Nuclear Engineering and Technology

Korean Nuclear Society (한국원자력학회)
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Study on load tracking characteristics of closed Brayton conversion liquid metal cooled space nuclear power system

  • Received : 2023.06.04
  • Accepted : 2023.12.02
  • Published : 2024.05.25
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Abstract

It is vital to output the required electrical power following various task requirements when the space reactor power supply is operating in orbit. The dynamic performance of the closed Brayton cycle thermoelectric conversion system is initially studied and analyzed. Based on this, a load tracking power regulation method is developed for the liquid metal cooled space reactor power system, which takes into account the inlet temperature of the lithium on the hot side of the intermediate heat exchanger, the filling quantity of helium and xenon, and the input amount of the heat pipe radiator module. After comparing several methods, a power regulation method with fast response speed and strong system stability is obtained. Under various changes in power output, the dynamic response characteristics of the ultra-small liquid metal lithium-cooled space reactor concept scheme are analyzed. The transient operation process of 70 % load power shows that core power variation is within 30 % and core coolant temperature can operate at the set safety temperature. The second loop's helium-xenon working fluid has a 65K temperature change range and a 25 % filling quantity. The lithium at the radiator loop outlet changes by less than ±7 K, and the system's main key parameters change as expected, indicating safety. The core system uses less power during 30 % load power transient operation. According to the response characteristics of various system parameters, under low power operation conditions, the lithium working fluid temperature of the radiator circuit and the high-temperature heat pipe operation temperature are limiting conditions for low-power operation, and multiple system parameters must be coordinated to ensure that the radiator system does not condense the lithium working fluid and the heat pipe.

Keywords

Acknowledgement

We gratefully acknowledge the assistance of Hefei Institute of Physical Science, Chinese Academy of Sciences in providing the preliminary conceptual scheme of ultra-small solid-core SNRP. This project is supported by the National Key Research and Development Program of China (2018YFB190064) and the National Natural Science Foundation of China (12005162).

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