首页 /研究 /Design, Modeling, and Control of a Differential Drive Rimless Wheel That Can Move Straight and Turn
LOCOMOTION

Design, Modeling, and Control of a Differential Drive Rimless Wheel That Can Move Straight and Turn

S. F. Sánchez, Pranav A. Bhounsule

发表年份
2021
引用次数
9
访问权限
开放获取

摘要

A rimless wheel or a wheel without a rim, is the simplest example of a legged robot and is an ideal testbed to understand the mechanics of locomotion. This paper presents the design, modeling, and control of a differential drive rimless wheel robot that achieves straight-line movement and turning. The robot design comprises a central axis with two 10-spoked springy rimless wheels on either side and a central body that houses the electronics, motors, transmission, computers, and batteries. To move straight, both motors are commanded to constant pitch control of the central body. To turn while maintaining constant pitch, a differential current is added and subtracted from currents on either motor. In separate tests, the robot achieved the maximum speed of 4.3 m per sec (9.66 miles per hour), the lowest total cost of transport (power per unit weight per unit velocity) of 0.13, and a smallest turning radius of 0.5 m. A kinematics-based model for steering and a dynamics-based sagittal (fore-aft) plane model for forward movement is presented. Finally, parameters studies that influence the speed, torque, power, and energetics of locomotion are performed. A rimless wheel that can move straight and turn can potentially be used to navigate in constrained spaces such as homes and offices.

关键词

Turning radiusElectronic differentialControl theory (sociology)TorqueKinematicsRobotPower (physics)EngineeringSimulationComputer science

相关论文

查看 LOCOMOTION 分类全部论文