A vehicle front structure includes a dash upper panel and a grille top face portion having outside air introduction holes taking in outside air. The vehicle front structure includes a cover member covering an engine from a vehicle upper side and having a top plate rear portion opposed to the grille top face portion on a vehicle lower side throughout a predetermined range, including the outside air introduction holes, in a vehicle width direction, and a grille front face portion disposed from the grille top face portion to the top plate rear portion on a vehicle front side of the outside air introduction holes. The top plate rear portion has a shape having inclined surfaces extending from a vehicle lower side of the outside air introduction holes in the vehicle width direction, the inclined surfaces being gradually inclined to the vehicle lower side toward vehicle-width-direction outer sides.

A vehicle front structure includes a dash upper panel and a grille top face portion having outside air introduction holes taking in outside air. The vehicle front structure includes a cover member covering an engine from a vehicle upper side and having a top plate rear portion opposed to the grille top face portion on a vehicle lower side throughout a predetermined range, including the outside air introduction holes, in a vehicle width direction, and a grille front face portion disposed from the grille top face portion to the top plate rear portion on a vehicle front side of the outside air introduction holes. The top plate rear portion has a shape having inclined surfaces extending from a vehicle lower side of the outside air introduction holes in the vehicle width direction, the inclined surfaces being gradually inclined to the vehicle lower side toward vehicle-width-direction outer sides.

A vehicle component includes a polymeric material, a first filler, and a second filler. The polymeric material can be present at a concentration of at least about 35% by weight of the vehicle component. The first filler can be a carbon-containing filler dispersed within the polymeric material. The carbon-containing filler can be present at a concentration of at least about 20% by weight of the vehicle component. The second filler includes a substrate and carbon nanotubes. The carbon nanotubes extend from a surface of the substrate.

A vehicle body structure includes: a front pillar; a front side member located in front of the front pillar and extending in a longitudinal direction of the vehicle; a side sill connected to a bottom end of the front pillar; and a rear lower member connecting the front side member, the side sill, and the front pillar, where the rear lower member includes a front connection portion connected to a rear portion of the front side member, and a rear connection portion connected to a lower portion of the front pillar and a front portion of the side sill, and the rear connection portion includes an upper engagement wall joined to the front pillar, and a lower engagement wall joined to the side sill.

A vehicle includes a dash cross member extending along a vehicle width direction, a front side member arranged in front of the dash cross member and joined to the dash cross member, a floor member arranged behind the dash cross member, and a brace joined to the dash cross member and joined to the floor member. A joint between the brace and the dash cross member overlaps a joint between the front side member and the dash cross member in the vehicle width direction. The brace includes an extending portion. The extending portion is joined to the floor member.

A vehicle includes a dash cross member extending along a vehicle width direction, a front side member arranged in front of the dash cross member and joined to the dash cross member, a floor member arranged behind the dash cross member, and a brace joined to the dash cross member and joined to the floor member. A joint between the brace and the dash cross member overlaps a joint between the front side member and the dash cross member in the vehicle width direction. The brace includes an extending portion. The extending portion is joined to the floor member.

A steering apparatus for a vehicle that utilizes steer-by-wire controls and may selectively be operated in an autonomous mode comprises a body mounted sliding steering column. The body mounted sliding steering column includes an arm that slides between a stowed position and a use position on at least one rail attached to a frame of the vehicle. The arm supports a steering column that may also be adjustable between a retracted position and an extended position. The arm also houses a force feedback motor in force-transmitting communication with the steering column.

A steering apparatus for a vehicle that utilizes steer-by-wire controls and may selectively be operated in an autonomous mode comprises a body mounted sliding steering column. The body mounted sliding steering column includes an arm that slides between a stowed position and a use position on at least one rail attached to a frame of the vehicle. The arm supports a steering column that may also be adjustable between a retracted position and an extended position. The arm also houses a force feedback motor in force-transmitting communication with the steering column.

A vehicle body may include a dash crossmember, a rocker extending rearwards from an end of the dash crossmember, a front pillar extends upwards from the rocker along the side portion of the cabin and a reinforcement plate including a first end joined to the dash crossmember and a second end joined to the front pillar. An inner wall of the dash crossmember may have an uneven shape that defines at least one bend extending in the right-left direction. The first end of the reinforcement plate may at least partly have a bent shape that conforms with the uneven shape of the dash crossmember.

An assembly for a vehicle comprising a crossmember, which is provided for connecting to two pillars lying opposite each other with respect to the x-y plane of the vehicle; a mounting that is connected to the crossmember, protrudes therefrom in the radial direction, and has two mounts, which are mutually spaced in the y direction, and end-face connection means; and a panel-shaped instrument which is connected to the connection means of the mounting at a distance to the upper closure thereof and which is held such that the operating surface of the instrument faces the passenger compartment of the vehicle in the x direction. The two mounts are designed as supporting frame mounts with a respective upper cord and a respective lower cord, each of which has limbs adjoining one another at an angle, one limb lying on the y-z plane and the other lying on the x-y plane, and which are inclined relative to each other so as to have a greater distance to each other at the instrument connection side than at the end facing the crossmember. At least one of the two cords has at least one predetermined bending point, which is provided by the geometry of the cord, between the two connection points of the cord, said cord bending at the predetermined bending point in the z and/or y direction in the event of a load (x direction).