A non-pneumatic tire defining axial, radial and circumferential directions, the non-pneumatic tire comprising an annular shear band (106) including an annular shear layer (252) comprising an elastomeric material, and a plurality of discrete, annular reinforcing elements positioned within the shear layer (252) along a plurality of axially-extending rows (254.sub.A, 254.sub.B, 254.sub.C, 254.sub.D, 254.sub.E) within a radial plane of the tire, the reinforcing elements having circular cross-sections along the radial plane of the tire, wherein along each row the reinforcing elements alternate between reinforcing elements (250.sub.D1) having a first diameter and reinforcing elements (250.sub.D2) having a second diameter that is less than the first diameter.

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.

A tire and wheel assembly includes a non-pneumatic tire and a wheel. The non-pneumatic tire has a tread, a plurality of spokes, and an inner liner with a first side, a second side, and at least one taper extending between the first side and the second side. The wheel has an inboard side, an outboard side, and an outer surface with at least one complimentary taper extending between the inboard side and the outboard side such that the non-pneumatic tire is serviceably mounted on the wheel. A locking ring can be included and the locking ring can be configured to abut against the inboard side or the outboard side of the wheel. Also, a wheel flange extending inwardly from the inner liner can be included and the wheel flange is configured to abut against the outboard side or the inboard side of the wheel.

A tire and wheel assembly includes a non-pneumatic tire and a wheel. The non-pneumatic tire has a tread, a plurality of spokes, and an inner liner with a first side, a second side, and at least one taper extending between the first side and the second side. The wheel has an inboard side, an outboard side, and an outer surface with at least one complimentary taper extending between the inboard side and the outboard side such that the non-pneumatic tire is serviceably mounted on the wheel. A locking ring can be included and the locking ring can be configured to abut against the inboard side or the outboard side of the wheel. Also, a wheel flange extending inwardly from the inner liner can be included and the wheel flange is configured to abut against the outboard side or the inboard side of the wheel.

A tire and wheel assembly includes a non-pneumatic tire and a wheel. The non-pneumatic tire incudes a tread, an inner liner, and a plurality of spokes extending between and coupling the tread to the inner liner. The plurality of spokes have a first width and the inner liner has a second width greater than the first width such that a pair of inner liner flanges extend beyond the plurality of spokes in an axial direction. The wheel includes a rim and the inner liner is configured to be mounted on the rim with the pair of inner liner flanges fastened to the rim such that the non-pneumatic tire is serviceably mounted on the wheel.

A tire and wheel assembly includes a non-pneumatic tire and a wheel. The non-pneumatic tire incudes a tread, an inner liner, and a plurality of spokes extending between and coupling the tread to the inner liner. The plurality of spokes have a first width and the inner liner has a second width greater than the first width such that a pair of inner liner flanges extend beyond the plurality of spokes in an axial direction. The wheel includes a rim and the inner liner is configured to be mounted on the rim with the pair of inner liner flanges fastened to the rim such that the non-pneumatic tire is serviceably mounted on the wheel.

According to the present invention, when a first point (P1) is set on an end edge on an outer end portion (15a) side of a coupling member (15) and a fifth point (P5) is set on an end edge on an inner end portion (15b) side of the coupling member (15), and when a distance (H1) from the fifth point (P5) to the second point (P2) along a reference straight line (RL) passing through the first point (P1) and a tire axis is set to 0.80 times a reference distance (H) from the fifth point (P5) to the first point (P1) along the reference straight line, a distance (H2) from the fifth point (P5) to the third point along the reference straight line is set to 0.65 times the reference distance (H), and a distance (H3) from the fifth point (P5) to the fourth point (P4) along the reference straight line is set to 0.30 times the reference distance (H), the third point (P3) is disposed on the other side in the tire circumferential direction of an overall inclined straight line (SL) passing through the first point (P1) and the fifth point (P5), and a horizontal distance (D2) between the second point (P2) and the third point (P3) in a perpendicular direction (D) perpendicular to the reference straight line (RL) is larger than each of a horizontal distance D1 between the first point (P1) and the second point (P2) in the perpendicular direction (D) and a horizontal distance (D4) between the fourth point (P4) and the fifth point (P5) in the perpendicular direction (D).

According to the present invention, when a first point (P1) is set on an end edge on an outer end portion (15a) side of a coupling member (15) and a fifth point (P5) is set on an end edge on an inner end portion (15b) side of the coupling member (15), and when a distance (H1) from the fifth point (P5) to the second point (P2) along a reference straight line (RL) passing through the first point (P1) and a tire axis is set to 0.80 times a reference distance (H) from the fifth point (P5) to the first point (P1) along the reference straight line, a distance (H2) from the fifth point (P5) to the third point along the reference straight line is set to 0.65 times the reference distance (H), and a distance (H3) from the fifth point (P5) to the fourth point (P4) along the reference straight line is set to 0.30 times the reference distance (H), the third point (P3) is disposed on the other side in the tire circumferential direction of an overall inclined straight line (SL) passing through the first point (P1) and the fifth point (P5), and a horizontal distance (D2) between the second point (P2) and the third point (P3) in a perpendicular direction (D) perpendicular to the reference straight line (RL) is larger than each of a horizontal distance D1 between the first point (P1) and the second point (P2) in the perpendicular direction (D) and a horizontal distance (D4) between the fourth point (P4) and the fifth point (P5) in the perpendicular direction (D).

Embodiments of collapsible wheels and methods of making collapsible wheels are generally described herein. Other embodiments may be described and claimed.

Embodiments of collapsible wheels and methods of making collapsible wheels are generally described herein. Other embodiments may be described and claimed.