Time-varying error compensation for horizontal machining center based on mechanism-driven model

被引:0
|
作者
Song L. [1 ]
Liu K. [1 ]
Cui Y. [1 ]
Chen H. [2 ]
Chen Y. [2 ]
Wang Y. [1 ]
机构
[1] Key Laboratory for Precision and Non-traditional Machining Technology of Ministry of Education, Dalian University of Technology, Dalian
[2] Kede CNC Co., Ltd., Dalian
来源
Hangkong Xuebao/Acta Aeronautica et Astronautica Sinica | 2022年 / 43卷 / 07期
基金
中国国家自然科学基金;
关键词
compensation; feed axis; horizontal machining center; mechanism driven; time-varying error;
D O I
10.7527/S1000-6893.2021.25549
中图分类号
学科分类号
摘要
The demand for CNC machine tools in aviation industry is characterized by high accuracy, compound and multi-axis link-age. The accuracy stability of the aeronautical parts machined by batch-process is affected by time-varying error of CNC machine tools. Therefore, the time-varying error of feed axes for horizontal machining center of aero engine enterprises is compensated in real-time based on mechanism-driven time-varying error model. The time-varying error of feed axes is measured, and the thermal characteristic parameters in the model are identified. The compensator of time-varying error communicates with CNC system based on TCP/IP protocol. The method of machine tool coordinate origin offset was used to compensate the time-varying error. Finally, the test verification is implemented on a horizontal machine tool, the HAAS HS-1RP. The results show that the time-varying error of feed axis can be reduced by 85.2% with error compensation, and the accuracy stability of machine tool is improved greatly. © 2022 AAAS Press of Chinese Society of Aeronautics and Astronautics. All rights reserved.
引用
收藏
相关论文
共 21 条
  • [11] ZHANG Y F, WANG P, LIU T, Et al., Active and intelligent control onto thermal behaviors of a motorized spindle unit, International Journal of Advanced Manufacturing Technology, 98, 9-12, pp. 3133-3146, (2018)
  • [12] MA C, ZHAO L, MEI X S, Et al., Thermal error compensation based on genetic algorithm and artificial neural network of the shaft in the high-speed spindle system [J], Proceedings of the Institution of Mechanical Engineers Part B-Journal of Engineering Manufacture, 231, 5, pp. 753-767, (2017)
  • [13] LIU J L, MA C, WANG S L., Data-driven thermally-induced error compensation method of high-speed and precision five-axis machine tools, Mechanical Systems and Signal Processing, 138, (2020)
  • [14] YAO X P, YIN G F, LI G M., Positioning error of feed axis decouple-separating modeling and compensating research for CNC machine tools, Journal of Mechanical Engineering, 52, 1, pp. 184-192, (2016)
  • [15] LIN Y X, YANG J G., Application of grey system model to thermal error modeling on machine tools [J], China Mechanical Engineering, 23, pp. 2439-2442, (2006)
  • [16] ABDULSHAHED A M, LONGSTAFF A P, FLETCHER S, Et al., Thermal error modelling of a gantry-type 5-axis machine tool using a grey neural network model, Journal of Manufacturing Systems, 41, pp. 130-142, (2016)
  • [17] WANG H T, LI T M, WANG L P, Et al., Review on thermal error modeling of machine tools, Journal of Mechanical Engineering, 51, 9, pp. 119-128, (2015)
  • [18] AHN J Y, CHUNG S C., Real-time estimation of the temperature distribution and expansion of a ball screw system using an observer, Proc IMechE, Part B: J Engineering Manufacture, 218, 12, pp. 1667-1681, (2004)
  • [19] ATTIA M, FRASER S., A generalized modelling methodology for optimized real-time compensation of thermal deformation of machine tools and CMM structures, Inter-national Journal of Machine Tools & Manufacture, 39, pp. 1001-1016, (1999)
  • [20] SHI H, MAC, YANG J, Et al., Investigation into effect of thermal expansion on thermally induced error of ball screw feed drive system of precision machine tools, International Journal of Machine Tools & Manufacture, 97, pp. 60-71, (2015)
123