In certain embodiments, an electric vehicle includes a front cage, a rear floor, an intermediate section, a utility cabinet, and a flatbed. In other embodiments, an electric vehicle includes a front cage, a rear floor, an intermediate section, and a flatbed. In some embodiments, the front cage at least partially defines an operator cabin, the rear floor is positioned rearward of the front cage in a longitudinal direction, and the intermediate section is disposed at least partially between the front cage and the rear floor in the longitudinal direction.

Aspects are provided for retaining components of an assembly to a support, including additively manufactured (AM) parts of a vehicle chassis to an assembly table. A cartridge for securing the component to the assembly table is provided which includes a housing including at least one compartment, an adhesive disposed within the at least one compartment, a fastener removably attached to the assembly table, and a membrane lid enclosing an opening of the housing. The membrane lid is configured to receive a protruding member from the component such that the protruding member becomes adhered to the adhesive upon penetrating the membrane lid. The cartridge thus allows the component to be quickly retained in any selected position while constraining movement of the component along six degrees of freedom, thereby allowing AM and non-AM parts to be securely retained to accommodate strict tolerance and precise fit between the components of the assembly.

A recreational vehicle body includes a base and a chassis integrally molded with the base, the chassis including a plurality of ribs that extend downward from the base. The recreational vehicle body includes one or more layers that are molded to integrally form the base and chassis.

A lower cross member for a vehicle is disposed on a floor of a vehicle. The lower cross member includes a core member and a reinforcing layer. The core member is made of a composite material containing 70 wt. % or more of unidirectional carbon fibers, and the reinforcing layer is made of a composite material containing 70 wt. % or more of fiberglass.

The present disclosure relates to custom additively manufactured core structures and the manufacture thereof. In one aspect, a panel for use in a transport structure includes first and second face sheets, and an additively manufactured (AM) core affixed between the first and second face sheets. The AM core is foldable such that at least one portion of the AM core is movable between a folded position and an unfolded position. In another aspect of the disclosure, a method for producing a panel for use in a transport structure includes additively manufacturing a core is disclosed.

Land vehicles, powertrain units for land vehicles, and methods of using land vehicles are disclosed herein. In certain embodiments, the land vehicles are provided as delivery vehicles and/or utility vehicles. A land vehicle includes a frame structure having a front cage that defines an operator cabin and a rear floor positioned rearward of the front cage. The frame structure supports a plurality of wheels to permit movement of the vehicle relative to an underlying surface in use of the land vehicle. An underside of the frame structure is disposed in confronting relation with the underlying surface.

Electric vehicles are disclosed herein. In certain embodiments, an electric vehicle includes a front cage, a rear floor, an intermediate section, a utility cabinet, and a flatbed. In other embodiments, an electric vehicle includes a front cage, a rear floor, an intermediate section, and a flatbed. In some embodiments, the front cage at least partially defines an operator cabin, the rear floor is positioned rearward of the front cage in a longitudinal direction, and the intermediate section is disposed at least partially between the front cage and the rear floor in the longitudinal direction.

In certain embodiments, an electric vehicle includes a front cage, a rear floor, an intermediate section, a utility cabinet, and a flatbed. In other embodiments, an electric vehicle includes a front cage, a rear floor, an intermediate section, and a flatbed. In some embodiments, the front cage at least partially defines an operator cabin, the rear floor is positioned rearward of the front cage in a longitudinal direction, and the intermediate section is disposed at least partially between the front cage and the rear floor in the longitudinal direction.

A method of manufacturing a unitary energy absorbing structure for a vehicle includes providing a first mold having a cavity receiving a first mandrel and a second mold having a cavity receiving a second mandrel. At least one mandrel segment is positioned in the first mold cavity and cooperates with the first mandrel. One or more layers of composite material at least partially cover the first mold cavity, first mandrel, at least one mandrel segment and second mold. The unitary structure is formed from the first layer, the second layer and the third layer of composite material with the first mandrel, the at least one mandrel segment and the second mandrel in the first mold and the second mold.

A vehicle frame structure includes a pair of side members located on both right and left sides of a vehicle, each of the pair of side members extending both forward and rearward of a cabin along a respective side of the cabin. As each of the pair of side members extends in a longitudinal direction at a substantially uniform height, a load applied to one end can be transferred toward the other end.