A wheel casing including a body portion configured to be positioned along an inboard sidewall of a tire having an axis of rotation and at least a front strake positionable over tread of the tire. The front strake having a first edge adjacent the body portion and extending outwardly to a second edge of the front strake that terminates at or inboard of an outboard side of the tire, the front strake defining a lower edge and an upper edge, the lower edge and the upper edge both configured to be positioned forward of the axis of rotation, and tread of the tire positioned rearward of the upper edge is uncovered by the wheel casing.

A work vehicle includes an driver's seat disposed in the rear region of a vehicle body, a left and a right fender that are disposed on the left and right laterally outward sides of the driver's seat, and a partition wall that divides, at a position behind the driver's seat, the vehicle body into a front region of the vehicle body on the front side of the partition wall and a rear region of the vehicle body on the back side thereof. Operation tools for operating working equipment provided on the vehicle body are disposed on one of the fenders, and the partition wall is provided offset toward a side where operation tools are disposed relative to the driver's seat.

A wheel casing for a vehicle having a wheel assembly including a wheel and a tire. The wheel casing includes a body portion positionable adjacent an inboard surface of the tire, and a brake cooling duct defining an air inlet opening and an air outlet opening. The air outlet opening is in fluid communication with a brake system component and the air inlet opening is positionable inboard of the body portion when the body portion is positioned adjacent the inboard surface of the tire, thereby providing cooling air flow through the brake cooling duct to the brake system component when the vehicle is in forward motion. The wheel casing further includes a suspension arm undercover extending inboard of the body portion and configured to protect predetermined components of the vehicle.

An aerodynamic mud flap includes a body having a first lateral side, an opposite second lateral side, an upper end, an opposite lower end, a front face, and an opposite rear face. The body extends in a horizontal, vertical, and transverse directions. The body has a generally planar upper portion extending vertically from the upper end to a horizontal transition line, and an arcuate lower portion extending vertically from the transition line to the lower end. The lower portion is curved along the vertical direction such that the lower end of the body is offset from the upper end in the transverse direction and is disposed rearward of the upper end. A plurality of octagonal openings in the body extend from the front face to the rear face to allow for air flow through the mud flap from the front side to the rear side.

An embodiment structure for reinforcing rigidity of a quarter member includes a rear shock absorber member configured to position a rear shock absorber, a quarter vertical member extending from an upper end portion of the rear shock absorber member to an upper portion of a quarter glass pane, and a rear pillar member extending from the upper portion of the quarter glass pane up to a rear glass pane and overlapping a portion of the quarter vertical member.

A wheel arch for housing at least one wheel of a vehicle and for attachment to a chassis of a vehicle is described. The wheel arch comprises a load bearing mounting point, wherein the wheel arch is configured to receive, in use, forces at the load bearing mounting point from a vehicle component mounted at the load bearing mounting point. A vehicle and a method of assembling a vehicle comprising the wheel arch is also described.

A vehicle body structure for suspension mounting includes a cross-sectional structure and a connecting structure of a vehicle body on which a rear suspension is mounted that exhibits vehicle body strength with a reduced number of components. A mounting panel is provided on a wheel housing panel and has a plurality of mounting holes through which a top portion of a suspension extends so as to be mounted on the mounting panel. A reinforcing unit is provided in the mounting panel and has a shape of a ring surrounding the mounting holes.

A tire skirt support assembly for a compactor comprising a bracket and one or more skirt support members. The bracket can be oriented horizontally, and each skirt support member can have a body that is elongate with a first end and a second end opposite the first end. For each said skirt support member, the first end can be fixed to the bracket, and the second end can be below the bracket and is a free end configured to removably engage a skirt via an attachment opening in the skirt.

An apparatus and method, according to an exemplary aspect of the present disclosure includes, among other things, a quarter panel comprised of a sheet molding compound and a fascia bracket. The fascia bracket includes a first flange integrated into the quarter panel, a second flange comprising a vehicle body mount interface, and a gripping feature configured to grip a portion of a fascia to be attached to the quarter panel.

Apparatus and associated methods relate to a tire containment device securely mounted to an axle of a vehicle to contain shrapnel caused by a tire blowout. In an illustrative example, the tire containment device may include an axle bracket and a tire fender. The axle bracket, for example, may be mounted to an axle of the vehicle. The tire fender may, for example, have a substantially continuous containment cavity. In some examples, when the tire fender is coupled to a vehicle axle by the axle bracket, the containment cavity may extend over at least a top and an exterior face of an upper third of a diameter of a tire. For example, the containment cavity may substantially intercept shrapnel from failure of the tire before it reaches a body of the vehicle. Various embodiments may advantageously reduce damage to a body of the vehicle during a tire blowout.