High-speed high-efficient grinding of CMCs with structured grinding wheels

Q3 Engineering International Journal of Abrasive Technology Pub Date : 2019-02-27 DOI:10.1504/IJAT.2019.097964

B. Azarhoushang, M. Kadivar, Robert Bösinger, Sergey Shamray, Ali Zahedi, A. Daneshi

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引用次数: 4

Abstract

The implantation of ceramic matrix composites (CMCs) is limited due to their high machining costs. To overcome this problem, modified grinding wheels, one macro-structured by segmenting and another laser-structured were used. The grinding tests were carried out at different material removal rates and cutting speeds. The grinding forces, surface roughness, and induced residual stress were compared. The results showed that the wheel structuring resulted in a better performance of the grinding wheel. The grinding forces were respectively 30% and 20% lower in the case of segmented wheel and laser-structured wheel in comparison with the conventional grinding. In addition, the tensile residual stress was reduced as a negative output of the grinding process via structuring. A high-speed high-efficient grinding of CMCs without presence of surface damage was achieved by optimising the process parameters. The material removal rate could be elevated without changing the grinding forces with application of the structured wheel.

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结构砂轮高速高效磨削CMC

陶瓷基复合材料（CMC）的植入由于其高加工成本而受到限制。为了克服这个问题，使用了改进的砂轮，一个宏观结构通过分割，另一个激光结构。研磨试验是在不同的材料去除率和切割速度下进行的。比较了磨削力、表面粗糙度和诱导残余应力。结果表明，砂轮的结构使砂轮具有更好的性能。分段砂轮和激光结构砂轮的磨削力分别比传统磨削低30%和20%。此外，拉伸残余应力通过结构化作为研磨过程的负输出而降低。通过优化工艺参数，实现了CMC的高速高效研磨，而不存在表面损伤。可以在不改变研磨力的情况下提高材料去除率。

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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来源期刊

International Journal of Abrasive Technology Engineering-Industrial and Manufacturing Engineering

CiteScore

0.90

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0.00%

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