基于磨削痕迹仿真的磨削纹理生成机理

doi:10.3969/j.issn.1004-132X.2021.14.006

摘要/Abstract

摘要： 针对球面和非球面垂直磨削法加工中出现的磨削纹理，开展了基于磨削痕迹轨迹仿真的磨削纹理生成机理研究，建立了磨削痕迹运动分布方程，仿真分析了磨削痕迹在垂直磨削表面的生成和分布机制，揭示了磨削加工参数变化引起的磨削纹理生成机理。通过仿真结果可以看出，垂直磨削后的工件表面残留磨削痕迹分布为中心区域密集、外缘区域稀疏，并具备周期性、放射分布的特征；砂轮圆周上参与磨削的磨粒残留在工件表面的磨削痕迹长度、形状和分布规律几乎完全相同，磨削痕迹间仅存在一定的相位偏差；砂轮与工件的转速比为整数时，相邻螺旋周期的破碎磨削痕迹首尾相接，使得磨削痕迹交接处发生了破碎的耦合与扩展，加剧了工件表面的破碎，并将破碎的磨削痕迹连接在一起，形成磨削纹理。

关键词: 垂直磨削法, 磨削痕迹分布, 磨削纹理, 生成机理

Abstract: Because grinding marks would remain on spherical and aspherical surfaces in cross grinding, so generating mechanism of grinding marks was investigated based on grinding trace simulations. Distribution equation of grinding traces was established. Generation and distribution mechanism of grinding traces on ground surfaces was analyzed in cross grinding, and the generation mechanism of grinding marks caused by alteration of grinding parameters was revealed. From the results of simulations, it may be found that the distribution of grinding traces is dense at central areas and sparse at outer areas of ground surfaces, and the distributions are periodic and radial. Length regularity, shape regularity, and distribution regularity of all the grinding traces remained on the ground surfaces were similar, except a certain phase angle is varied among grinding traces. When ratio of grinding wheel rotary speed to workpiece rotary speed is as integer, the worst grinding traces of two adjacent periods are connected together end-to-end, which leads to coupling and propagation of cracks at the junction. And then, breakage situation of ground surfaces is aggravated. Finally, the broken grinding traces are connected together, and the grinding marks are generated.

Key words: cross grinding method, distribution of grinding trace, grinding mark, generation mechanism

中图分类号:

TH162

陈冰, 罗良, 焦浩文, 邓朝晖, 姚洪辉. 基于磨削痕迹仿真的磨削纹理生成机理[J]. 中国机械工程, 2021, 32(14): 1677-1685.

CHEN Bing, LUO Liang, JIAO Haowen, DENG Zhaohui, YAO Honghui. Generation Mechanism of Grinding Marks Based on Grinding Trace Simulations[J]. China Mechanical Engineering, 2021, 32(14): 1677-1685.

导出引用管理器 EndNote|Ris|BibTeX

链接本文: http://www.cmemo.org.cn/CN/10.3969/j.issn.1004-132X.2021.14.006

http://www.cmemo.org.cn/CN/Y2021/V32/I14/1677

参考文献

［1］HUANG C Y, KUO C H, YU Z R, et al. Development of an Intelligent Grinding System for Fabricating Aspheric Glass Lenses［J］. The International Journal of Advanced Manufacturing Technology, 2020, 111(5):1351-1359.
［2］WEI X, LI B, CHEN L, et al. Tool Setting Error Compensation in Large Aspherical Mirror Grinding［J］. The International Journal of Advanced Manufacturing Technology, 2018, 94(9):4093-4103.
［3］YOSHIHARA N, KURIYAGAWA T, ONO H, et al. Nano-topography on Axisymmetric Aspherical Ground Surfaces［J］. International Journal of Manufacturing Technology & Management, 2017, 9(9):51-63.
［4］SUN X, STEPHENSON D J, OHNISHI O, et al. An Investigation into Parallel and Cross Grinding of BK7 Glass［J］. Precision Engineering, 2006, 30(2):145-153.
［5］WANG T, LIU H, WU C, et al. Three-dimensional Modeling and Theoretical Investigation of Grinding Marks on the Surface in Small Ball-end Diamond Wheel Grinding［J］. International Journal of Mechanical Sciences, 2020, 173:105467.
［6］陈实, 张执南, 蔡晓江,等. 磨削参数对工件表面形貌及其摩擦性能的影响［J］. 上海交通大学学报, 2018, 52(5):575-581.
CHEN Shi, ZHANG Zhinan, CAI Xiaojiang, et al. Influence of Grinding Parameters on Workpiece Surface Morphology and Friction Performance［J］. Journal of Shanghai Jiao Tong University, 2018, 52(5):575-581.
［7］朱双霞, 刘莹, 李小兵,等. 磨削加工表面纹理的特征分析［J］. 机械设计与制造, 2008(8):142-143.
ZHU Shuangxia, LIU Ying, LI Xiaobing, et al. Analyzing on Surface Texture Processed by Grinding［J］. Machinery Design & Manufacture, 2008(8):142-143.
［8］LIN X, LIU J, KE X, et al. Investigation of Waviness Error in Surface Grinding of Large Axisymmetric Aspheric Lenses［J］. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 2016, 230:1195-1202.
［9］GAO S, KANG R, DONG Z, et al. Edge Chipping of Silicon Wafers in Diamond Grinding［J］. International Journal of Machine Tools and Manufacture, 2013, 64:31-37.
［10］ZHANG Z, HUO F, WU Y, et al. Grinding of Silicon Wafers Using an Ultrafine Diamond Wheel of a Hybrid Bond Material［J］. International Journal of Machine Tools and Manufacture, 2011, 51(1):18-24.
［11］HUO F W, KANG R K, LI Z, et al. Origin, Modeling and Suppression of Grinding Marks in Ultra Precision Grinding of Silicon Wafers［J］. International Journal of Machine Tools and Manufacture, 2013, 66:54-65.
［12］SUN W, PEI Z J, FISHER G R. Fine Grinding of Silicon Wafers:Effects of Chuck Shape on Grinding Marks［J］. International Journal of Machine Tools and Manufacture, 2005, 45(6):673-686.
［13］CHIDAMBARAM S, PEI Z J, KASSIR S. Fine Grinding of Silicon Wafers:a Mathematical Model for the Chuck Shape［J］. International Journal of Machine Tools and Manufacture, 2003, 43(7):739-746.
［14］SUN W, PEI Z J, FISHER G R. Fine Grinding of Silicon Wafers:a Mathematical Model for the Wafer Shape［J］. International Journal of Machine Tools and Manufacture, 2004, 44(7):707-716.
［15］PEI Z J, STRASBAUGH A. Fine Grinding of Silicon Wafers:Grinding Marks［J］. International Journal of Machine Tools & Manufacture, 2002, 41(5):659-672.
［16］CHIDAMBARAM S, PEI Z J, KASSIR S. Fine Grinding of Silicon Wafers:a Mathematical Model for Grinding Marks［J］. International Journal of Machine Tools and Manufacture, 2003, 43(15):1595-1602.
［17］王玉珏, 许黎明, 李冬冬, 等. 摆动式展成球面磨削表面的纹理分析［J］. 上海交通大学学报, 2012, 46(5):740-745.
WANG Yujue, XU Liming, LI Dongdong, et al. Sphere Generation Grinding Based Spherical Surface Marks Analysis［J］. Journal of Shanghai Jiao Tong University, 2012, 46(5):740-745.
［18］WANG P, ZHANG H, HUI C. Theoretical and Experimental Investigation of Grinding Marks in Sphere NC Grinding Process［C］∥7th International Symposium on Advanced Optical Manufacturing and Testing Technologies. Harbin, 2014:92810T-7.
［19］CHEN S, CHEUNG C F, ZHANG F, et al. Three-dimensional Modelling and Simulation of Vibration Marks on Surface Generation in Ultra-precision Grinding［J］. Precision Engineering, 2018, 53:221-235.
［20］PAN Y, ZHAO Q, GUO B, et al. An Investigation of the Surface Waviness Features of Ground Surface in Parallel Grinding Process［J］. International Journal of Mechanical Sciences, 2020, 170:105351.
［21］CHEN B, LI S, DENG Z, et al. Grinding Marks on Ultra-precision Grinding Spherical and Aspheric Surfaces［J］. International Journal of Precision Engineering and Manufacturing—Green Technology, 2017, 4(4):419-429.
［22］席建普, 刘同士, 李亚东, 等. 大口径非球面镜交叉磨削中波纹度产生机理的研究［J］. 金刚石与磨料磨具工程, 2020, 40(3):91-97.
XI Jianpu, LIU Tongshi, LI Yadong, et al. Study on Mechanism of Waviness in Cross Grinding Large Diameter Aspherical Mirror［J］. Diamond & Abrasives Engineering, 2020, 40(3):91-97.
［23］OLIVEIRA J F G, BOTTENE A C, FRANA T V. A Novel Dressing Technique for Texturing of Ground Surfaces［J］. CIRP Annals, 2010, 59(1):361-364.
［24］赵国伟, 吕玉山, 李雨菲, 等.有序化砂轮磨削表面粗糙度仿真［J］.机械设计与制造, 2018(3):223-225.
ZHAO Guowei, LYU Yushan, LI Yufei, et al. Simulation of the Surface Roughness with Grinding Wheel of Ordered Abrasive Pattern［J］. Machinery Design & Manufacture, 2018(3):223-225.
［25］CHEN B, GUO B, ZHAO Q. An Investigation into Parallel and Cross Grinding of Aspheric Surface on Monocrystal Silicon［J］. International Journal of Advanced Manufacturing Technology, 2015, 80(5/8):737-746.
［26］CHEN B, GUO B, ZHAO Q. On-machine Precision form Truing of Arc-shaped Diamond Wheels［J］. Journal of Materials Processing Technology, 2015, 223:65-74.

[1]	白小帆, 刘志强, 刘彦士. 轴向低频振动对皮质骨钻削进给力的影响试验与分析[J]. 中国机械工程, 2023, 34(20): 2411-2427.
[2]	刘英杰, 胡强, 赵新明, 张少明, 黄帅, 王永慧. 汽车发动机连接支架拓扑优化及增材制造研究[J]. 中国机械工程, 2023, 34(18): 2238-2267.
[3]	谢法吾, 李玲玲, 李丽, 黄洋鹏. 基于多目标混合进化算法的作业车间混排可变分批节能调度方法[J]. 中国机械工程, 2023, 34(13): 1576-1588,1598.
[4]	王成兵, 熊建军, 江磊, 马术文. 钻尖直线刃后刀面的砂轮磨削轨迹算法研究[J]. 中国机械工程, 2022, 33(16): 1906-1911.
[5]	夏琴香, 曾伟国, 陈明星, 肖刚锋, 黄国军. 基于实例推理的模具零件加工工艺决策模型构建及应用[J]. 中国机械工程, 2022, 33(08): 970-976，985.
[6]	余建杭, 颜培, 范雷, 顾慧卿, 焦黎, 仇天阳, 王西彬. 相态对镍钛合金清洁切削性能和表面完整性的影响[J]. 中国机械工程, 2022, 33(05): 569-576.
[7]	杨晓龙, 唐煜, 朱荻. 面向薄膜沸腾传热的仿生拓扑表面毛细传输研究[J]. 中国机械工程, 2021, 32(23): 2799-2807.
[8]	陈妮, 韦佳伟, 张鑫磊, 李亮, 何宁. 激光改性后氮化铝基板的可加工性研究[J]. 中国机械工程, 2021, 32(23): 2817-2882.
[9]	吴柯, 陆新明, MEHMOOD Awais, 周立波, 袁巨龙. 基于固结磨粒的单晶蓝宝石自旋转磨削加工方法[J]. 中国机械工程, 2021, 32(16): 2002-2007，2015.
[10]	白小帆;侯书军;李慨;曲云霞. 轴向低频振动辅助皮质骨钻削的钻削力和温升[J]. 中国机械工程, 2021, 32(03): 321-330.
[11]	高彦凯;陈东;夏慧超;武广涛. 热轧钢卷打捆中的延迟锁扣技术[J]. 中国机械工程, 2021, 32(03): 363-367.
[12]	焦浩文1;陈冰1;罗良1;李锦棒2,3. 纳秒激光加工2.5维Cf/SiC复合材料的烧蚀孔洞特征[J]. 中国机械工程, 2020, 31(08): 983-990.
[13]	张恒;李爱平;傅翔;邵焕;刘雪梅. 面向混批加工的装夹方案选择与线平衡集成优化方法[J]. 中国机械工程, 2019, 30(20): 2497-2504.
[14]	盛精1,2;解若愚1. 一种塑制汽车离合器泵的旋转摩擦焊接工艺参数的设计方法[J]. 中国机械工程, 2019, 30(14): 1742-1747.
[15]	李国民;高亮;李新宇. 不确定性环境下轨道自动导引车动态调度[J]. 中国机械工程, 2019, 30(08): 926-931.