Assembly angle optimization of curvic couplings considering contact status and mechanical characteristics
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摘要:
为了探究圆弧端齿加工偏差对接触状态和力学特性的影响规律,优化圆弧端齿连接安装角度,分析了圆弧端齿结构受力模型,研究了齿面加工误差对接触压力的影响,建立了圆弧端齿连接的切向刚度模型。理论研究和试验研究表明:齿面偏差导致齿面配合状态和力学特性不一致,在初始切向刚度阶段和刚度损失阶段通过优化安装角度能使切向刚度显著提高,改善装配力学性能。为圆弧端齿连接结构装配特性与装配工艺优化研究提供基础,对于提高圆弧端齿连接的航空发动机转子装配品质具有重要的意义。
Abstract:In order to investigate the influence of machining deviation of curvic couplings on the contact status and mechanical characteristics and to optimize the assembly angle of curvic couplings connection, the force model of curvic couplings structure was analyzed, the effect of surface deviation on contact pressure was investigated, and the tangential stiffness model of curvic couplings connection was established. Theoretical and experimental studies showed that the tooth surface deviation led to inconsistency of curvic couplings contact status and mechanical characteristics. The optimized assembly angle can improve the tangential stiffness and optimize the mechanical characteristics of the assembly during the initial tangential stiffness phase and the stiffness loss phase. This could provide a basis for the study of the assembly characteristics and optimization of the assembly process of the curvic couplings connection structure, which is of great significance to improve the assembly quality of the aero-engine rotor with curvic couplings connection.
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Key words:
- curvic coupling /
- surface deviation /
- contact status /
- mechanical characteristics /
- assembly angle
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表 1 圆弧端齿连接结构装配初始间隙
Table 1. Initial assembly clearance of curvic couplings connection structure
mm 编号 ${\lambda _1} = 0{\text{°}} $ ${\lambda _2} = 18{\text{°}} $ 编号 ${\lambda _1} = 0{\text{°}} $ ${\lambda _2} = 18{\text{°}} $ 编号 ${\lambda _1} = 0{\text{°}} $ ${\lambda _2} = 18{\text{°}} $ 编号 ${\lambda _1} = 0{\text{°}} $ ${\lambda _2} = 18{\text{°}} $ 1 0.145 0.300 11 0.202 0.215 21 0.190 0.086 31 0.109 0.124 2 0.089 0.096 12 0.000 0.149 22 0.329 0.236 32 0.158 0.121 3 0.233 0.206 13 0.205 0.226 23 0.224 0.237 33 0.187 0.000 4 0.125 0.134 14 0.263 0.360 24 0.203 0.121 34 0.173 0.210 5 0.329 0.236 15 0.158 0.121 25 0.089 0.096 35 0.000 0.149 6 0.125 0.131 16 0.258 0.114 26 0.116 0.175 36 0.216 0.208 7 0.203 0.121 17 0.173 0.210 27 0.125 0.134 37 0.263 0.360 8 0.109 0.124 18 0.145 0.300 28 0.202 0.215 38 0.190 0.086 9 0.116 0.175 19 0.216 0.208 29 0.125 0.131 39 0.258 0.114 10 0.187 0.000 20 0.233 0.206 30 0.205 0.226 40 0.224 0.237 表 2 扭转试验的参数设置
Table 2. Parameter setting for torsion test
扭转试验参数 数值 安装角度λk/(°) 0,30,60,90,120,150,180,
210,240,270,300,330螺栓紧固扭矩/(N·m) 5,10,15 试验扭矩/(N·m) 300 -
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