Laser and microwave instrumentation for ITER and future reactors

G. Vayakis
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Abstract

ITER diagnostics include an extensive set of laser and microwave diagnostics to give access to a wealth of information on the core and edge plasma and to support high performance operation of ITER. For example, Core and Edge Thomson scattering systems build detailed density and temperature profiles on time scales much faster than τ E to follow transient events; ECE and reflectometry add time resolution to follow MHD events. Implementing these diagnostics is challenging, needing a panoply of technologies to keep them functioning reliably for thousands of hours despite extreme events such as disruptions and wall conditioning cycles. Shielding, shutters and cleaning systems protect the forward elements of most optical systems from the build-up of deposits and damage. Still, plasma-facing mirrors must survive laser loads and endure erosion, deposition and in-situ RF cleaning. Calibration and monitoring systems ensure accurate and drift-free operation. These support systems are also not straightforward and required specific R&D. Access also drives the design: to deal with the neutron and gamma sources yet allow maintenance of activated components, ITER uses large, multi-purpose ports that couple otherwise distinct systems into modules for maintenance. Machine movement requires provisions to maintain alignment and calibration, from these port plugs, shown in figure 1, to the accessible areas 10–50 m away. A final complication comes from the difficulty of employing electronics near the plugs. Extensive qualification for radiation resistance is needed. This paper examines design adaptations that ITER adopted for its near-reactor environment, consider the lessons learnt from the ITER design activity specifically for laser and microwave systems and lays out some possible evolution paths for the reactor diagnostician that must follow a more industrial approach.
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用于热核实验堆和未来反应堆的激光和微波仪器
热核实验堆诊断包括一套广泛的激光和微波诊断,以获取有关核心和边缘等离子体的大量信息,并支持热核实验堆的高性能运行。例如,核心和边缘汤姆逊散射系统在比τ E快得多的时间尺度上建立了详细的密度和温度曲线,以跟踪瞬态事件;ECE和反射测量增加了时间分辨率,以跟踪MHD事件。这些诊断技术的实施极具挑战性,需要采用一系列技术,才能在发生中断和墙体调节周期等极端事件时仍能保持数千小时的可靠运行。屏蔽、快门和清洁系统可以保护大多数光学系统的前向元件免受沉积物和损坏的影响。但是,面向等离子体的反射镜仍必须承受激光负载,并经受侵蚀、沉积和原位射频清洗。校准和监控系统可确保运行精确无漂移。这些支持系统也并非简单易行,需要进行专门的研发。接入也是设计的驱动因素:为了处理中子源和伽马源,同时又能对激活的组件进行维护,ITER 使用了大型多用途端口,将原本不同的系统连接到模块中进行维护。机器的移动需要保持对准和校准,从这些端口插头(如图 1 所示)到 10-50 米以外的可进入区域。最后一个复杂因素来自于在插头附近安装电子设备的难度。需要进行广泛的抗辐射鉴定。本文探讨了热核实验堆针对其近堆环境所采取的设计调整措施,考虑了热核实验堆设计活动中专门针对激光和微波系统的经验教训,并为反应堆诊断人员提出了一些可能的发展途径,这些诊断人员必须遵循更加工业化的方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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