Analysis of numerical studies on the thermal-hydraulic and neutronic thermal-hydraulic stability of supercritical water reactors

Artavazd M Sujyan,Vladimir S Kharitonov,Viktor I Deev

doi:10.3897/nucet.7.78368

Abstract

The paper presents a review of modern studies on the potential types of coolant flow instabilities in the supercritical water reactor core. These instabilities have a negative impact on the operational safety of nuclear power plants. Despite the impressive number of computational works devoted to this topic, there still remain unresolved problems. The main disadvantages of the models are associated with the use of one simulated channel instead of a system of two or more parallel channels, the lack consideration for neutronic feedbacks, and the problem of choosing the design ratios for the heat transfer coefficient and hydraulic resistance coefficient under conditions of supercritical water flow. For this reason, it was decided to conduct an analysis that will make it possible to highlight the indicated problems and, on their basis, to formulate general requirements for a model of a nuclear reactor with a light-water supercritical pressure coolant. Consideration is also given to the features of the coolant flow stability in the supercritical water reactor core. In conclusion, the authors note the importance of further computational work using complex models of neutronic thermal-hydraulic stability built on the basis of modern achievements in the field of neutron physics and thermal physics.

Highlights

An important task in the research of nuclear power plants is to determine the boundaries of their stable operation modes, which is necessary to ensure safety
There are two main types of stability related to supercritical pressure water reactors (SCWR): (1) thermal-hydraulic, which is characterized by the retention of operating parameters of the coolant flow, as well as heat transfer parameters during operation, and (2) neutronic thermal-hydraulic, which consists in maintaining the stability of the processes of energy release and heat removal in the core
By tradition and by analogy with a boiling coolant, in computational studies of the thermal-hydraulic stability of systems with supercritical water, frequency and time analysis methods are used with process models of different levels of complexity