Modelling of the complete heat flux deposition on the CFETR first wall with neon seeding

Steady-state heat flux deposition on the first wall of the Chinese Fusion Engineering Testing Reactor (CFETR) is investigated for 1 GW fusion power and under the updated design scheme. The computation is accomplished by the modelling of two simulation systems: SOLPS-ITER and PFCFlux. Seeding neon (N...

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Bibliographic Details
Published in:Plasma physics and controlled fusion 2021-09, Vol.63 (9), p.95004
Main Authors: Nian, Feifei, Yang, Zhongshi, Ding, Rui, Chen, Jingbo, Niu, Guojian, Liu, Xiaoju, Zhang, Bin, Firdaouss, Mehdi, Li, Kedong, He, Tao, Xie, Yudong, Puyang, Shouan, Luo, Guang-Nan
Format: Article
Language:English
Subjects:
CFETR
complete heat flux
Engineering Sciences
first wall
modelling
Ne seeding
Physics
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Summary:Steady-state heat flux deposition on the first wall of the Chinese Fusion Engineering Testing Reactor (CFETR) is investigated for 1 GW fusion power and under the updated design scheme. The computation is accomplished by the modelling of two simulation systems: SOLPS-ITER and PFCFlux. Seeding neon (Ne) gas is considered to be one of the possible methods of protecting the CFETR divertor from high heat flux damage. Simulations with different Ne seeding rates were carried out on a standard divertor with a lower single-null configuration to determine the effect of Ne seeding on heat flux deposition on the first wall. A blob-based transport model was used to investigate the effect of enhanced cross-field transport on the CFETR first wall, as with ITER and EU DEMO simulations. This work establishes a potential method for simulating the complete heat flux deposition on the first wall for the CFETR steady state by SOLPS-ITER and PFCFlux. After modelling and energy analysis, the peak value of complete heat flux on each module of the CFETR first wall is obtained, which may provide the basic reference for the CFETR physics and engineering design team. The CFETR first wall module which receives the highest heat flux has also been identified, and Ne seeding has a positive effect on reducing the heat flux on the CFETR first wall from around 2.5 MW m -2 to 1 MW m -2 , which is within the engineering requirement.
ISSN:0741-3335
1361-6587
DOI:10.1088/1361-6587/ac0a3d