Numerical analysis of using a fluidized bed as a prototypic mass production device for IFE target layering

2009 23rd IEEE/NPSS Symposium on Fusion Engineering Pub Date : 2009-06-01 DOI:10.1109/FUSION.2009.5226372

K. Boehm, A. Raffray, N. Alexander, D. Frey, D. Goodin

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Abstract

A fluidized bed has been identified as a very promising method for mass production of Inertial Fusion Energy (IFE) targets. While large beds could be filled with many targets to provide large-scale production, a proof of principle can be achieved by small scale laboratory experiments. The nearisothermal environment required for smooth layering to meet the specifications for the ice layer can be maintained, in principle, around each target through the random movement and spin of individual targets in a precisely controlled gas stream. Pre-experimental numerical studies have been performed to define the window of parameters, in which the layering process can be expected to work optimally. These numerical analyses address several topics, including the effect of unbalanced spheres on the bed behavior and ultimately on the target thermal environment, as well as effects of target collisions. The influence of the thermal environment around an individual target on the layer formation needs to be assessed and used as input for the fluidized bed model, as it affects the unbalance of the individual spheres.

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流化床作为IFE靶层原型量产装置的数值分析

流化床已被认为是一种非常有前途的大规模生产惯性聚变能靶材的方法。虽然大床可以填充许多目标以提供大规模生产，但可以通过小规模的实验室实验来实现原理验证。原则上，通过在精确控制的气流中单个目标的随机运动和旋转，可以保持每个目标周围的近等温环境，以满足平滑分层所需的冰层规格。已经进行了预实验数值研究，以确定参数窗口，在此窗口中分层过程可以预期最佳工作。这些数值分析涉及几个主题，包括不平衡球体对床层行为的影响，最终对目标热环境的影响，以及目标碰撞的影响。需要评估单个目标周围的热环境对层形成的影响，并将其用作流化床模型的输入，因为它影响单个球体的不平衡。

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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2009 23rd IEEE/NPSS Symposium on Fusion Engineering

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