Enhanced self-cleaning performance of bio-inspired micropillar-arrayed surface by shear

Inspired by the sliding behavior of gecko feet during climbing, the contribution of the shear effect to the self-cleaning performance of a bio-inspired micropillar-arrayed surface is studied through a load-shear-pull contact process. It is found that self-cleaning efficiency can be enhanced signific...

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Veröffentlicht in:	Bioinspiration & biomimetics 2022-11, Vol.17 (6), p.66005
Hauptverfasser:	An, Huazhen, Jia, Ning, Wang, Shuai, Peng, Zhilong, Chen, Shaohua
Format:	Artikel
Sprache:	eng
Schlagworte:	contact state load-shear-pull microparticle micropillar-arrayed surface self-cleaning efficiency
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container_title	Bioinspiration & biomimetics
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creator	An, Huazhen Jia, Ning Wang, Shuai Peng, Zhilong Chen, Shaohua
description	Inspired by the sliding behavior of gecko feet during climbing, the contribution of the shear effect to the self-cleaning performance of a bio-inspired micropillar-arrayed surface is studied through a load-shear-pull contact process. It is found that self-cleaning efficiency can be enhanced significantly by shear. The efficiency also depends on microparticle size. For the case of relatively large and small microparticles, self-cleaning efficiency increases first and then almost keeps a constant with the increase of shear distance at different preloads. For medium microparticles, shear can effectively improve self-cleaning efficiency only when the preload is small. The mechanical mechanism under such enhancement is mainly due to the varying contact states between microparticles and micropillars with the shear distance. When the shear distance is large enough, the final self-cleaning efficiency is not sensitive to shear distance anymore because the contact state reaches dynamic equilibrium. Based on such a self-cleaning mechanism of large microparticles, a simple and effective manipulator that can efficiently transfer solid particles is further proposed.
doi_str_mv	10.1088/1748-3190/ac877b
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title	Enhanced self-cleaning performance of bio-inspired micropillar-arrayed surface by shear
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