An anti-rolling wheel includes: a ring-shaped main wheel; an inner frame positioned inside the main wheel, wherein the inner frame comprising at least two auxiliary wheels that come into contact with an inner surface of the main wheel and rotate when the main wheel is driven; and a sliding block provided to be movable under the guide of the inner frame.

The present teachings generally provide for an overrunable test vehicle for dynamic vehicle testing of advanced driver assistant systems along a driving plane. The overrunable test vehicle comprising a chassis with a first end and a second end and including a mounting area configured to receive a soft target, and defining an axis of rotation transverse to the driving plane between the first end and the second end, four drive mechanisms coupled with the chassis, each drive mechanism having an electric motor with a drive wheel, and a control system coupled with the electric motors, and configured to control speed and torque of each of the electric motors, forming a torque vector that rotates the overrunable test vehicle about the axis of rotation to a target rotation angle. The axis of rotation is a location between the two drive mechanisms that the chassis turns about when the torque vector is applied to the chassis of the overrunable test vehicle.

The Reconfigurable Wheel-Track (RWT) device is a novel mechanism that allows a wheel to transform into a track, and vice versa. The wheel mode allows a vehicle to travel quickly over smooth and semi-rough terrain, then, on-the-fly, transform rapidly into a powered track mode for crossing extreme terrain. The reconfigurable wheeltrack device comprises several main components: an outer tire/tread, a drive mechanism for driving the tread when in track mode and a reconfiguration mechanism that facilitates the transformation from wheel mode to track mode and vice versa. The reconfigurable wheel-track includes sensing, actuation, and controls to facilitate efficient and effective transitions, and securely maintain each wheel and track shape.

The Reconfigurable Wheel-Track (RWT) device is a novel mechanism that allows a wheel to transform into a track, and vice versa. The wheel mode allows a vehicle to travel quickly over smooth and semi-rough terrain, then, on-the-fly, transform rapidly into a powered track mode for crossing extreme terrain. The reconfigurable wheeltrack device comprises several main components: an outer tire/tread, a drive mechanism for driving the tread when in track mode and a reconfiguration mechanism that facilitates the transformation from wheel mode to track mode and vice versa. The reconfigurable wheel-track includes sensing, actuation, and controls to facilitate efficient and effective transitions, and securely maintain each wheel and track shape.

A wheel device includes: a plurality of wing members configured to rotate around a central axis, wherein each wing member of the plurality of wing members may include an outer circumferential surface and each wing member of the plurality of wing members is configured to be movable to a first position in which the respective outer circumferential surfaces combine to form a circle, and to a second position in which an end of each outer circumferential surface is rotated away from the central axis of the wheel device; a deforming device configured to move each wing member of the plurality of wing members to the first position or the second position; a plurality of rollers provided on the respective outer circumferential surfaces of the plurality of wing members, wherein each roller of the plurality of rollers has a rotation axis that is not parallel to the central axis; and a braking device including a brake pad configured to contact one or more rollers of the plurality of rollers when the plurality of wing members are in the second position and to separate from the plurality of rollers when the plurality of wing members are in the first position.

A surgical robotic system includes a robotic arm cart for supporting a robotic arm, and a docking station configured to be secured to an operating room floor around a surgical table. The robotic arm cart has a plurality of legs having wheels for facilitating movement of the robotic arm cart along the floor of the operating room. The robotic arm cart is configured to transition from an enlarged footprint state to a reduced footprint state. When the robotic arm cart is in the reduced footprint state, the robotic arm cart may be connected to the docking station to provide stability to the robotic arm cart.

An electric walking assisting vehicle configured such that in accordance with operating amounts acting on an operation part, driving of driving motors is controlled and includes an inclination detector which detects inclination of a vehicle body in a forward-backward direction, and on flat land where inclination is less than a threshold, with an operation origin of the operation part as a center, the driving motors are controlled to generate torque in a forward direction by operation of pushing the operation part forward and to generate torque in a backward direction by operation of pulling the operation part backward, on an uphill road on which the inclination is the threshold value or more, the operation origin is shifted to an pulling operation side, and on a downhill road on which the inclination is the threshold value or more, the operation origin is shifted to a pushing operation side.

A convertible item of furniture including: a plurality of shelf units, wherein each shelf unit has a horizontally extending leave and at least one leave support for supporting the leave; a drive system operably connected to each leave support such that the leaves remain horizontal when the shelf units are moved between a vertical configuration and a horizontal configuration; and, an anti-tip leg system. The anti-tip leg system has a front leg assembly and a rear leg assembly including an upwardly extending pair of rear legs, each rear leg comprising a rear leg upper region operably connected to a shelf unit or a part of the drive system, and a rear leg lower region supporting at least one wheel, and a linkage assembly interconnecting the front and rear leg assemblies. A spacing between the front and rear leg lower regions increases as the shelf units move towards the horizontal configuration.

To provide an idler of a crawler-type traveling device which secures the strength while suppressing an increase in the weight and cost, and a crawler-type traveling device provided with the same. An idler includes a hub section that is axially supported; a rim section that is disposed coaxially with the hub section; and plates that connect the hub section and the rim section. At least one of the hub section and the rim section has flange sections that rise toward the other. The plates are mounted to the flange sections.

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.