Parametric optimization while turning Ti-6Al-4V alloy in Mist-MQCL (Green environment) using the DEAR method

IF 1.9 Q3 ENGINEERING, MANUFACTURING

Manufacturing Review Pub Date : 2020-01-01 DOI:10.1051/mfreview/2020034

V. Lakshmi, K. Subbaiah, Arun Vikram Kothapalli, K. Suresh

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引用次数: 14

Abstract

Sustainability in any production emphasizes green-manufacturing techniques, improvement in quality with energy-efficient techniques, and environment-friendly processes. Titanium machining productivity is greatly influenced by speed, as high cutting velocity raises the temperatures in the shear zone and heat, owing to its low thermal conductivity. Hence in this work, an attempt is made to increase productivity by exploring the efficacy at transition speed for titanium alloy machining. Water-soluble lubricant is mist-sprayed as aerosols at a near-zero temperature in minor quantity, to minimize the temperatures generated during the cutting process at increased speed. Besides, an optimal decision variable vector optimizes multi-goals of machining Titanium grade 5 alloys under Minimum quantity cooling lubrication explored in this study in transitional speed zones. The response goals are the optimization of “vibration, surface quality, tool wear rate, and Material removal rate.” Multi goal optimization achieved by hybrid Taguchi coupled with Data Envelopment Analysis based Ranking (DEAR). The tool wear is very rapid at velocities of 200 mm/min. DEAR technique uses computed Multi performance rank index (MPRI) to predict the best data set at: (velocity, feed, doc) at (120 mm/min, 0.2 mm/rev, 1.0 mm). In this setting, the responses are compared in dry, flood, and MQL environment. It is observed a 30%, 60%, 40% improvement in surface finish, tool life, and vibrations compared to a dry environment and 13% and 3% of roughness and tool wear rate compared to a flood environment. Thus MQCL can be adopted for Ti6Al4V at transitional speeds.

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采用DEAR方法对Ti-6Al-4V合金在Mist-MQCL (Green environment)环境下的车削参数进行优化

任何生产的可持续性都强调绿色制造技术，用节能技术提高质量，以及环境友好的过程。钛的加工效率很大程度上受速度的影响，因为高切削速度提高了剪切区的温度和热量，这是由于钛的低导热性。因此，本工作试图通过探索钛合金加工过渡速度的有效性来提高生产率。少量的水溶性润滑剂以气溶胶的形式在接近零的温度下喷雾，以尽量减少在增加速度的切割过程中产生的温度。此外，本文还提出了一个最优决策变量向量，对过渡速度区5级钛合金在最少量冷却润滑条件下加工的多目标进行了优化。响应目标是“振动、表面质量、刀具磨损率和材料去除率”的优化。混合田口法结合基于数据包络分析的排序法实现多目标优化。在200毫米/分钟的速度下，刀具磨损非常快。DEAR技术使用计算的多重性能排名指数(MPRI)来预测(速度，进料，文件)在(120 mm/min, 0.2 mm/rev, 1.0 mm)下的最佳数据集。在此设置中，比较了干旱、洪水和MQL环境下的响应。与干燥环境相比，表面光洁度、工具寿命和振动提高了30%、60%和40%，与水浸环境相比，粗糙度和工具磨损率分别提高了13%和3%。因此，MQCL可以在过渡速度下用于Ti6Al4V。

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

Manufacturing Review ENGINEERING, MANUFACTURING-

CiteScore

5.40

自引率

12.00%

发文量

审稿时长

8 weeks

期刊介绍： The aim of the journal is to stimulate and record an international forum for disseminating knowledge on the advances, developments and applications of manufacturing engineering, technology and applied sciences with a focus on critical reviews of developments in manufacturing and emerging trends in this field. The journal intends to establish a specific focus on reviews of developments of key core topics and on the emerging technologies concerning manufacturing engineering, technology and applied sciences, the aim of which is to provide readers with rapid and easy access to definitive and authoritative knowledge and research-backed opinions on future developments. The scope includes, but is not limited to critical reviews and outstanding original research papers on the advances, developments and applications of: Materials for advanced manufacturing (Metals, Polymers, Glass, Ceramics, Composites, Nano-materials, etc.) and recycling, Material processing methods and technology (Machining, Forming/Shaping, Casting, Powder Metallurgy, Laser technology, Joining, etc.), Additive/rapid manufacturing methods and technology, Tooling and surface-engineering technology (fabrication, coating, heat treatment, etc.), Micro-manufacturing methods and technology, Nano-manufacturing methods and technology, Advanced metrology, instrumentation, quality assurance, testing and inspection, Mechatronics for manufacturing automation, Manufacturing machinery and manufacturing systems, Process chain integration and manufacturing platforms, Sustainable manufacturing and Life-cycle analysis, Industry case studies involving applications of the state-of-the-art manufacturing methods, technology and systems. Content will include invited reviews, original research articles, and invited special topic contributions.