International Journal of Innovative Research in Engineering and Management
Year: 2017, Volume: 4, Issue: 3
First page : ( 658) Last page : ( 663)
Online ISSN : 2350-0557.
DOI: 10.21276/ijirem.2017.4.3.4 |
DOI URL: https://doi.org/10.21276/ijirem.2017.4.3.4
Crossref
This is an Open Access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0) (http://creativecommons.org/licenses/by/4.0)
Article Tools: Print the Abstract | Indexing metadata | How to cite item | Email this article | Post a Comment
Abhishek Kumar Sharma , Ankit Singhania , Ankit Kumar D, Ranendra Roy , Bijan Kumar Mandal
Gas turbine could play a key role in future power generation addressing issues of producing clean, efficient and fuel flexible power generation. In the field of energy generation, gas turbines have often been chosen in the past when fast start and shut down on demand is required. In this paper an attempt has been made to review research activities and studies carried out worldwide so far on gas turbine power plant. The historical development in chronological order has been presented first, followed by some fundamental features about gas turbine. This paper mainly reviews the effect of different operating parameters and atmospheric conditions on the performance of gas turbine power plant. Moreover, various studies based on the modeling and simulations have been reviewed. Research on gas turbines with evaporative coolers, heat exchangers and absorption chillers has also been assessed.
[1] Sharma, S., Sharma, A. and Sharma, M. 2015. Gas turbinescurrent scenario and future prospects in India. International Journal of Scientific & Engineering Research. 6, 8, 867 - 876.
[2] Olumayegun, O., Wanga, M. and Kelsall, G. 2016. Closedcycle gas turbine for power generation: A state-of-the-art review. Fuel. 180, 694–717.
[3] Keller, C. 1978. Forty years of experience on closed-cycle gas turbines. Annals of Nuclear Energy. 5, 405–422.
[4] Johnson, R. S. 1988. The theory and operation of evaporative coolers for industrial gas turbine installations. Journal of Engineering for Gas Turbines and Power. 111, 2, 327 – 334.
[5] Bird, J. and Grabe, W. 1991. Humidity effects on gas turbine performance. The American Society of Mechanical Engineers. 91 – GT – 329.
[6] Ondryas, I. S., Wilson, D. A., Kawamoto, M. and Haub, G. L. 1991. Options in gas turbine power augmentation using inlet air chilling, engineering for gas turbine and power. Journal of Engineering for Gas Turbines and Power. 113, 2, 203- 211.
[7] El-Hadik, A. A. 1990. The impact of atmospheric conditions on gas turbine performance. Journal of Engineering for Gas Turbines and Power. 112, 4, 590-596.
[8] Kakaras, E., Doukelis, A. and Karellas, S. 2004, Compressor intake-air cooling in gas turbine plants. Energy. 29, 12 – 15, 2347-2358.
[9] Petek, J. and Hamilton, P. P. 2005. Performance monitoring for gas turbines. GE Energy. 65-74.
[10] Farzaneh-Gord, M. and Deymi-Dashteba, M. 2009. Approach for enhancing performance of a gas turbine (Case study: Khangiran Refinery). Applied Energy. 86, 12, 2750,- 2759
[11] Ahmadi, P. and Dincer, I. 2011. Thermodynamic and exergoenvironmental analyses, and multi-objective optimization of a gas turbine power plant. Applied Thermal Engineering. 31, 14 – 15, 2529-2540
[12] Ameri, M. and Enadi, N. 2012. Thermodynamic modelling and second law based performance analysis of a gas turbine power plant (Exergy and Exergoeconomic Analysis). Journal of Power Technologies. 03, 183-191.
[13] Popli, S. Rodgers, P. and Eveloy, V. 2013. Gas turbine efficiency enhancement using waste heat powered absorption chillers in the oil and gas industry. Applied Thermal Engineering. 1, 918-931.
[14] Gopinath, V. and Navaneethakrishnan, G. 2013. Performance evaluation of gas turbine by reducing the inlet air temperature. International Journal of Technology Enhancements and Emerging Engineering Research. 1, 2347-4289.
[15] Jasim, M. M. and Tariq, M. 2014. Analysis of a combined regenerative and reheat gas turbine cycle using MATLAB. International Journal of Scientific Engineering and Technology Research. 03, 0665-0672.
[16] Mohanty, D. K. and Venkatesh, V. 2014. Performance analysis of a combined cycle gas turbine under varying operating conditions. Mechanical Engineering: An International Journal (MEIJ). 1, 23-35.
[17] Ghaderi, R. and Damircheli, M. 2014. Investigating factors affecting the efficiency of gas turbine power cycle. Scientific Journal of Pure and Applied Sciences. 3, 5, 271–279.
[18] Bade, M. H. and Bandyopadhyay, S. 2014. Analysis of gas turbine integrated cogeneration plant: Process integration approach. Applied Thermal Engineering. 78, 118-128.
[19] Hosseini, R., Beshkani, A. and Soltani, M. 2007. Performance improvement of gas turbines of Fars (Iran) combined cycle power plant by intake air cooling using a media evaporative cooler. Energy Conversion and Management. 48, 4, 1055–1064.
Department of Mechanical Engineering Indian Institute of Engineering Science and Technology, Shibpur Howrah – 711103, India
No. of Downloads: 8 | No. of Views: 982