Chunying Jiang scite author profile

Purpose The mechanical properties between wheel and ground will affect the motion performance of wheeled omnidirectional mobile robot (OMR). MY3 wheel is an omnidirectional wheel. This paper aims to analyze the contact mechanical characteristics between MY3 wheel and ground to improve the motion accuracy of an omnidirectional mobile platform with MY3 wheel (MY3-OMR). Design/methodology/approach This method takes MY3 wheel as the research objective. The normal and tangential contact mechanics model and rolling contact mechanics model of MY3 wheel are established by analyzing the structure of MY3 wheel, and thereby, the slip ratio of MY3 wheel in the process of motion is calculated. The kinematics model of MY3-OMR is optimized by taking the slip ratio as the optimization parameter that aims to improve motion accuracy of MY3-OMR. Findings The correctness of the mechanical analysis and the feasibility of the method are verified by the MY3-OMR prototype. Let MY3-OMR move along the set circular trajectory and square trajectory, and the error between the motion trajectory before and after optimization and the standard trajectory is obtained. It illustrates that the error in the square trajectory is reduced by 1.5%, and the circular trajectory error is reduced by 2%; therefore, the method is effective. Originality/value A method based on contact mechanics is proposed and verified. Through the establishment of wheel-ground contact mechanics model to optimize MY3-OMR kinematics model, and thereby, the motion accuracy of MY3-OMR is improved, which lays a foundation for MY3-OMR engineering application.

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Effect of grinding parameters on microstructure evolution of TC21 titanium alloy with bimodal starting microstructure

Wang

Xiu

Zhang

et al. 2020

Journal of Alloys and Compounds

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A Study on Slippage and Tip-over Stability for an Omnidirectional Mobile Robot with Longitudinal MY-wheels

Jiang

et al. 2019

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Simulation of One Aircraft Fuel Supply System Based on AMESim

Feng

Jiang

et al. 2022

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Chunying Jiang

Fuzzy adaptive PID control method for multi-mecanum-wheeled mobile robot

Motion optimization of an omnidirectional mobile robot with MY wheel based on contact mechanics

Effect of grinding parameters on microstructure evolution of TC21 titanium alloy with bimodal starting microstructure

A Study on Slippage and Tip-over Stability for an Omnidirectional Mobile Robot with Longitudinal MY-wheels

Simulation of One Aircraft Fuel Supply System Based on AMESim

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