Analysis of Cutting Forces During Grinding of Titanium Alloy and Corrosion-Resistant Steel by Diamond, Electrocorundum and Cubic Borine Nitrid Wheels

V. Lebedev, T. Chumachenko, A. Bespalova, T. Nikolaeva, Y. Omelchenko
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Abstract

The object of research is the process of circular and surface grinding of titanium alloy and corrosion-resistant steel, namely, the cutting forces arising from mechanical processing. One of the most problematic areas in work is the selection of the required grinding modes, material and grinding wheel grain size.

In the course of the experiment, we used samples of VT8 titanium alloy and 12Х18N9T steel, on which the grinding process was studied with wheels made of various materials (electrocorundum, cubic boron nitride (CBN), diamond). The values of the cutting forces Py and Pz were obtained in the latitude of permissible modes, which are most often used in circular and flat grinding, and can reach maximum values, respectively, Py=27 N, Pz=15.5 N. The data were obtained at a low wheel speed from electrocorundum, about 15 m/s and grain size 8. By reducing the grain size of the wheel, we get the effect of increasing the energy consumption of the grinding process, due to the increase in the values of the cutting forces. If we compare the cutting forces arising from grinding with different wheels, then the following can be noted. Compared to electrocorundum wheels, when using CBN wheels, the cutting forces are reduced by 20–25 %, and when grinding with diamond wheels (despite the high wear of the diamond wheel), the effect of cutting forces is reduced by 25–30 %. This is due to the fact that cutting conditions are the most favorable for diamond and CBN grains, which makes it possible to use more intense cutting conditions.

The results of the study allow predicting the performance of the grinding wheel, reducing the energy consumption of production, and also adjusting the processing mode of the part to obtain the necessary quality indicators of the surface layer and the geometric dimensions of the part.
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金刚石、电刚玉和立方硼氮轮磨削钛合金和耐蚀钢的切削力分析
研究对象是钛合金和耐蚀钢的圆磨和面磨过程,即机械加工产生的切削力。工作中最棘手的问题之一是选择所需的磨削方式、材料和砂轮粒度。在实验过程中,我们以VT8钛合金和12Х18N9T钢为样品,对不同材料(电刚玉、立方氮化硼(CBN)、金刚石)的砂轮进行磨削过程研究。切削力Py和Pz的取值在圆磨和平磨中最常用的允许模态纬度上,分别可以达到最大值Py=27 N, Pz=15.5 N。数据是在低轮速下由电刚玉获得的,约为15 m/s,晶粒尺寸为8。通过减小砂轮的晶粒尺寸,由于切削力值的增加,我们得到了增加磨削过程能耗的效果。如果我们比较用不同的砂轮磨削所产生的切削力,那么可以注意到以下几点。与电刚玉砂轮相比,使用CBN砂轮时,切削力降低了20 - 25%,而使用金刚石砂轮磨削时(尽管金刚石砂轮磨损高),切削力的效果降低了25 - 30%。这是由于切削条件对金刚石和CBN晶粒最有利,这使得使用更强的切削条件成为可能。研究结果可以预测砂轮的性能,降低生产能耗,还可以调整零件的加工方式,以获得必要的表面层质量指标和零件的几何尺寸。
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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