基于磨削力的铣刀螺旋槽磨削工艺优化*

doi:10.16731/j.cnki.1671-3133.2024.02.009

现代制造工程 ›› 2024, Vol. 521 ›› Issue (2): 61-67.doi: 10.16731/j.cnki.1671-3133.2024.02.009

基于磨削力的铣刀螺旋槽磨削工艺优化^*

张富能, 林志伟, 薛勇, 李坰其, 傅建中

浙江大学制造技术及装备自动化研究所,杭州 310015

收稿日期:2023-05-29 出版日期:2024-02-18 发布日期:2024-05-29
通讯作者: 林志伟,博士,助理研究员,主要研究方向为计算机辅助制造研究。E-mail:zjtzhylin@zju.edu.cn
作者简介:张富能,硕士研究生,主要研究方向为球头立铣刀的CAM研究。E-mail:funeng@zju.edu.cn
基金资助:
*浙江省重点研发计划项目基金项目(2021C01096)

Optimization of the milling cutter spiral groove grinding process based on grinding force

ZHANG Funeng, LIN Zhiwei, XUE Yong, LI Jiongqi, FU Jianzhong

Institute of Manufacturing Technology and Equipment Automation,Zhejiang University,Hangzhou 310015,China

Received:2023-05-29 Online:2024-02-18 Published:2024-05-29

摘要/Abstract

摘要： 为了提高铣刀磨削质量,以铣刀磨制过程中的磨削力为对象,通过求取砂轮与铣刀接触线的表达方程,建立铣刀螺旋槽磨削过程磨削力求解模型,讨论磨削力对铣刀磨削质量的影响。以影响磨削力的主要因素铣刀进给速度及磨削深度为变量,提出等进给速度及变进给速度两种减小磨削力、降低应变的优化方案。通过调节进给速度及磨削深度,在保证磨削效率不变的情况下,减小磨削力,从而减小螺旋槽在磨削过程中因磨削力而产生的形变量。建立铣刀三维模型,导入ANSYS的 Workbench中进行磨削过程仿真,得出具体形变量,验证磨削优化方案的准确性。

关键词: 磨削力, 进给速度, 磨削深度, 磨削效率, 仿真

Abstract: In order to optimize the milling cutter grinding process,taking the grinding force in the grinding process of the milling cutter as the object,the grinding solution model of the grinding cutter spiral groove grinding process was established by finding the expression of the contact line between the grinding wheel and the milling cutter,and the influence of the grinding force on the grinding quality of the milling cutter was discussed.Taking the main factors affecting the grinding force,milling cutter feed speed and grinding depth,two optimization schemes were proposed—equal feed speed and variable feed speed. By adjusting the feed speed and grinding depth,the grinding force was reduced under the condition that the grinding efficiency remains unchanged,thereby reducing the shape variable caused by the grinding force in the grinding process of the spiral groove.The 3D model of the milling cutter was established and imported into ANSYS for grinding process simulation to obtain specific shape variables to verify the accuracy of the grinding optimization scheme.

Key words: grinding force, feed rate, grinding depth, grinding efficiency, simulation

中图分类号:

TH136

张富能, 林志伟, 薛勇, 李坰其, 傅建中. 基于磨削力的铣刀螺旋槽磨削工艺优化^*[J]. 现代制造工程, 2024, 521(2): 61-67.

ZHANG Funeng, LIN Zhiwei, XUE Yong, LI Jiongqi, FU Jianzhong. Optimization of the milling cutter spiral groove grinding process based on grinding force[J]. Modern Manufacturing Engineering, 2024, 521(2): 61-67.

参考文献

[1] CHEN Z,JI W,HE G,et al.Iteration based calculation of position and orientation of grinding wheel for solid cutting tool flute grinding[J].Journal of Manufacturing Processes,2018,36(12):209-215.
[2] DENKENA B,KRDEL A,THEUER M.Novel continuous generating grinding process for the production of cutting tools[J].CIRP Journal of Manufacturing Science and Technology,2020,28:1-7.
[3] 陈展.整体硬质合金立铣刀螺旋槽磨削及误差预测补偿算法研究[D].哈尔滨:哈尔滨理工大学,2021.
[4] 黎文娟,倪高明,王强,等.整体硬质合金螺旋立铣刀磨槽工艺优化[J].工具技术,2018,52(7):98-101.
[5] 李国超,周宏根,景旭文,等.基于小生境粒子群算法的刀具容屑槽刃磨工艺设计[J].计算机集成制造系统,2019,25(7):1746-1756.
[6] 周博文.基于遗传算法和代理模型的螺旋槽管槽形优化研究[D].武汉:华中科技大学,2021.
[7] 沙业典,关世玺,赵宏,等.基于模拟退火算法优化的支持向量回归机对内螺旋槽切削力的预测[J].工具技术,2023,57(1):100-105.
[8] JURKOVIC Z,CUKOR G,BREZOCNIK M,et al.A comparison of machine learning methods for cutting parame-ters prediction in high speed turning process[J].Journal of Intelligent Manufacturing,2018,29(8):1683-1693.
[9] UHLMANN E,HUBERT C.Tool grinding of end mill cutting tools made from high performance ceramics and cemented carbides[J].CIRP Annals-manufacturing Technology,2011,60(1):359-362.
[10] 宋铁军,周志雄,李伟,等.硬质合金刀具螺旋槽缓进给磨削力研究[J].中国机械工程,2014,25(9):1153-1158.
[11] ASLAN D,BUDAK E.Surface roughness and thermo-mechanical force modeling for grinding operations with regular and circumferentially grooved wheels[J].Journal of Materials Processing Technology,2015,223:75-90.
[12] 随卡卡.整体硬质合金刀具关键工步磨削工艺实验研究[D].长沙:湖南大学,2014.
[13] WITOLD F H.Effect of bond type and process parameters on grinding force components in grinding of cemented carbide[J].Procedia Engineering,2016,149:122-129.
[14] 孙倩楠.立铣刀螺旋槽磨削力变化及其影响分析研究[D].贵阳:贵州大学,2017.
[15] 刘丹丹,张树有,刘元开,等.一种基于特征点识别的曲线离散化方法[J].中国图象图形学报,2004(6):115-119.
[16] 詹友基.陶瓷结合剂金刚石砂轮高速磨削硬质合金的机理研究[D].泉州:华侨大学,2013.
[17] DING W F,XU J H,CHEN Z Z,et al.Grindabilityand surface integrity of cast nickel-based superalloyin creep feed grinding with brazed CBN abrasive wheels[J]. Chinese Journal of Aeronautics,2010,23(4):501-510.

基于磨削力的铣刀螺旋槽磨削工艺优化^*

Optimization of the milling cutter spiral groove grinding process based on grinding force

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