表面织构对聚四氟乙烯材料密封性能的影响

Macromol Pub Date : 2022-06-08 DOI:10.3390/macromol2020015
X. Ding, Jian Wu, Yonggang Wang, B. Cui, S. An, B. Su, Youshan Wang
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引用次数: 1

摘要

由于动水压力效应,织构摩擦副表面油膜的承载能力大于光滑表面。本文利用FLURNT仿真研究了PTFE表面织构参数(形状、深度、宽度和面积比)对润滑下密封系统油膜承载能力和泄漏量的影响。在本研究中发现,更大的纹理深度不一定导致更好的密封性能。当纹理深度超过一定深度时,纹理底部会发生逆流,从而减弱动水压力效应。最佳织构深度为5 ~ 10 μm时,油膜承载能力最大。在一定范围内,油膜承载能力随织构宽度增大而增大。此外,矩形织构的泄漏量随织构宽度的增加而显著增加。纹理面积比越大,泄漏量越大,但承载能力随面积比的增加先上升后下降,最大值为70 ~ 80%。考虑到织构参数对油膜承载能力和泄漏量的影响,选择最合适的织构参数进行表面织构处理,可以优化密封系统的性能。本文的研究结果为利用织构处理提高高端航空装备的密封性能提供了理论依据,从而使应用表面织构技术提高材料的摩擦学性能成为可能。
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Influence of Surface Texture on Sealing Performance of PTFE Materials
Due to the hydrodynamic pressure effect, the bearing capacity of the oil film on the surface of a textured friction pair is greater than that of a smooth surface. In this paper, the effects of PTFE surface texture parameters (shape, depth, width, and area ratio) on the oil film bearing capacity and leakage of the sealing system under lubrication are studied using the FLURNT simulation. It is found in this present study that greater texture depths do not necessarily lead to better sealing performance. When the texture depth exceeds a certain level, a reverse flow occurs at the bottom of the texture, thereby weakening the hydrodynamic pressure effect. An optimal texture depth of 5–10 μm maximizes the oil film bearing capacity. Within a certain range, the oil film bearing capacity increases along with texture widths. In addition, leakage of the rectangular texture rises significantly with growing texture widths. Larger texture area ratios result in higher leakage, but the bearing capacity first rises and then falls with an increase in the area ratio, with a maximum value of 70–80%. Considering the influence of texture parameters on oil film bearing capacity and leakage, selecting the most appropriate texture parameters for surface texture treatment optimizes the performance of the sealing system. The findings of this paper provide a theoretical basis for improving the sealing performance of high-end aviation equipment using texture treatment, thereby enabling the application of surface texture technology to improve the tribological properties of materials.
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