Design and Assembly Accuracy Evaluation of Precision Forging Blade Fixture for Aero-Engine

ZHAO Bing; ZHANG Shen; QIAO Yueqi; LIANG Jiawei; WANG Hui; XU Lijun; ZHOU Fen

doi:10.16080/j.issn1671-833x.2025.12.014

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Design and Assembly Accuracy Evaluation of Precision Forging Blade Fixture for Aero-Engine

更新时间：2026-03-27

- Design and Assembly Accuracy Evaluation of Precision Forging Blade Fixture for Aero-Engine
- Aeronautical Manufacturing Technology Vol. 68, Issue 12, Pages: 14-23(2025)
- 作者机构：
  
  1. 青海大学机械工程学院,西宁,810016
  2. 清华大学机械工程系,北京,100084
  3. 北京航空航天大学航空发动机研究院,北京,102206
  4. 中国航发动力股份有限公司,西安,710021
- 作者简介：
- 基金信息：
- DOI：10.16080/j.issn1671-833x.2025.12.014
  CLC：
- Published：2025
- 稿件说明：
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赵兵，张申，乔悦琦，梁嘉伟，王辉，许立君，周奋. 航空发动机精锻叶片夹具设计及装配精度评估[J]. 航空制造技术, 2025, 68(12): 14-23.

ZHAO Bing, ZHANG Shen, QIAO Yueqi, LIANG Jiawei, WANG Hui, XU Lijun, ZHOU Fen. Design and Assembly Accuracy Evaluation of Precision Forging Blade Fixture for Aero-Engine[J]. Aeronautical Manufacturing Technology, 2025, 68(12): 14-23.
赵兵，张申，乔悦琦，梁嘉伟，王辉，许立君，周奋. 航空发动机精锻叶片夹具设计及装配精度评估[J]. 航空制造技术, 2025, 68(12): 14-23. DOI： 10.16080/j.issn1671-833x.2025.12.014.

ZHAO Bing, ZHANG Shen, QIAO Yueqi, LIANG Jiawei, WANG Hui, XU Lijun, ZHOU Fen. Design and Assembly Accuracy Evaluation of Precision Forging Blade Fixture for Aero-Engine[J]. Aeronautical Manufacturing Technology, 2025, 68(12): 14-23. DOI： 10.16080/j.issn1671-833x.2025.12.014.

摘要

航空发动机精锻叶片是典型的复杂曲面薄壁零件，针对榫头夹具装配精度提高的需求，提出多点柔性夹具设计方法。结合所设计夹具结构，对其装配精度进行评估优化。首先，基于六点定位原理探究不同装夹位置下铣削力对零件变形量的影响，进而对叶片装夹位置和装夹方式进行优化。然后，采用三坐标测量仪对其装配精度进行测量，发现叶片与叶盆定位柱、进气边定位柱接触效果较差，平面最大误差达0.0353 mm。最后，采取一体化加工策略对夹具装配过程进行优化。根据夹具装配精度测量试验结果可知，采用优化后的夹具工艺时，叶片榫头3个相邻平面的装配精度分别为±0.0049 mm、±0.0063 mm、±0.0063 mm，满足叶片榫头加工需求。

Abstract

Precision forging blade of aero-engine is a typical thin-walled part with complex curved surface. In order to improve the assembly accuracy of tenon fixture

a multi-point flexible fixture design method is proposed. Combined with the designed fixture structure

the assembly accuracy is evaluated and optimized. Firstly

based on the six-point positioning principle

the influence of milling force on the deformation of parts under different clamping positions was investigated

and then clamping position and clamping mode of the blades were optimized. Secondly

a coordinate measuring machine is used to test the assembly accuracy

revealing poor contact between the blade and blade basin positioning pillars/air inlet edge positioning pillars

with a maximum planar error of 0.0353 mm. Finally

an integrated processing strategy is implemented to optimize the assembly process of the tooling fixture. According to the test results of fixture assembly accuracy

when using the optimized tooling fixture process

assembly accuracy for the three adjacent planes of the blade tenon is ±0.0049 mm

±0.0063 mm and ±0.0063 mm

meeting the processing requirements for the blade tenon.

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