Ground-Based Gas Turbine Combustion

doi:10.1017/CBO9781139015462.005

2 - Ground-Based Gas Turbine Combustion

Metrics, Constraints, and System Interactions

from Part 1 - Overview and Key Issues

Published online by Cambridge University Press: 05 June 2013

Vincent McDonell and

Manfred Klein

Edited by

Tim C. Lieuwen and

Vigor Yang

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Tim C. Lieuwen: Affiliation:
Georgia Institute of Technology
Vigor Yang: Affiliation:
Georgia Institute of Technology

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Summary

Introduction

A serious need for future energy resources worldwide is apparent, driven by high-population countries such as India and China that are rapidly developing infrastructure for energy, as well as growth or repowering in developed countries. Gas turbines play a preeminent role in the stationary power generation marketplace and should remain a critical part of the market mix for the foreseeable future, despite competition from reciprocating engines and newer technologies such as fuel cells. Alternative technologies compete with gas turbines in certain size classes, but at power generation levels above 5 MW, gas turbines offer the most attractive option because of their relatively low capital, operating, and maintenance costs. Hence, these engines are increasingly relied upon for clean power production from a variety of fuels. The configurations for these systems involve high efficiencies as well. As a result, the market will continue to demand gas turbines.

Chapter 1 discusses the drivers and consideration for aero gas turbines. While much of that discussion applies to gas turbines in general, the use of gas turbines for ground-based applications gives rise to additional and/or different metrics, constraints, and much wider possible overall system interactions relative to the combustion system. These turbines vary in size from 10 s of kW to hundreds of MW. The applications vary from power generation to mechanical work (e.g., Soares, 2008). In power generation, the gas turbine shaft is coupled to a generator either directly or via a gearbox (“direct drive”). For mechanical work, the gas turbine provides power to a mechanical device such as a compressor or pump (“mechanical drive”). In power generation, the gas turbine may often be combined with other equipment to form “combined cycle” systems (e.g., combining a gas turbine generator with infrastructure to collect exhaust heat to produce steam to drive a steam turbine).

Type: Chapter
Information: Gas Turbine Emissions , pp. 24 - 80

DOI: https://doi.org/10.1017/CBO9781139015462.005 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2013

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References

Araki, H., Koganezawa, T., Myouren, C., Higuchi, S., Takahashi, T., and Eta, T. (2012). “Experimental and Analytical Study on the Operation Characteristics of the AHAT System.” J. Engr Gas Turbine and Power 134(5): 051701–1: 8.CrossRef Google Scholar

Ballal, D. R., and Lefebvre, A. H. (1979). “Weak Extinction Limits of Turbulent Flowing Mixtures.” ASME J. Engineering for Gas Turbines and Power 101: 343.CrossRef Google Scholar

Balling, L. (2010). “Fast-cycling and Starting Combined Cycle Power Plants to Backup Fluctuating Renewable Power.” Industrial Fuels and Power August 27.

Beerer, D. J., and McDonell, V. G. (2008). “Autoignition of Hydrogen and Air inside a Continuous Flow Reactor with Applications to Lean Premixed Combustion.” Journal of Engineering for Gas Turbines and Power 130: 051507–1.CrossRef Google Scholar

Beerer, D. J., McDonell, V. G., Samuelsen, G. S., and Angello, L. (2011). “An Experimental Ignition Delay Study of Alkane Mixtures in Turbulent Flows at Elevated Pressure and Intermediate Temperatures.” Journal of Engineering for Gas Turbines and Power 133: 101503–1–11.CrossRef Google Scholar

Belgiorno, V. et al. (2003). “Energy from Gasification of Solid Wastes.” Waste Management 23: 1–15.CrossRef Google Scholar PubMed

Bolszo, C. D., and McDonell, V. G. (2009). “Evaluation of Plain-Jet Air Blast Atomization and Evaporation of Alternative Fuels in a Small Gas Turbine Engine Application.” Atomization and Sprays 19(8): 771–85.CrossRef Google Scholar

Bradley, D. (1992). “How Fast Can We Burn?” Symposium (International) on Combustion 24(1): 247–62.CrossRef Google Scholar

Bunz, W. J., Ziady, G. N., and Von E. Doring, H. (1984). “Crude Oil Burning Experience in MS5001P Gas Turbines.” Journal of Engineering for Gas Turbines and Power 106(4): 812–19.CrossRef Google Scholar

Chaos, M., Burke, M. P., Ju, Y., and Dryer, F. L. (2010). “Syngas Chemical Kinetics and Reaction Mechanisms,” chapter 2 in Synthesis Gas Combustion: Fundamentals and Applications, Lieuwen, T., Yang, V., and Yetter, R. eds., Taylor, & Francis, , Boca Raton, FL.Google Scholar

Cheng, R. (2010). “Turbulent Combustion Properties of Premixed Syngas,” chapter 5 in Synthesis Gas Combustion: Fundamentals and Applications, Lieuwen, T., Yang, V., and Yetter, R. eds., Taylor, & Francis, , Boca Raton, FL.Google Scholar

Chaudhuri, S., Kosta, S., Renfro, M. W., and Cetegen, B. M. (2010). “Blowoff Dynamics of Bluff Body Stabilized Turbulent Premixed Flames.” Combustion and Flame 157: 790–802.CrossRef Google Scholar

Collot, A. G. (2006). “Matching Gasification Technologies to Coal Properties.” International Journal of Coal Geology 65: 191–212.CrossRef Google Scholar

Dämkholer, G. (1947). “Influence of Turbulence on the Velocity of Flame in Gas Mixtures.” Z. Elektrochem 46: 601–26 (1950). English translation, NACA-TM-I 112.Google Scholar

Demirbas, A. (2007). “Progress and Recent Trends in Biofuels.” Progress in Energy and Combustion Science 33(1): 1–17.CrossRef Google Scholar

DeZubay, E. A. (1950). “Characteristics of Disk-controlled Flames.” Aero Digest, 54(6): 102–4.Google Scholar

Ducruix, S., Schuller, T., Durox, D., and Candel, S. (2005). “Combustion Instability Mechanisms in Premixed Combustors,” in Combustion Instabilities in Gas Turbine Engines, Lieuwen, T. and Yang, V. eds., AIAA Press., pp 179–212.Google Scholar

Eichler, C., Baumgartner, G., and Sattelmayer, T. (2012). “Experimental Investigation of Turbulent Boundary Layer Flashback Limits for Premixed Hydrogen-air Confined in Ducts.” Journal of Engineering for Gas Turbines and Power 134: 011502–1–8.CrossRef Google Scholar

EPRI (1993). A Feasibility and Assessment Study for FT4000 Humid Air Turbine (HAT), Report TR-102156.

Fritz, J., Kröner, M., and Sattelmayer, T. (2004). “Flashback in a Swirl Burner with Cylindrical Premixing Zone.” Journal of Engineering for Gas Turbines and Power 126: 267–83.CrossRef Google Scholar

George, D.L., and Bowles, E.B. (2011). “Shale Gas Measurement and Associated Issues,” Pipeline and Gas Journal 238: 7.Google Scholar

Guin, C. (1998). “Characterization of Autoignition and Flashback in Premixed Injection Systems.” AVT Symposium on Gas Turbine Engine Combustion, Emissions, and Alternative Fuels, Lisbon.

Hauserman, W. B. (1994).“High-Yield Hydrogen Production by Catalytic Gasification of Coal or Biomass.” International Journal of Hydrogen Energy 19: 413–19.CrossRef Google Scholar

Higuchi, S., Koganezawa, T., Horiuchi, Y., Araki, H., Shibata, T., and Marushima, S. (2008). “Test Results from the Advanced Humid Air Turbine System Pilot Plant: Part 1 – Overall Performance.” TurboEXPO.CrossRef

Jones, R. M., and Shilling, N. Z. (2003). “IGCC Gas Turbines for Refinery Applications.” GE Power Systems Report GER-4219, 05/03.

Kavanagh, R. M., and Parks, G. T. (2009a). “A Systematic Comparison and Multi-Objective Optimization of Humid Power Cycles – Part I: Thermodynamics.” Journal of Engineering for Gas Turbines and Power 131(4): 041701.CrossRef Google Scholar

Kavanagh, R. M., and Parks, G. T. (2009b). “A Systematic Comparison and Multi-Objective Optimization of Humid Power Cycles – Part II: Economics.” Journal of Engineering for Gas Turbines and Power 131(4): 041702.CrossRef Google Scholar

Kharchenko, N. V. (1998). Advanced Energy Systems, Taylor & Francis, Washington DC.Google Scholar

Kido, H., Nakahara, M., Hashimoto, J., and Barat, D. (2002). “Turbulent Burning Velocities of Two-Component Fuel Mixtures of Methane, Propane and Hydrogen.” JSME International Journal Series B 45(2): 355–62.CrossRef Google Scholar

Kiesewetter, F., Konle, M., and Sattelmayer, T. (2007). “Analysis of Combustion Induced Vortex Breakdown Driven Flame Flashback in a Premixed Burner with Cylindrical Mixing Zone.” Journal of Engineering for Gas Turbines and Power 129: 929–36.CrossRef Google Scholar

Knothe, G. (2010). “Biodiesel and Renewable Diesel: A Comparison.” Progress in Energy and Combustion Science 36(3): 364–73.CrossRef Google Scholar

Konle, M., and Sattelmayer, T. (2010). “Time Scale Model for the Prediction of the Onset of Flame Flashback Driven by Combustion Induced Vortex Breakdown.” Journal of Engineering for Gas Turbines and Power 132: 041503.CrossRef Google Scholar

Kröner, M., Fritz, J., and Sattelmayer, T. (2003). “Flashback Limits for Combustion Induced Vortex Breakdown in a Swirl Burner.” Journal of Engineering for Gas Turbines and Power 125: 693–700.CrossRef Google Scholar

Lefebvre, A. H., and Ballal, D. (2010). Gas Turbine Combustion, 3rd Edition, CRC Press, Boca Raton, FL.CrossRef Google Scholar

Lefebvre, A. H., Freeman, W., and Cowell, L. (1986). “Spontaneous Ignition Delay Characteristics of Hydrocarbon Fuel/Air Mixtures.” NASA Contractor Report 175064.Google Scholar

Leonard, P. A., and Mellor, A. M. (1983). “Correlation of Lean Blowoff of Gas Turbine Combustors using Alternative Fuels.” Journal of. Energy 7(6): 729–32.CrossRef Google Scholar

Lewis, B., and Von Elbe, G. (1943). “Stability and Structure of Burner Flames.” Journal of Chemical Physics 11: 75–98.CrossRef Google Scholar

Lewis, B., and Von Elbe, G. (1987). Combustion, Flames and Explosions of Gases, 3rd Edition, Academic, New York.Google Scholar

Li, S. C., and Williams, F. A. (2002). “Reaction Mechanism for Methane Ignition.” Journal of Engineering for Gas Turbines and Power 124: 471–80.CrossRef Google Scholar

Lieuwen, T. C., and Yang, V., eds. (2005). “Combustion Instabilities in Gas Turbine Engines: Operational Experience, Fundamental Mechanisms, and Modeling.” Progress in Astronautics and Aeronautics, 210, AIAA, Virginia.

Lieuwen, T. C., McDonell, V., Petersen, E., and Dantavicca, D. (2008). “Fuel Flexibility Influences on Premixed Combustor Blowout, Flashback, Autoignition, and Stability.” Journal of Engineering for Gas Turbines and Power 130(January): 011506–1 – 011506–10.CrossRef Google Scholar

Lieuwen, T. C., Yang, V., and Yetter, R., eds. (2010). Synthesis Gas Combustion: Fundamentals and Applications, CRC Press, FL.

Liss, W. E., and Rue, D. (2005). “Natural Gas Composition and Fuel Quality.” Information Report from the Gas Technology Institute.Google Scholar

Liss, W. E., Thrasher, W. H., Steinmetz, G. F., Chowdiah, P., and Attari, A. (1992). “Variability of Natural Gas Composition in Select Major Metropolitan Areas of the United States.” GRI Report 92/0123.

Littlejohn, D., Cheng, R. K., Noble, D. R., and Lieuwen, T. C. (2010). “Laboratory Investigations of Low-Swirl Injectors Operating With Syngases.” Journal of Engineering for Gas Turbines and Power 132(1): 011502–011508.CrossRef Google Scholar

Liu, Y. and Lenze, B. (1992). “Investigation of Flame Generated Turbulence in Premixed Flames and Low and High Burning Velocities.” Experimental Thermal and Fluid Science 5(3): 410–15.CrossRef Google Scholar

McDonell, V. (2008). “Lean Combustion in Gas Turbines,” in Lean Combustion – Technology and Control, Dunn-Rankin, D. ed., Academic Press, San Diego, pp. 121–160.Google Scholar

Moore, J. J., Kurz, R., Garcia-Hernandez, A., and Brun, K. (2009). “Experimental Evaluation of the Transient Behavior of a Compressor Station During Emergency Shutdowns.” Paper GT2009–59064, TurboEXPO 2009, Orlando, FL, June.CrossRef Google Scholar

NGC+ (2005). White Paper on Natural Gas Interchangeability and Non-Combustion End Use.

Ni, M. et al. (2006). “An Overview of Hydrogen Production From Biomass.” Fuel Processing Technology 87: 461–72.CrossRef Google Scholar

Nigam, P. S., and Singh, A. (2011). “Production of Liquid Biofuels from Renewable Sources.” Progress in Energy and Combustion Science, 37(1): 52–68.CrossRef Google Scholar

Notari, B. (1991). “C-1 Chemistry, A Critical Review.” Catalytic Science and Technology 1: 55–76.Google Scholar

Peschke, W. T., and Spadaccini, L. J. (1985). “Determination of Autoignition and Flame Speed Characteristics of Coal Gases Having Medium Heating Values.” Final Report for AP-4291 Research Project 2357–1, November.

Petersen, E. L., Kalitan, D. M., Barrett, A. B., Reehal, S. C., Mertens, J. D., Beerer, D. J., Hack, R. L., and McDonell, V. G. (2007). “New Syngas/Air Ignition Data at Lower Temperature and Elevated Pressure and Comparison to Current Kinetics Models.” Combustion and. Flame 149(1–2): 244–7.CrossRef Google Scholar

Rayleigh, J. S. W. (1945). The Theory of Sound, Vol. 2, Dover: New York.Google Scholar

Reale, M. J. (2004). “New High Efficiency Simple Cycle Gas Turbine – GE’s LMS100TM.” GER-4222A, June.

Rao, A. D., Francuz, D. J., and West, E. W. (1996). “Refinery Gas Waste Heat Energy Conversion Optimization in Gas Turbines.” IJPGC Conference, pp. 473–83.Google Scholar

Richards, G. A., McMillian, M. M., Gemmen, R. S., Rogers, W. A., and Cully, S. R. (2001). “Issues for Low-Emission, Fuel-Flexible Power System.” Progress in Energy and Combustion Science. 27: 141–69.CrossRef Google Scholar

Rizk, N. K., and Lefebvre, A. H. (1986). “Relationship between Flame Stability and Drag of Bluff-body Flameholders.” Journal of Propulsion and Power 2(4): 361.Google Scholar

Rocca, E., Steinmetz, P. and Moliere, M. (2003). “Revisiting the Inhibition of Vanadium-Induced Hot Corrosion in Gas Turbines.” Journal of Engineering for Gas Turbines and Power 125: 664.CrossRef Google Scholar

Rojey, A., Jaffret, C., Cornot-Gandolphe, S., Durand, B, Jullian, S., and Valais, M. (1994). Natural Gas Production, Processing, Transport, Imprimerie Nouvelle, Paris.Google Scholar

Rukes, B. and Taud, R. (2004). Status and Perspectives of Fossil Fuel Power Generation, Energy 29: 1853–74.CrossRef Google Scholar

Ryan, N. E., Larsen, K. M., and Black, P. C. (2002). “Smaller, Closer, Dirtier, Diesel Backup Generators in California.” Environmental Defense Fund Report.Google Scholar

Schäfer, O., Koch, R., and Wittig, S. (2001). “Flashback in Lean Prevaporized Premixed Combustion: Non-swirling Turbulent Pipe Flow Study.” ASME Paper 2001-GT-0053.CrossRef

Schelkin, K. I. (1943). “On Combustion in Turbulent Flow.” Zh.Tekh. Fiz 13: 520–30.Google Scholar

Shanbhogue, S. J., Husain, S., and Lieuwen, T. C. (2010). “Lean Blowoff of Bluff Body Stabilized Flames: Scaling and Dynamics.” Progress in Energy and Combustion Science 35: 98–120.CrossRef Google Scholar

Singer, B. C. (2007). “Natural Gas Variability in California: Environmental Impacts and Device Performance – Literature Review and Evaluation for Residential Appliances.” Report CEC-500–2006–110, February.

Soares, C. (2008). Gas Turbines, A Handbook of Air, Land, and Sea Applications, Elsevier, London.Google Scholar

Standby Systems, Inc. (2001–6). Propane Peak Shaving…an Overview.

Spath, P. L., and Dayton, D. C. (2003). “Preliminary Screening – Technical and Economic Assessment of Synthesis Gas to Fuels and Chemicals with Emphasis on the Potential for Biomass-Derived Syngas.” National Renewable Energy Laboratory.

Stephens-Romero, S., Carreras-Sospedra, M., Brouwer, J., Dabdub, D., and Samuelsen, S. (2009). “Determining Air Quality and Greenhouse Gas Impacts of Hydrogen Infrastructure and Fuel Cell Vehicles, Environmental Science and Technology.” online November 5.CrossRef Google Scholar PubMed

Stiegel, G. J., and Ramezan, M. (2006). “Hydrogen from Coal Gasification: An Economical Pathway to a Sustainable Energy Future.” International Journal of Coal Geology 65: 173–90.CrossRef Google Scholar

Tillman, D. A. and Harding, N. S. (2004). Fuel of Opportunity: Characteristics and Uses in Combustion Systems, Elsevier, Oxford.Google Scholar

Trommer, D. et al. (2005). “Hydrogen Production by Steam-Gasification of Petroleum Coke Using Concentrated Solar Power – I. Thermodynamic and Kinetic Analyses.” International Journal of Hydrogen Energy 30: 605–18.CrossRef Google Scholar

Walsh, P. P., and Fletcher, P. (2004). Gas Turbine Performance, 2nd Edition, Blackwell Publishing, Oxford.CrossRef Google Scholar

Wender, I. (1996). “Reactions of Synthesis Gas.” Fuel Processing Technology 48: 189–297.CrossRef Google Scholar

Wohl, K. (1952) “Quenching, Flash-Back, Blow-Off Theory and Experiment.” 4th Symposium (Int.) on Combustion, pp. 69–89.Google Scholar

Wright, F. H. (1959). “Bluff-body Stabilization: Blockage Effects.” Combustion and Flame 3: 319–37.CrossRef Google Scholar

Zinn, B. T., and Lieuwen, T. C. (2005). “Combustion Instabilities: Basic Concepts,” in Combustion Instabilities in Gas Turbine Engines. AIAA Press.Google Scholar

Zou, J. H. et al. (2007). “Modeling Reaction Kinetics of Petroleum Coke Gasification with CO2.” Chemical Engineering and Processing 46: 630–6.CrossRef Google Scholar

Zukoski, E. E. and Marble, F. E. (1955). “The Role of Wake Transition in the Process of Flame Stabilization on Bluff Bodies.” AGARD Combustion Research and Reviews, p. 167.Google Scholar

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