A system for managing lateral loads in a vehicle includes a crossmember and one or more structures that may be deformable. The crossmember is arranged laterally spanning a first longitudinal frame member, arranged on a first side of the vehicle, and a second longitudinal frame member of the vehicle, arranged on a second side of the vehicle. The structure is affixed to one lateral side of the vehicle, arranged longitudinally forward of the crossmember, arranged laterally outside of the first frame member, and is configured to deform during a small overlap collision. The structure, when under load, is configured to apply a lateral force on an end of the crossmember to cause lateral displacement of the vehicle. A vehicle may include a structure on each side of the vehicle to generate lateral displacement of the vehicle away from a colliding rigid barrier.

A system for managing lateral loads in a vehicle includes a crossmember and one or more structures that may be deformable. The crossmember is arranged laterally spanning a first longitudinal frame member, arranged on a first side of the vehicle, and a second longitudinal frame member of the vehicle, arranged on a second side of the vehicle. The structure is affixed to one lateral side of the vehicle, arranged longitudinally forward of the crossmember, arranged laterally outside of the first frame member, and is configured to deform during a small overlap collision. The structure, when under load, is configured to apply a lateral force on an end of the crossmember to cause lateral displacement of the vehicle. A vehicle may include a structure on each side of the vehicle to generate lateral displacement of the vehicle away from a colliding rigid barrier.

A system for managing lateral loads in a vehicle includes a crossmember and one or more structures that may be deformable. The crossmember is arranged laterally spanning a first longitudinal frame member, arranged on a first side of the vehicle, and a second longitudinal frame member of the vehicle, arranged on a second side of the vehicle. The structure is affixed to one lateral side of the vehicle, arranged longitudinally forward of the crossmember, arranged laterally outside of the first frame member, and is configured to deform during a small overlap collision. The structure, when under load, is configured to apply a lateral force on an end of the crossmember to cause lateral displacement of the vehicle. A vehicle may include a structure on each side of the vehicle to generate lateral displacement of the vehicle away from a colliding rigid barrier.

A system for managing lateral loads in a vehicle includes a crossmember and one or more structures that may be deformable. The crossmember is arranged laterally spanning a first longitudinal frame member, arranged on a first side of the vehicle, and a second longitudinal frame member of the vehicle, arranged on a second side of the vehicle. The structure is affixed to one lateral side of the vehicle, arranged longitudinally forward of the crossmember, arranged laterally outside of the first frame member, and is configured to deform during a small overlap collision. The structure, when under load, is configured to apply a lateral force on an end of the crossmember to cause lateral displacement of the vehicle. A vehicle may include a structure on each side of the vehicle to generate lateral displacement of the vehicle away from a colliding rigid barrier.

A vehicle front structure includes: a front side member disposed on a front of a vehicle; a bumper beam mounting bracket joined to a front end surface of the front side member; a subframe mounting bracket joined to a rear surface of the bumper beam mounting bracket, and having a seating surface to which a front end of a front subframe is joined; a heat exchanger support joined to the bumper beam mounting bracket; and a first reinforcing member joining the bumper beam mounting bracket and the heat exchanger support.

A vehicle front structure includes: a front side member disposed on a front of a vehicle; a bumper beam mounting bracket joined to a front end surface of the front side member; a subframe mounting bracket joined to a rear surface of the bumper beam mounting bracket, and having a seating surface to which a front end of a front subframe is joined; a heat exchanger support joined to the bumper beam mounting bracket; and a first reinforcing member joining the bumper beam mounting bracket and the heat exchanger support.

A vehicle is provided including a bumper attachment member, a radiator support beam, and a bumper support assembly coupled to the bumper attachment member and the radiator support beam. The bumper support assembly includes a center stay fixed to the radiator support beam and a center stay support having a receiver, an arm, and an anti-rotation pin. The arm extends in a vehicle-longitudinal direction from the receiver. The receiver is configured to receive and engage the bumper attachment member. The anti-rotation pin extends in the vehicle-lateral direction proximate an end of the arm opposite the receiver and engages the center stay to inhibit movement of the bumper attachment member with respect to the radiator support beam.

A vehicle is provided including a bumper attachment member, a radiator support beam, and a bumper support assembly coupled to the bumper attachment member and the radiator support beam. The bumper support assembly includes a center stay fixed to the radiator support beam and a center stay support having a receiver, an arm, and an anti-rotation pin. The arm extends in a vehicle-longitudinal direction from the receiver. The receiver is configured to receive and engage the bumper attachment member. The anti-rotation pin extends in the vehicle-lateral direction proximate an end of the arm opposite the receiver and engages the center stay to inhibit movement of the bumper attachment member with respect to the radiator support beam.

The present disclosure provides a collision energy absorbing apparatus capable of suppressing a peak load at the initial stage of a collision and a load drop immediately after it. The collision energy absorbing apparatus is an apparatus that absorbs collision energy, the apparatus being mounted on a vehicle and including a pressure member, an absorbing member, and a guide part that guides, a moving direction of the pressure member, in which a hole through which the pressure member guided and moved by the guide part enters is formed in the absorbing member, and in an event of a collision, the pressure member is guided by the guide part and a tip part of the pressure member enters the hole formed in the absorbing member while shearing an inner wall of the hole, to thereby absorb collision energy.

A method for joining members according to the present invention includes: providing a first member, a second member, a guide shaft member, a rubber member, a first plunger, a second plunger, and a drive mechanism; inserting the second member into a hole portion of the first member; inserting the guide shaft member into a through-hole of the rubber member; inserting the rubber member, into which the guide shaft member is inserted, inside the second member; arranging an assembly in which the first member, the second member, the rubber member, and the guide shaft member so as to horizontally extend; arranging the assembly so as to be sandwiched by the first plunger and the second plunger; and moving the second plunger toward the first plunger; compressing the rubber member by the first plunger and the second plunger in a direction where the guide shaft member extends, and expanding the rubber member radially outside the guide shaft member; and thus expanding and deforming at least a portion of the second member that is inserted into the hole portion to join the portion to the first member by press-fitting.