An Analysis of the Amount of Energy Used during the Milling of Aluminum 6061 with Higher Performance

K. H. Ram, R. R. Raj, D.S. Jenaris, P. Mohan, Manoj Abraham
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Abstract

Cutting down on energy usage while keeping the material removal rate (MRR) as high as possible is widely acknowledged to be one of the most important goals in the machining industry for a considerable amount of time. So that we can create a forecast model for side-milling machining that makes the most efficient use of the feasible amount of power, the response surface method was utilized. After that, this model was used to establish which parameters should be optimized for the machining process. The response surface approach was applied to investigate the effect that several distinct cutting elements, factors like radial slicing depth, feeding rate, and spindle rpm, all examples (RSM), had on the total power needed throughout the cutting process. The data indicate that the variable known as the feeding rate is the most important factor in the amount of energy consumed. Reduced power consumption is an unavoidable natural byproduct of accelerating cycle durations and increasing feed rates. A radial how deep the wound is in 0.3 millimetres, a feed rate of 6,000 millimetres per inch, and a spindle speed of 12,000 revolutions per minute can produce a minimum power usage of 82.38 kilowatts, as the optimization model indicates. Keywords: Material removal rate, Machining, Power consumption
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高性能铝 6061 铣削过程中的能耗分析
在保持尽可能高的材料去除率(MRR)的同时降低能耗,是机械加工行业长期以来公认的最重要目标之一。为了创建一个侧铣加工预测模型,以便最有效地利用可行的功率,我们采用了响应面法。然后,利用该模型确定加工过程中应优化的参数。响应面法用于研究几个不同的切削要素,如径向切片深度、进给速度和主轴转速(均为实例),对整个切削过程中所需总功率的影响。数据表明,进给速度这一变量是影响能耗的最重要因素。降低能耗是加快循环持续时间和提高进给率不可避免的自然副产品。如优化模型所示,0.3 毫米的径向伤口深度、每英寸 6000 毫米的进给速度和每分钟 12000 转的主轴转速可产生 82.38 千瓦的最低耗电量:材料去除率 加工 功率消耗
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