Investigation of Heat Annealing and Parametric Optimization for Drilling of Monel-400 Alloy

IF 3.3 Q2 ENGINEERING, MANUFACTURING

Journal of Manufacturing and Materials Processing Pub Date : 2023-09-15 DOI:10.3390/jmmp7050170

Basem M. A. Abdo, Redhwan Almuzaiqer, Mohammed A. Noman, Sanjay Chintakindi

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Abstract

A nickel-based copper alloy known as Monel-400 is extensively applied in many industries including aerospace, marine engineering, and nuclear power generation, owing to its exceptional characteristics such as extreme tensile strength and toughness, excellent corrosion resistance, and the ability to retain shape even at extremely high temperatures. Traditional methods of drilling Monel-400 alloy are difficult due to quick tool wear and poor surface polishing, resulting in expensive machining costs. In this study, a technique called heat annealing was implemented to externally heat-treat the Monel-400 alloy material before the drilling process. Cutting force, surface roughness, and tool wear were used as the responses to investigate the effect of heat annealing and the drilling parameters on the machinability of Monel-400. The results revealed that the cutting force (Fz) and surface roughness (Ra and Rt) could be reduced by 33%, 31%, and 25%, respectively, after annealing at 700 °C compared to the results of the drilled Monel-400 at room temperature. It can be observed that the maximum improvement can reach 42% of Fz, 35% of Ra, and 59% of Rt while annealing Monel-400 at 1000 °C. A significant reduction was observed in the tool wear for machining the annealed material, which minimized the tooling and overall machining cost. Regarding the effects of the drilling process on the considered responses, the results revealed that the spindle speed has a greater effect on the cutting force, whereas the feed rate has the most significant effect on Ra. The significance of the drilling input parameters on the outputs is determined by analysis of the main effect plots and surface plots. Subsequently, the multi-objective genetic algorithm (MOGA) is used to identify the optimal parametric conditions for minimizing the cutting force and surface roughness of the drilled holes. The optimized values achieved via multi-objective optimization are the cutting force, Fz = 388–466 N, and the surface roughness, Ra = 0.17–0.19 μm and Rt = 3–3.5 μm, respectively.

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Monel-400合金钻孔热退火及参数优化研究

一种名为Monel-400的镍基铜合金广泛应用于航空航天、海洋工程和核能发电等许多行业，因为它具有优异的抗拉强度和韧性、优异的耐腐蚀性以及即使在极高温度下也能保持形状的能力。传统的钻削Monel-400合金的方法由于刀具磨损快，表面抛光效果差，导致加工成本昂贵。在本研究中，采用了一种称为热退火的技术，在钻孔工艺之前对Monel-400合金材料进行外部热处理。以切削力、表面粗糙度和刀具磨损为响应，研究热处理和钻孔参数对Monel-400可加工性的影响。结果表明，与钻孔Monel-400相比，700℃退火后的切削力(Fz)和表面粗糙度(Ra和Rt)分别降低了33%、31%和25%。可以观察到，在1000℃下Monel-400退火时，最大改善率可达到42%的Fz, 35%的Ra和59%的Rt。在加工退火材料时，刀具磨损显著减少，从而最大限度地降低了刀具和整体加工成本。对于钻孔工艺对考虑响应的影响，结果表明主轴转速对切削力的影响较大，而进给速度对Ra的影响最为显著。通过对主效果图和地表效果图的分析，确定了钻孔输入参数对输出的重要意义。然后，利用多目标遗传算法(MOGA)识别出切削力和表面粗糙度最小的最优参数条件。通过多目标优化得到的最优值为切削力Fz = 388 ~ 466 N，表面粗糙度Ra = 0.17 ~ 0.19 μm, Rt = 3 ~ 3.5 μm。

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