材料工程与机械制造

高缠绕叶轮流道4+1轴高效分段开槽方法

  • 韩飞燕 ,
  • 张定华 ,
  • 吴宝海 ,
  • 罗明 ,
  • 张晓东
展开
  • 1. 西北工业大学 现代设计与集成制造技术教育部重点实验室, 西安 710072;
    2. 西安航空动力控制科技有限公司, 西安 710077
韩飞燕 女, 博士研究生。主要研究方向: 复杂曲面的计算机辅助几何设计及多坐标数控加工理论。 E-mail: hanfeiyan@126.com;张定华 男, 博士, 教授, 博士生导师。主要研究方向: 高速切削工艺、多坐标数控加工理论、叶片叶盘类零件的高效精密数控加工及无损检测。 Tel.: 029-88493009 E-mail: dhzhang@nwpu.edu.cn;吴宝海 男,博士, 副教授, 硕士生导师。主要研究方向: 自由曲面多轴加工、智能加工。 Tel.: 029-88493232-411 E-mail: wubaohai@nwpu.edu.cn;罗明 男, 博士, 助理研究员。主要研究方向: 复杂曲面的多坐标数控加工理论和多轴数控加工过程动力学优化。 E-mail: luoming@nwpu.edu.cn

收稿日期: 2014-06-27

  修回日期: 2014-08-08

  网络出版日期: 2014-08-25

基金资助

国家科技重大专项(2013ZX04011031); 高等学校学科创新引智计划(B13044); 西北工业大学基础研究基金(JCY20130121)

High-efficiency section-by-section slotting method for 4+1-axis NC machining of high-wrap impeller channel

  • HAN Feiyan ,
  • ZHANG Dinghua ,
  • WU Baohai ,
  • LUO Ming ,
  • ZHANG Xiaodong
Expand
  • 1. The Key Laboratory of Contemporary Design and Integrated Manufacturing Technology, Ministry of Education, Northwestern Polytechnical University, Xi'an 710072, China;
    2. AVIC Xi'an Aero-engine (Group) Ltd., Xi'an 710077, China

Received date: 2014-06-27

  Revised date: 2014-08-08

  Online published: 2014-08-25

Supported by

National Science and Technology Major Project (2013ZX04011031); "111" Project (B13044); Basic Research Fund of Northwestern Polytechnical University(JCY20130121)

摘要

高缠绕叶轮流道的高效粗加工是提高整个叶轮加工效率和缩短生产周期的关键。针对高缠绕叶轮流道的粗加工,提出了一种4+1轴高效分段开槽方法。首先,给出了分段开槽加工方法的基本概念,并分析了高缠绕叶轮流道加工特点;然后,结合机床结构特征,给出了五轴机床在主轴摆角固定为常值时切削点处单点最大刀具尺寸的计算方法;基于各切削点加工特征参数的分析,采用聚类算法进行了叶轮流道加工分段区域的划分;最后,确定了各分段区域的可加工刀具尺寸和4+1形式的刀轴矢量。算例分析表明,提出的4+1轴分段开槽方法得到的开槽轨迹旋转轴变化均匀,材料去除量较传统开槽方法增加了32.5%,改善了切削过程稳定性,提高了叶轮的粗加工效率。

本文引用格式

韩飞燕 , 张定华 , 吴宝海 , 罗明 , 张晓东 . 高缠绕叶轮流道4+1轴高效分段开槽方法[J]. 航空学报, 2015 , 36(5) : 1684 -1694 . DOI: 10.7527/S1000-6893.2014.0182

Abstract

High-efficiency rough machining method for the high-wrap impeller channel is the key path to enhance the whole impeller machining efficiency and shorten the production cycle. Aiming at the rough machining of high-wrap impeller channel, a high-efficiency slotting method for 4+1-axis section-by-section NC machining of high-wrap impeller channel is proposed in this paper. Firstly, the basic concept of the method is discussed from the machining principle and the five-axis machining features of the high-wrap impeller are analyzed. Secondly, the largest available tool of each cutting point is determined according to the structural features of the machine. The division of the high-wrap impeller channel machining region is made based on the analysis of the processing characteristics of each cutting point using the clustering algorithm. Finally, the largest available tool and the tool orientation in form of 4+1-axis of each subsection are calculated. Simulation results demonstrate that the proposed method obtains linearly changed rotational coordinates along the slotting path, material removal volume increased by 32.5% than the traditional slotting method, the impeller slotting machining stability and efficiency are obviously improved.

参考文献

[1] Wang N, Tang K. Automatic generation of gouge-free and angular velocity-compliant five-axis tool path[J]. Computer-Aided Design, 2007, 39(10): 841-852.
[2] Kersting P, Zabel A. Optimizing NC-tool paths for sim-ultaneous five-axis milling based on multi-population multi-objective evolutionary algorithms[J]. Advances in Engineering Software, 2009, 40(6): 452-463.
[3] Bi Q Z, Wang Y H, Zhu L M, et al. Wholly smoothing cutter orientations for five-axis NC machining based on cutter contact point mesh[J]. Science China: Technological Sciences, 2010, 40(10): 1159-1168 (in Chinese). 毕庆贞, 王宇晗, 朱利民, 等.刀触点网格上整体光顺五轴数控加工刀轴方向的模型与算法[J].中国科学: 技术科学, 2010, 40(10): 1159-1168.
[4] Balasubramaniam M, Sarma S E, Marciniak K. Collision free finishing tool paths from visibility data[J]. Computer-Aided Design, 2003, 35(4): 359-374.
[5] Bi Q Z, Wang Y H, Ding H. A GPU-based algorithm for generating collision-free and orientation-smooth five-axis finishing tool paths of a ball-end cutter[J]. International Journal of Production Research, 2010, 48(4): 1105-1124.
[6] Ho M C, Hwang Y R, Hu C H. Five-axis tool orientation smoothing using quaternion interpolation algorithm[J]. International Journal of Machine Tool & Manufacture, 2003, 43 (12): 1259-1267.
[7] Wang Q H, Li J R, Gong H Q. Graphics-assisted cutter orientation correction for collision-free five-axis machining[J]. International Journal of Production Research, 2007, 45(13): 2875-2894.
[8] Luo M, Zhang D H, Wu B H, et al. Tool orientation control using quaternion interpolation in multi-axis milling of blade[C]//2010 International Conference on Manufacturing Automation (ICMA). Piscataway, NJ: IEEE Press, 2010: 128-132.
[9] Li X Y, Ren J X, Liang Y S, et al. Tool axis planning for five-axis machining of complex channel parts[J]. Acta Aeronautica et Astronautica Sinica, 2014, 35(9): 2641-2651 (in Chinese). 李祥宇, 任军学, 梁永收, 等. 复杂通道类零件五轴加工刀轴规划方法[J]. 航空学报, 2014, 35(9): 2641-2651.
[10] Ren X G, Hou J Q. Method of tool path optimization in impeller NC machining based on configuration space theo-ry[J]. Advanced Materials Research, 2014, 842: 602-606.
[11] Edalew K O, Abdalla H S, Nash R J. A computer-based intelligent system for automatic tool selection[J]. Materials & Design, 2001, 22(5): 337-351.
[12] Jensen C G, Red W E, Pi J. Tool selection for five-axis curvature matched machining[J]. Computer-Aided Design, 2002, 34(3): 251-266.
[13] Chen Z C, Liu G. Automated tool-orientation determinations for 4-axis non-gouge, non-interference milling of axial-flow compressors airfoils[C]//Proceedings of ASME Turbo Expo 2007: Power for Land, Sea, and Air. Jalan Bukit Merah, Singapore: ASME, 2007, 5: 147-154.
[14] Li H Y, Zhang Y F. A geometric method for optimal multi-cutter selection in 5-axis finish cut of sculptured surfaces[C]//IEEE International Conference on Automation and Logistics(ICAL 2008). Piscataway, NJ: IEEE Press, 2008: 153-158.
[15] Chen Z C, Liu G. An intelligent approach to multiple cutters of maximum sizes for three-axis milling of sculptured surface parts[J]. Journal of Manufacturing Science and Engineering, 2009, 131(1): 014501-014505.
[16] Roman Flores A. Surface partitioning for 3+2-axis machining[D]. Waterloo: University of Waterloo, 2007.

文章导航

/