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Exergy, Exergy Destruction Rate and Exergy Efficiency Analysis of Thermal Power Plants by a Computer Software at Various Operating Conditions

Ankur Geete*

Associate Professor, Department of Mechanical Engineering, Sushila Devi Bansal College of Technology, Indore, Madhya Pradesh, India.

Periodicity:August - October'2015
DOI : https://doi.org/10.26634/jfet.11.1.3655

Abstract

This research work is based on coal fired thermal power plant. Component wise exergy, exergy destruction rates and exergy efficiencies are evaluated for the power plant. The component/device which has higher exergy, higher exergy destruction rate or which has lower exergy efficiency is identified. This work can be analyzed by manual calculations, but this method is hectic and also has chance of human error. So a computer software is designed for component wise analysis at various operating conditions. This software is also used to analyze exergy, exergy destruction rate and exergy efficiency for other coal fired thermal power plants. This work can be concluded as, maximum exergy destruction occurs in boiler for both plants, and maximum second law efficiency is achieved in steam turbine. Therefore, when amount of fuel used in the boiler increases, the exergy destruction rate increases and second law efficiency decreases. Effects of different ambient temperatures on the performance of the plants are observed, and for condenser, if mass flow rate of circulating water increases then the exergy destruction rate decreases and second law efficiency increases.

Keywords

Exergy, Exergy Destruction Rate, Exergy Efficiency, Power Plants, Computer Software.

How to Cite this Article?

Geete, A. (2015). Exergy, Exergy Destruction Rate and Exergy Efficiency Analysis of Thermal Power Plants by Computer Software at Various Operating Conditions. i-manager’s Journal on Future Engineering and Technology, 11(1), 8-22. https://doi.org/10.26634/jfet.11.1.3655

References

[1]. Yadav R., (2009). Steam and Gas Turbine and Power Plant Engineering, 7th ed., Central Publishing House, Allahabad, pp.58-60.

[2]. Nag P. K., (2009). Engineering Thermodynamics, 3rd ed., Tata Mcgraw Hill, New Delhi, pp.192-194.

[3]. Cotton K. C., (1993). Evaluating & Improving Steam Turbine Performance, 2nd ed., Cotton Fact Inc. Rexford, NY 12148 USA.

[4]. BHEL, (2010). “Document from Steam turbine engineering department, STE Department”, BHEL, Bhopal, Madhya Pradesh.

[ 5 ] . C e n g e l Y. A . , a n d M i c h a e l A . , ( 2 0 0 6 ) . Thermodynamics an engineering approach, 2nd ed., New Delhi: Tata McGraw Hill.

[6]. Kaushik S. C., Reddy Siva V., and Tyagi S. K., (2011). “Energy and Exergy analyses of Thermal Power Plants : A Review”, International Journal of Renewable and Sustainable Energy Reviews, Vol.15, pp.1857-1872.

[7]. Guoqiang Lv., Hua Wang, Wenhui Ma, and Chunwei Yu, (2011). “Energy and Exergy Analysis for 300 MW Thermal System of Xiaolongtan Power Plant”, Proceedings of the 2011 International Conference on Computer Distributed Control and Intelligent Environmental Monitoring, pp.180-184.

[8]. Ehsan Amirabedin, and Yilmazoglu M. Zeki, (2011). “Design and Exergy Analysis of a Thermal Power Plant Using Different Types of Turkish Lignite”, International Journal of Thermodynamics (IJoT), Vol.14, No.3, pp.125-133.

[9]. Vosough Amir, (2012). “Improving Steam Power Plant E f f i c i e n c y t h r o u g h E x e r g y A n a l y s i s : A m b i e n t Temperature”, 2nd International Conference on Mechanical, Production and Automobile Engineering (ICMPAE'2012), Singapore, pp 209-212.

[10]. Mali D. Sanjay, and Mehta N. S., (2012). “Easy Method of Exergy Analysis For Thermal Power Plant”, International Journal of Advanced Engineering Research and Studies (IJAERS), Vol.1, No.3, ISSN 2249–8974, pp.245- 247.

[11]. Sachdeva Bala Kiran, and Karun, (2012). “Performance Optimization of Steam Power Plant Through Energy and Exergy Analysis”, International Journal of Current Engineering and Technology, Vol.2, No.3, pp.285-289.

[12]. Geete A., and Khandwawala A. I., (2013). “Thermodynamic Analysis of 120MW Thermal Power Plant with Combined Effect of Constant Inlet Pressure (124.61 bar) and Different Inlet Temperatures”, Case Studies in Thermal Engineering, Vol.1, No.1, pp.17-25.

[13]. Geete A., and Khandwawala A. I., (2014). “Exergy Analysis for 120MW Thermal Power Plant with Different Inlet Temperature Conditions”, International Journal of Research in Engineering and Technology, Vol.2, No.1, pp.21-30.

[14]. Geete A., and Khandwawala A. I., (2014). “Exergy Analysis For 120mw Thermal Power Plant With Different Inlet Pressure Conditions And Generate Exergy Outlet Curves For Different Components”, Asian Academic Research Journal of Multidisciplinary, Vol.1, No.18, pp.234-247.

[15]. Geete A., and Khandwawala A. I., (2013). “Exergy Analysis of 120 MW Thermal Power Plant With Different Condenser Back Pressure and Generate Correction Curves”, International Journal of Current Engineering and Technology, ISSN 2277-4106, Vol.3, No.1, pp.164-167.

[16]. Steven H., (2000). Visual Basic 6.0 Programming Black Book, 1st ed., Dreamtech Press publication.

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Exergy, Exergy Destruction Rate and Exergy Efficiency Analysis of Thermal Power Plants by a Computer Software at Various Operating Conditions

Abstract

Keywords

How to Cite this Article?

References

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