Mathematical Calculation of Material Reliability Using Surface Roughness Feature Based on Plasma Material Interaction Experiment Results

Eksploatacja i Niezawodność – Maintenance and Reliability Pub Date : 2023-07-21 DOI:10.17531/ein/169815

A. Pahsa, Y. Aydoğdu, Fahrettin Göktaş

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Abstract

The choice of reactor structural material design must take into account the TOKAMAK fusion reactors' structural reliability. Due to their high levels of heat and energy, fusion reactions have significant deformation effects, which reduce the efficiency of energy production in reactors. Material selection, erosion and damage, heat and stress management, reliability analysis, maintenance, and inspection are crucial elements in determining how reliable fusion reactors are. The focus of this work is on material selection and reliability analysis based on these parameters. The most common wall materials used in fusion reactors are tungsten, beryllium, steel, or graphite. It is advised to utilize aluminum because harmful Beryllium dust limits the study of this element. For this purpose, a target of aluminum samples is established with a plasma of He ions created by glow discharge. The dependability of the samples is determined by calculating the Weibull Distribution and measuring the roughness of the sample surfaces following exposure.

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基于等离子体材料相互作用实验结果的表面粗糙度特征材料可靠性数学计算

反应堆结构材料设计的选择必须考虑到托卡马克聚变反应堆的结构可靠性。由于其高水平的热量和能量，聚变反应具有显著的变形效应，这降低了反应堆中能量产生的效率。材料选择、侵蚀和损坏、热和应力管理、可靠性分析、维护和检查是决定聚变反应堆可靠性的关键因素。本文的工作重点是在这些参数的基础上进行材料选择和可靠性分析。聚变反应堆最常用的壁材是钨、铍、钢或石墨。建议使用铝，因为有害的铍尘限制了这种元素的研究。为此，用辉光放电产生的氦离子等离子体建立铝样品的靶。通过计算威布尔分布和测量暴露后样品表面的粗糙度来确定样品的可靠性。

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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Eksploatacja i Niezawodność – Maintenance and Reliability

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