한국유체기계학회 논문집 (The KSFM Journal of Fluid Machinery)

한국유체기계학회 (Korean Society for Fluid machinery)
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바이오 가스를 연료로 사용하는 증기분사 가스터빈 열병합발전 시스템의 성능분석

Performance evaluation of a steam injected gas turbine CHP system using biogas as fuel

  • 투고 : 2010.09.20
  • 심사 : 2010.10.20
  • 발행 : 2010.12.01
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초록

MW-class gas turbines are suitable for distributed generation systems such as community energy systems(CES). Recently, biogas is acknowledged as an alternative energy source, and its use in gas turbines is expected to increase. Steam injection is an effective way to improve performance of gas turbines. This study intended to examine the influence of injecting steam and using biogas as the fuel on the operation and performance a gas turbine combined heat and power (CHP) system. A commercial gas turbine of 6 MW class was used for this study. The primary concern of this study is a comparative analysis of system performance in a wide biogas composition range. In addition, the effect of steam temperature and injected steam rate on gas turbine and CHP performance was investigated.

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참고문헌

  1. Bruno, J. C. and Coronas, A,. 2004, "Distributed Generation of Energy using Micro Gas Turbines : Polygeneration Systems and Fuel Flexibility," Proceedings of the International Conference on Renewable Energy and Power Quality (ICREPQ'04).
  2. Lepszy, S. and Chmielniak, T., 2008, "Analysis of The Biomass Integrated Combined Cycles with Two Different Structures of Gas Turbines," ASME paper GT2008-50317.
  3. Rodrigues M, Walter A and Faaij A, 2007, "Performance Evaluation of Atmospheric Biomass Integrated Gasifier Combined Cycle Systems Under Different Strategies for The Use of Low Calorific Gases," Energy Coversion and Management. Vol. 48, pp. 1289-1301. https://doi.org/10.1016/j.enconman.2006.09.016
  4. Colantoni, S., Gatta, S. D., De Prosperis, R., Russo, A., Fantozzi, F. and Desideri, U., 2009, "Gas Turbine Fired with Biomass Pyrolysis Syngas : Analysis of The Overheating of Hot Gas Path Components," ASME paper GT2009-59476.
  5. Fagbenle, R. L., Oguaka, A. B. C. and Olakoyejo O. T., 2007, "A Thermodynamic Analysis of a Biogas-fired Integrated Gasification Steam Injected Gas Turbine (BIG/STIG) Plant," Applied Thermal Engineering, Vol. 27, pp. 2220-2225. https://doi.org/10.1016/j.applthermaleng.2005.07.027
  6. Fischer, C. A., Frutschi, U. H. and Haselbacher, H., 2001, "Augmentation of Gas Turbine Power Output by Steam Injection," ASME paper 2001-GT-0107.
  7. Lee, J. J., Jeon, M. S. and Kim, T. S., 2010, "The Influence of Water and Steam Injection on the Performance of a Recuperated Cycle Microturbine for Combined Heat and Power Application," Applied Energy, Vol. 87, pp. 1307-1316. https://doi.org/10.1016/j.apenergy.2009.07.012
  8. 김동섭, 조문기, 노승탁, 고상근, 1997, "열회수를 고려한 소형 증기분사 가스터빈 시스템 해석," 대한기계학회 논문집, 제21권, 제8호, pp. 996-1008.
  9. Enter Software. GateCycle ver 6.0, 2006.
  10. Rocha, G., Reynolds, S. and Brown, T., "Introduction of The TaurusTM 65 Industrial Gas Turbine for Power Generation," ASME paper GT2008-51328.
  11. Palmer, C.A. and Erbes, M.R., 1994, "Simulation Methods Used to Analyze The Performance of the GE PG6541B Gas Turbine Utilizing Low Heating Value Fuels," ASME IGTI Cogen-Turbo, IGTI-Vol. 9 pp. 337-346.
  12. Erbes, M. R. and Gay, R. R., 1989, "GATE/CYCLE Predictions of The Off Design Performance of Combined Cycle Power Plants," Simulation of Thermal Energy Systems, ASME AES Vol. 6/HTD Vol. 124, pp. 43-51.
  13. Brun, K. and Simmons, H., "Aerodynamic Instability and Life Limiting Effects of Inlet and Interstage Water Injection into Gas Turbines," ASME paper GT2005-68007.