Design of a High Speed Internal Gear Pump to Increase the Power Density of Electro Hydraulic Actuators (EHA) in Mobile Applications

Volume 7: Fluids Engineering Pub Date : 2019-11-11 DOI:10.1115/imece2019-10351

Tobias Pietrzyk, D. Roth, G. Jacobs, Schmitz Katharina

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引用次数: 3

Abstract

Increasing the rotational speed of the internal gear pump entails addressing topics such as cavitation, overheating and filling problems of the tooth spaces. Besides the development of a tooth geometry and flow optimization, using CFD simulation is necessary. This paper discusses the design of the newly developed high speed internal gear pump. This includes a detailed description of the different parts as well as the dimensioning of the pump by using CFD simulations. The geometry of the pressure build-up groove has a significant effect of pressure build up inside the pump. Therefore, three different geometries are investigated. The calculation of the journal bearings for the internal gear as well as for the driving shaft is shown. To avoid cavitation problems, the suction pressure of the pump will be increased up to 25 bar. This paper will show the technical arrangements to reach this high suction pressure level whilst still using a radial shaft seal ring. In order to determine the efficiency of the newly developed high speed pump, a test rig was built up. The test rig allows the measurement of the volumetric efficiency as well as the hydraulic-mechanical efficiency at different operation points up to 10 000 rpm and 250 bar.

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高速内啮合齿轮泵的设计以提高移动应用中电液执行器(EHA)的功率密度

增加内部齿轮泵的转速需要解决的问题，如空化，过热和填充问题的齿空间。除了发展齿形和流动优化，使用CFD模拟是必要的。本文讨论了新研制的高速内齿轮泵的设计。这包括使用CFD模拟对不同部件的详细描述以及泵的尺寸。压力积聚槽的几何形状对泵内的压力积聚有重要影响。因此，研究了三种不同的几何形状。计算滑动轴承的内齿轮以及传动轴是显示。为了避免空化问题，泵的吸入压力将增加到25bar。本文将展示在使用径向轴密封圈的同时达到这种高吸入压力水平的技术安排。为了确定新研制的高速泵的效率，建立了一台试验台。该测试平台可以测量容积效率以及不同工作点的液压机械效率，最高可达10,000 rpm和250 bar。

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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Volume 7: Fluids Engineering

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