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Thermo-economic modeling of an indirectly coupled solid oxide fuel cell/gas turbine hybrid power plant |
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| Authors: | Denver F. Cheddie Renique Murray |
| Affiliation: | a Center for Energy Studies, University of Trinidad and Tobago, Point Lisas Campus, Esperanza Road, Brechin Castle, Couva, Trinidad and Tobago b Natural Gas Institute of the Americas, University of Trinidad and Tobago, Point Lisas Campus, Esperanza Road, Brechin Castle, Couva, Trinidad and Tobago |
| Abstract: | Power generation using gas turbine (GT) power plants operating on the Brayton cycle suffers from low efficiencies, resulting in poor fuel to power conversion. A solid oxide fuel cell (SOFC) is proposed for integration into a 10 MW gas turbine power plant, operating at 30% efficiency, in order to improve system efficiencies and economics. The SOFC system is indirectly coupled to the gas turbine power plant, paying careful attention to minimize the disruption to the GT operation. A thermo-economic model is developed for the hybrid power plant, and predicts an optimized power output of 20.6 MW at 49.9% efficiency. The model also predicts a break-even per-unit energy cost of USD 4.65 ¢ kWh−1 for the hybrid system based on futuristic mass generation SOFC costs. This shows that SOFCs may be indirectly integrated into existing GT power systems to improve their thermodynamic and economic performance. |
| Keywords: | AB, after burner AC, air compressor FC, fuel compressor GT, gas turbine HX, heat exchanger MX, mixer NPV, net present value (USD) PR, pre-reformer SOFC, solid oxide fuel cell |
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