Wheels for use on vehicles and methods of manufacturing vehicle wheels are described in the present disclosure. According to one embodiment, a method includes a step of manufacturing a wheel that includes a rim, a center disk, and a plurality of spokes. The rim may include a substantially-cylindrical barrel adapted to seal a tubeless tire. The center disk may include a central bore adapted for engagement with an axle of a vehicle. Also, the plurality of spokes may be adapted to connect the center disk to the rim. The method further includes the step of deforming outwardly-facing surfaces of the spokes using one or more hammering or punching instruments.

The wheel is for a railway vehicle that travels on a rail. The wheel includes a wheel tread, a flange and a throat portion. The wheel tread is provided at an outer circumferential portion of the wheel. The wheel tread faces a head surface of the rail. The flange is provided at the outer circumferential portion of the wheel. The flange projects further outward than the wheel tread in the radial direction of the wheel. The throat portion connects the surface of the flange and the wheel tread. The throat portion has a protrusion. The protrusion projects to the rail side. The protrusion extends along the entire circumference of the throat portion.

The present disclosure relates to a caster, having a housing, having an axle pin which is arranged in a housing opening which is oriented substantially horizontally, and on which at least one wheel is mounted, having, at the top, a pin opening oriented substantially vertically, for receiving a pivot pin, and having a braking device which brakes the at least one wheel, wherein the housing opening for the axle pin allows limited vertical displaceability of the axle pin and the braking device comprises at least one resilient housing part which acts on the axle pin. In order to provide a mechanically reliable braking device, the braking device is additionally provided with at least one spring element which cooperates with the at least one resilient housing part and amplifies the effect of its braking force and/or increases the mechanical load-bearing capacity of the at least one resilient housing part.

The present invention is directed to airless tires. Exemplary airless tires include a hub configured for attachment to an axle and includes a hub support extending away from the hub. Such exemplary airless tires also include a heel configured around the hub and connected at a distal end of the hub support, whereby the heel includes an elastomer base oriented in a ring around a circumference of the hub support. Such exemplary airless tires also include elastomeric tubes extending radially outward from the heel. Other exemplary airless tires include a centerless hub assembly configured for attachment to an axle and a heel configured around the centerless hub assembly. The heel in such exemplary airless tires includes an elastomer base oriented in a ring around a circumference of the centerless hub assembly. These other exemplary airless tires include elastomeric tubes extending radially outward from the heel.

The present invention is directed to airless tires. Exemplary airless tires include a hub configured for attachment to an axle and includes a hub support extending away from the hub. Such exemplary airless tires also include a heel configured around the hub and connected at a distal end of the hub support, whereby the heel includes an elastomer base oriented in a ring around a circumference of the hub support. Such exemplary airless tires also include elastomeric tubes extending radially outward from the heel. Other exemplary airless tires include a centerless hub assembly configured for attachment to an axle and a heel configured around the centerless hub assembly. The heel in such exemplary airless tires includes an elastomer base oriented in a ring around a circumference of the centerless hub assembly. These other exemplary airless tires include elastomeric tubes extending radially outward from the heel.

A hubcap for a heavy-duty duty vehicle that includes mounting structure that is formed with and cooperates with a side wall of the hubcap to provide a stiff, rigid structure that enables non-cantilevered connection to a wheel hub. The mounting structure can be a plurality of elongated bosses circumferentially spaced about the side wall that are formed with corresponding elongated bolt openings to enable the non-cantilevered attachment to the wheel hub. The elongated bosses cooperate with the hubcap side wall to provide a stiffened or rigid structure between the elongated bolt openings for increased and more uniform clamping force on a sealing gasket between the hubcap and the wheel hub. The hubcap profile provides clearance for removal of an outboard mounted disc brake rotor in heavy-duty vehicle wheel end assemblies that include such rotor configurations. The hubcap may support simple mounting of a hub odometer.

A method of making a work piece without the use of an auxiliary anode and a work piece created using the method are provided. The work piece includes a main face being generally planar. The work piece also includes a first area comprising a plateable resin configured to be plated using the plating process without the auxiliary anode and having a first current density during the plating process. Additionally, the work piece includes a second area comprising a non-plateable resin configured to not be plated using the plating process without the auxiliary anode. The first area and the second area are determined by a process referencing a predetermined minimum current density value with the first current density being greater than the predetermined minimum current density value.

A wheel structure includes a rim and a tire. The rim includes a body, hub and spokes. The body has two edges which first and second flanges are annularly disposed at, respectively, to form a tire holder. First and second walls are annularly disposed at the edges of the body in such a manner to face the first and second flanges, respectively, allowing a first engaging slot to be formed between the first flange and the first wall and a second engaging slot to be formed between the second flange and the second wall. The tire is coupled to the tire holder. First and second coupling portions are disposed at two inner edges of the tire and coupled to the first and second engaging slots, respectively. A hollow core portion is formed between the first and second coupling portions.

The present disclosure provides a two (2) piece wheel comprising a first section and a second section wherein the wheel comprises areas of varying diameter across its width and the first section and second section are joined at the area of the wheel with the smallest diameter.

The bicycle hub assembly includes a hub axle, a hub body, a bearing unit, a lock member, and a tool engagement member. The bearing unit is configured to rotatably support the hub body around the hub axle with respect to the rotational center axis. The bearing unit includes an outer race, an inner race and a plurality of rolling members. The lock member prevents the inner race of the bearing unit from rotating relative to the hub axle. The lock member has an outer peripheral surface. The tool engagement member is configured to rotate the inner race of the bearing unit relative to the hub axle. The tool engagement member has an inner peripheral surface. The inner peripheral surface of the tool engagement member is disposed radially outwardly relative to the outer peripheral surface of the lock member.