Theoretical and Experimental Analysis of a Non Contacting Elastohydrodynamic Sealing

IF 0.7 Q4 ENGINEERING, MECHANICAL International Journal of Fluid Power Pub Date : 2023-05-03 DOI:10.13052/ijfp1439-9776.2421

M. Scherrer, R. Scheidl

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Abstract

This paper presents a novel elastohydrodynamic sealing concept for the contactless sealing of spool valves. The basic goal is that the spool and the sleeve can be manufactured with standard mechanical engineering precision. High initial gaps are compensated for the elastic deformation of an elastomer seal driven by a self-regulating hydrodynamic effect. The final gap reveals a small leakage within the range normal for precisely manufactured spool valves and also features a low friction since a direct, solid contact between the seal and the sleeve is prevented. This sought-after behavior in ideal conditions is compared with imperfect situations by means of a simulation study and experiments. The simulation uses a Finite Element model which takes the seal‘s elastic deformation, the mechanical contact, the sealing gap pressure and the surface roughness into account. A simple prototype of the sealing system was produced to test its functionality in real conditions. Leakages of QLeak <= 18 ml/min @180 bar were recorded. However, an unexpectedly high friction occurred indicating an actual contact between the seal and the sleeve. The component roughness was identified as the cause of this behavior.

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非接触弹流密封的理论与实验分析

提出了一种新颖的滑阀非接触密封弹性流体动力密封概念。基本目标是，阀芯和套筒可以制造标准的机械工程精度。高初始间隙补偿弹性体密封的弹性变形驱动的自调节流体动力效应。最后的间隙显示出在精密制造的滑阀正常范围内的小泄漏，并且由于密封和套筒之间的直接，固体接触被防止，因此摩擦力低。通过仿真研究和实验，比较了理想条件下的理想行为和不理想情况下的理想行为。仿真采用考虑密封弹性变形、机械接触、密封间隙压力和表面粗糙度的有限元模型。制作了一个简单的密封系统原型，以测试其在实际条件下的功能。记录QLeak <= 18 ml/min @180 bar的泄漏量。然而，发生了意外的高摩擦，表明密封与套筒之间实际接触。部件的粗糙度被确定为这种行为的原因。

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International Journal of Fluid Power ENGINEERING, MECHANICAL-

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1.60

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