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干湿条件下仿生微六边形纹理表面与柔软配对表面相互作用的摩擦特性

Frictional Properties of Biomimetic Micro-Hexagonal-Textured Surfaces Interacting with Soft Counterfaces under Dry and Wet Conditions.

作者信息

Qatmeera Zain Eldin, Bajjaly Agnes, Kasem Haytam

机构信息

Department of Mechanical Engineering, Azrieli College of Engineering, Jerusalem 9103501, Israel.

出版信息

Biomimetics (Basel). 2024 Sep 7;9(9):542. doi: 10.3390/biomimetics9090542.

DOI:10.3390/biomimetics9090542
PMID:39329564
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11430730/
Abstract

Biomimetic micro-hexagonal-textured surfaces have sparked interest for their application in fields that demand high friction and adhesion, such as micro-robotics and biomedicine. Despite extensive research conducted on this specific microstructure, its friction behavior against soft counterfaces remains a topic that has not been fully investigated yet. This study examines how micro-hexagon textures behave when they come into contact with engineered and biological materials like gelatin and chicken skin in dry and wet conditions. The results show clearly that under dry contact conditions, flat surfaces generate higher friction compared to hexagon micropattern surfaces. Under wet conditions, hexagon micropattern surfaces generate higher friction compared to flat surfaces. In wet conditions specifically, the static coefficient of friction is up to 13 times greater than that of a flat specimen against glass, up to 11 times greater against gelatin, and up to 6 times greater against chicken skin. For the dynamic coefficient of friction, the patterned surface demonstrates a maximum increase by a factor of 28 against glass, 11 against gelatin, and 5 against chicken skin. These results further develop our knowledge of these hexagon micropattern surfaces and pave the way for their utilization in future technological advancements in which soft and wet counterfaces are to be considered, such as in biomedical applications that can benefit from increased friction in wet conditions for better control and stability.

摘要

仿生微六边形纹理表面因其在微机器人技术和生物医学等需要高摩擦力和附着力的领域的应用而引发了人们的兴趣。尽管对这种特定微观结构进行了广泛研究,但其与软质配对表面的摩擦行为仍是一个尚未得到充分研究的课题。本研究考察了微六边形纹理在干湿条件下与明胶和鸡皮等工程材料及生物材料接触时的表现。结果清楚地表明,在干接触条件下,平面产生的摩擦力高于六边形微图案表面。在湿条件下,六边形微图案表面产生的摩擦力高于平面。特别是在湿条件下,静摩擦系数比平面试样与玻璃接触时高出13倍,与明胶接触时高出11倍,与鸡皮接触时高出6倍。对于动摩擦系数,图案化表面与玻璃接触时最大增加28倍,与明胶接触时增加11倍,与鸡皮接触时增加5倍。这些结果进一步拓展了我们对这些六边形微图案表面的认识,并为其在未来技术进步中的应用铺平了道路,在这些技术进步中需要考虑软质和湿质配对表面,例如在生物医学应用中,可受益于湿条件下增加的摩擦力以实现更好的控制和稳定性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c965/11430730/cd2d7c4b4c73/biomimetics-09-00542-g015.jpg
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