An axle housing assembly includes an axle housing that includes a center portion and a first arm portion that extends from the center portion. The axle housing assembly further includes a wheel end housing that includes a wheel end body that extends from the first arm portion and a spindle that extends from the wheel end body.

An air reservoir for a steering axle is mounted on a trailer, the steering axle comprising a pair of rotation pivoting wheel assemblies. Each wheel assembly has a rotation plate and a steering arm connected thereto. A rod pivotally connects the steering arms, each wheel assembly being rotatably connected to either end of the axle. An air stabilizer assembly is mounted on the axle and is connected to the rod, the air stabilizer assembly having an inflatable damper assembly thereon. An air supply is fluidly connected to an air inlet on the axle, the air inlet being fluidly connected to the damper assembly. The air stabilizer assembly dampens pivotal movement of the wheel assemblies when compressed air from the air reservoir fills the damper assembly. The air stabilizer assembly allows the wheel assemblies to rotate more freely when pressure of the compressed air within the damper assembly is reduced.

A wheel assembly includes a wheel portion comprises a web having an inboard surface. The web may define a torque bar retention slot that extends from the inboard surface of the web. The wheel assembly may also include a bushing disposed in the torque bar retention slot, wherein the bushing comprises an open end and a closed end. Still further, the wheel assembly may include a torque bar coupled to the wheel, and the torque bar may include a boss extending into the bushing through the open end of the bushing such that the boss of the torque bar is at least partially disposed within the torque bar retention slot of the wheel portion.

A wheel assembly includes a first side plate having a first annular base, axially protruding first claw members projecting axially outward from the first annular base, axially protruding first hub mounts projecting axially outward from the first annular base, and axially protruding first spring mounts projecting axially outward from the first annular base; a hub member attached to the first side plate; and a tire assembly laid over the hub member such that spokes of the tire assembly are radially adjacent corresponding first claw members of the first side plate, a plurality of friction members and the first claw members sandwiching each of the spokes.

A wheel hub includes an outer collar region, as seen in the radial direction, and an inner core region, as seen in the radial direction, wherein, as seen in the axial direction, the inner core region is thicker than the outer collar region, and wherein, in the inner core region, the wheel hub has a substantially axially running primary recess for the connection of a brake disk.

A braking assembly can include a brake disc that may have a first segment and a second segment arranged to form a portion of a friction ring. The assembly can also include a fastening assembly that can include a first bracket that may have a first face configured to contact the wheel web and a second face opposite to the first face. The fastening assembly may also include a fastening device with a sliding pin disposed around a shaft. The first bracket may be disposed around the sliding pin and secured between the wheel web and a first component of the fastening device. The shaft may be disposed through the wheel web and the first bracket. The first component can contact the second face of the first bracket and may compress the first bracket against the wheel web to secure the first segment and the second segment to the wheel.

The apparatus is for use with a mechanism of the type which, when manufactured, has an axle tube terminating in a brake mount, a spindle extending from the brake mount, a spider plate mounted to the brake mount in surrounding relation to the spindle, a hub mounted to the spindle and a wheel mounted to the hub. The apparatus is adapted to receive the hub in the manner of the spindle, adapted to be mounted to the brake mount and adapted to capture the spider plate against the brake mount.

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 wheel includes a rim and a wheel center with several spokes with at least one butt strap. The at least one butt strap protrudes from a radially outer end of the spokes. The rim includes at least one opening arranged corresponding to the at least one butt strap. The at least one butt strap extends across the related opening in the rim and is attached to the outside of the rim.

Implementations disclosed and claimed herein provide a wheel cover system. In one implementation, an inward force exerted against a wheel cover of the wheel cover assembly in an inward direction towards the hub is received. The inward force overcomes a spring bias of a spring of the receiver and translates the wheel cover assembly in the inward direction. A first rotational force rotating the wheel cover assembly in a first direction is received. The first post guides and engages the first hook, and the second post guides and engages the second hook during rotation. A first positive feedback is generated in response to the inward force and the first rotational force. The wheel cover assembly is releaseably locked to the receiver by translating the wheel cover assembly in the outward direction using an outward force generated by the spring bias. The outward force provides a second positive feedback.