Prediction of cutting force in micro-end-milling by a combination of analytical and FEM method

Journal of Micromanufacturing Pub Date : 2020-01-21 DOI:10.1177/2516598419876158

A. Roushan, U. S. Rao, L. Vijayaraghavan

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引用次数: 3

Abstract

Abstract Mechanical micro-machining, in general, and micro-end-milling, in particular, has become a very good technique for fabricating 3D micro-features in a variety of materials. To optimize and control the process, prediction of the cutting force accurately is very important. In this work, a force prediction model is developed by a combination of analytical method and finite element (FE) simulations. The model predicts the cutting force components for micro-end-milling process successfully which is compared with experimental force signal obtained by using Al2024-T3 and AISI 4340 as workpiece materials. The predicted and experimental cutting forces are in very good agreement for both the amplitude and trend of the cutting force. The percentage deviation of the predicted force from the experimental force values for both feed force (Fx) and transverse force (Fy) is around 15% (except one case) for Al2024-T3. For the AISI 4340 material, the percentage deviation for Fx is around 25% and for Fy is approximately 10%. The methodology followed here is general in nature and it can be applied to any other machining process as well.

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解析法与有限元法相结合的微端铣削切削力预测

机械微加工，特别是微端铣加工，已经成为在各种材料中制造三维微特征的一种非常好的技术。为了优化和控制加工过程，切削力的准确预测是非常重要的。本文采用解析法和有限元模拟相结合的方法建立了一个力预测模型。该模型成功地预测了微立铣削过程的切削力分量，并与以Al2024-T3和AISI 4340为工件材料获得的实验力信号进行了比较。预测的切削力和实验的切削力在切削力的幅度和趋势上有很好的一致性。Al2024-T3的进给力(Fx)和横向力(Fy)的预测力与实验力值的百分比偏差约为15%(除一例外)。对于AISI 4340材料，Fx的百分比偏差约为25%，Fy的百分比偏差约为10%。这里遵循的方法本质上是通用的，它也可以应用于任何其他加工过程。

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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Journal of Micromanufacturing

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