Yuanzineng kexue jishu (Feb 2022)
Neutronics and Thermal-hydraulics Coupling High Fidelity Simulation of PWR Core with Heavy Reflector
Abstract
The reflector can reduce the neutron leakage from the reactor core, increase the neutron economy, and improve the fuel utilization. In commercial PWR, light water is usually used as the main body, combined with stainless steel shroud to form radial reflector. The industrial nuclear design code system has rich experience in calculating and verifying the neutron characteristics of the shroud/water reflector. In the design of some small reactors and large PWRs, the use of heavy reflector with better neutron reflection effect can further reduce neutron leakage and critical size, and improve reactor economy. The heavy reflector is usually made of metal materials, and its structure and neutron absorption characteristics are quite different from those of conventional shroud/water reflector. The simulation of heavy reflector core puts forward new requirements and challenges to the calculation and analysis ability of industrial nuclear design code system. The core high fidelity simulation program system can be used to accurately analyze the reflector effect and test the applicability of the design code. The calculation accuracy, simulation resolution and program application scope of high fidelity numerical reactor technology characterized by multiphysical field, multiscale coupling and highperformance calculation are better than the existing industrial nuclear design code system. It has important application value in design code verification, design result verification and new reactor design analysis. In this paper, the highprecision nuclear thermal coupling simulation program system developed based on the coupling of advanced neutronics program SCAPN and subchannel program SAPREIP was used to calculate and analyze the heavy reflector core of PWR. Firstly, NECPX program and SCAPN program were used to simulate the heavy reflector core problem of PWR. Five reflector models were established. The correctness of the modeling results and the calculation accuracy of SCAPN program were verified by comparing the results. Then, the calculation results of SCAP-N were compared with those of commercial nuclear design code system to analyze the difference of reflector modeling results between core high fidelity simulation program system and industrial nuclear design code system. Compared with the results of NECPX program, the results of NECPX and SCAPN programs are in good agreement. The influence of heavy reflector on the core eigenvalue is about +450 pcm. The change of coolant temperature in the water tunnel of heavy reflector has little effect on the calculation results. Compared with the accurate modeling scheme, the reactivity calculation deviation caused by the watermetal mixing modeling scheme of heavy reflector is within ±30 pcm, and the calculation deviation of component relative power distribution is within ±2%, which is within the acceptable range. Compared with the calculation results of SCAPN program of real geometric fine modeling scheme of heavy reflector, the eigenvalue calculation deviation of commercial nuclear design code is -34 pcm, the relative power distribution deviation of the module shows an external positive and internal negative distribution, and the most positive deviation is 553% and the most negative deviation is -7.35%.