机械工程学报 >

2017 , Vol. 53 >Issue 1: 101 - 109

DOI: https://doi.org/10.3901/JME.2017.01.101

机械动力学

五轴数控机床动态精度检验试件特性研究*

  • 王伟 ,
  • 陶文坚 ,
  • 李晴朝
展开
  • 电子科技大学机械电子工程学院 成都 611731
王伟,男,1980年出生,博士,副教授。主要从事五轴数控机床精度检测技术、基于物联网的数控机床组网等方面的研究。E-mail:wangwhit@163.com

网络出版日期: 2017-01-05

基金资助

* 国家自然科学基金(51205048)和国家科技重大专项(2014ZX04014-031)资助项目; 20160219收到初稿,20161021收到修改稿;

收起

Research on Characteristic of Test Specimen for Five-axis CNCMachine Tools

  • WANG Wei ,
  • TAO Wenjian ,
  • LI Qingzhao
Expand
  • School of Mechatronics Engineering, University of Electronic Science and Technology of China, Chengdu 611731

Online published: 2017-01-05

Fold

摘要

检验试件是对机床动态精度的最终考量,然而目前基于试件切削的机床性能评估还存在很多不确定性。通过分析四种常用的五轴机床精度检验试件造型方法,计算各试件的曲率、开闭角、扭曲角等重要几何特征,研究试件加工过程中各轴加速度冲击的跳变位置,得出试件几何特征是其具备检验特性的关键。最终,通过切削试验验证中国“S”试件的优越性。基于检验试件的分析有助于建立试件与机床动态性能间的映射关系,完成加工后误差的定向溯源与辨识,为采用试件切削的评价方法提供更加充分的依据。

关键词: 五轴数控机床; 检验试件; 几何特性; 加工特性

本文引用格式

王伟 , 陶文坚 , 李晴朝 . 五轴数控机床动态精度检验试件特性研究*[J]. 机械工程学报, 2017 , 53(1) : 101 -109 . DOI: 10.3901/JME.2017.01.101

Abstract

Test specimen usually applied on checking dynamic precision of machine tools, but the performances of machine tools based on specimen cutting are still indeterminate. The modelings of four common test specimens for five-axis CNC machine tools are analyzed firstly. Then some important geometric features including the curvature, open-close angle, twisted angle of each specimen are studied. Next, the sudden change positions of acceleration on each axis are obtained during processing. So the various geometric characteristics are the key to test function of specimens. Finally, the superiority of Chinese “S” specimen is verified by the cutting experiments. The analysis results can be used to set up the relationship between test specimen and machine’s dynamic performance, and contributed to the machine’s error identification and traceability.

 

Key words: five-axis CNC machine tools; test specimen; geometric characteristics; processing characteristics

参考文献

 [1]  ANDOLFATTOA LLAVERNHE SMAYER J. Evaluation of servogeometric and dynamic error sources on five-axis high-speed machine tool[J]. International Journal of Machine Tools and Manufacture201151(10-11)787-796.

 [2]  粟时平,李圣怡. 基于空间误差模型的加工中心几何误差辨识方法[J]. 机械工程学报,200238(7)121-122.

        SU ShipingLI Shengyi. Identification method for errors of machining center based on volumetric error model[J]. Chinese Journal of Mechanical Engineering200238(7)121-122.

 [3]蔡晓华,杜正春. 五轴数控机床的运动精度诊断评述[J].机床与液压,2013(21)149-15285.

        CAI XiaohuaDU Zhengchun. Error motion diagnosis and review for 5-axis machine tool[J]. Machine Tool and Hydraulics2013(21)149-15285.

 [4]  仇健. 数控机床切削性能测试典型试件综述[J]. 制造技术与机床,2014(9)193-203.

        QIU Jian. Review on typical part for cutting test of NC machining centre[J]. Manufacturing Technology and Machine Tool2014(9)193-203.

 [5]  NAS979. Uniform cutting test-NAS seriesmetal cutting equipment[R]. WashigtonUSANAS1969.

 [6]  杜丽,张信,王伟,等.S”形试件的五轴数控机床综合动态精度检测特性研究[J]. 电子科技大学学报,2014(4)629-635. 

        DU LiZHANG XinWANG Weiet al. Research on properties of “S” shaped test piece on synthesis dynamic accuracy detection of five-axis CNC machine tools[J]. Journal of University of Electronic Science and Technology of China2014(4)629-635. 

 [7]  UTSUMI KKOSUGI TSAITO Aet al. Measurement method of geometric accuracy of five-axis controlled machining centers[J]. Japan Society of Mechanical Engineering200673(719)2293-2298.

 [8]  TSUTSUMI MYUMIZA DUTSUMI K.Evaluation of synchronous motion in five-axis machining centers with a tilting rotary table[J].Journal of Advanced Mechanical


        DesignSystems and Manufacturing20071(1)24-35.

 [9]  SONG ZhiyongCUI Yawen. S-shape detection test piece and a detection method for detecting the precision of the numerical control milling machineUSAUS52306208A[P]. 2008-01-11.

[10]  施法中. 计算机辅助几何设计及非均匀有理B样条[M].北京:高等教育出版社,2001.

        SHI Fazhong. CAGD & NURBS[M]. BeijingHigher Education Press2001.

[11]  宋玉旺. 完全掌握UG NX8.5超级手册[M]. 北京:机械工业出版社,2014.

        SONG Yuwang. Grasp UG NX8.5 super manual completely[M]. BeijingChina Machine Press2014.

[12] 梅向明,黄敬之. 微分几何[M]. 4. 北京:高等教育出版社,2008.

        MEI XiangmingHUANG Jingzhi. Differential geometry[M]. 4 th ed. BeijingHigher Education Press2008.

[13]  RAO VRAO P. Effect of workpiece curvature on cutting forces and surface error in peripheral milling[J]. Proceedings of the Institution of Mechanical Engineers. Part BEngineering Manufacture2006220(9)1399-1407.

[14]  ZHU HaiguangLIU Riliang. A combined approach to tool path generation for flank milling of impeller blades with non–developable ruled surfaces[J]. International Journal of Manufacturing Research201510(1)1-16.

[15]  蔡永林,席光,查建中. 任意扭曲直纹面叶轮数控侧铣刀位计算与误差分析[J]. 西安交通大学学报,200438(5)517-520.

        CAI YonglinXI GuangCHA Jianzhong. Calculation of cutter-location and error analysis in numerical control flank milling of twisted ruled surface impeller[J]. Journal of Xi’an Jiaotong University200438(5)517-520.

Options
文章导航

/

版权所有 © 《机械工程学报》编辑部

技术支持:北京玛格泰克科技发展有限公司