Systems and methods are presented herein for a vehicle frame comprising a first rail member and a second rail member. Each of the first rail member and the second rail member comprise a front rail portion, wherein the front rail portion is configured to provide resistance to deformation to protect a battery pack assembly positioned between the first rail member and the second rail member. Additionally, each of the first rail member and the second rail member comprise a rail portion, wherein the rail portion is structured to mechanically deform when subjected to a threshold impact force.

A vehicle body structure and a vehicle are provided. The vehicle body structure includes a front longitudinal beam, a front compartment crossbeam, and a floor front crossbeam. The front longitudinal beam includes a left front longitudinal beam and a right front longitudinal beam that are disposed at an interval in a transverse direction. The front longitudinal beam is provided with a body section and a downward bent section connected to a rear end of the body section. The front compartment crossbeam is connected to the downward bent section of the left front longitudinal beam and the right front longitudinal beam, and is at least partially located below the body section. The floor front crossbeam is located behind the front compartment crossbeam at an interval, and is connected to the front longitudinal beam.

A frame system for a vehicle including a high-voltage component that includes a pair of spaced apart primary rails that extend from a front of the vehicle toward a rear of the vehicle and a pair of longitudinally extending sills. An impact support rail extends outward from each of the primary rails, and connects each respective primary rail to one of the sills. A cross-member extends outward from each of the primary rails, and connects each respective primary rail to one of the sills, and a laterally extending frame support member extends between the sills at a location between the impact support rails and the cross-members. A pocket is collectively formed between each primary rail, the respective impact support rail, the respective sill, the respective cross-member, and the laterally extending frame support member, and the pocket is configured for receipt and protection of the high-voltage component.

A frame system for a vehicle including a high-voltage component that includes a pair of spaced apart primary rails that extend from a front of the vehicle toward a rear of the vehicle and a pair of longitudinally extending sills. An impact support rail extends outward from each of the primary rails, and connects each respective primary rail to one of the sills. A cross-member extends outward from each of the primary rails, and connects each respective primary rail to one of the sills, and a laterally extending frame support member extends between the sills at a location between the impact support rails and the cross-members. A pocket is collectively formed between each primary rail, the respective impact support rail, the respective sill, the respective cross-member, and the laterally extending frame support member, and the pocket is configured for receipt and protection of the high-voltage component.

A frame assembly for a motor vehicle that may include a first load beam, a second load beam, and a frame rail that are configured for receipt and transfer of energy to a sill that can move the sill in a downward direction. A counterbalancing load beam that includes a first fixed end is attached to the first load beam and a second fixed end is attached to the frame rail. The counterbalancing load beam is configured for receipt of at least a portion of the energy applied to the first load beam, and the counterbalancing load beam is configured to transfer the energy received from the first load beam to the frame rail such that the transfer of energy to the sill that can move the sill in the downward direction is counterbalanced by the energy transferred by the counterbalancing load beam to the frame rail.

A military vehicle includes a chassis, an axle, a suspension system, and a driveline. The chassis includes a passenger capsule, a front module coupled to a front end of the passenger capsule, and a rear module coupled to a rear end of the passenger capsule. The axle is supported by the rear module. The suspension system is positioned between the rear module and the axle. The suspension system includes a first gas spring, a second gas spring, a first damper, and a second damper. The first damper and the second damper are cross-plumbed to provide a fluid body roll control function. The driveline is configured to drive the axle. The driveline includes a component having a housing that functions as a structural component of the rear module. The first gas spring, the second gas spring, the first damper, and the second damper are directly coupled to the housing.

A structural reinforcement utilized to reinforce a structural joint of a vehicle, and method of enforcing a structural joint of a vehicle. The structural reinforcement having a clamshell structure comprising two complimentary halves. The structural reinforcement further comprising an activatable composition.

A shock absorbing member which can increase impact absorption energy and also enables thinning of a steel sheet that is a starting material, a method for producing the shock absorbing member, and a method for producing a steel sheet for cold plastic working are provided. The shock absorbing member includes a ridge portion formed in a curved shape as viewed from a longitudinal direction, and a wall portion extending from the ridge portion. In the wall portion, a ratio σ.sub.5/τ.sub.5 between a tensile stress σ.sub.5 when an elongation in a tensile test is 5% and a shear stress τ.sub.5 when a shear strain in a shear test is 5√3% is 1.70 or less, or a ratio σ.sub.10/τ.sub.10 between a tensile stress σ.sub.10 when an elongation in a tensile test is 10% and a shear stress τ.sub.10 when a shear strain in a shear test is 10√3% is 1.70 or less.

A shock absorbing member which can increase impact absorption energy and also enables thinning of a steel sheet that is a starting material, a method for producing the shock absorbing member, and a method for producing a steel sheet for cold plastic working are provided. The shock absorbing member includes a ridge portion formed in a curved shape as viewed from a longitudinal direction, and a wall portion extending from the ridge portion. In the wall portion, a ratio σ.sub.5/τ.sub.5 between a tensile stress σ.sub.5 when an elongation in a tensile test is 5% and a shear stress τ.sub.5 when a shear strain in a shear test is 5√3% is 1.70 or less, or a ratio σ.sub.10/τ.sub.10 between a tensile stress σ.sub.10 when an elongation in a tensile test is 10% and a shear stress τ.sub.10 when a shear strain in a shear test is 10√3% is 1.70 or less.

A vehicle body lower structure may comprise: a rocker arranged at a lower lateral part of a vehicle body; a power supply package arranged under a floor panel of the vehicle; a first energy absorbing member fixed to a lateral side of the power supply package; and a second energy absorbing member being adjacent to the first energy absorbing member in a vehicle-width direction of the vehicle body, the second energy absorbing member being located outside the first energy absorbing member in the vehicle-width direction of the vehicle body. The first energy absorbing member may include a first protrusion protruding outward in the vehicle-width direction, the second energy absorbing member may include a second protrusion protruding inward in the vehicle-width direction, and the first protrusion and the second protrusion may overlap each other as seen along an up-down direction and are fixed together to the rocker by a bolt.