Granular Resistive Force Theory Extension for Saturated Wet Sand Ground

Ma, Xinmeng; Wang, Gang; Liu, Kaixin; Chen, Xi; Wang, Jixin; Pan, Biye; Wang, Liquan

doi:10.3390/machines10090721

Cited by 3 publications

(2 citation statements)

References 33 publications

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“…In cases where the lift coefficient is negative, the robot will exert more pressure on the ground as the relative velocity of the water flow increases, increasing the likelihood of becoming stuck in sediment. To calculate the lift and drag coefficients, we used the wet particle medium theory for a simplified analysis, as introduced by Ma et al [44]. This theory examines the force dynamics when a moving object infiltrates a wet particle medium, as represented by Equation (10).…”

Section: Inspiration Of Lift and Drag Coefficients On Underwater Atti...mentioning

confidence: 99%

Effect of Bionic Crab Shell Attitude Parameters on Lift and Drag in a Flow Field

Hu,

Chen,

et al. 2024

Biomimetics

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Underwater bionic-legged robots encounter significant challenges in attitude, velocity, and positional control due to lift and drag in water current environments, making it difficult to balance operational efficiency with motion stability. This study delves into the hydrodynamic properties of a bionic crab robot’s shell, drawing inspiration from the sea crab’s motion postures. It further refines the robot’s underwater locomotion strategy based on these insights. Initially, the research involved collecting attitude data from crabs during underwater movement through biological observation. Subsequently, hydrodynamic simulations and experimental validations of the bionic shell were conducted, examining the impact of attitude parameters on hydrodynamic performance. The findings reveal that the transverse angle predominantly influences lift and drag. Experiments in a test pool with a crab-like robot, altering transverse angles, demonstrated that increased transverse angles enhance the robot’s underwater walking efficiency, stability, and overall performance.

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Section: Inspiration Of Lift and Drag Coefficients On Underwater Atti...mentioning

confidence: 99%

Effect of Bionic Crab Shell Attitude Parameters on Lift and Drag in a Flow Field

Hu,

Chen,

et al. 2024

Biomimetics

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“…We refer to hydrostatic-like pressure as a pressure that increases proportionally with depth ( Aguilar and Goldman, 2016 ). It has been shown that different flowable materials, when stepped upon, generate a reaction force that is almost proportional to the depth of intrusion ( Sharpe et al., 2013 ; Godon et al., 2022 ; Ma et al., 2022 ). In the horizontal direction, thrust can be generated by relying on the cohesion and adhesion of the medium particles with the body.…”

Section: Background On Non-newtonian Yielding Materialsmentioning

confidence: 99%

Maneuvering on non-Newtonian fluidic terrain: a survey of animal and bio-inspired robot locomotion techniques on soft yielding grounds

2023

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Frictionally yielding media are a particular type of non-Newtonian fluids that significantly deform under stress and do not recover their original shape. For example, mud, snow, soil, leaf litters, or sand are such substrates because they flow when stress is applied but do not bounce back when released. Some robots have been designed to move on those substrates. However, compared to moving on solid ground, significantly fewer prototypes have been developed and only a few prototypes have been demonstrated outside of the research laboratory. This paper surveys the existing biology and robotics literature to analyze principles of physics facilitating motion on yielding substrates. We categorize animal and robot locomotion based on the mechanical principles and then further on the nature of the contact: discrete contact, continuous contact above the material, or through the medium. Then, we extract different hardware solutions and motion strategies enabling different robots and animals to progress. The result reveals which design principles are more widely used and which may represent research gaps for robotics. We also discuss that higher level of abstraction helps transferring the solutions to the robotics domain also when the robot is not explicitly meant to be bio-inspired. The contribution of this paper is a review of the biology and robotics literature for identifying locomotion principles that can be applied for future robot design in yielding environments, as well as a catalog of existing solutions either in nature or man-made, to enable locomotion on yielding grounds.

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Optimal design and implementation of an amphibious bionic legged robot

Wang

Liu

et al. 2023

Ocean Engineering

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Granular Resistive Force Theory Extension for Saturated Wet Sand Ground

Cited by 3 publications

References 33 publications

Effect of Bionic Crab Shell Attitude Parameters on Lift and Drag in a Flow Field

Effect of Bionic Crab Shell Attitude Parameters on Lift and Drag in a Flow Field

Maneuvering on non-Newtonian fluidic terrain: a survey of animal and bio-inspired robot locomotion techniques on soft yielding grounds

Optimal design and implementation of an amphibious bionic legged robot

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