Thermodynamic Performance Assessment of a Bio-gasification Based Small-scale Combined Cogeneration Plant Employing Indirectly Heated Gas Turbine

Pradip Mondal; Dr. Sudip Ghosh

Thermodynamic Performance Assessment of a Bio-gasification Based Small-scale Combined Cogeneration Plant Employing Indirectly Heated Gas Turbine

Year 2015, Volume: 5 Issue: 2, 354 - 366, 01.06.2015

Abstract

Thermodynamic model development of biomass gasification based indirectly heated combined cogeneration plant and its simulated performance is reported in this present study. Saw dust is considered as biomass feed, which undergoes gasification in a downdraft gasifier and the producer gas is combusted in a combustor-heat exchanger duplex (CHX) unit. The CHX unit heats up air for a 100 kWe Gas Turbine (GT) and the exhaust heat of CHX unit is utilized in generating bottoming steam turbine work output and utility steam. The performance of the plant is assessed over a wide range pressure ratio (rp) and turbine inlet temperature (TIT) for the GT block, as well as, by varying the steam turbine inlet pressure and temperature along with the outlet gas side temperature of the economizer. For the base case configuration (rp= 4 and TIT=1000 deg C) the plant gives an overall electrical efficiency of about 41% and, at the same time, produces utility steam at a rate of about 180 kg/hr. Its cogeneration performance, expressed in terms of fuel energy saving ratio (FESR), is found to optimize at particular values of topping cycle pressure ratio for different TITs. The study also includes discussion on the sizing of the major plant components. Further, a Second law analysis of the plant concludes that maximum exergy destruction takes place at the gasifier, followed by the CHX unit, together accounting for nearly 40% of the fuel exergy input.

Keywords

Bio-gasification; Indirectly heated; Combined cogeneration; Fuel energy saving ratio; exergy

References

B. Buragohain, P. Mahanta, and V.S. Moholkar, “Biomass gasification for decentralized power generation: The Indian perspective”, Renewable and Sustainable Energy Reviews, Vol. 14, pp. 73-92, 2010. (Article) doi:10.1016/j.rser.2009.07.034
Ankur Scientific Energy Technologies Pvt. Ltd. Website: http://www.ankurscientific.com/ (website)
C. Syred, W. Fick, A. J. Griffiths, and N. Syred, “Cyclone gasifier and cycle combustor for the use of biomass derived gas in the operation of a small gas turbine in co-generation plant”, Fuel, Vol. 83, pp. 2381-2392, 2000. (Article)
A. Bhattacharya, D. Manna, B. Paul, and A Datta, “Biomass integrated gasification combined cycle power generation with supplementary biomass firing: Energy and exergy based performance analysis”, Energy, Vol. 36, pp. 2599-2610, 2011. (Article) doi:10.1016/j.energy.2011.01.054
Yap, and M. Roy, Biomass integrated gasification combined cycles (BIGCC), University of New Orleans Theses and Dissertations, Paper 206, 2004. (Report)
N.S. Barman, S. Ghosh, and S. De, “Gasification of biomass in a fixed bed downdraft gasifier-A realistic model including tar”, Bioresource Technology, Vol. 107, doi:10.1016/j.biortech.2011.12.124 2012. (Article)
A. Datta, R. Ganguli, and L. Sarkar, “Energy and exergy analyses of an externally fired gas turbine (egft), cycle integrated with biomass gasifier for distributed power generation”, Energy, Vol. 35, pp. 341-350, 2010. (Article)
P. Mondal, and S. Ghosh, “Biomass based indirectly heated combined cycle plant: Energetic and exergetic performance analyses”, International Journal of Innovative Research in Science, Engineering and Technology, Vol. 3, Issue 2, pp. 9285-9294, 2014. (Article)
K.A. Al-attab, and Z.A. Zainal, “Performance of high- temperature heat exchangers in biomass fuel powered externally fired gas turbine systems”, Renewable Energy, Vol. 35, pp. 913–920, 2010. (Article) doi:10.1016/j.renene.2009.11.038
S. Soltani, S.M.S. Mahamoudi, M. Yari, and M.A. Rosen, “Thermodynamic analyses of an externally fired gas turbine combined cycle integrated with biomass gasification plant”, Energy Conversion and Management, Vol. 70, pp. 107-115, 2013. (Article) doi:10.1016/j.enconman.2013.03.002
Cycle-Tempo Software, Release 5 (TU Delft), 2012 (Available: http://www.cycle-tempo.nl/.) (Website)
J. H. Horlock, Cogeneration-Combined Heat and Power (CHP), Pergamon Press, New York, 1987. (Book)
S. Ghosh, and S. De, “First and second law performance variations of coal gasification fuel-cell based combined cogeneration plant with varying load”, Proceedings of the Institution of Mechanical Engineers, Part A, Journal of Power and Energy, pp. 477-485, 2004. (Article)
M. J Moran, “Availability Analysis: A Guide to Efficient Energy Use”, Prentice-Hall, Englewood Cliffs, New Jersey, 1982 (Book)

Year 2015, Volume: 5 Issue: 2, 354 - 366, 01.06.2015

Pradip Mondal Dr. Sudip Ghosh

Abstract

References

B. Buragohain, P. Mahanta, and V.S. Moholkar, “Biomass gasification for decentralized power generation: The Indian perspective”, Renewable and Sustainable Energy Reviews, Vol. 14, pp. 73-92, 2010. (Article) doi:10.1016/j.rser.2009.07.034
Ankur Scientific Energy Technologies Pvt. Ltd. Website: http://www.ankurscientific.com/ (website)
C. Syred, W. Fick, A. J. Griffiths, and N. Syred, “Cyclone gasifier and cycle combustor for the use of biomass derived gas in the operation of a small gas turbine in co-generation plant”, Fuel, Vol. 83, pp. 2381-2392, 2000. (Article)
A. Bhattacharya, D. Manna, B. Paul, and A Datta, “Biomass integrated gasification combined cycle power generation with supplementary biomass firing: Energy and exergy based performance analysis”, Energy, Vol. 36, pp. 2599-2610, 2011. (Article) doi:10.1016/j.energy.2011.01.054
Yap, and M. Roy, Biomass integrated gasification combined cycles (BIGCC), University of New Orleans Theses and Dissertations, Paper 206, 2004. (Report)
N.S. Barman, S. Ghosh, and S. De, “Gasification of biomass in a fixed bed downdraft gasifier-A realistic model including tar”, Bioresource Technology, Vol. 107, doi:10.1016/j.biortech.2011.12.124 2012. (Article)
A. Datta, R. Ganguli, and L. Sarkar, “Energy and exergy analyses of an externally fired gas turbine (egft), cycle integrated with biomass gasifier for distributed power generation”, Energy, Vol. 35, pp. 341-350, 2010. (Article)
P. Mondal, and S. Ghosh, “Biomass based indirectly heated combined cycle plant: Energetic and exergetic performance analyses”, International Journal of Innovative Research in Science, Engineering and Technology, Vol. 3, Issue 2, pp. 9285-9294, 2014. (Article)
K.A. Al-attab, and Z.A. Zainal, “Performance of high- temperature heat exchangers in biomass fuel powered externally fired gas turbine systems”, Renewable Energy, Vol. 35, pp. 913–920, 2010. (Article) doi:10.1016/j.renene.2009.11.038
S. Soltani, S.M.S. Mahamoudi, M. Yari, and M.A. Rosen, “Thermodynamic analyses of an externally fired gas turbine combined cycle integrated with biomass gasification plant”, Energy Conversion and Management, Vol. 70, pp. 107-115, 2013. (Article) doi:10.1016/j.enconman.2013.03.002
Cycle-Tempo Software, Release 5 (TU Delft), 2012 (Available: http://www.cycle-tempo.nl/.) (Website)
J. H. Horlock, Cogeneration-Combined Heat and Power (CHP), Pergamon Press, New York, 1987. (Book)
S. Ghosh, and S. De, “First and second law performance variations of coal gasification fuel-cell based combined cogeneration plant with varying load”, Proceedings of the Institution of Mechanical Engineers, Part A, Journal of Power and Energy, pp. 477-485, 2004. (Article)
M. J Moran, “Availability Analysis: A Guide to Efficient Energy Use”, Prentice-Hall, Englewood Cliffs, New Jersey, 1982 (Book)

There are 14 citations in total.

Details

Primary Language	English
Journal Section	Articles
Authors	Pradip Mondal This is me Dr. Sudip Ghosh This is me
Publication Date	June 1, 2015
Published in Issue	Year 2015 Volume: 5 Issue: 2

Cite

APA	Mondal, P., & Ghosh, D. S. (2015). Thermodynamic Performance Assessment of a Bio-gasification Based Small-scale Combined Cogeneration Plant Employing Indirectly Heated Gas Turbine. International Journal Of Renewable Energy Research, 5(2), 354-366.
AMA	Mondal P, Ghosh DS. Thermodynamic Performance Assessment of a Bio-gasification Based Small-scale Combined Cogeneration Plant Employing Indirectly Heated Gas Turbine. International Journal Of Renewable Energy Research. June 2015;5(2):354-366.
Chicago	Mondal, Pradip, and Dr. Sudip Ghosh. “Thermodynamic Performance Assessment of a Bio-Gasification Based Small-Scale Combined Cogeneration Plant Employing Indirectly Heated Gas Turbine”. International Journal Of Renewable Energy Research 5, no. 2 (June 2015): 354-66.
EndNote	Mondal P, Ghosh DS (June 1, 2015) Thermodynamic Performance Assessment of a Bio-gasification Based Small-scale Combined Cogeneration Plant Employing Indirectly Heated Gas Turbine. International Journal Of Renewable Energy Research 5 2 354–366.
IEEE	P. Mondal and D. S. Ghosh, “Thermodynamic Performance Assessment of a Bio-gasification Based Small-scale Combined Cogeneration Plant Employing Indirectly Heated Gas Turbine”, International Journal Of Renewable Energy Research, vol. 5, no. 2, pp. 354–366, 2015.
ISNAD	Mondal, Pradip - Ghosh, Dr. Sudip. “Thermodynamic Performance Assessment of a Bio-Gasification Based Small-Scale Combined Cogeneration Plant Employing Indirectly Heated Gas Turbine”. International Journal Of Renewable Energy Research 5/2 (June 2015), 354-366.
JAMA	Mondal P, Ghosh DS. Thermodynamic Performance Assessment of a Bio-gasification Based Small-scale Combined Cogeneration Plant Employing Indirectly Heated Gas Turbine. International Journal Of Renewable Energy Research. 2015;5:354–366.
MLA	Mondal, Pradip and Dr. Sudip Ghosh. “Thermodynamic Performance Assessment of a Bio-Gasification Based Small-Scale Combined Cogeneration Plant Employing Indirectly Heated Gas Turbine”. International Journal Of Renewable Energy Research, vol. 5, no. 2, 2015, pp. 354-66.
Vancouver	Mondal P, Ghosh DS. Thermodynamic Performance Assessment of a Bio-gasification Based Small-scale Combined Cogeneration Plant Employing Indirectly Heated Gas Turbine. International Journal Of Renewable Energy Research. 2015;5(2):354-66.