柴油机连杆小端轴承热生成与散热特性研究

Jiaming Guo, J. Xiang, Hongwei Chen
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引用次数: 0

摘要

基于热弹流体动力润滑和微凸峰值接触理论,建立了连杆小端轴承热弹性流体的计算模型。分析了小端轴承的润滑和摩擦特性。得到了小端轴承的散热机理和热分布规律。讨论了气缸压力、转速和小端轴承表面粗糙度对热生成和传热的影响。结果表明:连杆小端轴承在运动过程中大多处于混合润滑状态,热量主要通过轴承表面的摩擦产生;轴承主要通过小端和活塞销的热传导方式散热。活塞销和衬套占散热的99.8%,而通过润滑油排出轴承的散热相对较小。气缸压力、转速和粗糙度对轴承的产热有很大影响。气缸压力的增大将导致轴承的总摩擦功率损失增大。随着转速的增加,总摩擦功率损失先减小后增大。粗糙度的增加也增加了轴承的摩擦功率损失。轴承总摩擦功率损失的变化范围主要在曲轴角270°CA到630°CA之间。气缸压力、转速和粗糙度对轴承的热分布规律影响不大。气缸压力和转速的增加有利于润滑油的散热,而粗糙度的增加则不利于润滑油的散热。
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Study on heat generation and dissipation characteristics of connecting rod small-end bearing in diesel engine
Based on thermal-elastohydrodynamic lubrication and micro-convex peak contact theory, the calculation model of thermal-elastic fluid for connecting rod small-end bearing was established. The lubrication and friction characteristics of the small-end bearing were analyzed. The heat generation and dissipation mechanism and heat distribution rule of small-end bearing were obtained. The effect of cylinder pressure, rotation speed and roughness of small-end bearing surface on heat generation and heat transfer was discussed. The results show that the connecting rod small-end bearing is mostly in the state of mixed lubrication during the movement, and the heat is generated mainly through the friction on the bearing surface; the bearing mainly dissipates heat by means of heat conduction through small-end and piston pin. Piston pin and bushing accounted for 99.8% of heat dissipation, while the heat dissipation through lubricating oil out of bearing is relatively small. Cylinder pressure, rotation speed and roughness have great influence on the heat generation of the bearing. The increase of cylinder pressure will cause the total friction power loss of bearing increases. With the increase of rotation speed, the total friction power loss always increases after reduces. The increase of roughness also increases the friction power loss of bearing. The change of total friction power loss of the bearing mainly ranges from crankshaft angle 270°CA to 630°CA. Cylinder pressure, rotation speed and roughness have little influence on heat distribution rule of bearing. The increase of cylinder pressure and rotation speed is beneficial to the heat dissipation of lubricating oil, while the increase of roughness is not conducive to the heat dissipation of lubricating oil.
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