After the renewed interest in supercritical carbon dioxide cycles, a large number of cycle layouts have been proposed in literature. These works, which are essentially theoretical, consider different operating conditions and modeling assumptions, and thus, the results are not comparable. There are also works that aim to provide a fair comparison between different cycles in order to assess which one is most efficient. These analyses are very interesting but, usually, they combine thermodynamic and technical restrictions, which make it difficult to draw solid and general conclusions with regard to which the cycle of choice in the future should be. With this background, the present work provides a systematic thermodynamic analysis of 12 supercritical carbon dioxide cycles under similar working conditions, with and without technical restriction in terms of pressure and/or temperature. This yields very interesting conclusions regarding the most interesting cycles in the literature. Also, useful recommendations are extracted from the parametric analysis with respect to the directions that must be followed when searching for more efficient cycles. The analysis is based on efficiency and specific work diagrams with respect to pressure ratio and turbine inlet temperature in order to enhance its applicability to plant designs driven by fuel economy and/or footprint.
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Analysis of the Thermodynamic Potential of Supercritical Carbon Dioxide Cycles: A Systematic Approach
Francesco Crespi,
Francesco Crespi
Department of Energy Engineering,
University of Seville,
Camino de los descubrimientos s/n,
Seville 41092, Spain
e-mail: crespi@us.es
University of Seville,
Camino de los descubrimientos s/n,
Seville 41092, Spain
e-mail: crespi@us.es
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Giacomo Gavagnin,
Giacomo Gavagnin
Department of Energy Engineering,
University of Seville,
Camino de los descubrimientos s/n,
Seville 41092, Spain
e-mail: gavagnin@us.es
University of Seville,
Camino de los descubrimientos s/n,
Seville 41092, Spain
e-mail: gavagnin@us.es
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David Sánchez,
David Sánchez
Department of Energy Engineering,
University of Seville,
Camino de los descubrimientos s/n,
Seville 41092, Spain
e-mail: ds@us.es
University of Seville,
Camino de los descubrimientos s/n,
Seville 41092, Spain
e-mail: ds@us.es
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Gonzalo S. Martínez
Gonzalo S. Martínez
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Francesco Crespi
Department of Energy Engineering,
University of Seville,
Camino de los descubrimientos s/n,
Seville 41092, Spain
e-mail: crespi@us.es
University of Seville,
Camino de los descubrimientos s/n,
Seville 41092, Spain
e-mail: crespi@us.es
Giacomo Gavagnin
Department of Energy Engineering,
University of Seville,
Camino de los descubrimientos s/n,
Seville 41092, Spain
e-mail: gavagnin@us.es
University of Seville,
Camino de los descubrimientos s/n,
Seville 41092, Spain
e-mail: gavagnin@us.es
David Sánchez
Department of Energy Engineering,
University of Seville,
Camino de los descubrimientos s/n,
Seville 41092, Spain
e-mail: ds@us.es
University of Seville,
Camino de los descubrimientos s/n,
Seville 41092, Spain
e-mail: ds@us.es
Gonzalo S. Martínez
1Corresponding author.
Contributed by the Cycle Innovations Committee of ASME for publication in the JOURNAL OF ENGINEERING FOR GAS TURBINES AND POWER. Manuscript received July 12, 2017; final manuscript received August 8, 2017; published online November 14, 2017. Editor: David Wisler.
J. Eng. Gas Turbines Power. May 2018, 140(5): 051701 (10 pages)
Published Online: November 14, 2017
Article history
Received:
July 12, 2017
Revised:
August 8, 2017
Citation
Crespi, F., Gavagnin, G., Sánchez, D., and Martínez, G. S. (November 14, 2017). "Analysis of the Thermodynamic Potential of Supercritical Carbon Dioxide Cycles: A Systematic Approach." ASME. J. Eng. Gas Turbines Power. May 2018; 140(5): 051701. https://doi.org/10.1115/1.4038125
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