Tritium breeding performance of a self-cooled water based blanket

Nuclear engineering and design/fusion : an international journal devoted to the thermal, mechanical, materials, structural, and design problems of fusion energy Pub Date : 1987-01-01 DOI:10.1016/0167-899X(87)90005-X

M.J. Embrechts , D. Steiner , G. Varsamis , L. Deutsch , P. Gierszewski

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引用次数: 3

Abstract

A major issue in the design of fusion reactor blankets is the trade-off between tritium breeding and other blanket design requirements. While net breeding is required, the blanket design should also ensure adequate heat removal, efficient power production and sufficient shielding. A novel aqueous self-cooled blanket concept (ASCB) based on lithium compounds dissolved in water has been proposed and analyzed using one-dimensional neutronics calculations. This concept utilizes zircaloy for the structural material and a vanadium alloy for the first wall. Light water as well as heavy water systems lead to an acceptable design with respect to tritium breeding. One-dimensional tritium breeding ratios in the range 1.1–1.2 seem feasible for the proposed concept. Contrary to conventional blanket designs, the 3-D tritium breeding ratio is expected to be comparable to the 1-D performance because of the additional breeding in water cooled duct shields and high heat-flux components. The resulting design is simple, utilizes materials with a large data base, does not require additional neutron multiplying materials, and satisfies the commonly proposed criteria for a fusion blanket.

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自冷水基毡的氚增殖性能

聚变反应堆包层设计中的一个主要问题是在氚增殖和其他包层设计要求之间进行权衡。虽然需要净饲养，但毯的设计也应确保足够的散热，有效的发电和足够的屏蔽。提出了一种基于锂化合物溶于水的新型自冷层概念，并利用一维中子计算对其进行了分析。这个概念利用锆合金作为结构材料，钒合金作为第一面墙。轻水系统和重水系统在氚增殖方面的设计是可以接受的。在1.1-1.2范围内的一维氚增殖比似乎对提出的概念是可行的。与传统的包层设计相反，由于在水冷管道屏蔽层和高热流密度组件中添加了额外的氚增殖，3d氚增殖比有望与一维性能相当。最终的设计简单，利用具有大数据库的材料，不需要额外的中子倍增材料，并且满足聚变包层的一般标准。

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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Nuclear engineering and design/fusion : an international journal devoted to the thermal, mechanical, materials, structural, and design problems of fusion energy

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