Transient pressure analysis for the reactor core and containment of a HTGR after a primary loop pressure boundary break accident 被引量：1

Transient pressure analysis for the reactor core and containment of a HTGR after a primary loop pressure boundary break accident

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摘要 The pressure variances in the reactor core and containment of a High Temperature Gas-cooled Reactor (HTGR) after a primary loop pressure boundary break accident determine the structural integrity and safety of the reactor. Based on mass conservation, energy conservation and state equations, explicit formulae for the transient pressure and temperature variances in the pressure vessels were deduced, and a set of differential equations for the transient pressure and temperature variances in the containment were developed. Numerical simulation was also conducted to investigate the transient pressure and temperature variances in the pressure vessels and containment. The results show that energy transformation due to expansion work cannot be neglected. The maximum pressure in the containment could increase by 40 percent due to blockage caused by air in the containment. Detailed numerical simulations of the transient pressure and temperature variance in the reactor core flow passages were also conducted. The results show that the pressures acting on the reactor core and containment are below acceptable values. The pressure variances in the reactor core and containment of a High Temperature Gas-cooled Reactor (HTGR) after a primary loop pressure boundary break accident determine the structural integrity and safety of the reactor. Based on mass conservation, energy conservation and state equations, explicit formulae for the transient pressure and temperature variances in the prcssurc vessels were deduced, and a set of differential equations for the transient pressure and temperature vasiances in the containment were developed. Numerical simulation was also conducted to investigate the transient pressure and temperature variances in the pressure vessels and containment. The results show that energy transformation due to expansion work cannot be neglected. The maximum pressure in the containment could increase by 40 percent due to blockage caused by air in the containment. Detailed numerical simulations of the transient pressure and temperature variance in the reactor core flow passages were also conducted. The results show that the pressures acting on the reactor core and containment are below acceptable values.

作者 LI XiaoWei LI XiaoTian SHI Li HE ShuYan

机构地区 Institute of Nuclear and New Energy Technology

出处《Chinese Science Bulletin》 SCIE EI CAS 2011年第23期2486-2494,共9页

基金 supported by the National Natural Science Foundation of China (51006061)

关键词高温气冷堆瞬态压力压力分析断裂事故压力边界主回路堆芯温度变化 transient pressure theoretical analysis numerical simulation high temperature gas-cooled reactor porous media containment

分类号 TL364.2 [核科学技术—核技术及应用]

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2011年第23期

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