External Combustion of Biomass Parallelly Coupled with the Gas Turbine Unit

• Autorzy: Chmielniak T. , Lepszy S.
• Konferencja: International Symposium SYMKOM Compressor & Turbine Flow Systems, Treory & Application Areas (21-23.09.2005; Łódź; Polska)
• Języki publikacji: EN

Abstrakty

EN

The paper deals with three exemplary structures of gas turbine units with an external combustion of the biomass. The energy efficiency and the index indicating the effectiveness of conversion the chemical energy of the biomass into mechanical energy as a function of the amount of air flowing through a high-temperature heat exchanger are discussed.

Słowa kluczowe

EN

gas turbine; biomass; renewable fuel

• Wydawca: Wydawnictwo Politechniki Łódzkiej
• Czasopismo: Zeszyty Naukowe. Cieplne Maszyny Przepływowe - Turbomachinery / Politechnika Łódzka
• Rocznik: 2005
• Tom: nr 128, vol. 1
• Strony: 107--114
• Opis fizyczny: Bibliogr. 16 poz.

Twórcy

autor

Chmielniak T.

• Politechnika Śląska Instytut Maszyn i Urządzeń Energetycznych tel. (+4832) 237-11-15

autor

Lepszy S.

• Politechnika Śląska Instytut Maszyn i Urządzeń Energetycznych tel. (+4832) 237-11-15

Bibliografia

• [1] Elmegard B., et al.: Open-cycle Indirectly Fired Gas Turbine for Wet Biomass Fuels. Proceedings of ECOS 2001, 361-368, 2001.
• [2] Chmielniak T., Skorek G.: Biomass Fueled Gas Turbines Cycles: Heat Transfer and Renewable Souarces of Energy 2004, Międzyzdroje, wrzesień 8-11, 2004.
• [3] Ferreira S.B., Pilidis P.: On the Economics of the use of Biomass Fuels in gas Turbine Cycles: Gasification vs. Externally Firing. ASME Paper GT 2004-53220.
• [4] Traverso A. et al.: Demonstration Plant and Expected Performance of an Externally Fired Micro Gas Turbines for Distributed Power Generation. ASME Paper GT 2003-38268.
• [5] Elmegaard B., Qvale B.: Analysis of Indirectly Fired Gas Turbine for wet Biomass Fuels Based on Commercial Micro Gas Turbine Data. ASME Paper GT-2002-30016, 2002.
• [6] Eidensten L., Yan J., Svedberg G.: Biomass Externally Fired Gas Turbine Cogeneration. Trans.of ASME. J. of Engineering for Gas Turbines and Power. Vol 118, July 1996, 604-609.
• [7] O’Doherty T., Jolly A.J., Bates C.J.: Analysis of a bayonet tube heat exchanger. App. Thermal Engineering, 21, 2001, 1-18.
• [8] Chmielniak T.J., Skorek G.: Skojarzona produkcja ciepła i elektryczności z wykorzystaniem biomasy. Przegląd Elektrotechniczny LXXX, 9, 2004, 889-893.
• [9] Liscinsky D.S. et al.: Advanced Technology Biomass-Fueled Combined Cycle. ASME Paper GT 2003-38295, 2003.
• [10] Stähl K., Neergaardt M.: IGCC Power Plant for Biomass Utilization, Värnamo, Sweden. Biomass and Bioenergy Vol 15, 3, p. 205-211, 1998.
• [11] Bridgwater A.V.: The technical and economic feasibility of biomass gasification for power generation. Fuel Vol 74, 5, 631-653, 1995.
• [12] Faaij A. et al.: Gasification of Biomass Wastes and Residues for Electricity Production. Biomass and Bioenergy Vol 12, 6, 387-409, 1997.
• [13] Van der Drift A., de Kant H.F., Rojani J.B.: Commercialization Bivkin Based Gasification Technology. ECN-C-00-080, August 2000.
• [13] Kalina J., Skorek G., Cebula J.: Pozyskiwanie i energetyczne wykorzystanie biogazu z biogazowni rolniczych. Gospodarka Paliwami i Energia 11/2003.
• [15] Cousonni E.D., Larsen E.D.: Biomass-Gasifier/Aeroderivative Gas Turbine Combined Cycles. Part A and B. Trans. Of ASME, J. of Eng. For Gas Turbine and Power, Vol. 118, July 1996.
• [16] Belgiorno V., De Feo G., Della Rocca C.: Energy from Gasification of Solid Wastes. Waste Management 23, 2003, 1-15.