On the adoption of carbon dioxide thermodynamic cycles for nuclear power conversion: A case study applied to Mochovce 3 Nuclear Power Plant

Lorenzo Santini; Carlo Accornero; Andrea Cioncolini

doi:10.1016/j.apenergy.2016.08.046

On the adoption of carbon dioxide thermodynamic cycles for nuclear power conversion: A case study applied to Mochovce 3 Nuclear Power Plant

Lorenzo Santini^*, Carlo Accornero, Andrea Cioncolini

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

67 Scopus citations

Abstract

In this study, closed CO₂ cycles are investigated for potential application in existing nuclear power stations, referring in particular to Mochovce power station currently under construction in Slovak Republic. Three different CO₂ cycles layouts are explored in the range of temperatures offered by the nuclear source and of the existing cooling towers. The investigation shows that the common opinion that S-CO₂ cycles are well suited in the medium to a high temperature range only (higher than about 450 °C) seems unjustified. For a primary heat source with a maximum temperature of 299 °C and a heat sink with a minimum temperature of 19 °C and reasonable assumptions about advanced turbomachines and heat exchanger performances, the supercritical recompressed reheated regenerative CO₂ cycle would yield a net efficiency of 34.04%, which compares well with the 33.51% net efficiency of the existing Rankine cycle. The estimated length of the complete turboset (2 turbines, 1 pump and 1 compressor) would be less than 11 m (versus two wet steam turbines of 22 m each for the same power), resulting in a factor of 10 reduction in the footprint of the balance of plant. The total CO₂ cycle equipment and main pipelines would have a combined weight of 3957 tons, while in the Mochovce 3 NPP existing Rankine cycle, the main components and connecting piping weigh nearly 7377 tons, thus a 40% reduction. These results suggest that the adoption of CO₂ in nuclear power stations would not penalize the plant efficiency and would yield significant savings on installation costs and construction times from the much more compact balance of plant.

Original language	English
Pages (from-to)	446-463
Number of pages	18
Journal	Applied Energy
Volume	181
DOIs	https://doi.org/10.1016/j.apenergy.2016.08.046
State	Published - 1 Nov 2016
Externally published	Yes

Keywords

Carbon dioxide cycle
Energy conversion
Nuclear power
PWR
Supercritical CO
Thermodynamic cycle

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10.1016/j.apenergy.2016.08.046

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title = "On the adoption of carbon dioxide thermodynamic cycles for nuclear power conversion: A case study applied to Mochovce 3 Nuclear Power Plant",

abstract = "In this study, closed CO2 cycles are investigated for potential application in existing nuclear power stations, referring in particular to Mochovce power station currently under construction in Slovak Republic. Three different CO2 cycles layouts are explored in the range of temperatures offered by the nuclear source and of the existing cooling towers. The investigation shows that the common opinion that S-CO2 cycles are well suited in the medium to a high temperature range only (higher than about 450 °C) seems unjustified. For a primary heat source with a maximum temperature of 299 °C and a heat sink with a minimum temperature of 19 °C and reasonable assumptions about advanced turbomachines and heat exchanger performances, the supercritical recompressed reheated regenerative CO2 cycle would yield a net efficiency of 34.04%, which compares well with the 33.51% net efficiency of the existing Rankine cycle. The estimated length of the complete turboset (2 turbines, 1 pump and 1 compressor) would be less than 11 m (versus two wet steam turbines of 22 m each for the same power), resulting in a factor of 10 reduction in the footprint of the balance of plant. The total CO2 cycle equipment and main pipelines would have a combined weight of 3957 tons, while in the Mochovce 3 NPP existing Rankine cycle, the main components and connecting piping weigh nearly 7377 tons, thus a 40% reduction. These results suggest that the adoption of CO2 in nuclear power stations would not penalize the plant efficiency and would yield significant savings on installation costs and construction times from the much more compact balance of plant.",

keywords = "Carbon dioxide cycle, Energy conversion, Nuclear power, PWR, Supercritical CO, Thermodynamic cycle",

author = "Lorenzo Santini and Carlo Accornero and Andrea Cioncolini",

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AU - Santini, Lorenzo

AU - Accornero, Carlo

AU - Cioncolini, Andrea

PY - 2016/11/1

Y1 - 2016/11/1

N2 - In this study, closed CO2 cycles are investigated for potential application in existing nuclear power stations, referring in particular to Mochovce power station currently under construction in Slovak Republic. Three different CO2 cycles layouts are explored in the range of temperatures offered by the nuclear source and of the existing cooling towers. The investigation shows that the common opinion that S-CO2 cycles are well suited in the medium to a high temperature range only (higher than about 450 °C) seems unjustified. For a primary heat source with a maximum temperature of 299 °C and a heat sink with a minimum temperature of 19 °C and reasonable assumptions about advanced turbomachines and heat exchanger performances, the supercritical recompressed reheated regenerative CO2 cycle would yield a net efficiency of 34.04%, which compares well with the 33.51% net efficiency of the existing Rankine cycle. The estimated length of the complete turboset (2 turbines, 1 pump and 1 compressor) would be less than 11 m (versus two wet steam turbines of 22 m each for the same power), resulting in a factor of 10 reduction in the footprint of the balance of plant. The total CO2 cycle equipment and main pipelines would have a combined weight of 3957 tons, while in the Mochovce 3 NPP existing Rankine cycle, the main components and connecting piping weigh nearly 7377 tons, thus a 40% reduction. These results suggest that the adoption of CO2 in nuclear power stations would not penalize the plant efficiency and would yield significant savings on installation costs and construction times from the much more compact balance of plant.

AB - In this study, closed CO2 cycles are investigated for potential application in existing nuclear power stations, referring in particular to Mochovce power station currently under construction in Slovak Republic. Three different CO2 cycles layouts are explored in the range of temperatures offered by the nuclear source and of the existing cooling towers. The investigation shows that the common opinion that S-CO2 cycles are well suited in the medium to a high temperature range only (higher than about 450 °C) seems unjustified. For a primary heat source with a maximum temperature of 299 °C and a heat sink with a minimum temperature of 19 °C and reasonable assumptions about advanced turbomachines and heat exchanger performances, the supercritical recompressed reheated regenerative CO2 cycle would yield a net efficiency of 34.04%, which compares well with the 33.51% net efficiency of the existing Rankine cycle. The estimated length of the complete turboset (2 turbines, 1 pump and 1 compressor) would be less than 11 m (versus two wet steam turbines of 22 m each for the same power), resulting in a factor of 10 reduction in the footprint of the balance of plant. The total CO2 cycle equipment and main pipelines would have a combined weight of 3957 tons, while in the Mochovce 3 NPP existing Rankine cycle, the main components and connecting piping weigh nearly 7377 tons, thus a 40% reduction. These results suggest that the adoption of CO2 in nuclear power stations would not penalize the plant efficiency and would yield significant savings on installation costs and construction times from the much more compact balance of plant.

KW - Carbon dioxide cycle

KW - Energy conversion

KW - Nuclear power

KW - PWR

KW - Supercritical CO

KW - Thermodynamic cycle

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JO - Applied Energy

JF - Applied Energy

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On the adoption of carbon dioxide thermodynamic cycles for nuclear power conversion: A case study applied to Mochovce 3 Nuclear Power Plant

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Keywords

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