Optimizing end milling parameters for custom 450 stainless steel using ant lion optimization and TOPSIS analysis

IF 2 Q2 ENGINEERING, MECHANICAL
C. Devi, S. Mahalingam, R. Čep, Muniyandy Elangovan
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引用次数: 0

Abstract

The current research examines the effectiveness of cryogenically treated (CT) tungsten carbide cutting inserts on Custom450 stainless steel using multi-objective soft computing approaches. The Taguchi-based L27 orthogonal array was employed in the experiments. During milling operations, cutting force, surface roughness, and cutting temperature were measured at different spindle speeds (rpm), feed rates (mm/min), and constant depths of cut (mm). The surface roughness and chip morphology of the Custom 450 stainless steel machined by cryo-treated (CT) and untreated (UT) cutting tool inserts were compared across various responses to cutting temperature and force. This paper also carried out multi-objective optimization, employing algorithm techniques such as Grasshopper Optimization Algorithm (GHO), Grey Wolf Optimization(GWO), Harmony Search Algorithm(HAS), and Ant line Optimization (ALO). The Multi-objective Taguchi approach and TOPSIS were first used to optimize the machining process parameters (spindle speed, feed rate, and cryogenic treatment) with different performance characteristics. Second, to relate the machining process parameters with the performance characteristics (cutting force, cutting temperature, and surface roughness), a mathematical model was developed using response surface analysis. The created mathematical response model was validated using ANOVA. The results showed that in IGD values of GHO, GWO, HSA and ALO module had 2.5765, 2.4706, 2.3647 and 2.5882 respectively, ALO has the best performance indicator. A Friedman’s test was also conducted, revealing higher resolution with the ALO method than with the HSA, GWO, and GHO methods. The results of the scanning test show that the ALO approach is workable.
利用蚁狮优化和 TOPSIS 分析优化定制 450 不锈钢的端面铣削参数
目前的研究采用多目标软计算方法,考察了低温处理(CT)硬质合金切削刀片在 Custom450 不锈钢上的有效性。实验采用了基于 Taguchi 的 L27 正交阵列。在铣削操作过程中,以不同的主轴转速(转/分)、进给量(毫米/分)和恒定的切削深度(毫米)测量了切削力、表面粗糙度和切削温度。比较了低温处理(CT)和未处理(UT)切削工具刀片加工的 Custom 450 不锈钢的表面粗糙度和切屑形态对切削温度和切削力的各种响应。本文还采用草蜢优化算法(GHO)、灰狼优化算法(GWO)、和谐搜索算法(HAS)和蚁行优化算法(ALO)等算法技术进行了多目标优化。首先,采用多目标田口方法和 TOPSIS 方法对具有不同性能特征的加工工艺参数(主轴转速、进给量和低温处理)进行优化。其次,为了将加工工艺参数与性能特征(切削力、切削温度和表面粗糙度)联系起来,使用响应曲面分析法建立了一个数学模型。利用方差分析对建立的数学响应模型进行了验证。结果显示,GHO、GWO、HSA 和 ALO 模块的 IGD 值分别为 2.5765、2.4706、2.3647 和 2.5882,其中 ALO 的性能指标最好。还进行了弗里德曼检验,结果显示 ALO 方法的分辨率高于 HSA、GWO 和 GHO 方法。扫描测试的结果表明,ALO 方法是可行的。
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
Frontiers in Mechanical Engineering
Frontiers in Mechanical Engineering Engineering-Industrial and Manufacturing Engineering
CiteScore
4.40
自引率
0.00%
发文量
115
审稿时长
14 weeks
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