Trends and perspectives of heavy duty gas turbine and combined cycle technology

• Autorzy: Badyda K.
• Konferencja: International Symposium on Compressor & Turbine Flow Systems Theory & Application Areas "SYMKOM" (11 ; 20-23.10.2014 ; Łódź, Polska)
• Języki publikacji: EN

Abstrakty

EN

Information about the state of technology development of heavy duty gas turbines for power generation applications with particular attention to the progress observed in recent years is presented. Evaluation of current gas turbine and combined cycle market (key manufacturers, largest units, efficiency, emissions) is submitted. Examples of technical solutions in response to the key challenges associated with the development of technology and gas turbine market (parameter increasing of the working medium, the expectation of high flexibility, including the ability to work efficiently at partial load) are shown.

Słowa kluczowe

EN

power engineering; gas turbines; gas and steam combined cycle; technology progress

PL

energetyka cieplna; turbiny gazowe; układy gazowo-parowe; postęp technologii

• Wydawca: Wydawnictwo Politechniki Łódzkiej
• Czasopismo: Zeszyty Naukowe. Cieplne Maszyny Przepływowe - Turbomachinery / Politechnika Łódzka
• Rocznik: 2014
• Tom: nr 146
• Strony: 15--30
• Opis fizyczny: Bibliogr. 19 poz., wykr.

Twórcy

autor

Badyda K.

• Institute of Heat Engineering Warsaw University of Technology, Poland

Bibliografia

• [1] Tanaka Y., Nose M., Nakao M., Saitoh K., et al, Development of Low NOx Combustion System with EGR for 1700°C class Gas Turbine, Mitsubishi Heavy Industries Technical Review, Vol. 50, 1/2013.
• [2] Ishikawa M., Terauchi M., Komori T., Yasuraoka J., Development of High Efficiency Gas Turbine Combined Cycle Power Plant, Mitsubishi Heavy Industries Technical Reviev Vol. 45, 1/2008.
• [3] Ai T., Masada J., Ito E., Development of the High Efficiency and Flexible Gas Turbine M701F5 by Applying “J” Class Gas Turbine Technologies, Mitsubishi Heavy Industries Technical Review, Vol. 51, 1/2014.
• [4] Gas Turbine World Performance Specs, 30-th edition, January-February 2014, Vol.44, No 1.
• [5] Gas Turbine World 2007-2008 Handbook. Project, Planning, Pricing, Engineering, Construction and Maintenance, A Pequeot Publication, vol. 26.
• [6] Matta R.K., Mercer G.D., Tuthill R.S., Power Systems for the 21st Century – “H” Gas Turbine Combined-Cycles, GE Power Systems (GER-3935B).
• [7] Gas Turbine World Handbook 2013. Project, Planning, Pricing, Engineering, Construction and Maintenance, A Pequeot Publication, Vol. 30.
• [8] Badyda K., Iwański Z., Modern Heavy Duty Gas Turbines – Operation and Maintenance Conditions (in polish), Proceedings of V Konferencja Naukowo-Techniczna Energetyka Gazowa 2013, V2, 163-178.
• [9] FlexEfficiency *50 Combined Cycle Power Plant. Advanced power with a new standard of high efficiency and operational flexibility. GE Energy, http://www.ge-flexibility.com/solutions/flexefficiency-50-portfolio/index.html
• [10] Badyda K., Miller A., Energetyczne turbiny gazowe i układy z ich wykorzystaniem, Kaprint, Lublin, 2011, (second edition 2014).
• [11] Cornu L., Deleonardo G., Dreisbach T., Goldmeer J., et al., 9F Heavy Duty Gas Turbine Evolution White Paper, GE Energy, GEA 18576B, January 2012.
• [12] Gas Turbine World 2010 Handbook. Project, Planning, Pricing, Engineering, Construction and Maintenance, A Pequeot Publication, vol. 28.
• [13] Regulation of the Minister of Economy of 22 April 2011 concerning industrial plant emission standards (Dz.U.2001.95.558).
• [14] Directive 2010/75/EU of the European Parliament and of the Council of 24 November 2010 on industrial emissions (integrated pollution prevention and control, Official Journal of the European Union L 334, 17-119.
• [15] Best Available Techniques (BAT) Reference Document for the Large Combustion Plants. Industrial Emissions Directive 2010/75/EU, Integrated Pollution Prevention and Control JOINT RESEARCH CENTRE, Institute for Prospective Technological Studies Sustainable Production and Consumption Unit European IPPC Bureau, Draft 1 (June 2013).
• [16] Järpner Ch., Movaghar A., Thorbergsson E., Grönstedt T., An assessment of cooled air cooling for combined cycle gas turbines, 5th International Conference on Applied Energy, Energy Solutions for Sustainable World, Pretoria, South Africa 1-4.VII.2013.
• [17] Badyda K., Trends, Conditions and Prospects for the Construction of New Gas Turbine Combined Cycle Plants in Poland (in polish), Rynek Energii, 2013, 5 (108), 26-33.
• [18] Chmielniak T., Gas Turbines – Main Development Tendencies (in polish), Rynek Energii, 2014, 3 (112), 69-75.
• [19] Kotowicz J., Bartela Ł., The influence of change of the gas-steam heat and power plant loads on the thermodynamic characteristics (in polish). Rynek Energii, 2008, 5 45-50.