📝 SummarXiv

Abstract

Nuclear power plants are prominent examples of heat-to-work conversion systems, and optimizing their thermodynamic performance offers significant potential for enhancing energy efficiency. With a development history of less than a century, optimization trends in nuclear power plants indicate that classical thermodynamics alone may be insufficient, particularly when maximizing output power rather than efficiency becomes the primary focus. This paper re-examines nuclear power plant thermodynamic cycles through the lens of finite-time thermodynamics, an approach specifically developed to address the practical requirement of enhancing power output. Beginning with the simpler Brayton cycle without phase transitions, we obtain the famous Curzon-Ahlborn formula for efficiency at maximum power. Subsequently we analyze the more complex Rankine cycle, which incorporates phase transitions. By explicitly considering the working fluid undergoing phase transitions within the cycle, we uncover the inherent trade-off between output power and efficiency. Additionally, we demonstrate that both the maximum attainable power and efficiency increase as latent heat rises. These findings shall provide insights and methodologies for future thermodynamic optimization of nuclear power plants and other Rankine-type cycle systems.