Research Progress of Bionic Water Strider Robot

Jiang, Jingang; Tan, Qiyun; Yu, Xiaoyang; Wu, Dianhao; Liang, Yao

doi:10.2174/2212797614666210426083837

MENG

2022

DOI: 10.2174/2212797614666210426083837

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Research Progress of Bionic Water Strider Robot

Jingang Jiang

Qiyun Tan

Xiaoyang Yu

et al.

Abstract: Background: As a kind of bionic robot, the bionic water strider robot can achieve sliding, jumping and other movements on the water surface, with advantages of small size, light weight, flexible movements and other characteristics. It can detect the quality of water, investigate and search the water surface and perform some other operations. It has a very broad range of applications and development prospects. Therefore, the trend of biomimetic water strider robot is catching more and more attention. Objectiv… Show more

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2024

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Maximum spreading of an impact droplet on a conical tip

Zhang,

Li,

Liu

et al. 2024

Physics of Fluids

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The droplet impact process on a conical tip is one of the key problems in the field of fluid mechanics and surface and interface science. This study examines the impact process of water droplets on the conical tip using experimental, numerical, and theoretical approaches. The volume of fluid method and the dynamic contact angle model are used and validated by comparing the numerical and experimental results in both the present work and literature. The effects of the Weber number, contact angle, and cone angle on the droplet behavior, especially the maximum spreading factor, are investigated. The findings indicate that the maximum spreading factor becomes larger at a larger Weber number, a smaller contact angle, and a cone angle. Based on energy conservation, two theoretical models considering the film and ring profiles are proposed to describe the droplet maximum spreading factor. The film and ring models are recommended for use when the maximum spreading factor is below and above 2.4, with the relative deviation of all calculated data less than ±18%. This study enhances the understanding of droplet impacts on complex surfaces and provides valuable guidance for engineering applications.

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Maximum spreading of an impact droplet on a conical tip

Zhang,

Li,

Liu

et al. 2024

Physics of Fluids

View full text Add to dashboard Cite

show abstract

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Research Progress of Bionic Water Strider Robot

Cited by 1 publication

References 50 publications

Maximum spreading of an impact droplet on a conical tip

Maximum spreading of an impact droplet on a conical tip

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