Development of a neutronics/thermal-hydraulic coupling optimization code and its application on the CFETR HCSB blanket

“…In our previous work, 14,29 NTCOC, a Nuclear‐Thermal Coupling Code has been developed for optimizing the radial structure layout of HCCB blanket. It has been applied on optimizing the radial structure layout of the typical outboard CFETR phase I HCCB blanket with P f = 200 MW, 14,15 which verifies the feasibility of this code and the integrated optimization method.…”

“…In our previous work, 14,29 NTCOC, a Nuclear‐Thermal Coupling Code has been developed for optimizing the radial structure layout of HCCB blanket. It has been applied on optimizing the radial structure layout of the typical outboard CFETR phase I HCCB blanket with P f = 200 MW, 14,15 which verifies the feasibility of this code and the integrated optimization method. However, as the final core design parameters of CFETR phase II have been just determined, and both the dimensions and the NWL of CFETR phase II HCCB blanket are much bigger than phase I, the radial structure layout optimization work for phase II blanket should be initialized.…”

“…In this section, based on the original integrated optimization method, the radial structure layout of the outboard equatorial CFETR phase II HCCB blanket is calculated by NTCOC and the whole optimization process is illustrated in Figure 6A‐H. The whole optimization process is exactly similar to that of the previous phase I blanket 14 . For the sake of brevity, we will not cover it in this article.…”

“…Until now, there are many research institutes which have performed conceptual design, comprehensive analyses, and optimizations work for phase I HCCB blanket in detail 8,9,13‐19 . However, the operational stage of CFETR has transformed from Phase I to Phase II, and the latest core design parameters have been just determined (major radius equals to 7.2 m, minor radius equals to 2.2 m) 20 .…”

“…Therefore, 23 only focuses on the optimization of CP He thickness for satisfying the pressure drop limit, while the temperature distributions of BUs, which have great influence on the tritium breeding and releasing performance, are not taken into consideration temporarily. In this work, based on the original integrated optimization method 14,15 and the optimum CP He thickness, 23 the radial structure layout optimization of the outboard equatorial phase II HCCB blanket module is conducted by NTCOC firstly 14 . However, the calculation results show that the original optimization method provides inadequately optimized tritium breeding performance and insufficient tritium releasing ability under the condition of high fusion power.…”

A new method for improving the tritium breeding and releasing performance of China Fusion Engineering Test Reactor phase II helium‐cooled ceramic breeder blanket

“…In our previous work, 14,29 NTCOC, a Nuclear‐Thermal Coupling Code has been developed for optimizing the radial structure layout of HCCB blanket. It has been applied on optimizing the radial structure layout of the typical outboard CFETR phase I HCCB blanket with P f = 200 MW, 14,15 which verifies the feasibility of this code and the integrated optimization method.…”

“…In our previous work, 14,29 NTCOC, a Nuclear‐Thermal Coupling Code has been developed for optimizing the radial structure layout of HCCB blanket. It has been applied on optimizing the radial structure layout of the typical outboard CFETR phase I HCCB blanket with P f = 200 MW, 14,15 which verifies the feasibility of this code and the integrated optimization method. However, as the final core design parameters of CFETR phase II have been just determined, and both the dimensions and the NWL of CFETR phase II HCCB blanket are much bigger than phase I, the radial structure layout optimization work for phase II blanket should be initialized.…”

“…In this section, based on the original integrated optimization method, the radial structure layout of the outboard equatorial CFETR phase II HCCB blanket is calculated by NTCOC and the whole optimization process is illustrated in Figure 6A‐H. The whole optimization process is exactly similar to that of the previous phase I blanket 14 . For the sake of brevity, we will not cover it in this article.…”

“…Until now, there are many research institutes which have performed conceptual design, comprehensive analyses, and optimizations work for phase I HCCB blanket in detail 8,9,13‐19 . However, the operational stage of CFETR has transformed from Phase I to Phase II, and the latest core design parameters have been just determined (major radius equals to 7.2 m, minor radius equals to 2.2 m) 20 .…”

“…Therefore, 23 only focuses on the optimization of CP He thickness for satisfying the pressure drop limit, while the temperature distributions of BUs, which have great influence on the tritium breeding and releasing performance, are not taken into consideration temporarily. In this work, based on the original integrated optimization method 14,15 and the optimum CP He thickness, 23 the radial structure layout optimization of the outboard equatorial phase II HCCB blanket module is conducted by NTCOC firstly 14 . However, the calculation results show that the original optimization method provides inadequately optimized tritium breeding performance and insufficient tritium releasing ability under the condition of high fusion power.…”

A new method for improving the tritium breeding and releasing performance of China Fusion Engineering Test Reactor phase II helium‐cooled ceramic breeder blanket

Preliminary design and analyses of the helium cooled ceramic breeder blanket for CFETR phase II

Numerical research on the coupling optimization design rule of the CFETR HCSB blanket using the NTCOC code