A vehicle body structure includes a front side member, a body attachment structure and an off-center impact structure. The body attachment structure is attached to an outboard wall of the front side member along a front-section forward of an outboard opening and extends in an outboard direction from the front side member. The off-center impact structure has an elongated member with a straight portion that extends through the outboard opening and into a hollow interior of the front side member. The elongated member is fixedly coupled to the outboard wall of the front side member adjacent to, spaced apart from and rearward of the body attachment structure. In response to an impact event of an off-center impact test the body attachment structure deforms and moves into contact with the elongated member transferring impact force to the elongated member.

A vehicle frame assembly includes a main frame part including a side sill extending in a longitudinal direction of the vehicle frame assembly. The side sill has a C-shaped cross-section with a top and bottom walls, an inboard sidewall interconnecting the top and bottom walls, and an open outboard sidewall. A rear frame part is secured to the main frame part and includes a rear frame member extending in the longitudinal direction. The rear frame member has a U-shaped cross-section with an inboard and outboard sidewalls, a bottom wall interconnecting the inboard and outboard sidewalls, and an open top wall. The inboard sidewall at a rearward end portion of the side sill includes a section bulging away from the open outboard sidewall in a lateral direction of the vehicle frame assembly, and the inboard sidewall of the rear frame member is secured to the bulging section of the side sill.

A vehicle structure includes a vehicle frame and a push arm. The vehicle frame includes surfaces that define an intersection of a first side member and a first cross-member. The surfaces extend from the first side member to the first cross-member with an upper surface of a mid-section of the first cross-member being vertically spaced apart from an upper surface of the first side member. The push arm is coupled to the vehicle frame proximate the intersection. A rear surface of the push arm faces and is adjacent to a front area of the intersection. A main body of the push arm extends forward and laterally outboard from the rear surface such that the front surface is located laterally outboard of the first side member.

A vehicle structure includes a vehicle frame and a push arm. The vehicle frame includes surfaces that define an intersection of a first side member and a first cross-member. The surfaces extend from the first side member to the first cross-member with an upper surface of a mid-section of the first cross-member being vertically spaced apart from an upper surface of the first side member. The push arm is coupled to the vehicle frame proximate the intersection. A rear surface of the push arm faces and is adjacent to a front area of the intersection. A main body of the push arm extends forward and laterally outboard from the rear surface such that the front surface is located laterally outboard of the first side member.

A front suspension structure has a front portion on a first side member of a vehicle frame and a rear portion on the first side member rearward of the front portion. A front wheel is supported by a wheel support structure that is pivotally mounted to a front suspension structure of the first side member. A stop structure is installed to the first side member at the rear portion of the front suspension structure. The stop structure extends in an outboard direction of the first side member. The stop structure has a stop surface that defines an angle relative to the vehicle longitudinal direction between 110 and 130 degrees. In response to an impact event to a front area of the front wheel, the front wheel pivots relative to the wheel support structure moving a rear area of the front wheel into contact with the stop surface.

A front suspension structure has a front portion on a first side member of a vehicle frame and a rear portion on the first side member rearward of the front portion. A front wheel is supported by a wheel support structure that is pivotally mounted to a front suspension structure of the first side member. A stop structure is installed to the first side member at the rear portion of the front suspension structure. The stop structure extends in an outboard direction of the first side member. The stop structure has a stop surface that defines an angle relative to the vehicle longitudinal direction between 110 and 130 degrees. In response to an impact event to a front area of the front wheel, the front wheel pivots relative to the wheel support structure moving a rear area of the front wheel into contact with the stop surface.

A first structure extends to a forward side of a cross-member of a vehicle frame with a first gap being defined between the first structure and the cross-member. A second structure extends rearward from the cross-member with a second gap defined between the second structure and the cross-member. An attachment bracket fixed to the cross-member retains one of the first and second structures. The attachment bracket is configured to maintain one of the first gap and the second gap in a non-impacted state. In response to an impact event where a stationary barrier impacts forward of the first structure, impacting forces cause movement of the one of the first structure and the second structure relative to the attachment bracket thereby bringing at least the one of the first structure and the second structure into contact with the cross-member closing the corresponding one of the first gap and the second gap.

A vehicle body structure a front side member, a body attachment structure fixed to the front side member and an off-center impact structure. The off-center impact structure has a linearly shaped first elongated member defining a first end portion, a mid-section portion and a second end portion. The first end portion extends through a first outboard opening into a hollow interior of the front side member and is rigidly connected to the front side member forward of the body attachment structure. The mid-section portion is connected to an outboard wall of the front side member. The second end portion extends in an outboard direction away from the outboard wall such that in response to an impact event during an off-center impact test the mid-section of the first elongated member deforms with the second end portion moving rearward into contact with the body attachment structure.

A push arm is coupled to a vehicle frame proximate an intersection of a first side member and a first cross-member. A rear surface of the push arm is located adjacent to a front suspension structure with a gap defined therebetween. The push arm extends forward and laterally outward such that a front surface of the push arm is located outboard of and spaced apart from a front end of the first side member. An energy absorbing structure is positioned within the gap and is attached to the rear surface of the push arm. The energy absorbing structure is spaced apart from the front suspension structure in a non-impacted state. The energy absorbing structure is configured such that in response to an off-center impact event, impact force to the energy absorbing structure pushes the energy absorbing structure into contact with the front suspension structure, such that the energy absorbing structure deforms and absorbs impact energy.

A push arm is coupled to a vehicle frame proximate an intersection of a first side member and a first cross-member. A rear surface of the push arm is located adjacent to a front suspension structure with a gap defined therebetween. The push arm extends forward and laterally outward such that a front surface of the push arm is located outboard of and spaced apart from a front end of the first side member. An energy absorbing structure is positioned within the gap and is attached to the rear surface of the push arm. The energy absorbing structure is spaced apart from the front suspension structure in a non-impacted state. The energy absorbing structure is configured such that in response to an off-center impact event, impact force to the energy absorbing structure pushes the energy absorbing structure into contact with the front suspension structure, such that the energy absorbing structure deforms and absorbs impact energy.