Fabrication of micro holes using low power fiber laser: surface morphology, modeling and soft-computing based optimization

IF 4.2 2区工程技术 Q2 ENGINEERING, MANUFACTURING Advances in Manufacturing Pub Date : 2024-04-07 DOI:10.1007/s40436-024-00484-2

Tuhin Kar, Swarup S. Deshmukh, Arjyajyoti Goswami

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Abstract

Fiber laser micromachining is found extensive applications at industrial level because it is cheap and simple to use. Due to its high strength and low conductivity titanium is difficult to machine with conventional methods. In this investigation, micro holes were fabricated using a 30 W fiber laser on 2 mm thick α-titanium (Grade 2) and the process parameters were optimized through response surface methodology (RSM) and teaching learning-based optimization (TLBO) approach. Experimental runs were designed as per rotatable central composite design (RCCD). Material removal rate (MRR), hole circularity (HC), deviation in diameter (DEV) and heat affected zone (HAZ) were selected as output. A third-order polynomial prediction model was established using RSM. Analysis of variance (ANOVA) suggested that the developed model was 93.5% accurate. The impact of input factors on responses were studied by 3D surface plots. RSM desirability indicates that optimum micro drilling conditions are scan speed 275.43 mm/s, frequency 24.61 kHz, power 36.23% and number of passes 49.75. TLBO indicates that optimum micro drilling conditions are scan speed 100 mm/s, frequency 20 kHz, power 20% and number of passes 50. Comparison between RSM and TLBO suggested that TLBO provided better optimization results. Surface morphology of the fabricated micro holes were analyzed with scanning electron microscopy (SEM).

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利用低功率光纤激光器制造微孔：表面形态、建模和基于软计算的优化

摘要光纤激光微加工因其价格便宜、操作简单而在工业领域得到广泛应用。由于钛具有高强度和低传导性，因此难以用传统方法进行加工。在这项研究中，使用 30 W 光纤激光器在 2 mm 厚的α-钛（2 级）上制造了微孔，并通过响应面方法学（RSM）和基于教学的优化（TLBO）方法对工艺参数进行了优化。实验运行按照可旋转中心复合设计（RCCD）进行设计。选择材料去除率 (MRR)、孔圆度 (HC)、直径偏差 (DEV) 和热影响区 (HAZ) 作为输出。使用 RSM 建立了三阶多项式预测模型。方差分析（ANOVA）表明，所建立模型的准确率为 93.5%。通过三维曲面图研究了输入因素对响应的影响。RSM 理想度表明，最佳微钻孔条件为扫描速度 275.43 mm/s、频率 24.61 kHz、功率 36.23% 和通过次数 49.75。TLBO 表明，最佳微钻孔条件为扫描速度 100 mm/s、频率 20 kHz、功率 20%、通过次数 50。RSM 和 TLBO 的比较表明，TLBO 提供了更好的优化结果。用扫描电子显微镜（SEM）分析了制作的微孔的表面形态。

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来源期刊

Advances in Manufacturing Materials Science-Polymers and Plastics

CiteScore

9.10

自引率

3.80%

发文量

274

期刊介绍： As an innovative, fundamental and scientific journal, Advances in Manufacturing aims to describe the latest regional and global research results and forefront developments in advanced manufacturing field. As such, it serves as an international platform for academic exchange between experts, scholars and researchers in this field. All articles in Advances in Manufacturing are peer reviewed. Respected scholars from the fields of advanced manufacturing fields will be invited to write some comments. We also encourage and give priority to research papers that have made major breakthroughs or innovations in the fundamental theory. The targeted fields include: manufacturing automation, mechatronics and robotics, precision manufacturing and control, micro-nano-manufacturing, green manufacturing, design in manufacturing, metallic and nonmetallic materials in manufacturing, metallurgical process, etc. The forms of articles include (but not limited to): academic articles, research reports, and general reviews.