Thermodynamic Analysis and Comparison of Power Cycles for Small Modular Reactors

Kindra, Vladimir; Maksimov, Igor; Zlyvko, Olga; Rogalev, Andrey; Rogalev, Nikolay

doi:10.3390/en17071650

Cited by 1 publication

(1 citation statement)

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“…In study [16], power cycles for a lead-bismuth molten nuclear micro-reactor are addressed: the efficiency of different variations of Rankine cycles with an organic coolant, as well as the Bryton recompression cycle on carbon dioxide was analyzed. It was concluded that the recompression cycle becomes more efficient at an initial temperature above 460 • C. In [17], it is concluded that the use of the S-CO 2 recompression cycle for small modular reactors may be feasible at initial temperatures above 550 • C; however, pressure losses in heat exchangers have a significant impact on energy efficiency.…”

Section: Supercritical Carbon Dioxide Power Cyclesmentioning

confidence: 99%

Thermodynamic Analysis and Optimization of Binary CO2-Organic Rankine Power Cycles for Small Modular Reactors

Kindra,

Maksimov,

Patorkin

et al. 2024

Energies

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Small nuclear power plants are a promising direction of research for the development of carbon-free energy in isolated power systems and in remote regions with undeveloped infrastructure. Improving the efficiency of power units integrated with small modular reactors will improve the prospects for the commercialization of such projects. Power cycles based on supercritical carbon dioxide are an effective solution for nuclear power plants that use reactor facilities with an initial coolant temperature above 550 °C. However, the presence of low temperature rejected heat sources in closed Bryton cycles indicates a potential for energy saving. This paper presents a comprehensive thermodynamic analysis of the integration of an additional low-temperature organic Rankine cycle for heat recovery to supercritical carbon dioxide cycles. A scheme for sequential heat recovery from several sources in S-CO2 cycles is proposed. It was found that the use of R134a improved the power of the low-temperature circuit. It was revealed that in the S-CO2 Brayton cycle with a recuperator, the ORC add-on increased the net efficiency by an average of 2.98%, and in the recompression cycle by 1.7–2.2%. With sequential heat recovery in the recuperative cycle from the intercooling of the compressor and the main cooler, the increase in efficiency from the ORC superstructure will be 1.8%.

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Section: Supercritical Carbon Dioxide Power Cyclesmentioning

confidence: 99%