Influence of diamond grinding process on material removal mechanisms and surface roughness of 0/90° continuous carbon fiber reinforced ZrB2

IF 2.9 Q1 MATERIALS SCIENCE, CERAMICS

Open Ceramics Pub Date : 2024-09-04 DOI:10.1016/j.oceram.2024.100669

Achim Rösiger , Stefan Kleiner , Simon Unseld , Ralf Goller , Luca Zoli , Diletta Sciti

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引用次数: 0

Abstract

In manufacturing of UHTCMC components machining is often one of the ultimate process steps and have then important objectives, including dimensional tolerances and surface roughness. Additionally, the prevention of any damage to high-value components is very important. In this study, the machining of 0/90°-C/ZrB₂ composite is investigated to understand some fundamental mechanisms involved. Specifically, the material removal mechanisms of the heterogeneous and anisotropic material structure through scratch tests are explored. Grinding experiments are conducted to evaluate surface quality, measuring surface roughness and grinding forces. This allows an interpretation of machining induced damage mechanisms of UHTCMCs. 0/90°-C/ZrB₂ shows generally brittle removal mechanisms and influence of fiber cutting direction. Scratching depth and speed influences less on damage. This was also found in the grinding experiments, where roughness remains almost constant.

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金刚石磨削工艺对 0/90° 连续碳纤维增强 ZrB2 材料去除机制和表面粗糙度的影响

在 UHTCMC 组件的制造过程中，机加工通常是最终的工艺步骤之一，因此具有重要的目标，包括尺寸公差和表面粗糙度。此外，防止对高价值部件造成任何损坏也非常重要。本研究对 0/90°-C/ZrB2 复合材料的加工进行了研究，以了解其中涉及的一些基本机制。具体来说，通过划痕试验探讨了异质和各向异性材料结构的材料去除机制。磨削实验通过测量表面粗糙度和磨削力来评估表面质量。这有助于解释 UHTCMC 的加工诱导损伤机制。0/90°-C/ZrB2 显示出普遍的脆性去除机制和纤维切削方向的影响。划痕深度和速度对损坏的影响较小。磨削实验中也发现了这一点，其粗糙度几乎保持不变。

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来源期刊

Open Ceramics Materials Science-Materials Chemistry

CiteScore

4.20

自引率

0.00%

发文量

102

审稿时长

67 days