Investigation on machinability of aluminum 7075 under dry environment

IF 1.2 Q3 ENGINEERING, MECHANICAL

FME Transactions Pub Date : 2023-01-01 DOI:10.5937/fme2304470m

Raymond Magabe, Kapil Gupta

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Abstract

Aluminum is a light and soft material that is difficult to machine. It is the most produced non-ferrous metal and undergoes extensive machining for the development of a wide range of products. Advances in industry inspire the need to find sustainable ways of machining aluminum and its alloys using conventional machining processes. In the study reported in this paper, two sets of experiments were conducted to investigate the machinability of aluminum 7075 using a plain carbide tool under a dry environment, i.e., no lubrication. In the first set, four rough experiments were conducted where three important machining parameters, i.e., cutting speed CS (115-495 RPM), depth of cut DOC (0.8-1.5 mm), and Feed rate FR (0.08-0.2 mm/rev) have been varied at two levels each to check the behavior of responses or machinability indicators, i.e., surface roughness and tool wear, at machining parameters' highest and lowest values. Based on the results of the first set of experiments, the ranges and levels of parameters have been fixed in the second set for a detailed study of the machinability of aluminum. A total of nine experiments based upon Taguchi's robust design of experiment technique with orthogonal array L9 have been conducted where an additional machining parameter, i.e., machining time MT, has been introduced. The effect of machining parameters on tool wear and surface roughness has been studied in detail, and it is found that the dry machining of aluminum is possible without the early failure of the tool. Dry machining with low values of CS, DOC, FR, and medium MT is desirable for better machinability, i.e., minimum roughness and tool wear, an optimum combination of machining parameter cutting speed-115 RPM, depth of cut-0.8 mm, feed rate-0.12 mm/rev, and machining time-90 seconds. The findings of the present work will assist engineers and researchers in attaining quality, productivity, and sustainability while manufacturing parts and components from aluminum to be used in the automotive, defense, and aerospace sectors.

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7075铝合金在干燥环境下的可加工性研究

铝是一种轻而软的材料，很难加工。它是产量最大的有色金属，经过大量的加工，以开发各种各样的产品。工业的进步激发了寻找使用传统加工工艺加工铝及其合金的可持续方法的需要。在本文报道的研究中，进行了两组实验，研究了在干燥环境下，即无润滑情况下，使用普通硬质合金刀具对7075铝合金的可切削性进行了研究。在第一组实验中，进行了四次粗糙实验，在两个水平上分别改变三个重要的加工参数，即切削速度CS (115-495 RPM)、切削深度DOC (0.8-1.5 mm)和进给速度FR (0.08-0.2 mm/rev)，以检查在加工参数最高和最低值时的响应行为或可加工性指标，即表面粗糙度和刀具磨损。在第一组实验结果的基础上，确定了第二组实验参数的范围和水平，对铝的可加工性进行了详细的研究。基于Taguchi的正交阵列L9实验技术稳健设计，在引入加工时间MT的条件下，共进行了9个实验。详细研究了加工参数对刀具磨损和表面粗糙度的影响，发现可以在不发生刀具早期失效的情况下对铝进行干式加工。采用低CS、DOC、FR和中等MT值的干式加工可获得更好的可加工性，即最小的粗糙度和刀具磨损，加工参数的最佳组合切削速度为115 RPM，切削深度为0.8 mm，进给速度为0.12 mm/rev，加工时间为90秒。本工作的发现将有助于工程师和研究人员在制造用于汽车、国防和航空航天领域的铝零部件时获得质量、生产力和可持续性。

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

FME Transactions ENGINEERING, MECHANICAL-

CiteScore

3.60

自引率

31.20%

发文量

审稿时长

12 weeks