复杂曲面零部件高性能表面加工技术专栏

航空发动机整体叶盘磨料水射流开坯加工技术研究进展

  • 高航 ,
  • 袁业民 ,
  • 陈建锋 ,
  • 王宣平
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  • 大连理工大学 机械工程学院, 大连 116024

收稿日期: 2019-07-25

  修回日期: 2019-08-02

  网络出版日期: 2019-10-10

基金资助

国家自然科学基金-NSFC-辽宁联合基金(U1708256)

Research progress of abrasive water jet blanking technology for aero-engine integral blade

  • GAO Hang ,
  • YUAN Yemin ,
  • CHEN Jianfeng ,
  • WANG Xuanping
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  • College of Mechanical Engineering, Dalian University of Technology, Dalian 116024, China

Received date: 2019-07-25

  Revised date: 2019-08-02

  Online published: 2019-10-10

Supported by

National Natural Science Foundation of China-NSFC-Liaoning Joint Fund(U1708256)

摘要

整体叶盘结构是航空发动机技术发展的一个重要方向,且多采用难加工材料,如何实现整体叶盘高质高效加工是机械制造领域亟待解决的难题之一。通过高压磨料水射流(AWJ)加工技术实现整体叶盘毛坯的开坯粗加工,是一种有效缩短整体叶盘加工周期、降低昂贵铣削刀具成本、提高开坯效率的工艺手段。本文就磨料水射流加工材料去除机理、复杂曲面轨迹优化、多物理量和机械量参数组合优化和整体叶盘开坯设备概述了国内外的研究现状,在此基础上,针对当前具有复杂曲面结构的整体叶盘开坯面临的关键问题,提出了若干解决思路和技术途径,指出了高压磨料水射流在复杂曲面零件高效加工中的发展趋势。

本文引用格式

高航 , 袁业民 , 陈建锋 , 王宣平 . 航空发动机整体叶盘磨料水射流开坯加工技术研究进展[J]. 航空学报, 2020 , 41(2) : 623319 -623319 . DOI: 10.7527/S1000-6893.2019.23319

Abstract

Integral blade is an important development direction of aeroengine technology. However, the current integral blade is made of difficult-to-machine materials. How to achieve high quality and high efficiency machining of integral blade is one of the most urgent problems in the field of mechanical manufacturing. Roughening of integral blade blanking by Abrasive Water Jet (AWJ) technology is an effective means to improve the processing efficiency of integral blade and reduce the cost of expensive milling tools. In this paper, the domestic and foreign studies of the material removal mechanism of AWJ machining, the trajectory optimization of complex surface, the combination optimization of multi-physical and mechanical parameters, and the intergral blade blanking equipment are summarized. On this basis, the solutions to some key problems of the intergral blade blanking with complex surface structure are put forward. The development trend of AWJ in high efficiency machining of complex curved surface parts is pointed out. The application and feasibility of AWJ in high efficiency machining of complex curved surface parts are prospected.

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