Machinability and surface integrity investigation during helical hole milling in AZ31 magnesium alloy

Raviraja Adhikari , Gururaj Bolar , Ragavanantham Shanmugam , Ugur Koklu
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引用次数: 5

Abstract

Conventional drilling has been widely used for making holes in structural materials. However, drawbacks like high cutting forces, poor surface finish, high cutting temperatures, excessive tool wear, and undesirable burr formation while drilling magnesium alloys have necessitated the development of alternative hole-making methods. Lately, the helical milling process has attracted interest in facilitating hole-making for assembly applications. However, the machinability of magnesium alloys using the helical milling process needs more investigation. Therefore, the presented work analyzed the influence of axial pitch, tangential feed, and spindle speed on cutting forces and surface integrity while milling AZ31 magnesium alloy. Axial feed was the most crucial factor contributing to the thrust force (71.8%), followed by tangential feed (13.2%). All three process variables impacted the radial force. Spindle speed was the most influential variable affecting the surface roughness (48.7%), followed by axial pitch (31.4%) and tangential feed (12.5%). Microhardness closer to the free surface of the hole was higher than the subsurface hardness. Moreover, microhardness showed an upward trend with the rise in axial pitch and tangential feed; however, it reduced with increased spindle speed.

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AZ31镁合金螺旋孔铣削加工的可加工性和表面完整性研究
传统钻孔已被广泛用于在结构材料中钻孔。然而,在钻镁合金时,存在切削力高、表面光洁度差、切削温度高、刀具过度磨损和不希望形成毛刺等缺点,因此需要开发替代的制孔方法。最近,螺旋铣削工艺吸引了人们对促进组装应用的孔制造的兴趣。然而,使用螺旋铣削工艺的镁合金的可加工性需要更多的研究。因此,本文分析了在铣削AZ31镁合金时,轴向螺距、切向进给和主轴速度对切削力和表面完整性的影响。轴向进给是影响推力的最关键因素(71.8%),其次是切向进给(13.2%)。所有三个过程变量都影响径向力。主轴转速是影响表面粗糙度的最大变量(48.7%),其次是轴向螺距(31.4%)和切向进给(12.5%)。接近孔自由表面的显微硬度高于表面下硬度。显微硬度随轴向螺距和切向进给量的增加呈上升趋势;然而,它随着主轴速度的增加而减小。
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来源期刊
International Journal of Lightweight Materials and Manufacture
International Journal of Lightweight Materials and Manufacture Engineering-Industrial and Manufacturing Engineering
CiteScore
9.90
自引率
0.00%
发文量
52
审稿时长
48 days
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