An air cut-off valve module and a control method thereof is provided. The air cut-off valve module has a structure in which valve plates and driving mechanisms thereof are formed as one module, and is mounted in a stack. Thus, components related to the air cut-off valve are constructed as a compact module. Furthermore, a bypass flow path is formed to dilute exhaust gas of the stack, thereby reducing the concentration of hydrogen.

The present disclosure provides a male coupling member detachably couplable to a female coupling member that includes an outer coupling body having a first end inserted and fitted into the female coupling member, a second end opposite to the first end, and a passage extending from the first end to the second end. The male coupling member further includes an inner coupling body disposed coaxially with the outer coupling body at a position closer to the first end, and a filtration member detachably attached to the inner coupling body. The inner coupling body is attachable to and detachable from the outer coupling body from the first end. The filtration member is held in the passage when the inner coupling body is attached to the outer coupling body. The filtration member is detachable when the inner coupling body is detached from the outer coupling body.

A high-voltage unit casing 10 for on-vehicle use to house therein a plurality of devices includes: a first side face 20; a second side face 21 opposed to the first side face; and a connecting portion 22 for structurally connecting the first side face and the second side face to each other. The connecting portion includes a partitioning portion 50 which is fixed to the first side face at a fixing portion and which extends from the fixing portion toward the second side face, the partitioning portion being located at a position separate from an upper surface and a lower surface of the high-voltage unit casing in an inner surface of the first side face. Spaces for placing at least one device included in the plurality of devices are formed on both upper and lower sides, respectively, of the partitioning portion.

The fuel cell vehicle includes a fuel cell placed in a front room, an air compressor placed below the fuel cell in the front room to supply the fuel cell with cathode gas, and a refrigerant supply pump placed below the fuel cell in the front room to supply the fuel cell with a refrigerant. The refrigerant supply pump is placed forward of the air compressor.

An electric vehicle propulsion system includes an electric motor and a battery pack formed as a single, integrated unit. It is a self-contained, integrated electric propulsion system. It disrupts the long-established engineering paradigm that the electric motor and the battery pack have to be designed, built and installed as separate systems.

A fuel cell vehicle comprising: a hydrogen tank which is mounted on the vehicle so as to have a center axis generally parallel to a front/rear direction of the vehicle; a high-voltage electric component which is positioned either forward or rearward of the hydrogen tank and which operates on high voltage; an aftercooler placed between the hydrogen tank and the high-voltage electric component to cool compressed air; and a fuel cell stack which is supplied with the cooled compressed air.

The electric vehicle including one or more in-wheel motors, a battery electrically coupled to one or more in-wheel motors, a power electronics including a DC-AC inverter, a AC-DC inverter, and a boost converter that receives DC power from the battery and supplies AC power to the one or more in-wheel motors, and a generator electrically coupled to the battery via the power electronics. Further, it includes a Rankine cycle system including a pump, a first valve having an input, a first output, and a second output connected to the pump, the generator, and the one or more in-wheel motors, respectively. A second valve having a first input connects to the generator, a second input connects the one or more in-wheel motors and an output delivers the working fluid to the power electronics. An expander receives the working fluid from at least one of the power electronics.

A vehicle includes: a vehicle interior; a front room provided on a front side of the vehicle interior; a luggage room provided in a rear side of the vehicle interior; a weight part which includes at least one of a drive unit to drive a vehicle wheel and a power source to supply fuel or power to the drive unit; and a battery. The weight part includes a first weight part and a second weight part, at least one of the first weight part and the second weight part includes the drive unit, the battery is provided below the vehicle interior, the first weight part is provided in the front room, the second weight part is provided below the luggage room, and a height of the second weight part is lower than a height of the first weight part.

A motor vehicle includes an electrolysis device for decomposing water into hydrogen and oxygen, a storage battery, a hydrogen-powered energy source providing motive power for the motor vehicle and a controller configured to prioritize routing excess vehicular-generated electrical energy to the electrolysis device over the storage batter. A related method of efficiently operating a hydrogen-powered motor vehicle is also disclosed.

An electric power storage device includes an electric power storage module including a unit electric power storage portion, and a fixing member fixed to the electric power storage module. The electric power storage module includes a first exhaust port configured to discharge gas discharged from the unit electric power storage portion. The fixing member includes a fixing member body fixed to the electric power storage module and a cover member disposed on the fixing member body. The cover member is disposed on a surface of the fixing member body facing the electric power storage module. An exhaust passage, into which the gas discharged from the first exhaust port flows, is formed by the fixing member body and the cover member.