A front portion of a vehicle body includes front side frames, a subframe, and a vehicle compartment front structure body. The subframe has a subframe body, a leg portion, a front fastening portion, and a rear fastening portion. The front side frame has a subframe mounting portion which is arranged on a front side of a bending starting point and to which the front fastening portion is fastened. A component mounting bracket having an inclined guide portion with a front surface inclining downward toward a vehicle rear side is coupled to a rear side of the bending starting point of the front side frame. The inclined guide portion is arranged on a track in which the leg portion detached from the front side frame is displaced rearward when an impact load is input from the front of the vehicle.

Vehicle subframes and methods of producing the same are disclosed. An example apparatus includes a subframe of a vehicle including longitudinal members, and lateral extensions extending from the longitudinal members, the lateral extensions extending outward from a longitudinal centerline of the vehicle, outer edges of the lateral extensions including contours to avoid turn radii of steerable tires of the vehicle.

An embodiment is directed to a contact plate configured to establish electrical bonds between battery cells in a battery module, including at least one primary conductive layer, and a set of bonding connectors that are configured to provide direct electrical bonds between the contact plate and terminals of a group of battery cells, the set of bonding connectors being configured to connect the group of battery cells in parallel with each other, wherein at least one bonding connector in the set of bonding connectors is configured with a higher fuse rating than each other bonding connector in the set of bonding connectors so as to contain arcs among the set of bonding connectors to the at least one bonding connector.

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.

The present disclosure provides a chassis collision structure of a new energy vehicle, comprising a front lower collision beam assembly, a front sub-frame assembly, a front battery pack bottom fender, a rear battery pack bottom fender, and a rear sub-frame assembly which are arranged sequentially along a direction from a head to a tail of a vehicle, wherein the front lower collision beam assembly is connected to a front end of the front sub-frame assembly; the front battery pack bottom fender is connected to a bottom of the front sub-frame assembly; the rear battery pack bottom fender is connected to a bottom of the rear sub-frame assembly; and connecting parts which are connected with a battery pack are arranged at one end of the front battery pack bottom fender and one end of the rear battery pack bottom fender, which are close to each other, respectively.

Systems and methods are presented herein for a subframe mount of a front subframe comprising a vehicle frame. The subframe mount comprises a main body configured to receive a securing feature of a frame body of the vehicle frame. The subframe mount also comprises an open-ended slot configured to enable translation of the securing feature independent of the subframe mount in response to an impact event.

A road vehicle with a vehicle frame and a rear axle connected to the vehicle frame is provided with an ambient air purification device with filter elements for removing dust, particulate matter, and gases from ambient air. The ambient air purification device is arranged transverse to a longitudinal vehicle axis in an exterior region of the road vehicle at a vehicle rear of the road vehicle in an underfloor region such that at least the filter elements are arranged behind the rear axle of the road vehicle in a travel direction of the road vehicle. The ambient air purification device is received in an installation space of the vehicle frame. The ambient air purification device is flowed through in longitudinal vehicle direction. A free outflow zone of the ambient air purification device is arranged, in travel direction of the road vehicle, behind the ambient air purification device.

A motor vehicle has a passenger compartment and two longitudinal members provided with respective rear portions arranged longitudinally in the area of the passenger compartment and with respective struts, which project forward relative to the passenger compartment; the motor vehicle further has a powertrain, which is supported by the cross member and/or by the struts, and a cross member with front connection points connected to the longitudinal members so as to be suspended, by means of respective breakable connection members, and with rear connection points connected to the aforesaid rear portions by means of connection devices having weakened areas designed so as to break when a given load threshold is exceeded, in order to completely uncouple the cross member from the longitudinal members.

A sub-frame mounting combination structure of a vehicle body may include a fender apron side member mounted at the rear end portion of a front side member in the longitudinal direction of the vehicle body, a first side extension disposed in the transverse direction of the vehicle body and connected to the inside of the fender apron side member, a second side extension disposed in the transverse direction and connected to the outside of the fender apron side member, a tunnel member disposed in the transverse direction connecting the first side extensions at both sides at the center portion of the vehicle body to each other, and having the same phase as the first side extension, and a cap type bracket disposed to cover the fender apron side member at a portion where the fender apron side member and the first and second side extensions are connected.

A vehicle mounting structure for an electric unit 1 includes a side member 10, a suspension member 5 including a high rigidity portion 5a and a low rigidity portion 5b in a vehicle front-rear direction, and an electric unit 1 in which an inverter 2 and a motor 3 are integrated. The side member 10 includes a curved portion 10c having an upwardly convex curved shape. The curved portion 10c is disposed at a position overlapping with the inverter 2 in the vehicle front-rear direction. The electric unit 1 is fixed to the low rigidity portion 5b.