Small precision parts with miniaturized features are increasingly used in components such as sensors, micro-medical devices, micro-fuel cells, and others. Mechanical micromachining processes, e.g., turning, drilling, milling and grinding are often used for fabrication of miniaturized components. The small micro-tools (50 μm to 500 μm diameter) used in micromachining limit the surface speeds achieved at the cutting point, unless the rotational speeds are substantially increased. Although the cutting speeds increase to 240 m/min with larger diameter tools (e.g., 500 μm) when using the highest available spindle speed of 150,000 rpm, the cutting speed with the smaller 50 μm tools is limited to 24 m/min. This low cutting speed at the tool tip is much smaller than the speeds required for efficient cutting. For example, in macro-milling of aluminum alloys the recommended speed is on the order of 60-200 m/min. The use of low cutting speeds limits the production rate, increases tool wear and tendency for burr formation, and limits the degree of dimensional tolerance and precision that can be achieved. The purpose of the present paper is to provide preliminary results that show the feasibility of ultra high-speed micro-milling of an aluminum alloy with respect to surface quality and burr formation. A new ultra highspeed spindle was used for micro-milling of an aluminum alloy with micro-end-mills ranging in diameter from 51 μm to 305 μm. Straight channels were machined to obtain an array of square patterns on the surface. High surface cutting speeds up to 340 m/min were achieved at 350,000 rpm. Inspection of the machined surfaces indicated that edge quality and burr formation tendency are related to the undeformed chip thickness, and therefore the cutting speed and feed rate. The quantity of burrs observed on the cut surfaces was generally small, and therefore, the burr types were not systematically determined. Cutting with the 305 μm tool at a cutting speed of 150 m/min produced an excellent cut quality using a chip thickness of 0.13 μm. However, the cut quality deteriorated as the chip thickness was decreased to 0.06 μm by increasing the cutting speed to 340 mm/min. This result is consistent with published data that show the dependence of bur formation on ratio of chip thickness to tool tip radius. The channel widths were also measured and the width of channels cut with the small diameter tools became larger than the tool diameter at higher speeds. The dependence of the channel widths on rotational speed and the fact that a similar variation was not observed for larger diameter tools, suggested that this phenomena is related to dynamic run-out of the tool tip, which increases the channel width at higher speeds.
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机译:具有微型化特征的精密小零件越来越多地用于传感器,微医疗设备,微燃料电池等组件中。机械微加工工艺,例如车削,钻孔,铣削和磨削,通常用于制造微型零件。微加工中使用的小型微型工具(直径为50μm至500μm)会限制在切削点处获得的表面速度,除非旋转速度显着提高。尽管使用最大可用主轴转速150,000 rpm时,使用较大直径的刀具(例如500μm)时切削速度增加到240 m / min,但使用较小的50μm刀具时切削速度被限制为24 m / min。刀尖处的这种低切削速度比有效切削所需的速度小得多。例如,在铝合金的宏观铣削中,建议的速度约为60-200 m / min。低切削速度的使用限制了生产率,增加了工具的磨损和毛刺的形成趋势,并限制了可达到的尺寸公差和精度。本文的目的是提供初步的结果,表明在表面质量和毛刺形成方面进行铝合金超高速微铣削的可行性。新型超高速主轴用于直径为51μm至305μm的微型立铣刀的铝合金微铣削。对直通道进行机械加工以获得表面上的正方形图案阵列。在350,000 rpm时达到340 m / min的高表面切割速度。对加工表面的检查表明,边缘质量和毛刺形成趋势与未变形的切屑厚度有关,因此与切削速度和进给速度有关。在切割面上观察到的毛刺的数量通常很小,因此,不能系统地确定毛刺的类型。使用305μm刀具以150 m / min的切削速度进行切削时,使用0.13μm的切屑厚度可获得极佳的切削质量。但是,通过将切削速度提高至340mm / min,切削质量随着切屑厚度减小至0.06μm而恶化。该结果与公开的数据一致,该数据显示了bur的形成对切屑厚度与刀尖半径之比的依赖性。还测量通道宽度,并且在小速度下用小直径刀具切割的通道的宽度变得大于刀具直径。通道宽度对转速的依赖性以及大直径刀具未观察到类似变化的事实表明,这种现象与刀尖的动态跳动有关,这在较高速度下会增大通道宽度。
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