Abstract
The high temperature gas cooled reactor (HTR) is developing rapidly toward a modular, compact, and integral direction. As the main structure material, graphite plays a very important role in HTR engineering, and the reliability of graphite component has a close relationship with the integrity of reactor core. The graphite components are subjected to high temperature and fast neutron irradiation simultaneously during normal operation of the reactor. With the stress accumulation induced by high temperature and irradiation, the failure risk of graphite components increases constantly. Therefore it is necessary to study and simulate the mechanical behavior of graphite component under in-core working conditions and forecast the internal stress accumulation history and the variation of reliability. The work of this paper focuses on the mechanical analysis of pebble-bed type HTR's graphite brick. The analysis process is comprised of two procedures, stress analysis and reliability analysis. Three different creep models and two different reliability models are reviewed and taken into account in simulation. The stress and failure probability calculation results are obtained and discussed. The results gained with various models are highly consistent, and the discrepancies are acceptable.
Highlights
The high temperature gas cooled reactor is one of the candidate reactor types of the fourth generation advanced nuclear reactor [1]
This paper mainly focuses on the analysis and study of graphite component’s mechanical behaviors under in-core working conditions
The graphite components are subjected to high temperature load and fast neutron irradiation load simultaneously when the reactor operates
Summary
The high temperature gas cooled reactor is one of the candidate reactor types of the fourth generation advanced nuclear reactor [1]. In this step, the stress distribution gained in the first step is used as source data, and the reliability is estimated by form of failure probability or service life of graphite component [4]. The stress distribution gained in the first step is used as source data, and the reliability is estimated by form of failure probability or service life of graphite component [4] A candidate design of pebble-type HTR’s graphite brick is selected to develop a three-dimensional finite element geometric model. Both analysis steps are implemented in the code.
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