A structural component for a motor vehicle is configured to extend transversely to a direction of travel for the motor vehicle and is configured to separate a passenger compartment and a front compartment of the motor vehicle. The structural component includes: a dashboard; two A-pillars arranged in each case laterally with respect to the dashboard; and a transverse reinforcement running along an upper side of the dashboard. The structural component is one-part or a one-piece light-metal die casting.

For improving the driving dynamics of a motor vehicle with two rear longitudinal members which are spaced apart from one another and which each have a rear axle bushing for receiving a rear axle and are connected to one another by a cross-member which is at the rear in the main travel direction of the motor vehicle, the rear cross-member has in the plane of its extent an offset in the direction of the rear of the vehicle. When considered in the vertical direction of the motor vehicle, an upper cross-member is located above the rear cross-member, wherein the upper cross-member is attached to the rear longitudinal members in the region of the respective rear axle bushings.

For improving the driving dynamics of a motor vehicle with two rear longitudinal members which are spaced apart from one another and which each have a rear axle bushing for receiving a rear axle and are connected to one another by a cross-member which is at the rear in the main travel direction of the motor vehicle, the rear cross-member has in the plane of its extent an offset in the direction of the rear of the vehicle. When considered in the vertical direction of the motor vehicle, an upper cross-member is located above the rear cross-member, wherein the upper cross-member is attached to the rear longitudinal members in the region of the respective rear axle bushings.

This disclosure is directed to supercapacitor systems for supporting relatively high power transient electrical loads within vehicles. An exemplary supercapacitor system includes a mounting assembly and a supercapacitor housed within the mounting assembly. The mounting assembly may be employed to mount the supercapacitor system within a vehicle, such as within a cowl assembly or cargo space of the vehicle. The mounting assembly may include multiple panels. At least one of the multiple panels may be made of a thermally conductive polymer, and at least one other panel of the multiple panels may be made of a polymer that is reinforced by a structural foam.

A subframe structure includes a pair of left and right front-rear frames each mounted with a lower arm; and a transverse member connecting front portions of the front-rear frames. The front-rear frames each includes a rear horizontal portion formed substantially horizontally, an inclined portion extending frontward and upward from a front end of the rear horizontal portion, and a front horizontal portion extending horizontally frontward from a front end of the inclined portion. The transverse member is jointed at left and right ends thereof to the front horizontal portions respectively corresponding to the left and right ends, a rear end of the front horizontal portion is disposed to be positioned frontward of a front end of an engine, and the front-rear frames are deformed into a Z shape in vehicle side view in an event of a front-end collision and thereby energy of the front-end collision is absorbed.

A front end module assembly has a front end module structure of a vehicle, a heat exchanger support and a first heat exchanger unit. The heat exchanger support is supported to the vehicle front end module structure. The heat exchanger support has an opening. The first heat exchanger unit is accommodated in the opening of the heat exchanger support so that the transmission cooler is supported to the vehicle front end module structure via the heat exchanger support.

A front vehicle-body structure controls inward breakage of an apron reinforcement in the event of a small overlap collision, without increasing weight. Embodiments include a pair of right and left apron reinforcements extending in a vehicle front-rear direction; and a pair of right and left hinge pillars respectively connected to rear ends of the pair of apron reinforcements. A reinforcement outer member of the apron reinforcement includes a linear portion extending in the vehicle front-rear direction from a rear end of the apron reinforcement connected to the hinge pillar to an intermediate portion of the apron reinforcement. A horizontal bead, provided as a deformation facilitating portion to facilitate deformation toward an inside of a vehicle body, is disposed on an outer surface portion positioned on a vehicle-width-direction outer side of the linear portion, the horizontal bead having a reduced longitudinal rigidity toward a front side in the vehicle front-rear direction.

A front vehicle-body structure controls inward breakage of an apron reinforcement in the event of a small overlap collision, without increasing weight. Embodiments include a pair of right and left apron reinforcements extending in a vehicle front-rear direction; and a pair of right and left hinge pillars respectively connected to rear ends of the pair of apron reinforcements. A reinforcement outer member of the apron reinforcement includes a linear portion extending in the vehicle front-rear direction from a rear end of the apron reinforcement connected to the hinge pillar to an intermediate portion of the apron reinforcement. A horizontal bead, provided as a deformation facilitating portion to facilitate deformation toward an inside of a vehicle body, is disposed on an outer surface portion positioned on a vehicle-width-direction outer side of the linear portion, the horizontal bead having a reduced longitudinal rigidity toward a front side in the vehicle front-rear direction.

A support structure is provided for a vehicle component disposed inside a power-unit chamber where a powertrain unit of the vehicle is disposed. The support structure includes the power-unit chamber including a side frame extending in a vehicle front-and-rear direction, and a suspension tower housing formed overlapping with a part of the side frame in a plan view seen from above the vehicle. The vehicle component is disposed at a location where the vehicle component overlaps with the side frame in the plan view and forward of the suspension tower housing in the vehicle front-and-rear direction. The vehicle component is supported by one of the side frame, and a support member coupled to an inward side surface of a closed-cross-section member connected to the side frame at a location forward of the suspension tower housing in the vehicle front-and-rear direction.

A component tray assembly for a vehicle. For example, the component tray assembly may be installed between a body of the vehicle and a seat bulkhead of the vehicle. The component tray assembly may include at least a component shelf, a cover disposed over the component shelf, and one or more components. In some examples, the component shelf includes three openings and the one or more components include three speakers respectively disposed within the openings. The component shelf may further include notches located proximate to the side of the component shelf where the component shelf attaches to the seat bulkhead. The positions and shapes of the openings and the notches may create a weakened region of the component shelf that is configured to deform the component tray assembly during a collision. By deforming, the component tray assembly is configured to minimize the amount of force that is imparted to the seat.