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Air conditioning systems for aeronautical applications: a review

Published online by Cambridge University Press:  27 December 2019

M. Merzvinskas*
Affiliation:
EMBRAERSão José dos CamposSão PauloBrazil
C. Bringhenti
Affiliation:
Aeronautics Institute of Technology (ITA)São José dos CamposSão PauloBrazil
J.T. Tomita
Affiliation:
Aeronautics Institute of Technology (ITA)São José dos CamposSão PauloBrazil
C.R. de Andrade
Affiliation:
Aeronautics Institute of Technology (ITA)São José dos CamposSão PauloBrazil

Abstract

This paper presents a review of the various aeronautical air conditioning systems that are currently available and discusses possible system configurations in the context of the aeronautical environmental control systems. Descriptions of the standard vapor compression cycle and air cycles are provided. The latter includes, simple-cycle, bootstrap-cycle, simple-bootstrap cycle (3-wheel) and condensing cycle (4-wheel). Water separation and air recirculation systems are also explored. A comparison between vapor compression cycles and air cycles is provided, as well as a comparison between different air cycles. Air cycle units are far less efficient than vapor compression cycle units, but they are lighter and more reliable for an equivalent cooling capacity. Details regarding the aircraft conceptual design phase along with general criteria for the selection of an air conditioning system are provided. Additionally, industry trends and technological advances are examined. Conclusions are compiled to guide the systems engineer in the search for the most appropriate design for a particular application.

Type
Research Article
Copyright
© Royal Aeronautical Society 2019

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References

REFERENCES

SOCIETY OF AUTOMOTIVE ENGINEERS. Environmental Control Systems Terminology, (Aerospace Recommended Practice, ARP147 Rev. E), SAE International, 2001, Warrendale, PA, USA.Google Scholar
AMERICAN SOCIETY OF HEATING AND REFRIGERATING AND AIR-CONDITIONING ENGINEERS. ASHRAE Handbook: HVAC Applications SI, ASHRAE, 2011, Atlanta, GA, USA.Google Scholar
Lawson, C.P.Environmental control systems. In Encyclopedia of Aerospace Engineering, BLOCKLEY, R.H. and SHYY, W., (Eds), John Wiley & Sons Ltd, December 2010, Hoboken, NJ, USA, pp 49854994.Google Scholar
Mäkelä, L. Model-Based Fault Diagnosis of an Aircraft Environmental Control System, Programme in Automation Engineering, Master of Science Thesis, Tampere University of Technology, Tampere, Finland, 2016.Google Scholar
Santos, A.P.P., Andrade, C.R. and Zaparoli, E.L.A thermodynamic study of air cycle machine for aeronautical applications, Int J Thermodynamics, September 2014, 17, (3), pp 117126.CrossRefGoogle Scholar
Wright, S., Andrews, G. and Sabir, H.A review of heat exchanger fouling in the context of aircraft air-conditioning systems, and the potential for electrostatic filtering, Applied Thermal Engineering, September 2009, 29, (13), pp 25962609. https://doi.org/10.1016/j.applthermaleng.2009.01.002 .CrossRefGoogle Scholar
Affonso, W., da Silva, R.G.A., da Silva, F.S., Thomas, G., Kessler, S. and Domingos, R.H. Carbon nanotube (CNT) based ice protection system applied to a small aircraft, 17th AIAA Aviation Technology, Integration, and Operations conference, AIAA AVIATION Forum, (AIAA 2017-3069), June 2017, AIAA, Orlando, Florida, p 3069.CrossRefGoogle Scholar
SOCIETY OF AUTOMOTIVE ENGINEERS. Engine Bleed Air Systems for Aircraft, (Aerospace Recommended Practice, ARP1796A), SAE International, 2007, Warrendale, PA, USA.Google Scholar
Moir, I. and Seabridge, A.Environmental Control Systems in Aircraft Systems: Mechanical, Electrical, and Avionics Subsystems Integration, John Wiley & Sons, Ltd., 2008, Chichester, UK.CrossRefGoogle Scholar
SOCIETY OF AUTOMOTIVE ENGINEERS. Compartment Decompression Analysis, (Aerospace Information Report, AIR5661), SAE International, 2010, Warrendale, PA, USA.Google Scholar
Committee on Air Quality in Passenger Cabins of Commercial Aircraft, Board on Environmental Studies and Toxicology, National Research Council. The Airliner Cabin Environment and the Health of Passengers and Crew. National Academies Press (US), 2002, Washington, DC, USA.Google Scholar
Hunt, E., Reid, D., Space, D. and Tilton, F.Commercial airliner environmental control system: Engineering aspects of cabin air quality. In Aerospace Medical Association Annual Meeting, Hunt, E., Reid, D., Space, D. and Tilton, F. (Eds), Boeing Company, January 1995, Anaheim, CA, USA, pp 18.Google Scholar
SOCIETY OF AUTOMOTIVE ENGINEERS. Aircraft Cabin Pressurization Criteria, (Aerospace Recommended Practice, ARP1270 Rev. B), SAE International, 2001, Warrendale, PA, USA.Google Scholar
Heinrich, A., Ross, R., Zumwalt, G., Provorse, J. and Padmanabhan, V.Aircraft Icing Handbook: Volume 2 of 3, FAA, 1991, Atlantic City, NJ, USA.Google Scholar
Çengel, Y.A. and Boles, M.A.Thermodynamics: An Engineering Approach, McGraw-Hill College, 2006, Boston, MA, USA.Google Scholar
Gurney, J.D.Design and operation of airborne refrigeration equipment, Aircr Engineering Aerospace Technology, September 1961, 33, (11), pp 321325. https://doi.org/10.1108/eb033478.CrossRefGoogle Scholar
Kang, H., Jaehyeok, H. and Kim, Y.Performance characteristics of a vapor compression cooling cycle adopting a closed-loop air-circulation system for avionic reconnaissance equipment, Int J Refrigeration, June 2012, 35, (4), pp 785794. https://doi.org/10.1016/j.ijrefrig.2011.11.021.CrossRefGoogle Scholar
SOCIETY OF AUTOMOTIVE ENGINEERS. General Requirements for Application of Vapor Cycle Refrigeration Systems for Aircraft, (Aerospace Recommended Practice, ARP731 Rev. C), SAE International, 2015, Warrendale, PA, USA.Google Scholar
Tamura, T., Yakumaru, Y. and Nishiwaki, F.Experimental study on automotive cooling and heating air conditioning system using CO2 as a refrigerant, Int J Refrigeration, December 2005, 28, (8), pp 13021307. https://doi.org/10.1016/j.ijrefrig.2005.09.010.CrossRefGoogle Scholar
Verma, J.K., Satsangi, A. and Chaturani, V.A review of alternative to R134a (CH3CH2F) refrigerant, Int J Emerging Technology Advanced Engineering, 2013, 3, (1), pp 300304.Google Scholar
Baskaran, A. and Koshy Mathews, P. Dr. A performance comparison of vapour compression refrigeration system using eco friendly refrigerants of low global warming potential, Int J Scientific Research Publication, 2012, 2, (9), pp 18.Google Scholar
SOCIETY OF AUTOMOTIVE ENGINEERS. Aerothermodynamic Systems Engineering and Design, (Aerospace Information Report, AIR1168/3), SAE International, 1990, Warrendale, PA, USA.Google Scholar
SOCIETY OF AUTOMOTIVE ENGINEERS. Environmental Control Systems Life Cycle Cost, (Aerospace Information Report, AIR1812 Rev. B), SAE International, 2017, Warrendale, PA, USA.Google Scholar
ARORA, C.P.Refrigeration and Air Conditioning, Tata McGraw-Hill, 2009, New Delhi, India.Google Scholar
Shetty, J., Lawson, C.P. and Shahneh, A.Z.Simulation for temperature control of a military aircraft cockpit to avoid pilot’s thermal stress, CEAS Aeronaut J, 2015, 6, (2), pp 319333. https://doi.org/10.1007/s13272-015-0149-0.CrossRefGoogle Scholar
SOCIETY OF AUTOMOTIVE ENGINEERS. Air Conditioning Systems for Subsonic Airplanes, (Aerospace Recommended Practice, ARP85 Rev. F), SAE International, 2012, Warrendale, PA, USA.Google Scholar
De Francesco, G.L. Condensing cycle air conditioning system, International Conference on Environmental Systems, 16–20 July 1993, SAE International, Colorado Springs, pp 112.CrossRefGoogle Scholar
Leo, T.J. and Pérez-Grande, I.A thermoeconomic analysis of a commercial aircraft environmental control system, Applied Thermal Engineering, February 2005, 25, (2), pp 309325. https://doi.org/10.1016/j.applthermaleng.2004.06.011.CrossRefGoogle Scholar
Ordonez, J.C. and Bejan, A.Minimum power requirement for environmental control of aircraft, Energy, October 2003, 28, (12), pp 11831202. https://doi.org/10.1016/S0360-5442(03)00105-1.CrossRefGoogle Scholar
Lui, C., Quan, M. and Wong, R. Recirculating regenerative environmental control system, SAE Technical Paper No. 2004-01-2575, 2004.Google Scholar
Gabbay, E.J.Open cycle refrigeration, Aircr Engineering Aerospace Technology, 1958, 30, (3), pp 6471. https://doi.org/10.1108/eb032939.CrossRefGoogle Scholar
AEAT. Air conditioning, Aircr Engineering Aerospace Technology, 1974, 46, (10), pp 2325. https://doi.org/10.1108/eb035194.CrossRefGoogle Scholar
Gandolfi, R., Pellegrini, L.F., Silva, G.A.L. and Oliveira, S. Aircraft air management systems trade-off study using exergy analysis as a design comparison tool, 19th International Congress of Mechanical Engineering, January 2007, ABCM, Brasília, DF, pp 17.Google Scholar
Romani, R. and de Góes, L.C. Cabin temperature control model for commercial aircraft, AIAA Modeling and Simulation Technologies Conference, Guidance, Navigation, and Control and Co-located Conferences, 13–16 August 2012, AIAA, Orlando, Florida, pp 116.CrossRefGoogle Scholar
Turcio, W. and Neto, A.H. Dynamic behavior of aircraft cabin and air conditioning system, SAE Technical Paper 2003-01-2397 No. 0148-7191, 2003.Google Scholar
SOCIETY OF AUTOMOTIVE ENGINEERS. Aircraft Fuel Weight Penalty Due to Air Conditioning, (Aerospace Information Report, AIR1168/8), SAE International, 1989, Warrendale, PA, USA.Google Scholar
Zhao, H., Hou, Y., Zhu, Y., Chen, L. and Chen, S.Experimental study on the performance of an aircraft environmental control system, Applied Thermal Engineering, November 2009, 29, (16), pp 32843288. https://doi.org/10.1016/j.applthermaleng.2009.05.002.CrossRefGoogle Scholar
Leech, D.J.Aircraft refrigeration systems, Aircr Engineering Aerospace Technology, April 1961, 33, (6), pp 156163. https://doi.org/10.1108/eb033419.CrossRefGoogle Scholar
Allison, D., Alyanak, E. and Shimmin, K. Aircraft system effects including propulsion and air cycle machine coupled interactions, 57th AIAA/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference, September 2016, AIAA, Orlando, Florida, pp 16.CrossRefGoogle Scholar
Chakraborty, I. Subsystem Architecture Sizing and Analysis for Aircraft Conceptual Design, Georgia Institute of Technology, Philosophy in the Daniel Guggenheim School of Aerospace Engineering, Doctoral Dissertation, Atlanta, GA, 2015.Google Scholar
Peng, X. Aircraft Environmental Control Systems Modeling for Configuration Selection, Cranefield University, PhD and Masters by Research Theses, Cranfield, England, 2013.Google Scholar
Wagner, W. Engine design decisions impact aircraft life cycle costs, 13th Propulsion Conference, Joint Propulsion Conference, April 1977, Aerospace Research Central, Orlando, Florida, pp 15.CrossRefGoogle Scholar
Eckels, W.E.Civil Transport Aircraft Design Methodology, AIAA Paper 83-2463, AIAA, Orlando, Florida, 1983.Google Scholar
Cavalcanti, V.C. and de Andrade, C.R. A trade-off study of a bleedless and conventional air conditioning systems, SAE Technical Paper No. 2008-36-0001, 2008.Google Scholar
Puttini, L.C. IVHM Development and the big data paradigm, SAE Technical Paper No. 2013-01-2332, 2013.Google Scholar
Qin, Y., Wang, Z.X., Chan, F.T.S., Chung, S.H. and Qu, T.A mathematical model and algorithms for the aircraft hangar maintenance scheduling problem, Applied Mathematics Modeling, March 2019, 67, (1), pp 491509. https://doi.org/10.1016/j.apm.2018.11.008.CrossRefGoogle Scholar
Knotts, R.Civil aircraft maintenance and support fault diagnosis from a business perspective, J Quality Maintenance Engineering, 1999, 5, pp 335348. https://doi.org/10.1108/13552519910298091 .CrossRefGoogle Scholar
Leão, B.P., Fitzgibbon, K.T., Puttini, L.C. and de Melo, G.P. Cost-benefit analysis methodology for PHM applied to legacy commercial aircraft, Proceedings of the IEEE Aerospace Conference, 2008, IEEE, Piscataway, New Jersey, pp 113.CrossRefGoogle Scholar
Ma, J., Lu, C. and Liu, H.Fault diagnosis for the heat exchanger of the aircraft environmental control system based on the strong tracking filter, PLoS One, 2015, 10, (3), p e0122829. https://doi.org/10.1371/journal.pone.0122829.CrossRefGoogle ScholarPubMed
Mahindru, D.V. and Mahendru, P.Environmental control system for military and civil aircraft, Global J Research Engineering, 2011, 11, (5_D), pp 17.Google Scholar
Jenab, K. and Rashidi, K.Operational reliability assessment of an aircraft environmental control system, Reliability Engineering System Safety, 2009, 94, (2), pp 456462. https://doi.org/10.1016/j.ress.2008.05.003.CrossRefGoogle Scholar
Farag, A. and Khalil, E.E. Personalized air conditioning of air craft cabins for passengers’ comfort and efficient energy use, 51st AIAA/SAE/ASEE Joint Propulsion Conference, 2015, AIAA, Orlando, Florida, p 4125.CrossRefGoogle Scholar
Giaconia, C., Orioli, A. and Di Gangi, A.Air quality and relative humidity in commercial aircrafts: an experimental investigation on short-haul domestic flights, Building Environment, September 2013, 67, (1), pp 6981. https://doi.org/10.1016/j.buildenv.2013.05.006.CrossRefGoogle Scholar
Conceição, S.T., Pereira, M.L. and Tribess, A.A review of methods applied to study airborne biocontaminants inside aircraft cabins, Int J Aerospace Engineering, March 2011, 2011, (1), p 15.CrossRefGoogle Scholar
Alvarenga, M.A., Andrade, C.R. and Zaparoli, E.L.A thermodynamic analysis of three and four-wheel air cycle machines for aeronautical applications, Int Review Mech Engineering, March 2015, 9, (2), p 190. https://doi.org/10.15866/ireme.v9i2.5543.Google Scholar
Conceição, S.T., Zaparoli, E.L. and Turcio, W.H.L. Thermodynamic study of aircraft air conditioning air cycle machine: 3-wheel× 4-wheel, SAE Technical Paper No. 2007-01-2579, 2007.Google Scholar
Cavalcanti, V.C. and de Andrade, C.R. A Trade-off Study of a Bleedless and Conventional Air Conditioning Systems, Technological Institute of Aeronautics, Aeronautical Engineering, M. Sc., 2008, São José dos Campos, Brazil.Google Scholar
Baharozu, E., Soykan, G. and Ozerdem, M.B.Future aircraft concept in terms of energy efficiency and environmental factors, Energy, December 2017, 140, (2), pp 13681377. https://doi.org/10.1016/j.energy.2017.09.007.CrossRefGoogle Scholar
Gandolfi, R., Pellegrini, L. and De Oliveira, S. More electric aircraft analysis using exergy as a design comparison tool, Proceedings of 48th AIAA Aerospace Sciences Meeting, November 2010, AIAA, Orlando, Florida, pp 120.CrossRefGoogle Scholar
Gandolfi, R., Pellegrini, L., Silva, G. and Oliveira, S. Exergy analysis applied to a complete flight mission of commercial aircraft, 46th AIAA Aerospace Sciences Meeting and Exhibit, July 2008, Reno, 2008, AIAA, Orlando, Florida, pp 15.CrossRefGoogle Scholar
Ensign, T. Performance and weight impact of electric environmental control system and more electric engine on citation CJ2, 45th AIAA Aerospace Sciences Meeting and Exhibit, November 2007, AIAA, Orlando, Florida, p 1395.CrossRefGoogle Scholar
Long, C., Zhang, X. and Yang, C. A new concept environmental control system with energy recovery considerations for commercial aircraft, 44th International Conference on Environmental Systems, August 2014, ICES, Arizona, Tucson, pp 110.Google Scholar
Michalak, T., Emo, S. and Ervin, J.Control strategy for aircraft vapor compression system operation, Int J Refrigeration, December 2014, 48, (1), pp 1018. https://doi.org/10.1016/j.ijrefrig.2014.08.010 .CrossRefGoogle Scholar
Went, T., Zhan, H., Zhang, D. and Lu, L.Development of evaporation pressure-capacity control strategy for aircraft vapor cycle system, Int J Refrigeration, November 2017, 83, (1), pp 1422. https://doi.org/10.1016/j.ijrefrig.2017.07.008 .Google Scholar
Jain, N. and Alleyne, A.G. Thermodynamics-based optimization and control of vapor-compression cycle operation: control synthesis, ASME 2011 Dynamic Systems and Control Conference and Bath/ASME Symposium on Fluid Power and Motion Control, June 2011, American Society of Mechanical Engineers, New York, NY, pp 827834.CrossRefGoogle Scholar
Memet, F. and Preda, A. An analysis of the performance of an ejector refrigeration cycle working with R134a, IOP Conference Series: Materials Science and Engineering, October 2015, IOP Publishing, Bristol, pp 16.CrossRefGoogle Scholar
Besagni, G., Mereu, R. and Inzoli, F.Ejector refrigeration: a comprehensive review, Renewable Sustainable Energy Reviews, 2016, 53, (1), pp 373407. https://doi.org/10.1016/j.rser.2015.08.059.CrossRefGoogle Scholar
Mezaal, N.A., Osintsev, K.V. and Zhirgalova, T.B. Review of magnetic refrigeration system as alternative to conventional refrigeration system, IOP Conference Series: Earth and Environmental Science, January 2017, IOP Publishing, Bristol, pp 18.CrossRefGoogle Scholar
Finn, J. and Sangiovanni-Vincentelli, A.L. Optimal architecture selection for an aircraft environmental control system, Technical Report No. UCB/EECS-2016-28, 2016.Google Scholar
MARTINEZ, I. Aircraft environmental control. Academic website webserver. dmt. upm. es/isidoro, 2014.Google Scholar