Preliminary fluid channel design and thermal-hydraulic analysis of glow discharge cleaning permanent electrode

• Published in: Fusion engineering and design Vol. 109-111; pp. 866 - 871
• Main Authors: Cai, Lijun, Lin, Tao, Wang, Yingqiao, Wang, Mingxu, Maruyama, So, Yang, Yu, Kiss, Gabor
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.11.2016
• Subjects: Fluid channel; Glow discharge cleaning; Optimization; Permanent electrode; Thermal-hydraulic analysis; Thermal-hydraulic analysis; Fluid channel; Glow discharge cleaning; Permanent electrode; Optimization
• ISSN: 0920-3796; 1873-7196
• DOI: 10.1016/j.fusengdes.2016.01.060

•The plasma facing closure cap has to survive after 30,000 thermal heat load cycles.•0.35MW/m2 radiation heat load plus nuclear heat load are very challenging for stainless steel.•Multilayer structure has been designed by using advanced welding and drilling technology to solve the neutron heating problem.•Accurate volumetric load application in analysis model by CFX has been mastered. Glow discharge cleaning (GDC) shall be used on ITER device to reduce and control impurity and hydrogenic fuel out-gassing from in-vessel plasma facing components. After first plasma, permanent electrode (PE) will be used to replace Temporary Electrode (TE) for subsequent operation. Two fundamental scenarios i.e., GDC and Plasma Operation State (POS) should be considered for electrode design, which requires the heat load caused by plasma radiation and neutron heating must be taken away by cooling water flowing inside the electrode. In this paper, multilayer cooling channels inside PE are preliminarily designed, and snakelike route in each layer is adopted to improve the heat exchange. Detailed thermal-hydraulic analyses have been done to validate the design feasibility or rationality. The analysis results show that during GDC the cooling water inlet and outlet temperature difference is far less than the allowable temperature rise under water flow rate 0.15kg/s compromised by many factors. For POS, the temperature rise and pressure drop are within the design goals, but high thermal stress occurs on the front surface of closure cap of electrode. After several iterations of optimization of the closure cap, the equivalent strain range after 30,000 loading cycles for POS is well below 0.3% design goals.