An assembly for a hybrid motor vehicle, in particular a partially electrified hybrid motor vehicle, includes a vehicle battery with a battery housing, and a vehicle seat with a seat face. The vehicle seat is connected or can be connected by means of at least two seat rails to a vehicle floor of the hybrid motor vehicle. The vehicle battery is arranged or capable of being arranged below the vehicle seat and above the vehicle floor, and, furthermore, the battery housing of the vehicle battery includes a deflection bevel which is arranged on the upper side or in an upper region of the vehicle battery and/or of the battery housing.

An assembly for a hybrid motor vehicle, in particular a partially electrified hybrid motor vehicle, includes a vehicle battery and a vehicle seat having a seat surface. The vehicle seat is connected or capable of connection to a vehicle floor of the hybrid motor vehicle by means of a seat bottom construction of the seat surface. In addition, the vehicle battery is furthermore arranged or capable of arrangement underneath the vehicle seat and above the vehicle floor and a first stiffened cross member, arranged in front of the vehicle battery in the direction of travel, and a second stiffened cross member, arranged behind the vehicle battery in the direction of travel, are provided. The vehicle battery is moreover connected to the first cross member by means of a first fixing arrangement and/or to the second cross member by means of a second fixing arrangement.

A vehicle battery assembly utilizing side cooling plates. This battery assembly avoids a stacked vertical battery and cooling plate or pack arrangement, optimizes tunnel (and other) space utilization, minimizes battery assembly intrusion into the passenger compartment of the associated vehicle, and allows seat position height to be as low as possible within the passenger compartment of the associated vehicle, while still allowing vertical access to the access points and electrical contacts of the battery modules within the battery assembly. Further, such battery assembly is compatible with conventional and novel cooling pipe configurations and cooling systems.

An electric vehicle includes a chassis and a seat assembly that includes a plurality of seats mounted to the chassis. The chassis includes a vehicle frame defining a mounting space, and a battery module disposed in the mounting space and including an outer battery unit that is mounted to the vehicle frame, and an inner battery unit that is coupled to the outer battery unit. The vehicle frame is operable to switch between an expanded state, where the inner battery unit is permitted to be coupled to the outer battery unit and the seats are spaced apart from each other, and a collapsed state, where the inner battery unit is prevented from being coupled to the outer battery unit and the seats are overlapped with each other.

A vehicle chassis including a vehicle frame defining an inner space and being operable to switch between a first expanded state and a collapsed state, and a loading device mounted to the inner space and removably connected to the vehicle frame. The loading device defines a first loading surface when the vehicle frame is in the first expanded state, and the loading device defines a second loading surface that is smaller than the first loading surface when the vehicle frame is in the collapsed state.

An open cabin electric wheeled vehicle includes a large-capacity driving battery having a volume energy density higher than the volume energy density of a lead storage battery, the large-capacity driving battery being configured to supply electric power to a driving electric motor. The vehicle also includes a fuel-type electric power generation apparatus that generates electric power using a fuel. As seen from a leftward direction or a rightward direction, between the large-capacity driving battery and the fuel-type electric power generation apparatus, a recess overlaps with a passage region which allows people or baggage to pass through of an entrance and exit opening portion having no door, so that a bottom end of a front wall portion, a bottom end of a rear wall portion, and a bottom portion are located further downward than a top end of the large-capacity driving battery which has a volume energy density higher than the volume energy density of a lead storage battery, and a top end of the fuel-type electric power generation apparatus.

A battery electric counterbalanced forklift reliably prevents rainwater from entering an electrical part compartment in a counterweight and also allows a battery cover attachment task to be performed more readily than conventionally. The forklift includes a body frame forming a battery compartment within a vehicle body, an openable battery cover closing the battery compartment, a counterweight disposed adjacently behind the body frame, a hinge rotatably joining the body frame and the battery cover, and an inner cover disposed so as to extend widthwise beyond a boundary between the body frame and the counterweight. The inner cover and the hinge are fastened together to the body frame at a portion forming the boundary.

An electric or hybrid sport car comprising a battery pack incorporating at least one structural element of the vehicle frame, and wherein said structural element can be removed from the vehicle frame only together with the battery pack.

A power unit of an electric vehicle may be connected to a main battery, an AC inlet, and a DC inlet. The power unit may include a battery connector to which a battery power cable is connected, an AC inlet connector to which an AC inlet power cable is connected, and a DC inlet connector to which a DC inlet power cable is connected. The battery connector may be closer to the main battery than a center of the power unit is to the main battery. The AC inlet connector may be closer to the AC inlet than the center of the power unit is to the AC inlet. The DC inlet connector may be closer to the DC inlet than the center of the power unit is to the DC inlet.

An axle drive apparatus of the present invention includes an adapter unit that has an adapter case connectable to an axle drive case while supporting a first motor, an adapter input member connected to an output shaft of the first motor by connection of the first motor to the adapter case, an adapter output member that is connected to an axle drive input member of the axle drive apparatus by connection of the adapter case to an axle drive case, and an adapter power transmission mechanism that operatively transmits the rotational power of the adapter input member to the adapter output member. The axle drive apparatus is connectable to a vehicle frame through an axle drive case side frame connecting part and an adapter case side frame connecting part respectively provided at the axle drive case and the adapter case.