Simulation and experimental analysis of composite chamfering of superhard cutting tools based on edge grinding technology
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摘要: 为了改善圆弧刃倒棱聚晶金刚石(poly crystalline diamond,PCD)车刀加工有色金属的光亮程度,特在圆弧刃倒棱车刀基础上进行二次倒棱处理,使其形成复合倒棱结构。在CATIA软件中根据COBORN RG9磨床实际刃磨PCD倒棱刀具的工艺,建立圆柱形后刀面复合倒棱车刀三维模型,使用Deform V11.0软件进行PCD复合倒棱车刀的三维切削仿真分析,并根据仿真分析结果进行PCD复合倒棱车刀与PCD一阶倒棱车刀的切削实验对比。结果表明:复合倒棱结构只在较大的切削深度时才有提升工件光亮度的作用;在相同切削深度下,PCD复合倒棱车刀的切削温度小于PCD一阶倒棱车刀的;在切削深度为0.14 mm时,随着切削时间增加,PCD复合倒棱车刀加工零件的表面粗糙度要小于PCD一阶倒棱车刀的。结合PCD刀具的最终磨损状态发现,PCD复合倒棱车刀对切削后工件的捋平效果更佳,工件的光亮度更高,其抗磨损性能更好。Abstract: Objectives: Circular edge chamfering PCD turning tools often feature a chamfered surface at the cutting edge to enhance tool durability. However, the arc at the tool tip causes a large amount of chip accumulation in front of the tool, making chip discharge difficult. This leads to increased cutting temperatures, accelerated tool wear, and reduced surface brightness of the workpiece. To improve the brightness of circular edge chamfering PCD turning tools when processing non-ferrous metals and enhance the tool's durability, a composite chamfering structure is created by performing secondary chamfering on the basis of the circular edge chamfering tool. Methods: Using CATIA software and based on the actual grinding process of the PCD chamfering tool by the COBORN RG9 grinder, the grinding wheel is positioned at different points along the tool's moving path using the trajectory discrete envelope method. The unmachined tool is enveloped, and the overlap between the grinding wheel and the tool is removed, resulting in a three-dimensional approximate model of the composite chamfering tool. By extracting point coordinates, performing curve fitting, surface fitting, surface joining, and other methods, a three-dimensional model of the composite chamfering tool with a cylindrical back surface is established. Deform V11.0 software is then used to simulate the 3D cutting of the PCD composite chamfering tool, calculating the root-mean-square value of the cutting force and the mean cutting temperature under different cutting depths and second-order chamfering widths, as well as under different cutting depths and second-order chamfering angles. The analysis focuses on selecting the second-order chamfering width for different cutting depths when the first-order chamfering width is fixed, and choosing the second-order chamfering angle for different cutting depths when the second-order chamfering width is fixed. Based on this analysis, the effects of different inclination angles on the machining performance of the composite chamfering tool—such as chip flow changes, tool temperature variations, and tool wear—are analyzed. Finally, cutting experiments comparing the PCD composite chamfering tool and the PCD first-order chamfering tool are conducted to analyze changes in cutting temperature under different cutting depths, surface roughness of the workpiece over different processing times, and the final wear states of the two tools. Results: The simulation analysis results show that: (1) When the first-order chamfering width is constant and the cutting depth is smaller than the first-order chamfering width, the second-order chamfering width should be greater than the cutting depth. (2) If the cutting depth is large (even close to the first-order chamfering width), the second-order chamfering width should be smaller than the cutting depth. (3) When the cutting depth is small and does not exceed the second-order chamfering area, a larger second-order chamfering angle should be selected. (4) When the cutting depth is large, a smaller second-order chamfering angle should be selected. When cutting at an oblique angle, as the inclination angle of the tool gradually increases, interference with chip removal generally increases. The wear and tool temperature of the composite chamfered turning tool generally increase, but when the inclination angle is 10°, wear and temperature of the tool are lower, and chip removal interference is minimized. (5) When cutting at an oblique angle, as the inclination angle of the tool gradually increases, chip removal interference generally shows an increasing trend. However, at a 10° inclination angle, tool wear and temperature are lower, and chip removal interference is reduced. Specific experimental results of PCD tools show that, at the same cutting depth, the cutting temperature of the PCD composite chamfering tool is lower than that of the PCD first-order chamfering tool. Furthermore, when the cutting depth is 0.14 mm and the workpiece is turned for 30 minutes, as processing time increases, the surface roughness of the workpiece processed by the PCD composite chamfering tool remians lower than that of the PCD first-order chamfering tool. Conclusions: The composite chamfering of the PCD tool improves the brightness of the workpiece when the cutting depth is greater. The final wear state of the tool indicates that the PCD composite chamfering tool has a better smoothing effect during cutting than the PCD first-order chamfering tool, resulting in higher workpiece brightness and better wear resistance.
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Key words:
- PCD turning tool /
- cutting depth /
- surface roughnesse /
- tool wear
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图 3 砂轮与刀具的运动关系图
Figure 3. Motion relationship diagram between grinding wheel and cutting tool
图 4 复合倒棱刀具的圆弧刃近似模型
Figure 4. Approximate model of arc edge for compound chamfering tools
图 10 不同切深、不同二阶倒棱宽度时的切削力均方根值
Figure 10. Root mean square values of cutting forces at different cutting depths and second-order chamfering widths
图 11 不同切深、不同二阶倒棱宽度时的切削温度均值变化
Figure 11. Mean variation of cutting temperatures at different cutting depths and second-order chamfering widths
图 12 不同切深、不同二阶倒棱角度时的切削力均方根值
Figure 12. Root mean square values of cutting forces at different cutting depths and second-order chamfering angles
图 13 不同切深、不同二阶倒棱角度时的切削温度均值变化
Figure 13. Mean variation of cutting temperature at different cutting depths and second-order chamfering angles
图 15 不同刃倾角下2点在x轴上的位置变化
Figure 15. Position changes of two points on x-axis under different cutting edge inclination angles
图 16 不同刃倾角下2点在y轴上的位置变化
Figure 16. Position changes of two points on y-axis under different cutting edge inclination angles
图 17 不同刃倾角时刀具的瞬时温度
Figure 17. Instantaneous temperatures of tool at different cutting edge inclination angles
图 18 不同刃倾角时刀具的平均温度
Figure 18. Average temperatures of tool at different cutting edge inclination angles
图 20 不同刃倾角时刀具的磨损平均深度变化
Figure 20. Change in average depth of tool wear at different cutting edge inclination angles
图 24 2种刀具下工件表面切削温度随切削深度的变化
Figure 24. Variation of workpiece surface cutting temperatures with cutting depths under two kinds of tools
图 26 零件表面粗糙度随加工时间的变化
Figure 26. Variation of surface roughness of part with processing time
表 1 实验车床具体参数
Table 1. Specific parameters of experimental lathe
参数 规格或取值 机床最大回转直径 D / mm 320 最大工件长度 L / mm 750 主轴转速范围 n / (r·min−1) 200~ 3000 主轴电机功率 P / kW 5.5 刀方尺寸 20 mm×20 mm 
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