The present disclosure relates to an apparatus and method for a load handling system such that direction change of a transporting device is more easily and quickly realised. A transporting device includes an omnidirectional driving unit, and is arranged to transport a container, the container being stored in a facility. The facility is arranged to store the container in a plurality of stacks, a plurality of pathways being arranged in cells so as to form a grid-like structure above the stacks, the transporting device being arranged to operate on the grid-like structure and to be driven in a first direction and/or second direction.

The present disclosure relates to an apparatus and method for a load handling system such that direction change of a transporting device is more easily and quickly realised. A transporting device includes an omnidirectional driving unit, and is arranged to transport a container, the container being stored in a facility. The facility is arranged to store the container in a plurality of stacks, a plurality of pathways being arranged in cells so as to form a grid-like structure above the stacks, the transporting device being arranged to operate on the grid-like structure and to be driven in a first direction and/or second direction.

A wear computing system (100, 200, 300) for computing a wear of a wheel (3) of a vehicle (2) comprises a revolution sensor (48) configured to detect a number of revolutions of the wheel (3), an acceleration sensor (49) configured to detect an acceleration of the vehicle (2) in a travel direction thereof, and a control unit (7) configured to compute a travel distance of the vehicle from the acceleration of the vehicle, and compute the wear from the travel distance and the number of revolutions of the wheel (3).

A cart includes a vehicle body, at least one omnidirectional wheel provided at the vehicle body and configured to move the vehicle body in all directions along a floor, a drive unit configured to drive the omnidirectional wheel, a handle provided at the vehicle body and configured to accept an operation by a user, at least one sensor configured to detect loads in a width direction and a front-and-rear direction of the vehicle body applied to the handle, and a control unit configured to control the drive unit based on the loads detected by the sensor, wherein the handle includes a first portion extending in the width direction and at least one second portion extending in a front-and-rear direction.

A quick release mechanism for a wheel includes a hub and a clip, which interact with a wheel or roller that may or may not be part of the invention per se. The hub is disposable on a drive shaft such that it will rotate with the drive shaft. An optional hub cap is disposable on the wheel and has an opening that is complimentary to the geometry of the hub to allow engagement thereof such that the hub the hub cap rotate together. The clip is disposable on the hub in a closed or an open position so that the hub cap cannot or can be removed from the hub.

(Task) To provide a wheel of an omni-wheel type which can be made at low cost, and a method for making such a wheel.

(Means to Accomplish the Task) The wheel (3) comprises a core member (32) consisting of a tubular member (140) formed with a plurality of V-shaped notches (142) on one side thereof, and bent into an annular shape so as to close the notches, and a plurality of free rollers (60) each rotatably fitted on a linear section (120) of the tubular member located between a mutually adjoining pair of the V-shaped notches via a bearing (122) provided with an inner race (124) and an outer race (126), wherein a raised piece (130) is provided for each inner race on another side of the tubular member opposite from the one side as well as a protrusion (138) so as to engage an end surface of the inner race and fixedly secure the inner race to the core member.

A new and improved anatomical imaging system which includes a new and improved movement system, wherein the movement system comprises an omnidirectional powered drive unit and wherein the movement system can substantially eliminate lateral walk (or drift) over the complete stroke of a scan, even when the floor includes substantial irregularities, whereby to improve the accuracy of the scan results and avoid unintentional engagement of the anatomical imaging system with the bed or gurney which is supporting the patient.

The welding shaft for a universal wheel includes a big wheel welding shaft and a small wheel welding shaft, wherein the big wheel welding shaft includes a big wheel welding shaft body, a big wheel welding shaft retainer ring and a big wheel welding shaft fixing head which are sequentially assembled into a whole. The small wheel welding shaft includes a small wheel welding shaft body, a small wheel welding shaft retainer ring and a small wheel welding shaft fixing head which are sequentially assembled into a whole. The wheel assembly for a universal wheel includes a wheel shaft fixing plate, the welding shaft, a big wheel, and a small wheel. The universal wheel includes an outer protection plate, an outer fixing plate, a wheel shaft drive connector, multiple wheel assemblies, an inner fixing plate, an inner protection plate, and multiple shock absorption assemblies.

An all-terrain load transport system including a cylindrical first base member and at least three pairs of arms is provided. A handle is removably attached to an attachment member disposed on the cylindrical first base member. The cylindrical first base member defines a space for receiving at least one piece of accessory equipment. Each pair of the three pairs of arms defines a wheel support assembly at an end of each pair distal from an outer periphery of the cylindrical first base member. The three pairs of arms are detachably attached to the outer periphery of the cylindrical first base member. The wheel support assembly includes a cylindrical second base member defining a space for receiving a spherical wheel. The spherical wheel moves omnidirectionally within the defined space. Roller bearings positioned along an inner periphery of the cylindrical second base member facilitate the omnidirectional movement of the spherical wheel.

A vehicle includes a wheel to contact a surface having a reference surface plane in operation of the vehicle; a chassis; an axle housing having an axis which is normal to the reference surface plane; and an axle. The axle extends from the axle housing, to couple the wheel to the axle housing and to support rotation of the wheel relative to the axle housing to support motion of the vehicle across the surface in operation of the vehicle. A suspension system couples the wheel to the chassis and includes a linkage assembly having a first end pivotably coupled to the chassis and a second end pivotably coupled to the axle housing. The first end of the linkage assembly is spaced apart laterally from the second end of the linkage assembly along a longitudinal axis of the linkage assembly. The suspension system is configured to maintain the axis of the axle housing at an angle normal to the reference surface plane in response to an angular displacement between the chassis and the reference surface plane.