A tire stabilizer is provided that includes an upper block, a lower block, and a biasing device. The upper block has an inclined surface that is inclined relative to a bottom surface. The biasing device is disposed between the upper block and the lower block. A method of rotating a lug nut of a vehicle that is elevated above a ground surface is also provided. The method includes positioning a tire stabilizer between the ground surface and a tire of the vehicle, placing a wrench over the lug nut, rotating the wrench, removing the wrench from the lug nut, and removing the tire stabilizer from the tire. The tire stabilizer includes an upper block having an inclined surface, a lower block partially disposed within the upper block, and a biasing device disposed between the upper block and the lower block.

A tire stabilizer is provided that includes an upper block, a lower block, and a biasing device. The upper block has an inclined surface that is inclined relative to a bottom surface. The biasing device is disposed between the upper block and the lower block. A method of rotating a lug nut of a vehicle that is elevated above a ground surface is also provided. The method includes positioning a tire stabilizer between the ground surface and a tire of the vehicle, placing a wrench over the lug nut, rotating the wrench, removing the wrench from the lug nut, and removing the tire stabilizer from the tire. The tire stabilizer includes an upper block having an inclined surface, a lower block partially disposed within the upper block, and a biasing device disposed between the upper block and the lower block.

Systems and methods for controlling wheel motion during a collision are provided. A retaining member may be connectable between a vehicle frame and a wheel assembly to control motion of the wheel assembly during a collision of a vehicle with an object. The retaining member may include one or more of a first attachment point connecting the retaining member to the vehicle frame, a second attachment point connecting the retaining member to the wheel assembly, a retaining member routing, and/or one or more break-away connections attaching the retaining member to the vehicle frame and/or to the wheel assembly. The first and second attachment points, retaining member routing, and/or break-away connections may be selected to control motion of the wheel assembly within a preferred path to control loading between the object and the vehicle.

Systems, methods and apparatus for automated vehicle wheel removal and replacement are provided. One system includes a computer system with applications for scheduling the replacement of tires for the vehicle. An electronically controlled lift device and robotic apparatus is configured for interaction with the computer system. The lift device mechanically adjusts arms for placement on lift points of vehicles. The robotic apparatus detects positioning of lug nut configuration for a wheel, removes lug nuts, and then removes the wheel from the wheel hub with gripping arms. The wheel and tire are then handed off to a separate tire changing machine. When a new tire is replaced the robotic apparatus then mounts the wheel to the original wheel hub, and then secures the lug nuts to the lug nut bolts.

A rough terrain cart for a wheel chair includes a frame operable to support a wheel chair and a wheel chair user. A pair of cart drive wheels are rotationally mounted to the frame. A locking mechanism is engaged with the frame. The locking mechanism is operable to secure the wheel chair to the cart. A rotational mechanism is engaged with the frame. The rotational mechanism is configured to support a pair of wheel chair drive wheels of the wheel chair and is operable to enable the wheel chair drive wheels to rotate when the wheel chair is secured to the cart by the locking mechanism. A transmission system is engaged with the frame. The transmission system is connectable to the wheel chair drive wheels. The transmission system is operable to transmit torque from the wheel chair drive wheels to the cart drive wheels.

In one embodiment, a wheel righting apparatus includes a main frame and a wheel latching frame that is pivotally coupled to the main frame. The wheel latching frame is configured to be removably coupled to a wheel. The wheel righting apparatus also includes a winch assembly coupled to the main frame. The winch assembly is operable to move the wheel from a horizontal position to a vertical position by pivoting the wheel latching frame relative to the main frame.

In one embodiment, a wheel righting apparatus includes a main frame and a wheel latching frame that is pivotally coupled to the main frame. The wheel latching frame is configured to be removably coupled to a wheel. The wheel righting apparatus also includes a winch assembly coupled to the main frame. The winch assembly is operable to move the wheel from a horizontal position to a vertical position by pivoting the wheel latching frame relative to the main frame.

A wheel detailing stand that provides for 3-point contact with a wheel mounted thereon is disclosed. The wheel detailing stand includes a base frame having a bottom frame member and a back frame member extending upwardly from the bottom frame member, a pair of bottom rollers attached to the bottom frame member where the pair of rollers are arranged in parallel and spaced apart from one another, and a back roller attached to the back frame member and oriented generally orthogonally to the pair of bottom rollers. The pair of bottom rollers and the back roller provide 3-point contact with a wheel positioned on the wheel detailing stand.

Disclosed is a foldable bearing vehicle, comprising a bracket and a rolling wheel assembly. The rolling wheel assembly is provided at the side of the bracket and comprises a front rolling wheel and a rear rolling wheel; the front end of the bracket is provided with a front supporting plate, and the rear end of the bracket is provided with a rear supporting plate; the bracket is provided with a rotating assembly and a locking assembly; when the bearing vehicle is folded, the bracket is flipped upwards or downwards to be folded; when the bearing vehicle is used, the bracket is reversely rotated to be unfolded and reset, and the locking assembly locks the unfolded bracket.

A tire stabilizer is provided that includes an upper block, a lower block, and a biasing device. The upper block has an inclined surface that is inclined relative to a bottom surface. The biasing device is disposed between the upper block and the lower block. A method of rotating a lug nut of a vehicle that is elevated above a ground surface is also provided. The method includes positioning a tire stabilizer between the ground surface and a tire of the vehicle, placing a wrench over the lug nut, rotating the wrench, removing the wrench from the lug nut, and removing the tire stabilizer from the tire. The tire stabilizer includes an upper block having an inclined surface, a lower block partially disposed within the upper block, and a biasing device disposed between the upper block and the lower block.