Peijin Zi scite author profile

Peijin Zi

5Publications

21Citation Statements Received

486Citation Statements Given

How they've been cited

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325

486

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Beihang University

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Learning from biological attachment devices: applications of bioinspired reversible adhesive methods in robotics

Ding

2022

Front. Mech. Eng.

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Many organisms have attachment organs with excellent functions, such as adhesion, clinging, and grasping, as a result of biological evolution to adapt to complex living environments. From nanoscale to macroscale, each type of adhesive organ has its own underlying mechanisms. Many biological adhesive mechanisms have been studied and can be incorporated into robot designs. This paper presents a systematic review of reversible biological adhesive methods and the bioinspired attachment devices that can be used in robotics. The study discussed how biological adhesive methods, such as dry adhesion, wet adhesion, mechanical adhesion, and sub-ambient pressure adhesion, progress in research. The morphology of typical adhesive organs, as well as the corresponding attachment models, is highlighted. The current state of bioinspired attachment device design and fabrication is discussed. Then, the design principles of attachment devices are summarized in this article. The following section provides a systematic overview of climbing robots with bioinspired attachment devices. Finally, the current challenges and opportunities in bioinspired attachment research in robotics are discussed.

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A mechanical adhesive gripper inspired by beetle claw for a rock climbing robot

Tian

et al. 2023

Mechanism and Machine Theory

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Gait Analysis of Quadruped Robot Using the Equivalent Mechanism Concept Based on Metamorphosis

Ding

2019

Chin. J. Mech. Eng.

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The previous research regarding the gait planning of quadruped robot focuses on the sequence for lifting off and placing the feet, but neglects the influence of body height. However, body height affects gait performance significantly, such as in terms of the stride length and stability margin. We herein study the performance of a quadruped robot using the equivalent mechanism concept based on metamorphosis. Assuming the constraints between standing feet and the ground with hinges, the ground, standing legs and robot body are considered as a parallel mechanism, and each swing leg is regarded as a typical serial manipulator. The equivalent mechanism varies while the robot moves on the ground. One gait cycle is divided into several periods, including step forward stages and switching stages. There exists a specific equivalent mechanism corresponding to each gait period. The robot's locomotion can be regarded as the motion of these series of equivalent mechanisms. The kinematics model and simplified model of the equivalent mechanism is established. A new definition of the multilegged robot stability margin, based on friction coefficient, is presented to evaluate the robot stability. The stable workspaces of the equivalent mechanism in the step forward stage of trotting gait under different friction coefficients are analyzed. The stride length of the robots is presented by analyzing the relationship between the stable workspaces of the equivalent mechanisms of two adjacent step forward stages in one gait cycle. The simulation results show that the stride length is larger with increasing friction coefficient. We herein propose a new method based on metamorphosis, and an equivalent mechanism to analyze the stability margin and stable workspace of the multilegged robot.

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A Mechanical Adhesive Gripper Inspired by Beetle Claw for a Rock Climbing Robot

Zi¹,

Xu²,

Tian³

et al. 2022

SSRN Journal

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Design of an Integrated Hand-Foot End-Effector for Multi-Legged Robots

et al. 2018

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Peijin Zi

Learning from biological attachment devices: applications of bioinspired reversible adhesive methods in robotics

A mechanical adhesive gripper inspired by beetle claw for a rock climbing robot

Gait Analysis of Quadruped Robot Using the Equivalent Mechanism Concept Based on Metamorphosis

A Mechanical Adhesive Gripper Inspired by Beetle Claw for a Rock Climbing Robot

Design of an Integrated Hand-Foot End-Effector for Multi-Legged Robots

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