An omni-wheel may include a shaft, a plurality of rollers, and a braking device. The plurality of rollers may be circumferentially arranged about the shaft and arranged radially outward from the shaft. The braking device may include an at least one flexible clutch member, an at least one brake pad, and an actuator. The at least one flexible clutch member may have an outer diameter arranged about the shaft. The at least one brake pad may be arranged on the outer diameter of the at least one flexible clutch member. The actuator may be arranged to axially displace the at least one flexible clutch member. The at least one flexible clutch member may expand radially outward when axially displaced by the actuator, which may displace the at least one brake pad arranged on the outer diameter of the at least one flexible clutch member radially outward to contact at least one of the plurality of rollers, preventing rotation of the roller.

The present disclosure generally relates to an omni-direction wheel system and methods for controlling the omni-direction wheel system. The omni-direction wheel system includes a plurality of suspension systems that operate independently of one another. Each suspension system may include an electromagnetic steering hub configured to rotate a wheel 360 degrees about a vertical axis based on a polarity of an electromagnetic signal applied to the electromagnetic steering hub. The suspension system may further include an in-wheel motor configured to rotate with the wheel and drive the wheel about a horizontal axis.

A robot for transporting a biodevice from one place to another place, comprising a body for carrying the biodevice; a driving assembly for driving the body in omnidirectional motion; a sensing unit for sensing at least a position and orientation of the body; and a control unit coupled to the driving assembly and the sensing unit for generating one or more control signals based on at least the sensed position and orientation of the body to drive the driving assembly so as to move the body to a desired place and to arrive with the correct orientation.

Devices, Systems, and Methods for controlled movement of the robot system. The surgical robot system may include a robot having a robot base, a robot arm coupled to the robot base, and an end-effector coupled to the robot arm. The robot may include a plurality of omni-directional wheels affixed to the robot base allowing multiple-axis movement of the robot. The robot may further include sensors for detecting a desired movement of the robot base and a control system responsive to the plurality of sensors for controlling the multiple-axis movement of the robot by actuating two or more of the plurality of omni-directional wheels.

To provide a frictional drive unit that can arrange drive rollers with high density and facilitate an attachment operation of the drive rollers, a frictional drive unit 2 includes a pair of drive disks 4, a plurality of drive rollers 5 rotatably supported by an outer circumferential portion of each drive disk, a pair of actuators 8 configured to independently rotate the pair of drive disks, and an annular main wheel 7 arranged between the pair of drive disks and coming into contact with the drive rollers. Each drive roller includes a roller shaft 41 and a round roller body 42 provided on an intermediate portion of the roller shaft. Each drive disk includes plural pairs of bearing grooves 45 each receiving both ends of the roller shaft of each drive roller. Each bearing grooves open toward the main wheel.

The improved mobile robot utilizes a cooperative wheeled support arrangement having a unique axle design that preferably cooperates with a base support module. A tri-axle is preferably used to support at least one omni-wheel on each axle section. Multiple omni-wheels on each section can be used for higher load applications. The tri-axle is of a fixed design and each wheel pivots on the individual axle section. Preferably, the axle sections are welded to each other.

The present disclosure is directed to wheel-based human-powered spinning system comprising: a chassis configured to secure a user; a track surrounding said chassis; and at least one omni wheels attached to said chassis, wherein said chassis spins with unlimited range of motion, along pitch, yaw and roll axes, inside the track while supported by said at least one omni wheels, said track being independent of contact from said chassis.

An omnidirectional wheel and a scooter having an omnidirectional wheel are provided. The omnidirectional wheel includes: a hub; support members, in which the support members are circumferentially distributed on the hub, each of the support members has a first mounting surface and a second mounting surface disposed oppositely, the first mounting surface is provided with a first mounting shaft, the second mounting surface is provided with a second mounting shaft, and a distance between a first axis of the first mounting shaft and a wheel center of the hub is less than a distance between a second axis of the second mounting shaft and the wheel center of the hub; first rollers, in which at least one of the first rollers is rotatably disposed on each first mounting shaft; and second rollers, in which at least one of the second rollers is rotatably disposed on each second mounting shaft.

A trailer includes a set of removable castor wheels attached to a rear portion thereof, wherein the castor wheels are oriented to face rearwardly when the trailer is oriented in the traditional horizontal position. This arrangement allows the trailer to be tilted upwardly into a vertical orientation so that it rests on the castor wheels, thus providing an apparatus and method for easily moving and storing trailers more efficiently due to the reduced footprint required for such trailer storage. The castor wheels, in one embodiment, include mounting brackets that may be attached to the trailer using a securing rod, similarly to the mounting mechanisms commonly used for removably attaching trailer hitches into trailer hitch sleeves, thus rendering the castor wheels removable from the trailer when they are not in use for storage purposes.

The present invention relates to the construction of Mecanum wheels for a robot-operated painting system. The wheels have special characteristics given the difficulties and obstacles where they will be used. They were designed to facilitate the movement of the painting system on vertical and horizontal walls and to avoid coating losses. The Mecanum wheels consist of a set of wheel covers that are used to secure the rollers. The rollers, arranged at 45° and in a cylindrical-convex shape, contain bearings passing through their central axis, and have rollers at the ends of the bearings. The magnetic base is placed between the two wheels, being at an optimal height to exert magnetic force against the surface and to be able to pass over obstacles. Mecanum wheel geometries and materials are designed to be inert to the coating.