结合部对HSK主轴系统动态特性的影响

中国机械工程 ›› 2015, Vol. 26 ›› Issue (9): 1161-1166.

结合部对HSK主轴系统动态特性的影响

陈建1;田良2;商宏谟2;沈春根1;王贵成1,3

1.江苏大学，镇江，212013
2.成都工具研究所有限公司，成都，610051
3.南通理工学院，南通，226002

出版日期:2015-05-10 发布日期:2015-05-08
基金资助:
国家科技重大专项（2013ZX04009031）；国家自然科学基金资助项目（51075192,51275217）；江苏省博士创新计划资助项目(CXZZ13_0656)；南通市精密加工技术重点实验室资助项目（CP12014002）

Effects of Joint Part on HSK Spindle System Dynamic Performance

Chen Jian1;Tian Liang2;Shang Hongmo2;Shen Chungen1;Wang Guicheng1,3

1.Jiangsu University,Zhenjiang,Jiangsu,212013
2.Chengdu Tool Research Institute Co.,Ltd.,Chengdu,610051
3.Nantong Polytechnic College,Nantong，Jiangsu,226002

Online:2015-05-10 Published:2015-05-08
Supported by:
National Science and Technology Major Project ( No. 2013ZX04009031);National Natural Science Foundation of China（No. 51075192,51275217）

摘要/Abstract

摘要：

根据HSK主轴系统的工作原理，在ANSYS软件中建立了HSK主轴系统的动力学模型。其中，各结合部都简化为均布弹簧单元，各部件简化为多段梁，并使用Timoshenko梁理论和有限元理论系统分析结合部对HSK主轴系统动态特性的影响。模态实验和有限元分析结果对比证实了Timoshenko梁理论分析HSK主轴系统动力学模型动态特性的可行性和有效性。提出结合部对主轴系统各阶模态影响的研究思路，并利用ANSYS有限元软件中的谐响应分析模块，分别研究了轴承-主轴、主轴-刀柄和刀柄-刀具各结合部对HSK主轴-热装刀柄-刀具系统刀尖点频响函数的影响，提出了相应的抗振措施。

关键词: 结合部, HSK主轴系统, Timoshenko梁, 动态特性

Abstract:

According to the working principles of HSK spindle system, a FEM (finite element method) dynamic model of HSK spindle system was built in ANSYS software, the joint parts were simplified as spring element and the parts were simplified as multi-parts beam. The dynamic performance of HSK spindle system was analyzed with Timoshenko beam theory and FEM, and the modal experiments were made in HSK tooling system. The Timoshenko theory for analyzing dynamic performance of HSK spindle system was proved to be feasible, compared with modal results. At last, the joint parts affecting HSK spindle system tool point frequency response were studied, some anti-vibration solutions were proposed.

Key words: joint part;HSK spindle system, Timoshenko beam, dynamic performance

中图分类号:

TG504

陈建, 田良, 商宏谟, 沈春根, 王贵成, . 结合部对HSK主轴系统动态特性的影响[J]. 中国机械工程, 2015, 26(9): 1161-1166.

Chen Jian, Tian Liang, Shang Hongmo, Shen Chungen, Wang Guicheng, . Effects of Joint Part on HSK Spindle System Dynamic Performance[J]. China Mechanical Engineering, 2015, 26(9): 1161-1166.

参考文献

[1]王贵成,王树林,董广强.高速加工工具系统[M]. 北京：国防工业出版社, 2005.
[2]Schmitz T, Duncan G. Three-component Receptance Coupling Substructure Analysis for Tool Point Dynamics Prediction[J]. Journal of Manufacturing Science and Engineering, 2005,127(12): 781-790.
[3]Schmitz T, Powell K, Won D,et al. Shrink Fit Tool Holder Connection Stiffness/Damping Modeling for Frequency Response Prediction in Milling[J]. International Journal of Machine Tools & Manufacture, 2007, 47: 1368-1380.
[4]Park S,Altintas Y, Movahhedy M. Receptance Coupling for End Mills[J]. International Journal of Machine Tools & Manufacture, 2003,43: 889-896.
[5]Namazia M, Altintasa Y, Abeb T, et al. Modeling and Identification of Tool Holder-spindle Interface Dynamics[J]. International Journal of Machine Tools & Manufacture, 2007,47: 1333-1341.
[6]闫蓉, 蔡飞飞, 彭芳瑜.基于响应耦合方法的铣刀刀尖点频响函数预测[J].华中科技大学学报(自然科学版),2013,41(4):1-5.
Yan Rong, Cai Feifei, Peng Fangyu. Predicting Frequency Response Function for Tool Point of Milling Cutter Using Receptance Coupling[J]. J.Huazhong Univ. of Sci. & Tech: Natural Science edition, 2013,41(4):1-5.
[7]Ertürk A, Budak E. Effect Analysis of Bearing and Interface Dynamics on Tool Point FRF for Chatter Stability in Machine Tools by Using a New Analytical Model for Spindle-tool Assemblies[J].International Journal of Machine Tools & Manufacture，2007,47 (1)：23-32.
[8]Budak E, Ertürk A, zgüven H N. A Modeling Approach for Analysis and Improvement of Spindle-holder-tool Assembly Dynamics[J]. Annals of the CIRP, 2006,56（1）：155-160.
[9]汪博,孙伟,闻邦椿.考虑主轴—刀柄—刀具结合面的高速主轴系统动力学特性有限元建模[J].机械工程学报,2012,48(15): 83-89.
Wang Bo, Sun Wei,Wen Bangchun. The Finite Element Modeling of High-speed Spindle System Dynamics with Spindle-holder-tool Joints[J]. Journal of Mechanical Engineering, 2012,48(15): 83-89.
[10]赵万华,杜超,张俊,等.主轴转子系统动力学解析建模方法[J].机械工程学报,2013,49(6): 44-51.
Zhao Wanhua, Du Chao, Zhang Jun, et al. Analytical Modeling Method of Dynamics for the Spindle Totor Dystem[J]. Journal of Mechanical Engineering,2013,49(6): 44-51.
[11]楼梦麟,任志刚. Timoshenko简支梁的振动模态特性精确解[J].同济大学学报, 2002,30(8):911-915.
Lou Menglin, Ren Zhigang. Precise Solution to Modal Characteristics of Timoshenko Pin-ended Beams[J]. Journal of Tongji University, 2002, 30(8):911-915.
[12]徐延忠,蒋书运,黄国庆,等.高速角接触陶瓷球轴承与钢球轴承动力学特性对比分析术[J].精密制造与自动化,2004,13(1): 17-22.
Xu Yanzhong, Jiang Shuyun, Huang Guoqin, et al. High-speed Angular Contact Ceramic Ball Bearings and Ball Bearings Dynamic Characteristics Analysis[J]. Precise Manufacturing & Automation,2004,13(1):17-22.

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