使用自动化和机器学习来最大限度地提高车削中心的刀具使用率,以获得更好的表面光洁度

IF 2.4 Q2 ENGINEERING, MULTIDISCIPLINARY Innovation and Emerging Technologies Pub Date : 2023-01-01 DOI:10.1142/s2737599423400030
Akash D. Pandya, Ajay M. Patel, B. Hindocha, M. Kumar, Ankit D. Oza, K. Bhole, M. Kumar, Manish Gupta
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引用次数: 0

摘要

在现代制造业中,自动化加工系统已成为一种必需品。然而,优化资源利用率和实现良好的表面光洁度仍然是一项具有挑战性的任务。车削中心刀具使用过多、表面光洁度差是车削中心常见的问题,影响了生产效率和产品质量。在这项研究中,我们提出了一种利用自动化和机器学习技术来最大化工具使用和提高表面光洁度的方法。我们的目标是研究刀具寿命和表面粗糙度之间的关系,并开发一种方法,可以优化车削中心的切削参数。我们对提出的方法进行了实验研究,该方法涉及到基于机器学习算法的自动确定切削参数,得出切削速度为43.10[公式:见文]m/min时,铝材料的表面光洁度为1.98[公式:见文]m。对于低碳钢材料,在切削速度为25.13 m/min时,表面光洁度为12[公式:见文][公式:见文]m/min。同样,对于铸铁材料,在切削速度为30.16[公式:见文]m/min时,表面光洁度为8.45[公式:见文]m。结果表明,该方法在表面光洁度、刀具使用率和加工时间方面优于传统的手工方法。我们的方法可以应用于其他加工系统,为提高加工过程的效率和质量提供了实用有效的解决方案。本文提出了一个实验,探讨了刀具寿命与表面粗糙度之间的关系。在此基础上,提出了一种消除加工中G码的自动化方法,提高了机床的加工效率和表面光洁度。目的:通过结合自动化和机器学习,最大限度地提高车削中心的刀具利用率和表面光洁度。本研究旨在探索在车削中心使用自动化和机器学习来优化切削参数并获得更好的表面光洁度。想法描述:这项研究是通过对三种不同的材料,即铝、低碳钢和铸铁进行实验来进行的。切削参数包括主轴转速、进给量和切削深度,由集成了转速表和游标的可编程逻辑控制器(PLC)控制。使用表面粗糙度测试仪测量表面光洁度,并使用监督机器学习算法分析数据。
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Using automation and machine learning to maximize tool use in turning centers for better surface finish
In modern manufacturing industries, automated machining systems have become a necessity. However, optimizing resource utilization and achieving a good surface finish remain challenging tasks. Excessive tool usage and poor surface finish are common problems encountered in turning centers, which affect productivity and product quality. In this research, we propose an approach that leverages automation and machine learning techniques to maximize tool use and improve surface finish. Our objective is to investigate the relationship between tool life and surface roughness and to develop a method that can optimize cutting parameters for turning centers. We have conducted an experimental study to evaluate the proposed approach, which involves the automatic determination of cutting parameters based on machine learning algorithms, and concluded a cutting speed of 43.10[Formula: see text]m/min, the surface finish achieved for aluminum material was 1.98[Formula: see text][Formula: see text]m. In the case of mild steel material, the surface finish was 12[Formula: see text][Formula: see text]m at a cutting speed of 25.13[Formula: see text]m/min. Similarly, for cast iron material, the surface finish was 8.45[Formula: see text][Formula: see text]m at a cutting speed of 30.16[Formula: see text]m/min. Our results show that the proposed method outperforms the traditional manual method in terms of surface finish, tool usage, and machining time. Our approach can be applied to other machining systems, providing a practical and effective solution to improve the efficiency and quality of machining processes. This paper presents an experiment that explores the relationship between tool life and surface roughness. Furthermore, an automated approach is proposed for eliminating G code in machining, which can improve the efficiency of machine tools and result in a better surface finish. Objective: To maximize tool use and improve surface finish in turning centers by incorporating automation and machine learning. Idea: This research aims to explore the use of automation and machine learning in turning centers to optimize the cutting parameters and achieve a better surface finish. Description of the idea: The study was conducted by performing experiments on three different materials, i.e., aluminum, mild steel, and cast iron. The cutting parameters, including spindle speed, feed, and depth of cut, were controlled by a programmable logic controller (PLC) integrated with a tachometer and Vernier scale. The surface finish was measured using a surface roughness tester, and the data was analyzed using a supervised machine learning algorithm.
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