A front vehicle body reinforcing structure may include a dash panel, a front side member extending along a length direction of a vehicle for coupling to a lower part of the dash panel, a fender apron member extending along the length direction of the vehicle and coupled to an upper part of the dash panel, a front shock absorber housing having a lower part coupled to the front side member and an upper part coupled to the fender apron member, a cowl cross member extending along a width direction of the vehicle for coupling to the upper part of the dash panel and having both ends overlapping and coupled to the front shock absorber housing along the width direction, and a front shock absorber housing side member adhered to an inner surface of the front shock absorber housing, and having an upper part coupled to the cowl cross member.

An electric vehicle frame strut tower to body structure interface bracket is disclosed. An example electric vehicle disclosed herein includes a frame, a battery pack supported by the frame, a body coupled to the frame, a strut tower coupled to the frame to support the body and absorb road surface impacts on the electric vehicle, and a strut tower interface bracket to couple the strut tower to the body.

A front vehicle-body structure for reducing second-order vibration of a windshield, and improving NVH performance in a vehicle cabin. A tower bar coupling each of left and right front suspension housings with a region around a vehicle-width-direction center portion of a cowl forming a lower edge of an opening for a front windshield has a center portion extending in a vehicle width direction along the cowl. A bracket extending from the cowl toward a front of a vehicle is provided in a region including a vehicle-width-direction center portion of the front windshield in the lower edge of the opening. The center portion of the tower bar is fixed to the bracket from above, and a reinforcement member supporting the fixing region from below is provided.

A lower body for a vehicle includes front and rear main bodies each including pipes, a pair of first longitudinal members extending in a forward/rearward direction and spaced apart from each other in a transverse direction, a first transverse member extending in the transverse direction and connecting the first longitudinal members, and mounting parts each having an outer side to which the first longitudinal members and the first transverse member are coupled, and a pair of lower body main members connecting the outer sides of the mounting parts and two opposite sides of upper ends of the front and rear main bodies spaced apart from each other, the pair of lower body main members each having a pipe shape and extending forward and rearward to constitute upper side members of the front and rear main bodies and defining an overall length of the vehicle.

A vehicle body includes a plurality of shock absorber housings each covering and supporting a respective shock absorber that is configured to be connected to a respective wheel of a vehicle, a pillar member having a first end connected to one of the shock absorber housings to form a corner, wherein the pillar member connects two of the plurality of shock absorber housings to form a portion of a cabin of the vehicle, wherein the two of the plurality of shock absorber housings are disposed at a side of the vehicle at a front portion and a rear portion of the vehicle, and a supporting member disposed at the corner of the shock absorber housing, an upper end of the supporting member being coupled to the pillar member and a lower end of the supporting member being coupled to the shock absorber housing.

A structural load path assembly includes an upper rail configured to be coupled to a suspension system, a lower rail spaced apart from the upper rail along a vertical direction, a first outer bracket interconnecting the upper rail and the lower rail, a second outer bracket interconnecting the upper rail and the lower rail, a first inner bracket interconnecting the upper rail and the lower rail, wherein the first inner bracket is spaced apart from the first outer bracket along a horizontal direction, and the horizontal direction is perpendicular to the vertical direction, a second inner bracket interconnecting the upper rail and the lower, and a box section sized to receive a shock absorber.

An object of the present invention is to provide a battery protection member capable of achieving both securement of a capability to allow a passenger to reside in a vehicle and protection of a battery at the same time. According to one aspect of the present invention, a battery protection member includes a hollow-shaped battery containing frame extending in a vehicle lateral direction of the vehicle. The battery containing frame includes a surface where a seat occupied by a driver is disposed on an outer surface side thereof. The battery containing frame is configured to contain the battery on an inner surface side thereof.

A front vehicle body structure includes a fender apron upper member, a shock absorber housing disposed under the fender apron upper member, and a front side member disposed under the shock absorber housing, and the fender apron upper member, the shock absorber housing and the front side member are integrally formed.

A hybrid structural assembly for a motor vehicle includes a casting and a structural inlay. The casting includes a plurality of structural components joined together in a casting process to form structural load paths and extending in a plurality of directions in a 3D space. The casting includes a cast-allowable alloy material. The structural inlay is secured to at least one of the structural components. The structural inlay includes a material having at least one of a higher ductility and a higher toughness than the cast-allowable alloy material.

A straddle-type vehicle includes a vehicle body frame; a power unit supported by the vehicle body frame; a seat mounted at a position higher than the power unit; a handle bar mounted at a position more forward than the seat; a pair of front wheels spaced apart from each other in a vehicle width direction; a pair of suspensions spaced apart from each other in the vehicle width direction and connecting the pair of front wheels to the vehicle frame; and a vehicle body vibration control damper including end portions connected to a first attachment portion and a second attachment portion, respectively, mounted on the vehicle body frame so as to be spaced apart from each other in a vehicle front-back direction, and mounted so as to extend in the vehicle front-back direction with at least a portion thereof located between the pair of suspensions.