Thermal Expansion Simulation of Bi-Directional Taper Formation in Composite Hydrodynamic Thrust Bearings

Isaiah Yasko, A. Lutfullaeva, C. Fais, Muhammad Ali, K. Alam
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Abstract

Tapered-land hydrodynamic thrust bearings require taper depths of approximately 20–100 μm to operate efficiently within the hydrodynamic regime. Machining the tapers in traditionally manufactured bearings increase production time and costs. The thermo-mechanical analysis presented in this work shows that the utilization of composite laminas in place of taper machining may be used to provide taper formation in hydrodynamic bearings by exploiting the thermal expansion produced from frictional heating. Thermal expansion of three different carbon/epoxy composite layups (AS-4/3501-6, IM7/3501-6, T-300/3501-6) was analyzed using ABAQUS/CAE composite module. The analysis shows that the composites provide bidirectional taper depths of 24.25 μm, 23.7 μm, and 22.27 μm while being subjected to in-service film pressures and temperatures.
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复合流体动力推力轴承双向锥度形成的热膨胀模拟
锥形土地流体动力推力轴承要求锥度深度约为20-100 μm,才能在流体动力范围内有效运行。在传统制造的轴承中加工锥度增加了生产时间和成本。本文的热力学分析表明,利用复合材料薄片代替锥度加工,可以利用摩擦加热产生的热膨胀,在流体动力轴承中形成锥度。利用ABAQUS/CAE复合材料模块分析了三种不同碳/环氧复合材料层(as /3501-6、IM7/3501-6、T-300/3501-6)的热膨胀性能。分析表明,复合材料在服役膜压力和温度作用下的双向锥度深度分别为24.25 μm、23.7 μm和22.27 μm。
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