Liquid Wall Chambers | |
Meier, W R | |
关键词: BREEDING; COOLANTS; FIRST WALL; FLIBE; LIQUID METALS; NEUTRON FLUX; NEUTRONS; NOZZLES; SHIELDS; STEELS; TARGETS; THICKNESS; THIN FILMS; TRITIUM; | |
DOI : 10.2172/1021070 RP-ID : LLNL-TR-471596 PID : OSTI ID: 1021070 Others : TRN: US1103951 |
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美国|英语 | |
来源: SciTech Connect | |
【 摘 要 】
The key feature of liquid wall chambers is the use of a renewable liquid layer to protect chamber structures from target emissions. Two primary options have been proposed and studied: wetted wall chambers and thick liquid wall (TLW) chambers. With wetted wall designs, a thin layer of liquid shields the structural first wall from short ranged target emissions (x-rays, ions and debris) but not neutrons. Various schemes have been proposed to establish and renew the liquid layer between shots including flow-guiding porous fabrics (e.g., Osiris, HIBALL), porous rigid structures (Prometheus) and thin film flows (KOYO). The thin liquid layer can be the tritium breeding material (e.g., flibe, PbLi, or Li) or another liquid metal such as Pb. TLWs use liquid jets injected by stationary or oscillating nozzles to form a neutronically thick layer (typically with an effective thickness of {approx}50 cm) of liquid between the target and first structural wall. In addition to absorbing short ranged emissions, the thick liquid layer degrades the neutron flux and energy reaching the first wall, typically by {approx}10 x x, so that steel walls can survive for the life of the plant ({approx}30-60 yrs). The thick liquid serves as the primary coolant and tritium breeding material (most recent designs use flibe, but the earliest concepts used Li). In essence, the TLW places the fusion blanket inside the first wall instead of behind the first wall.
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