Performance analysis of a small lead-cooled fast reactor coupled with a copper-chloride cycle hydrogen production system

Abstract

Hydrogen is widely acknowledged as a pivotal energy carrier in the global transition towards sustainable energy. One promising approach to hydrogen production is method copper-chlorine cycle powered by nuclear energy. This article presents an innovative integrated system for small lead-cooled fast reactors that are coupled with a copper-chlorine cycle. To assess the performance of the entire system with regards to energy, exergy, and economics, comprehensive modeling, simulation, and analysis are conducted using the simulation tool Simulink. Furthermore, a comprehensive examination of key operating parameters was conducted to explore their impact on the system. The obtained results demonstrate the energy efficiency of system is 21.3 % and the exergy efficiency of system is 40.9 %. The overall system based on the small LFR can produce high-pressure compressed hydrogen gas at a rate of 2.34 g/s and generate 53.9 kW of electricity. According to the study, the levelized cost of energy production is determined to be $0.04252/kW·h. The specific energy cost is primarily influenced by equipment investment, including the costs associated with operating and maintaining the system. Notably, the small lead-cooled fast reactor and the copper-chlorine cycle plant represent the major capital investments within the system. This study provides valuable insights and serves as a significant reference for the future engineering applications of lead-cooled fast reactors coupled with copper-chlorine cycle hydrogen systems.