Disclosed is a method of forming a wheel assembly consisting of a wheel portion and a cover portion. The method includes handling the wheel portion from dunnage to a work cell with an outboard face of the wheel portion facing away from a supporting surface. Next, determining a planar position and a rotational position of wheel portion and retrieving the cover portion. The method proceeds with applying an adhesive to at least one of the back side of the cover portion and the outboard face of the wheel portion. Then, aligning the cover portion with the wheel portion utilizing the planar position and the rotational position. The next step is engaging the cover portion and the wheel portion with one another and maintaining the wheel portion in engagement with the cover portion for a predetermined amount of time with a predetermined amount of pressure to form the wheel assembly.

Disclosed is a method of forming a wheel assembly consisting of a wheel portion and a cover portion. The method includes handling the wheel portion from dunnage to a work cell with an outboard face of the wheel portion facing away from a supporting surface. Next, determining a planar position and a rotational position of wheel portion and retrieving the cover portion. The method proceeds with applying an adhesive to at least one of the back side of the cover portion and the outboard face of the wheel portion. Then, aligning the cover portion with the wheel portion utilizing the planar position and the rotational position. The next step is engaging the cover portion and the wheel portion with one another and maintaining the wheel portion in engagement with the cover portion for a predetermined amount of time with a predetermined amount of pressure to form the wheel assembly.

This disclosure concerns wheels for industrial vehicles, including scissor lift vehicles and aerial platform vehicles. More particularly, this disclosure concerns a wheel fabricated with a substantially cylindrical wheel rim and a front face surface which includes a center hub section that is inwardly offset from the front edge by an amount and at an angle providing flexibility to recover from incidences that can damage the wheel.

This disclosure concerns wheels for industrial vehicles, including scissor lift vehicles and aerial platform vehicles. More particularly, this disclosure concerns a wheel fabricated with a substantially cylindrical wheel rim and a front face surface which includes a center hub section that is inwardly offset from the front edge by an amount and at an angle providing flexibility to recover from incidences that can damage the wheel.

Provided are an anti-fatigue in-situ aluminum-based nanocomposite material for heavy-load automobile hubs and a preparation method therefor. By means of the fine adjustment of components and a forming process, in situ nano-compositing, micro-alloying and rapid compression moulding techniques are combined. That is, after the addition of Zr and B, an in-situ reaction occurs to form a nano ZrB.sub.2 ceramic reinforcement, which is distributed in aluminum crystals and crystal boundaries and bonded to a metallurgical interface kept firm with the matrix.

Provided are an anti-fatigue in-situ aluminum-based nanocomposite material for heavy-load automobile hubs and a preparation method therefor. By means of the fine adjustment of components and a forming process, in situ nano-compositing, micro-alloying and rapid compression moulding techniques are combined. That is, after the addition of Zr and B, an in-situ reaction occurs to form a nano ZrB.sub.2 ceramic reinforcement, which is distributed in aluminum crystals and crystal boundaries and bonded to a metallurgical interface kept firm with the matrix.

A longitudinally tapered wheel spoke having a thin aerodynamic cross-sectional profile proximate to the wheel rim and tapering to a round profile toward the central hub, with the tapered section optimized to minimize drag against a combined headwind and crosswind impinging upon the primary vehicle-drag-inducing uppermost region of the wheel assembly.

A three-layer soft rubber shock absorbing wheel including a hub. An outer surface of the hub is bonded with a hard body, a first layer of tread and a second layer of tread having a hardness lower than that of the first layer of tread. The hard body, the first layer of tread, and the second layer of tread are arranged from inside to outside in sequence. The second layer of tread is bonded in a concave surface portion on an outer surface of the first layer of tread. The first layer of tread and the second layer of tread are both elastic bodies. The hard body is configured to have an I-shaped structure body. The three-layer soft rubber shock absorbing wheel is a wheel body made by bonding three layers of materials with different hardness.

A wheel is provided including a disc face, an open end opposing the disc face, and a wheel rim extending between the disc face and the open end, the wheel rim including a rib extending radially inward from the rim and a rim section including the rib.

A wheel is provided including a disc face, an open end opposing the disc face, and a wheel rim extending between the disc face and the open end, the wheel rim including a rib extending radially inward from the rim and a rim section including the rib.