Physics and systems design analyses are carried out to estimate the desired fusion core parameters for an ST based Volume Neutron Source (ST-VNS) that utilizes a single-turn toroidal field coil (TFC). A design with a major radius R/sub 0/=1.07 m is estimated to have large margins in physics, technology, and engineering for the initial operation at moderate performance (neutron wall load, W/sub /spl lambda//=0.5-2.0 MW/m/sup 2/). The VNS therefore begins with technologies already assumed in the ITER EDA, and the relatively conservative physics to be tested initially by the ST proof-of-principle experiments presently being built. Given continued advances in technology via the VNS and in physics via the ST experiments, the design should permit upgrades to test components and operation at the level of future Pilot Plant and Power Plants (W/sub L/=5 MW/m/sup 2/). This approach to VNS places premium on modular components and remote maintenance, encourages continued innovation and optimization in ST fusion and plasma science, and enhances the practicality of the ST pathway to fusion power.
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机译:进行了物理和系统设计分析,以估算基于ST的利用单匝环形场线圈(TFC)的基于体积的中子源(ST-VNS)所需的融合核参数。估计半径R / sub 0 / = 1.07 m的设计在物理,技术和工程方面具有较大的裕度,可以在中等性能(中子壁载荷,W / sub / spl lambda // = 0.5- 2.0 MW / m / sup 2 /)。因此,VNS始于ITER EDA中已经采用的技术,并且目前正在建立由ST原理证明实验初步测试的相对保守的物理学。鉴于VNS技术和ST实验在物理技术方面的不断进步,设计应允许在未来的试验工厂和发电厂级别上升级测试组件和操作(W / sub L / = 5 MW / m / sup 2 /)。 VNS的这种方法在模块化组件和远程维护上具有优势,鼓励在ST融合和等离子体科学领域进行不断的创新和优化,并增强了ST融合能力的实用性。
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