An example apparatus disclosed herein includes a first frame subassembly and a second frame subassembly, each of the first and second frame subassemblies defining a wheel axle of a vehicle, the first frame subassembly including a first bridge portion oriented generally upward relative to the wheel axle, the second frame subassembly including a second bridge portion oriented generally downward relative to the wheel axle, and a central frame couplable to the first frame subassembly via the first bridge portion and couplable to the second frame subassembly via the second bridge portion, the central frame configured for a first ride height when coupled to the first frame subassembly and configured for a second ride height when coupled to the second frame subassembly, the first ride height greater than the second ride height.

A battery assembly for an electric vehicle includes two spaced-apart longitudinal profiles extending in a length direction L, interconnected to a front and a rear transverse beam. At least three beam shaped battery modules are interconnected along their longitudinal sides via a plate-shaped interconnecting member, and extend in the length direction, to be attached to an inner surface of the front transverse beam via a bracket. Each battery module is provided with cooling channels extending in the length direction L and having an inlet situated between a transverse end face of the module and the inner surface of the front transverse beam. A water inlet duct extends from an external side the front transverse beam in a central area situated between the brackets, for connecting to a coolant inlet of the central battery module.

A vehicle floor structure may include a floor disposed on a bottom portion of a vehicle body; a plurality of tank mounting members attached to a bottom surface of the floor; and a plurality of hydrogen tanks mounted on the plurality of tank mounting members, wherein each tank mounting member is aligned to extend in a longitudinal direction of the vehicle, the plurality of tank mounting members is spaced from each other in a width direction of the vehicle, each tank mounting member has a plurality of lower recessed portions provided in a lower portion thereof, and at least predetermined upper portions of the hydrogen tanks are received in the lower recessed portions of the tank mounting members, respectively.

A battery enclosure for a vehicle chassis having a base member with raised surface features on the upper surface outlining individual cells, each cell configured to receive at least one battery; a cover member having a plurality of depending surface features on the lower surface which are aligned with the surface features of the base member. The cover member includes a channel formed in the upper surface thereof, aligned with and extending along a length of the depending surface feature disposed on the bottom surface. A lattice support structure is also included which has a plurality of support members extending axially and transversely, wherein the lattice support structure is configured to be at least partially disposed within the channel of the cover member and mounted to the vehicle chassis. The lattice support member providing increased rigidity and a load distribution path for externally applied forces (e.g. crash events) to prevent or inhibit enclosure breakage or puncture.

An apparatus may generate energy in response to a vehicle wheel rotation. The apparatus may include a roller, a shaft, and a generator. The roller may rotate in response to a movement or motion of the wheel and may apply a friction to the wheel to decrease a rotational velocity of the wheel. The shaft may rotate in response to a rotation of the roller. The generator may generate an electrical output based on rotation of the shaft and convey the electrical output to an energy storage device or to a motor of the vehicle.

A mounting structure for a power storage device includes: a power storage device including a power storage stack and a housing case; a floor member; and a rear bracket. The housing case includes a lower case having a rear wall, and an upper case. The floor member is provided with an attachment portion for attaching the rear bracket. The rear bracket includes a front end portion and a rear end portion that is attached to the attachment portion. The power storage stack is disposed inside the housing case to provide a gap between the power storage stack and the rear wall. The front end portion of the rear bracket is fixed to the rear wall to be located between an upper surface and a lower surface of the power storage stack in an up-down direction.

A battery rear undercover assembly for an eco-friendly vehicle enables the bottom of a vehicle to be flattened while covering a lower portion of the rear of a high-voltage battery in an eco-friendly vehicle. The battery rear undercover assembly includes a body having a front end that can be fastened to a lower portion of a rear end of a high-voltage battery and a battery rear undercover formed to extend from each of both side ends of the body upward and formed with a side cover that can be fastened to a vehicle body of a vehicle. The battery rear undercover assembly includes a reinforcement member formed in a longitudinal direction of the vehicle and fastened to an upper surface of the battery rear undercover.

A bodywork support structure for a vehicle includes two side sills that are spaced apart in a transverse direction where the two side sills have a reinforcing element that is disposed in a hollow space. A floor is disposed between the two side sills and connected to the two side sills and an energy store for storing electrical energy and/or a fuel for powering the vehicle is disposed under the floor. The reinforcing element is formed as a corner reinforcement disposed in a corner area where the corner reinforcement has a first connection area that is attached to an external wall, a second connection area that is attached to a lower flange, and a wall area that connects the first and second connection areas with each other across the corner. An open space is formed between the corner reinforcement and an internal wall in the transverse direction of the vehicle.

A battery cooling air discharge structure is configured to suppress noise of the cooling air for a battery. The battery cooling air discharge structure includes a floor panel, a floor, a plurality of rows of seats and an exhaust duct. The floor panel bottom forms a lower part of a vehicle body of a vehicle and enables placement of a battery. The floor panel top portion is arranged above the floor panel to allow placement of the battery between the floor panel top portion and the floor panel. The seats are arranged on the floor. The exhaust duct discharges battery cooling air. The exhaust duct has an exhaust port located between the floor and a seating part of a rear seat that constitutes the seats. An underside of the seating part has a notch. At least an area of the exhaust port is located adjacent to the notch.

A passenger compartment which has a first connection device, by which the passenger compartment can be coupled to an aircraft, and a second connection device, by which the passenger compartment can be coupled to a land vehicle. The passenger compartment has an electrical circuit with an electrical energy storage. The electrical circuit of the passenger compartment has a coupling device by which electrical energy can be input from the electrical energy storage into an electrical circuit of the aircraft. The electrical circuit of the passenger compartment has a further coupling device by which electrical energy can be input from the electrical energy storage into an electrical circuit of the land vehicle.