Numerical Investigation of Turbopump Bearing Heat Generation in Liquid Methane

IF 2.2 3区 工程技术 Q2 ENGINEERING, MECHANICAL
Hiromitsu Kakudo, S. Takada, T. Hirayama
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引用次数: 0

Abstract

Liquid methane is one of the most promising candidates for the next-generation rocket propellant because it has an excellent balance between several propulsion performances such as specific impulse, storability, and structural coefficient. JAXA has developed rocket engine technologies for liquid methane engines. In this paper, we investigate heat generation characteristics of ball bearings used in liquid methane turbopumps. A usual approach to evaluate a cryogenic ball bearing performance is to conduct experimental testing which costs a lot. This research introduces numerical approaches based on physical mechanisms in rotating ball bearings to clarify the heat generation characteristics. The main factors of the heat generation are friction heat generation and fluid heat generation. The friction heat generation is caused by mechanical friction of bearing elements and calculated based on bearing motion analysis and Hertzian contact theory. The fluid heat generation is caused by the fluid drag force on bearing elements and calculated by CFD analysis. The theoretical model is compared with experimental results, showing an excellent agreement. It is clarified that the dominant factor of the bearing heat generation in liquid methane environment is the friction heat generation on races-balls contact at lower velocity condition while it tends to change to the fluid heat generation due to the bearing elements' rotational motion at higher velocity condition. In addition, cryogenic bearing characteristics which are clarified by theoretical modeling are discussed.
液化气中涡轮泵轴承产热的数值研究
液态甲烷是下一代火箭推进剂中最有前途的候选者之一,因为它在比冲、储存性和结构系数等几种推进性能之间具有良好的平衡。JAXA开发了液态甲烷发动机的火箭发动机技术。本文研究了用于液态甲烷涡轮泵的滚珠轴承的产热特性。评估低温球轴承性能的常用方法是进行实验测试,这一方法成本很高。本研究引入了基于物理机制的数值方法来阐明旋转球轴承的产热特性。产生热量的主要因素是摩擦产生热量和流体产生热量。摩擦热的产生是由轴承元件的机械摩擦引起的,根据轴承运动分析和赫兹接触理论进行计算。流体热的产生是由流体对轴承元件的阻力引起的,并通过CFD分析进行计算。将理论模型与实验结果进行了比较,结果吻合良好。阐明了液态甲烷环境下轴承产热的主导因素是低速条件下球球接触时的摩擦产热,高速条件下由于轴承元件的旋转运动而趋向于流体产热。此外,还讨论了理论建模澄清的低温承载特性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Tribology-transactions of The Asme
Journal of Tribology-transactions of The Asme 工程技术-工程:机械
CiteScore
4.20
自引率
12.00%
发文量
117
审稿时长
4.1 months
期刊介绍: The Journal of Tribology publishes over 100 outstanding technical articles of permanent interest to the tribology community annually and attracts articles by tribologists from around the world. The journal features a mix of experimental, numerical, and theoretical articles dealing with all aspects of the field. In addition to being of interest to engineers and other scientists doing research in the field, the Journal is also of great importance to engineers who design or use mechanical components such as bearings, gears, seals, magnetic recording heads and disks, or prosthetic joints, or who are involved with manufacturing processes. Scope: Friction and wear; Fluid film lubrication; Elastohydrodynamic lubrication; Surface properties and characterization; Contact mechanics; Magnetic recordings; Tribological systems; Seals; Bearing design and technology; Gears; Metalworking; Lubricants; Artificial joints
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