五轴加工通用刀具切触区高效计算及切削力预测

doi:10.3901/JME.2025.09.132

机械工程学报 ›› 2025, Vol. 61 ›› Issue (9): 132-141.doi: 10.3901/JME.2025.09.132

• 特邀专栏：高性能制造 • 上一篇

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五轴加工通用刀具切触区高效计算及切削力预测

高书颜, 黄明坤, 黄涛, 张小明, 丁汉

华中科技大学智能制造装备与技术全国重点实验室武汉 430074

收稿日期:2024-05-09 修回日期:2024-09-23 发布日期:2025-06-12
通讯作者: 黄涛,男,1987年出生,副教授,硕士研究生导师。主要研究方向为智能化加工与工业软件研发。E-mail:tao.huang@hust.edu.cn E-mail:tao.huang@hust.edu.cn
作者简介:高书颜,男,1999年出生,博士研究生。主要研究方向为智能化加工与工业软件研发。E-mail:gaoshuyaan@foxmail.com
基金资助:
国家自然科学基金(52075205，92160207，52188102)资助项目。

Efficient Computation of Cutter-workpiece Engagement and Cutting Force Prediction for General Cutter in Five-axis Machining

GAO Shuyan, HUANG Mingkun, HUANG Tao, ZHANG Xiaoming, DING Han

State Key Laboratory of Digital Manufacturing Equipment and Technology, Huazhong University of Science and Technology, Wuhan 430074

Received:2024-05-09 Revised:2024-09-23 Published:2025-06-12

摘要/Abstract

摘要： 切削力准确预测有助于优化铣削加工参数、提高效率，在五轴加工中，不同形状刀具的切触区高效计算是预测切削力的核心难题之一。为此，提出了一种基于距离场的“等效运动+自适应八叉树”方法，实现了五轴加工通用刀具切触区高效计算。基于距离场和八叉树方法对工件表面进行初始化并存储，构建通用刀具的表面距离函数；提出了计算材料去除后工件表面的等效运动法，避免了刀具扫掠体计算，大幅提升材料去除仿真效率；建立了基于距离函数的刀具-工件切触区域面片提取方法，采用STL切片方法获取刀具微元上的边界点并计算切入切出角；基于机械力模型计算瞬时切削力。材料去除仿真、切削力预测功能集成于自主开发的数控加工仿真与优化软件TurboCut，通过与ModuleWorks、ACIS B-rep的仿真对比以及切削实验结果验证，表明本文提出的方法能够实现高效切触区域计算和切削力预测。

关键词: 通用刀具, 五轴数控加工, 刀具切触区域, 切削力预测

Abstract: Accurate prediction of cutting force is essential for optimizing milling process parameters and improving efficiency. In five-axis machining, the efficient computation of cutter-workpiece engagement (CWE) for different cutter remains challenge in the prediction of cutting force. An efficient computation method for the CWE of a general cutter in five-axis machining, based on distance fields and adaptive octrees, is proposed. The method involves initializing and storing the workpiece surface using distance field and octree techniques, as well as constructing a surface distance function for the general cutter. Then, an equivalent motion method for calculating the workpiece surface after material removal is introduced, eliminating the need to calculate the cutter swept volume, which significantly improves the efficiency of material removal simulations. Furthermore, the extraction of tool-workpiece contact region facets is established based on the distance function, using the STL slicing method to obtain boundary points on the cutter elements, followed by determining the entry and exit angles. Instantaneous cutting forces are computed based on a mechanical force model. The integrated functionalities of material removal simulation and cutting force prediction are implemented in the self-developed CNC machining simulation and optimization software, TurboCut. The simulation results are shown to have advantages when compared with those obtained using ModuleWorks or the B-rep method. Validation against cutting test is demonstrated to show that the proposed method achieves efficient CWE computation and cutting force prediction.

Key words: general tool, five-axis milling, cutter-workpiece engagement, cutting force prediction

中图分类号:

TG156

高书颜, 黄明坤, 黄涛, 张小明, 丁汉. 五轴加工通用刀具切触区高效计算及切削力预测[J]. 机械工程学报, 2025, 61(9): 132-141.

GAO Shuyan, HUANG Mingkun, HUANG Tao, ZHANG Xiaoming, DING Han. Efficient Computation of Cutter-workpiece Engagement and Cutting Force Prediction for General Cutter in Five-axis Machining[J]. Journal of Mechanical Engineering, 2025, 61(9): 132-141.

参考文献

[1] LAZOGLU I,BOZ Y,ERDIM H. Five-axis milling mechanics for complex free form surfaces[J]. CIRP Annals,2011,60(1):117-120.
[2] DUAN Z,LI C,DING W,et al. Milling force model for aviation aluminum alloy:Academic insight and perspective analysis[J]. Chinese Journal of Mechanical Engineering,2021,34(1):18.
[3] YAN B,HAO Y,ZHU L,et al. Towards high milling accuracy of turbine blades:A review[J]. Mechanical Systems and Signal Processing,2022,170:108727.
[4] 董永亨,李淑娟,张倩,等. 基于半解析法的球头铣刀静态铣削力的建模[J]. 机械工程学报,2022,58(11):282-294. DONG Yongheng,LI Shujuan,ZHANG Qian,et al. Modeling on static milling force of ball-end-milling cutters based on semi-analytical method[J]. Journal of Mechanical Engineering,2022,58(11):282-294.
[5] 曹玉娟,武殿梁. 支持机床在线可视化监控的切削仿真算法研究[J]. 计算机仿真,2020,37(12):157-160,213. CAO Yujuan,WU Dianliang. Research on cutting simulation algorithm supporting online visual monitoring of machine tools[J]. Computer Simulation,2020,37(12):157-160,213.
[6] 吴石,张添源. 凸曲面拼接模具球头铣刀的瞬时铣削力预测[J]. 振动、测试与诊断,2020,40(5):948-956. WU Shi,ZHANG Tianyuan. Prediction of the instantaneous milling force of ball end milling cutter for convex surface splicing mold[J]. Journal of Vibration,Measurement& Diagnosis,2020,40(5):948-956.
[7] YANG Y,ZHANG W,WAN M,et al. A solid trimming method to extract cutter-workpiece engagement maps for multi-axis milling[J]. The International Journal of Advanced Manufacturing Technology,2013,68(9):2801-2813.
[8] XI X,CAI Y,GAO Y,et al. An analytical method to calculate cutter-workpiece engagement based on arc-surface intersection method[J]. The International Journal of Advanced Manufacturing Technology,2020,107(1):935-944.
[9] 魏兆成,王敏杰,王学文,等. 球头铣刀曲面多轴加工的刀具接触区半解析建模[J]. 机械工程学报,2017,53(1):198-205. WEI Zhaocheng,WANG Minjie,WANG Xuewen,et al. A semi-analytical cutter workpiece engagement model for ball end milling of sculptured surface[J]. Journal of Mechanical Engineering,2017,53(1):198-205.
[10] KIM G M,CHO P J,CHU C N. Cutting force prediction of sculptured surface ball-end milling using Z-map[J]. International Journal of Machine Tools and Manufacture,2000,40(2):277-291.
[11] 董永亨,李淑娟,洪贤涛,等. 基于Z-MAP方法的球头铣刀铣削力的建模[J]. 机械工程学报,2020,55(19):201-212. DONG Yongheng,LI Shujuan,HONG Xiantao,et al. Modeling on static milling force of ball-end-milling cutters based on Z-MAP method[J]. Journal of Mechanical Engineering,2022,58(11):201-212.
[12] QIN S,HAO Y,ZHU L,et al. CWE identification and cutting force prediction in ball-end milling process[J]. International Journal of Mechanical Sciences,2023,239:107863.
[13] DAMBLY V,RIVIÈRE-LORPHÈVREÉ,DUCOBU F,et al. Tri-dexel-based cutter-workpiece engagement:Computation and validation for virtual machining operations[J]. The International Journal of Advanced Manufacturing Technology,2024,131(2):623-35.
[14] NIE Z,FENG H Y. Integrated and efficient cutter-workpiece engagement determination in three-axis milling via voxel modeling[J]. The International Journal of Advanced Manufacturing Technology,2023,128(1):391-403.
[15] PUJOL E,CHICA A. Adaptive approximation of signed distance fields through piecewise continuous interpolation[J]. Computers & Graphics,2023,114:337-346.
[16] 徐金亭,刘伟军,卞宏友,等. 基于网格曲面模型的等残留刀位轨迹生成方法[J]. 机械工程学报,2010,46(11):193-198. XU Jinting,LIU Weijun,BIAN Hongyou,et al. Constant scallop tool path for triangular surface machining[J]. Journal of Mechanical Engineering,2010,46(11):193-198.
[17] ENGIN S,ALTINTAS Y. Mechanics and dynamics of general milling cutters.:Part I:Helical end mills[J]. International Journal of Machine Tools and Manufacture,2001,41(15):2195-2212.
[18] ModuleWorks GMBH. Module Wooks/CAM components[EB/OL].[2023-12-25]. https://www.moduleworks.com/.
[19] Spatial CORP. 3D ACIS Modeler|Spatial[EB/OL].[2023-12-25]. https://www.spatial.com/products/3d-acis-modeling.

五轴加工通用刀具切触区高效计算及切削力预测

Efficient Computation of Cutter-workpiece Engagement and Cutting Force Prediction for General Cutter in Five-axis Machining

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