M. (2003) Ultrasonic flowmeters: Temperature gradients and transducer geometry effects. Ultrasonics, 41(2): 105–114.Google Scholar
Willatzen, M. (2004a) Ultrasonic flow measurement and wall acoustic impedance effects. Ultrasonics, 41(9): 719–726.Google Scholar
Willatzen, M. (2004b) Flow acoustics modelling and implications for ultrasonic flow measurement based on the transit-time method. Ultrasonics, 41(10): 805–810.Google Scholar
Willatzen, M. and Kamath, H. (2008) Nonlinearities in ultrasonic flow measurement. Flow Measurement and Instrumentation, 19(2): 79–84.Google Scholar
Willer, M. D. (1978) Gyroscopic principle key to mass flowmeter. Canadian Controls & Instruments, 117(1): 28.Google Scholar
Williams, E. J. (1930) The induction of emfs in a moving fluid by a magnetic field and its application to an investigation of the flow of liquids. Proceedings of the Royal Society, London, England, 42: 466–478.
Williams, T. J. (1970) Behaviour of the secondary devices in pulsating flowmeasurement. Instrumentation Measurement& Control Symposium on the Measurement of Pulsating Flow: 56–61.Google Scholar
Wilson, H. A. (1901) Phil Mag S5 2 No 7 July pp 144–150.
Wilson, H. A. (1904) Phil Trans A, London, 204 pp 121–137.
Wilson, H. A. and Wilson, M. (1913) Phil Trans A, London, 89 pp 99–106.
Windorfer, H. and Hans, V (2000a) Correlation of ultrasound and pressure in vortex shedding flow-meters. FLOMEKO'2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper E7.
Windorfer, H. and Hans, V (2000b) Experimental optimisation of bluff bodies in ultrasound vortex shedding flow-meters. FLOMEKO'2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper E8.
Wislicenus, G. F. (1947) Fluid mechanics of turbomachinery. McGraw-Hill, New York (subsequent ed. Dover publ, inc. New York).
Withers, V. R., Inkley, F. A. and Chesters, D. A. (1971) Flow characteristics of turbine flowmeters. Proc International Conference on Flow Measurements, Harwell PPL Conference Publication, 10: 305–320.
Withers, V. R., Strang, W. and Allnutt, G. (1996) Practical application of Coriolis meters for offshore tanker loading from the Harding Field. North Sea Flow Measurement Workshop, Peebles, Scotland.
Witlin, W. G. (1979) Theory, design and application of vortex shedding flowmeters. Proceedings of the Symposium on Measurement Technology for the 80s: Analytical Instrumentation, 17: 120–125.Google Scholar
Wojtkowiak, J., Kim, W. N. and Hyun, J. M. (1997) Computations of the flow characteristics of a rotating-piston-type flowmeter. Journal of Flow Measurement and Instrumentation, 8: 17–25.Google Scholar
Womack, A. (2008) Flow meter selection for improved gas flow measurements. Heat Treating Progress, 8(4): 25–29.Google Scholar
Wong, H. A., Rhodes, E. and Scott, D. S. (1981) Flow metering in horizontal, adiabatic, two-phase flow. Proc. 2nd Symp. on Flow: Its Measurement and Control in Science and Industry (ed. W. W. Durgin), ISA, St Louis, 2: 505–516.
Woo, S. and O'Neal, D. L. (2006) The effect of elbows on the accuracy of liquid flow measurement with an insertion flowmeter. ASHRAE Transactions, (Monograph title: ASHRAE Transactions – Technical and Symposium Papers presented at the 2006 Winter Meeting of the American Society of Heating, Refrigerating and Air-Conditioning Engineers) 112(PART 1):195–201.
Wood, G. (1994) Introduction. Measurement & Control, 27 (2): 37.Google Scholar
Wood, I. M., Daniel, P. and Downing, A. (2003) Penguin Wet Gas Measurement. 21st North Sea Flow Metering Workshop 2003, Paper 5.
Worch, A. (1998a) A clamp-on ultrasonic cross correlation flowmeter for one-phase flow. Measurement Science and Technology, 9: 622–630.Google Scholar
Worch, A. (1998b) A clamp-on ultrasonic cross-correlation flowmeter for two-phase flow, FLOMEKO '98 Proceedings of the 9th International Conference on Flow Measurement, Lund, Sweden, pp. 121–126.
Wright, J. D. (2010) Properties for accurate gas flow measurements. 15th Flow Measurement Conference (FLOMEKO), 13–15 October Taipei, Taiwan, Paper B8-2.
Wright, J. D. and Johnson, A. N. (2000) Uncertainty in primary gas flow standards due to flow work phenomena. FLOMEKO'2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper D11.
Wright, J. D., Kayl, J. P., Johnson, A. N. and Kline, G. M. (2008) NIST Measurement Services: Gas Flowmeter Calibrations with the Working Gas Flow Standard. NIST Special Publication , 250–280.
Wright, J. D. Cobu, T., Berg, R. F. and Moldover, M. R. (2012) Calibration of laminar flow meters for process gases. Flow Measurement and Instrumentation, 25: 8–14.Google Scholar
Wright, P. H. (1993) The application of sonic (critical flow) nozzles in the gas industry. Journal of Flow Measurement and Instrumentation, 4: 67–72.Google Scholar
Wright, W. and Brini, S. (2005) Capacitive ultrasonic transducers for gas flow metering applications. FLOMEKO 2005 13th International Flow Measurement Conference, Peebles, Scotland, Paper 1.2.
Wu, G. B. and Meng, H. (1996) Application and improvement of the Youden analysis in the inter comparison between flowmeter calibration facilities. Flow Measurement and Instrumentation, 7(1): 19–24.
Wu, G. and Yan, S. (1996) The calculation of the discharge coefficient of critical Venturi nozzles using the finite element method. FLOMEKO '96 Proceedings of the 8th International Conference on Flow Measurement, China: Beijing: 611–618.
Wyatt, D. G. (1986) Electromagnetic flowmeter sensitivity with two-phase flow. International Journal of Muultiphase Flow, 12(6): 109–117.Google Scholar
Wylie, S. R., Shaw, A. and Al-Shamma'a, A. I. (2006) RF sensor for multiphase flow measurement through an oil pipeline. Measurement Science and Technology, 17(8): 2141–2149.Google Scholar
Xiaozhang, Z. (1995) New multi-meter system for flow measurement of water-oil-gas mixture. ISA Advances in Instrumentationand Control: International Conference and Exhibition, 50.1: 113–120.Google Scholar
Xing, J. and Zhang, T. (2009) Oil-water two-phase flow measurement using vortex flowmeter. Chinese Journal of Scientific Instrument, 30(4): 882–886 (in Chinese)Google Scholar
Xu, L. A., Yang, H. L., Zhang, T., Chen, W., Li, J. and Ran, Z. M. (1994) A clamp-on ultrasound cross-correlation flowmeter for liquid/solid two-phase flow measurement. Journal of Flow Measurement and Instrumentation, 5: 203–208.Google Scholar
Xu, L. J., Li, X. M., Dong, F., Wang, Y. and Xu, L.A. (2001) Optimum estimation of the mean flow velocity for the multi-electrode inductance flowmeter. Measurement Science and Technology, 12(8): 1139–1146.Google Scholar
Xu, L., Wang, Y., Dong, F. and Yan, Y. (2003) On-line monitoring of non-axisymmetric flow profile with a multi-electrode inductance flowmeter. Conference Record – IEEE Instrumentation and Measurement Technology Conference, 2: 1541–1546.Google Scholar
Xu, Y. (1992a) Calculation of the flow around turbine flowmeter blades. Flow Measurement and Instrumentation, 3: 25–35.Google Scholar
Xu, Y. (1992b) A model for the prediction of turbine flowmeter performance. Flow Measurement and Instrumentation, 3: 37–43.Google Scholar
Xu, Y., Zhang, T., Wang, H., Liu, Z. and Chen, D. (2004) Computational investigation on the float-type flowmeter in three-dimensional turbulence flow field. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Xu-bin, Q. (Oct 1993) The simple economic elbow meter for flow measurement. Measurement & Control. 26: 245–246.Google Scholar
Xue, G. and Shen, Y. (2008) Study on measurement of oil gas water three phase flow with conductance correlative flow meter. Proceedings of the IEEE International Conference on Automation and Logistics, ICAL 2008, 1295–1297.Google Scholar
Yajun, L., Dian, T., Jun, L. and Lumkes, J. (2012) Wear behaviour of piston seals in flow meter of fuel dispenser under different pressure conditions. Flow Measurement and Instrumentation, 28: 45–49.Google Scholar
Yamamoto, T., Yao, H. and Kshiro, M. (2004) Advanced hybrid ultrasonic flow meter utilizing pulsed-Doppler method and transit time method. Technical Papers of ISA, 454: 163–173.Google Scholar
Yamasaki, H. (1993) Progress in hydrodynamic oscillator type flowmeters. Journal of Flow Measurement and Instrumentation, 4: 241–248.Google Scholar
Yamashita, Y. (1996) Development of Coriolis mass flowmeter with a single straight tube as flow tube. FLOMEKO'96 Proceedings of the 8th International Conference on Flow Measurement, Beijing, China: 265–270.
Yan, Y. (1996) Mass flow measurement of bulk solids in pneumatic pipelines. Measurement Science and Technology, 7: 1687–1706.Google Scholar
Yan, Y. (2000) Flow measurement of particulate solids in pipelines. Flow Measurement and Instrumentation, 11(3): 151.Google Scholar
Yan, Y. (2005a) Tomographic techniques for multiphase flow measurement. Flow Measurement and Instrumentation, 16(2–3): 63.Google Scholar
Yan, Y. (2005b) Optical techniques for multiphase flow measurement. Flow Measurement and Instrumentation, 16(5): 275.Google Scholar
Yan, Y., Xu, L. and Lee, P. (2006) Mass flow measurement of fine particles in a pneumatic suspension using electrostatic sensing and neural network techniques. IEEE Transactions on Instrumentation and Measurement, 55(6): 2330–2334.Google Scholar
Yang, B., Cao, L. and Luo, Y. (2011) Forced oscillation to reduce zero flow error and thermal drift for non-reciprocal operating liquid ultrasonic flow meters. Flow Measurement and Instrumentation, 22(4): 257–264.Google Scholar
Yang, C.-T., Chen, J.-Y. and Shaw, J.-H. (2002) CFD simulation of three double-elbow pipe flows. 5th International symposium of Fluid Flow Measurement, Arlington, VA, USA.
Yang, W. Q. and Beck, M. S. (1997) An intelligent cross correlator for pipeline flow velocity measurement. Journal of Flow Measurement and Instrumentation, 8: 77–84.Google Scholar
Yao, J., Wang, W. G. and Shi, J. (2011) Study on electromagnetic flowmeter for partially filled flow measurement. 23rd Chinese Control and Decision Conference, 23–25 May 2011, Mianyang, China.
Yao, Y., Chen, C. C., Wu, X. and Huang, L. (2010) MEMS thermal time-of-flight flow meter. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A8-3.
Yeh, T. T. and Mattingly, G. E. (1994) Pipeflow downstream of a reducer and its effects on flowmeters. Journal of Flow Measurement and Instrumentation, 5: 181–187.Google Scholar
Yeh, T. T. and Mattingly, G. E. (1997) Computer simulations of ultrasonic flowmeter performance in ideal and non-ideal pipeflows, ASME Fluids Engineering Division Summer Meeting FEDSM'97, Paper 3012.
Yeh, T. T. and Mattingly, G. E. (2000) Ultrasonic technology: prospects for improving flow measurements and standards. FLOMEKO'2000 the 10th International Conference on Flow Measurement, Salvador, Brazil: Paper A2.
Yeh, T. T., Espina, P. I. and Osella, S. A. (2001) An intelligent ultrasonic flow meter for improved flow measurement and flow calibration facility. IEEE Instrumentation and Measurement Technology Conference, 3: 1741–1746.Google Scholar
Yeung, H., Hemp, J., Henry, M. and Tombs, M. (2004) Coriolis meter in liquid/liquid, liquid/gas and liquid/liquid/gas flows. S.E. Asia Hydrocarbon Flow Measurement Workshop, Singapore, March 2004.
Yinping, J. (2007) Research and application of magnetic suspension technology in wide range turbine flow meter. Proceedings of the 2007 IEEE Sensors Applications Symposium, SAS, San Diego, CA, United States.
Yokota, S., Son, W. C. and Kim, D. T. (1996) Unsteady flow measurement by using a drag-plate-type force flowmeter. FLOMEKO '96 Proceedings of the 8th International Conference on Flow Measurement, Beijing, China: 661–666.
Yoo, S. Y., Lee, S. Y., Yoon, K. Y., Park, K. A. and Paik, J. S. (1993) Experimental study on the factors influencing discharge coefficients of sonic nozzles. FLOMEKO '93 Proceedings of the 6th International Conference on Flow Measurement: 363–371.
Yoshida, Y., Amata, Y. and Frugawa, M. (1993) Development of a partially-filled electromagnetic flowmeter. FLOMEKO'93 Proceedings of the 6th International Conference on Flow Measurement, Korea Research Institute of Standards and Science: 452–459.
Youden, W. J. (1959) Graphical diagnosis of interlaboratory test results. Journal of Industrial Quality, 15: 11.Google Scholar
Young, A. (1990) Coriolis flowmeters for accurate measurement of liquid properties. Advances in Instrumentation, ISA Proceedings, 45, Pt. 4: 1891–1898.Google Scholar
Yu, H., Gong, J., Li, Y., Liao, Y. and Liao, M. (2000) Optical fibre magneto-optic sensor in the turbine mass flowmeter. Proceedings of SPIE – The International Society for Optical Engineering, 4074: 166–170.Google Scholar
Yuan, B.-Z., Nishiyama, S., Fukada, M. and Kanamori, H. (2003) Hydraulic design procedure for bypass flow meters using a pipe bend. Transactions of the American Society of Agricultural Engineers, 46(2):279–85.Google Scholar
Yun, W. Y. and Park, M. H. (2008) An approach to reduce measurement uncertainty of fuel channel coolant flow rate for CANDU plants with a CROSSFLOW ultrasonic flow meter. Societe Francaise d'Energie Nucleaire – International Congress on Advances in Nuclear Power Plants – ICAPP 2007, “The Nuclear Renaissance at Work”, Report number:7142: 848–852.
Zanker, K. J. (2001) An ultrasonic meter for stratified wet gas service. 19th North Sea Flow Measurement Workshop, Kristiansand, Norway, 22–25 October 2001, Paper 9.
Yeh, T. T. and Mattingly, G. E. (2006) The calibration, proving and validation of ultrasonic flow meters. Proc. 6th International Symposium on Fluid Flow Measurement (ISFFM), Queretero, Mexico.
Zanker, K. J. and Cousins, T. (1975) The performance and design of vortex meters. Conference on Fluid Flow Measurement in the Mid 1970s, National Engineering Laboratory, East Kilbride, Glasgow, Scotland: Paper C-3.
Zanker, K. J. and Freund, W. R. Jr. (1996) Practical experience with gas ultrasonic flow meters. North Sea Flow Measurement Workshop, Peebles, Scotland.
Zanker, K. J. and Freund, W. R. (2004) A powerful new diagnostic tool for transit time ultrasonic meters. 22nd North Sea Flow Metering Workshop 2004, Paper 3.1.
Zanker, K. and Goodson, D. (2000) Qualification of a flow conditioning device according to the new API 14.3 procedure. Journal of Flow Measurement and Instrumentation, 11(2): 79–87.Google Scholar
Zanker, K. J. and Mooney, T. (2003) The transit time difference ultrasonic gas meter – a reassessment. 21st North Sea Flow Metering Workshop 2003, Paper 10.
Zanker, K. J. and Mooney, T. (2010) Celebrating quarter of a century of gas ultrasonic custody transfer metering. 28th International North Sea Flow Metering Workshop, Paper 9.2
Zedan, M. F. and Teyssandier, R. G. (1990) Effect of errors in pressure tap locations on the discharge coefficient of a flange-tapped orifice plate. Journal of Flow Measurement and Instrumentation, 1: 141–148.Google Scholar
Zhang, F., Dong, F. and Tan, C. (2010) High GVF and low pressure gas-liquid two-phase flow measurement based on dual-cone flowmeter. Journal of Flow Measurement and Instrumentation, 21(3): 410–417.Google Scholar
Zhang, H., Huang, Y. and Sun, Z. (2006) A study of mass flow rate measurement based on the vortex shedding principle. Flow Measurement and Instrumentation, 17(1): 29–38.Google Scholar
Zhang, J., Coulthard, J., Cheng, R. and Keech, R. (2004c) On-line flow measurement and control of pulverised fuel. Measurement and Control, 37(9): 273–275.Google Scholar
Zhang, L., Hu, H., Meng, T. and Wang, C. (2013) Effects of flow disturbance on multipath ultrasonic flowmeters. FLOMEKO 2013 Proceedings of 16th International Conference on Flow Measurement, Paris, France.
Zhang, T., Sun, H. and Wu, P. (2004a) Wavelet denoising applied to vortex flowmeters. Flow Measurement and Instrumentation, 15(5–6): 325–329.Google Scholar
Zhang, X., Wu, P., Liang, M. and Sun, Y. (2004b) The experimental study and uncertainty analysis on the double turbine mass flowmeter with the corrective property for velocity distribution. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Zhang, X-Z. (1997) The effect of the phase distribution on the weight function of an electromagnetic flow meter in 2D and in the annular domain. Measurement Science and Technology,. 8: 1285–1288.Google Scholar
Zhang, X-Z. (1998) Virtual current of an electromagnetic flowmeter in partially filled pipes. Measurement Science and Technology, 9: 622–630.Google Scholar
Zhang, X-Z. (1999) On the virtual current in an electromagnetic flow meter containing a number of bubbles by two-dimensional analysis. Measurement Science and Technology,, 10: 1087–1091.Google Scholar
Zhang, X-Z. (2001) Calculation and measurement of the magnetic field in a large diameter electromagnetic flow meter. ISA TECH/EXPO Technology Update Conference Proceedings, 416: 287–290.Google Scholar
Zhang, X-Z. (2002) Theory to help the use of electromagnetic flow meters. American Society of Mechanical Engineers, Fluids Engineering Division (Publication) FED, 257: 11–14.
Zhang, X-Z. (2003) Calculation and measurement of the magnetic field in a large diameter electromagnetic flow meter. ISA Transactions, 42(2): 167–170.Google Scholar
Zhang, X-Z. (2007) Measurement errors caused by asymmetry in electromagnetic flow meter. FLOMEKO 2007 Proceedings of a meeting held 18–21 September 2007, Sandton, Gauteng, South Africa.
Zhang, X-Z. (2010) Theory and methods for flow measurement by electromagnetic induction. Tsinghua University Press.
Zhang, X-Z. (2012) Preliminary experimental study on multi-parameter measurement of fluid flow by vibrating tube, Applied Mechanics and Materials, 241–244: 70–74.Google Scholar
Zhang, X. Z. and Hemp, J. (1994) Measurement of pipe flow by an electromagnetic probe. ISA Transactions, 33: 181–184.Google Scholar
Zhang, X. Z. and Hemp, J. (1995) Calculation of the virtual current around an electromagnetic velocity probe using the alternating method of Schwarz. Flow Measurement and Instrumentation, 5: 146–149.Google Scholar
Zhang, X.-Z. and Li, Y. (2004) Calculation of the virtual current in an electromagnetic flow meter with one bubble using 3D model. ISA Transactions, 43(2): 189–194.Google Scholar
Zhang, X.-Z. and Wang, G.-Q. (2004) Electromagnetic inductive flow pattern reconstruction by means of spectrum expanding. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Zhang, Y. and Li, Z. (2015) Improving the accuracy of time-difference measurement by reducing the impact of baseline shift. IEEE Transactions on Instrumentation and Measurement, 64(11): 3013–3020.
Zhao, W. and Cao, C. (2008) Study of computerized tomography based multiphase flow measurement. Proceedings of the IEEE International Conference on Automation and Logistics, ICAL, Qingdao, China: 2286–2290.
Zhen, W. and Tao, Z. (2008) Computational study of the tangential type turbine flowmeter. Flow Measurement and Instrumentation, 19(5): 233–239.Google Scholar
Zheng, D. and Zhang, T. (2008) Research on vortex signal processing based on double-window relaxing notch periodogram. Flow Measurement and Instrumentation, 19(2): 85–91.Google Scholar
Zheng, D.-D., Zhang, T., Sun, L.-j., Meng, T., Hu, H.-M. and Wang, C. (2010) Installation effects of ultrasonic flowmeter in single bend pipe. 15th Flow Measurement Conference (FLOMEKO), 13–15 October 2010, Taipei, Taiwan, Paper A10-2.
Zheng, D., Zhang, P. and Xu, T. (2011) Study of acoustic transducer protrusion and recess effects on ultrasonic flowmeter measurement by numerical simulation. Flow Measurement and Instrumentation, 22(5): 488–493.Google Scholar
Zheng, D., Zhang, P., Zhang, T. and Zhao, D. (2013) A method based on a novel flow pattern model for the flow adaptability study of ultrasonic flowmeter. Flow Measurement and Instrumentation, 29: 25–31.Google Scholar
Zheng, D., Zhao, D. and Mei, J. (2015) Improved numerical integration method for flowrate of ultrasonic flowmeter based on Gauss quadrature for non-ideal flow fields. Flow Measurement and Instrumentation, 41: 28–35.Google Scholar
Zheng, G.-B., Jin, N.-D., Jia, X.-H., Lv, P.-J. and Liu, X.-B. (2008a) Gas-liquid two phase flow measurement method based on combination instrument of turbine flowmeter and conductance sensor. International Journal of Multiphase Flow, 34(11): 1031–1047.Google Scholar
Zheng, Y., Pugh, J.R., McGlinchey, D. and Ansell, R.O. (2008b) Simulation and experimental study of gas-to-particle heat transfer for non-invasive mass flow measurement. Measurement: Journal of the International Measurement Confederation, 41(4): 446–454.Google Scholar
Zhou, S. and Halttunen, J. (2004) Application of electrical impedance tomography in pulp flow measurement. 12th International Conference on Flow Measurement FLOMEKO Guilin China.
Zhu, H-L. and Min, Z. (1999) New simple non-invasive method for flow measurement. Measurement and Control, 32(6): 178–80.Google Scholar
Ziani, E. M., Bennouna, M. and Boissier, R. (2004) Ultrasonic flow measurement for irrigation process monitoring. Proceedings of SPIE – The International Society for Optical Engineering, 5232: 184–95.Google Scholar

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  • References
  • Roger C. Baker
  • Book: Flow Measurement Handbook
  • Online publication: 05 August 2016
  • Chapter DOI: https://doi.org/10.1017/CBO9781107054141.026
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  • Book: Flow Measurement Handbook
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  • Chapter DOI: https://doi.org/10.1017/CBO9781107054141.026
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