A power supply device used for a wheel rim is mounted on a wheel rim of a vehicle. The power supply device includes a magnetism assembly, an axle member, a magnet, a weight block, a seat, a coil module, and a control module. The seat is disposed on the wheel rim. One side of the seat is provided with an axle seat for connection of the axle member. The seat is driven by the wheel rim to turn relative to the magnetism assembly. When the seat is turned to generate power through the magnet and the coil module, the control module selectively transmits the power to a light-emitting device provided on the wheel rim.

A vent plug for a hub cap is provided. The vent plug includes a cover and base forming a chamber. A vent plug body extends from the base and forms a cavity. A shield is coupled to the vent plug body. The shield comprises an annularly extending disc that traverses the cavity. The shield includes a connecting surface to connect the shield to the vent plug body. The shield provides a lubrication/liquid barrier to inhibit lubrication (or other liquid) from entering the cavity formed by the vent plug body and the chamber. The connection between the shield and the vent plug body allows a gas (typically air) to vent past the shield into the cavity and, when pressure is sufficiently high, to the chamber and eventually atmosphere.

A vent plug for a hub cap is provided. The vent plug includes a cover and base forming a chamber. A vent plug body extends from the base and forms a cavity. A shield is coupled to the vent plug body. The shield comprises an annularly extending disc that traverses the cavity. The shield includes a connecting surface to connect the shield to the vent plug body. The shield provides a lubrication/liquid barrier to inhibit lubrication (or other liquid) from entering the cavity formed by the vent plug body and the chamber. The connection between the shield and the vent plug body allows a gas (typically air) to vent past the shield into the cavity and, when pressure is sufficiently high, to the chamber and eventually atmosphere.

In one embodiment, a vehicle wheel cover assembly is provided that includes a mount having an attachment portion with a release configuration that permits the attachment portion to engage inboard and outboard surfaces of a wheel hub flange of a wheel and a secured configuration that fixes the attachment portion to the wheel hub flange. The wheel cover assembly includes a retainer shiftable relative to the attachment portion of the mount from an unlocked position wherein the retainer permits the attachment portion to be reconfigured between the release configuration and the secured configured configuration to a locked position wherein the retainer maintains the attachment portion in the secured configuration. The wheel cover assembly further includes a cover assembly configured to be releasably secured to the mount to cover an opening of the wheel.

In one embodiment, a vehicle wheel cover assembly is provided that includes a mount having an attachment portion with a release configuration that permits the attachment portion to engage inboard and outboard surfaces of a wheel hub flange of a wheel and a secured configuration that fixes the attachment portion to the wheel hub flange. The wheel cover assembly includes a retainer shiftable relative to the attachment portion of the mount from an unlocked position wherein the retainer permits the attachment portion to be reconfigured between the release configuration and the secured configured configuration to a locked position wherein the retainer maintains the attachment portion in the secured configuration. The wheel cover assembly further includes a cover assembly configured to be releasably secured to the mount to cover an opening of the wheel.

Aspects of the present disclosure involve a wheel cover configured to streamline a wheel of a motor vehicle. In one implementation, the wheel cover includes a unit that mounts and dismounts to the hub of a wheel of a vehicle without brackets, bolts, and assembly kits. The wheel cover system may include a circular cover that covers the center of the wheel hub. An engaging structure may include one or more hooks opposed from each other with small access ports to facilitate mounting and dismounting of the wheel cover on the wheel hub. To cover the wheel hub, the wheel cover system is placed over the wheel hub and the four hooks are engaged to latch onto a back edge of the wheel hub. Through the simple activation of the hooks, the wheel cover system may be easily mounted and dismounted on the wheel hub.

Aspects of the present disclosure involve a wheel cover configured to streamline a wheel of a motor vehicle. In one implementation, the wheel cover includes a unit that mounts and dismounts to the hub of a wheel of a vehicle without brackets, bolts, and assembly kits. The wheel cover system may include a circular cover that covers the center of the wheel hub. An engaging structure may include one or more hooks opposed from each other with small access ports to facilitate mounting and dismounting of the wheel cover on the wheel hub. To cover the wheel hub, the wheel cover system is placed over the wheel hub and the four hooks are engaged to latch onto a back edge of the wheel hub. Through the simple activation of the hooks, the wheel cover system may be easily mounted and dismounted on the wheel hub.

A multi-piece rim structure for a wheel includes a rim base 10, a bead seat ring 20 (ring member) and a lock ring 30. The bead seat ring 20 receives a load in a radial direction and an axial direction from a bead portion of a tire. An annular ridge 35 of the lock ring 30 can be received in an annular lock ring groove 15 of the rim base 10. A receiving groove 15a is formed in an inner surface of the lock ring groove 15 of the rim base 10. A sacrificial anticorrosion material 80 is embedded in the receiving groove 15a. The sacrificial anticorrosion material 80 includes metal such as zinc and aluminum that has a greater ionization tendency than iron that is a base material of the rim base 10 and the lock ring 30. Corrosion of the rim base 10 and the lock ring 30 can be suppressed by ionization of the sacrificial anticorrosion material 80.

Implementations described and claimed herein provide systems and methods for streamlining wheels. In one implementation, a wheel streamlining device includes a cover assembly having a flexible connection extending around a periphery of a ring configured to contact a tapered portion of a wheel. A hook is configured to removably engage the cover assembly, and a bale is configured to releasably engage an inner surface of an opening in a face of the wheel. A springy portion extends between the bale and the hook and is configured to apply a tension force between the ring and the tapered portion of the wheel.