Impact of Microstructures on the Movement of Droplets Regulated by Bioinspired Functional Wedge‐Shaped Surfaces

Li, Jing; Yu, Shouyang; Feng, Qunxiang; Du, Feng; Du, Xin; Liu, Ren

doi:10.1002/adem.202201704

Cited by 2 publications

(1 citation statement)

References 38 publications

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“…Youqiang Xing et al [22] showed that the bionic surface microtexture composite DLC coating reduced the friction coe cient of Al-Si-10Mg by 82%-86.6% relative to that of the base material. Additionally, We note that banana and rice leaves have good hydrophilic and water-holding properties, and their surface texture structure can better adsorb liquids, thus improving the lubricating environment of the friction pair [23][24][25]. However, the study of the high-temperature tribological performance of AMCs enhanced with Feamorphous composite banana leaf or rice leaf bionic microtexture under simulated biodiesel engine piston operating conditions has not been reported.…”

Section: Introductionmentioning

confidence: 93%

Synergistic effect of Fe-amorphous and bionic microtexture in enhancing high-temperature tribological properties of Al-12Si piston materials

Wang,

Lin,

Yin

et al. 2023

Preprint

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The objective of this study is to enhance the friction properties of piston materials under high temperatures. To achieve this, we developed a novel piston composite material (Fe-amorphous/Al-12Si) by incorporating Fe-amorphous. Additionally, we employed bionic micro-textured laser surface treatment technology to improve its wear resistance. The influence of Fe-amorphous content on the frictional properties of the composite material was investigated, together with the synergistic mechanism of Fe-amorphous addition and biomimetic texture on Al-12Si under the lubrication conditions of B30 biodiesel diluted engine oil. The results indicate that the frictional properties of the untextured surface of the Fe-amorphous/Al-12Si composite material depend primarily on the amount of Fe-amorphous added. The 10 wt% Fe-amorphous/Al-12Si composite exhibits a dense, void-free microstructure with optimum anti-friction and anti-wear performance. It is noteworthy that the interaction between the "anchoring effect" caused by the Fe-amorphous addition and the "fluid-dynamic lubrication effect" induced by the biomimetic texture further enhances the high-temperature friction properties of Al-12Si. Therefore, this study provides a novel approach for the development of piston materials for biodiesel engines.

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Section: Introductionmentioning

confidence: 93%

Synergistic effect of Fe-amorphous and bionic microtexture in enhancing high-temperature tribological properties of Al-12Si piston materials

Wang,

Lin,

Yin

et al. 2023

Preprint

View full text Add to dashboard Cite

show abstract

Synergistic effect of Fe-amorphous and bionic microtexture in enhancing high-temperature tribological properties of Al-12Si piston materials

Wang,

Lin,

Yin

et al. 2024

Preprint

View full text Add to dashboard Cite

This study designs new Fe-amorphous/Al-12Si piston composite materials. Study the effect and synergistic mechanism of the addition of Fe-amorphous and bionic micro-textured laser surface on the high-temperature friction performance of Al-12Si piston material under mixed lubrication conditions of B30 biodiesel and engine lubricating oil. The results indicate that the frictional properties of the untextured surface of the Fe-amorphous/Al-12Si composite material depend primarily on the amount of Fe-amorphous added. The 10 wt% Fe-amorphous/Al-12Si composite exhibits a dense, void-free microstructure with optimum anti-friction and anti-wear performance. It is noteworthy that the interaction between the "anchoring" effect caused by the Fe-amorphous addition and the synergistic effect of the bionic microtexture providing a stable lubricating environment further enhances the high-temperature friction properties of Al-12Si.

show abstract

Impact of Microstructures on the Movement of Droplets Regulated by Bioinspired Functional Wedge‐Shaped Surfaces

Cited by 2 publications

References 38 publications

Synergistic effect of Fe-amorphous and bionic microtexture in enhancing high-temperature tribological properties of Al-12Si piston materials

Synergistic effect of Fe-amorphous and bionic microtexture in enhancing high-temperature tribological properties of Al-12Si piston materials

Synergistic effect of Fe-amorphous and bionic microtexture in enhancing high-temperature tribological properties of Al-12Si piston materials

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