用SPH正交切削过程模拟的机器学习模型预测Ti6Al4V的切削力

Q2 Engineering

Journal of Machine Engineering Pub Date : 2022-03-24 DOI:10.36897/jme/147201

H. Klippel, Eduardo Gonzalez Sanchez, Margolis Isabel, M. Röthlin, M. Afrasiabi, Kuffa Michal, K. Wegener

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引用次数: 5

摘要

机械加工过程的预测是一项具有挑战性的任务，通常需要大量的实验基础。这些实验是耗时的，并且需要在各种工艺条件下制造和测试不同的工具几何形状，以找到最佳的加工设置。本文提出了Ti6Al4V正交切削过程的机器学习模型，用于预测前角、后角、切削刃半径、进给和切削速度等多种工艺条件下的切削力和进给力。该模型使用虚拟实验生成的训练数据，这些实验是使用基于物理的平滑粒子流体动力学（SPH）模拟正交切削过程进行的。ML训练集由2500个GPU加速SPH模拟实例的输入参数和输出过程力组成。所得到的模型提供了快速的过程力预测，并且与经典的分析方法相比，可以考虑刀具的几何形状。

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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Cutting Force Prediction of Ti6Al4V using a Machine Learning Model of SPH Orthogonal Cutting Process Simulations

The prediction of machining processes is a challenging task and usually requires a large experimental basis. These experiments are time-consuming and require manufacturing and testing of different tool geometries at various process conditions to find optimum machining settings. In this paper, a machine learning model of the orthogonal cutting process of Ti6Al4V is proposed to predict the cutting and feed forces for a wide range of process conditions with regards to rake angle, clearance angle, cutting edge radius, feed and cutting speed. The model uses training data generated by virtual experiments, which are conducted using physical based simulations of the orthogonal cutting process with the smoothed particle hydrodynamics (SPH). The ML training set is composed of input parameters, and output process forces from 2500 instances of GPU accelerated SPH simulations. The resulting model provides fast process force predictions and can consider the cutter geometry in comparison to classical analytical approaches.

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来源期刊

Journal of Machine Engineering Engineering-Industrial and Manufacturing Engineering

CiteScore

2.70

自引率

0.00%

发文量

审稿时长

25 weeks

期刊介绍： ournal of Machine Engineering is a scientific journal devoted to current issues of design and manufacturing - aided by innovative computer techniques and state-of-the-art computer systems - of products which meet the demands of the current global market. It favours solutions harmonizing with the up-to-date manufacturing strategies, the quality requirements and the needs of design, planning, scheduling and production process management. The Journal'' s subject matter also covers the design and operation of high efficient, precision, process machines. The Journal is a continuator of Machine Engineering Publisher for five years. The Journal appears quarterly, with a circulation of 100 copies, with each issue devoted entirely to a different topic. The papers are carefully selected and reviewed by distinguished world famous scientists and practitioners. The authors of the publications are eminent specialists from all over the world and Poland. Journal of Machine Engineering provides the best assistance to factories and universities. It enables factories to solve their difficult problems and manufacture good products at a low cost and fast rate. It enables educators to update their teaching and scientists to deepen their knowledge and pursue their research in the right direction.