Title :
Modeling of DEMO PFC Erosion Due to ELM Impact
Author :
Igitkhanov, Yuri ; Bazylev, Boris
Author_Institution :
Inst. for Pulsed Power & Microwave Technol, Karlsruhe Inst. of Technol., Karlsruhe, Germany
Abstract :
The transient events could pose a severe tread causing a melting and erosion of plasma-facing components in the fusion power plant DEMO. Here we analyze the impact of the edge-localized modes (ELMs) on the divertor target and the first wall (FW) surface. The expected ELMs characteristics in DEMO are derived by extrapolating predictions made for ITER and using the scaling arguments found from existing experiments. The tungsten armor damage and effect of melt layer motion owing to the repetitive ELM loads are numerically investigated. The detailed description of the model for simulation of the melt motion (used in the melt motion at surfaces code) is described. It is shown that due to the unmitigated repetitive ELM impact, the divertor plate melts whereas FW does not. The divertor surface of monoblock W divertor module with water coolant tolerates the mitigated ELMs with 33 times (like in ITER) does not melt even in the case of advanced version of DEMO loads.
Keywords :
Tokamak devices; fusion reactor divertors; melting; plasma boundary layers; plasma simulation; plasma toroidal confinement; plasma-wall interactions; tungsten; DEMO PFC Erosion; ELM impact; ITER; W; divertor surface; divertor target; edge localized modes; first wall surface; fusion power plant; melt layer motion; melting; numerical simulation; plasma-facing components; surface code; transient events; tungsten armor damage; tungsten divertor module; water coolant; Heating; Load modeling; Mathematical model; Plasmas; Rough surfaces; Surface roughness; Tungsten; DEMO design; DEMO divertor; DEMO first wall module; ELMs; off-normal events; tungsten erosion;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2014.2334274
