A hybrid plug-in battery and hydrogen fuel internal combustion engine vehicle with swappable modular hydrogen tanks and integrated with solar power generation system comprises: a plug-in chargeable battery bank; a hydrogen fuel internal combustion engine; a water electrolysis system; a solar electric power generation system; and multiple modular swappable hydrogen tanks. The hybrid electric vehicle can be electrically charged by using electric charging infrastructure and mechanically charged by swapping hydrogen tanks. The introduction of the water electrolysis system into the new structure of the hybrid vehicle enables onboard hydrogen generation. The swappable hydrogen tanks comprise sensors and wireless communication electronic terminals to be shared by all vehicles.

A vehicle includes an electrical device in which a high-voltage part is disposed within a case, and a fuel tank. The high-voltage part is disposed near a first side end of the case in a vehicle width direction. The fuel tank has a first end portion in the vehicle width direction and a second end portion opposite to the first end portion. When a collision load equal to or greater than a predetermined value is applied to the fuel tank from the outside in a vehicle front-rear direction, the fuel tank is configured to be horizontally rotated about the first end portion of the fuel tank, and the second end portion of the fuel tank is configured to contact the second side end of the electrical device.

A vehicle includes an electrical device in which a high-voltage part is disposed within a case, and a fuel tank. The high-voltage part is disposed near a first side end of the case in a vehicle width direction. The fuel tank has a first end portion in the vehicle width direction and a second end portion opposite to the first end portion. When a collision load equal to or greater than a predetermined value is applied to the fuel tank from the outside in a vehicle front-rear direction, the fuel tank is configured to be horizontally rotated about the first end portion of the fuel tank, and the second end portion of the fuel tank is configured to contact the second side end of the electrical device.

A fuel cell stack includes a stack body, a stack casing, and an exhaust duct. The stack body includes a first end, a second end, a bottom, a top, a side, and a downwardly inclined portion. The top has a substantially flat portion with an end point. The side extends between the top and the bottom and between the first end and the second end. The downwardly inclined portion connects the end point of the substantially flat portion and the side. The stack casing accommodates the stack body. The stack casing includes an upper wall and a side wall. The side wall is opposite to the side of the stack body. The exhaust duct is connected to the upper wall of the stack casing. The exhaust duct has an opening on the upper wall. The opening is arranged between the end point and the side wall.

A fuel cell stack includes a stack body, a stack casing, and an exhaust duct. The stack body includes a first end, a second end, a bottom, a top, a side, and a downwardly inclined portion. The top has a substantially flat portion with an end point. The side extends between the top and the bottom and between the first end and the second end. The downwardly inclined portion connects the end point of the substantially flat portion and the side. The stack casing accommodates the stack body. The stack casing includes an upper wall and a side wall. The side wall is opposite to the side of the stack body. The exhaust duct is connected to the upper wall of the stack casing. The exhaust duct has an opening on the upper wall. The opening is arranged between the end point and the side wall.

A saddle-ride type vehicle includes a vehicle body frame steerably supporting a front fork by a head pipe and swingably supporting a rear wheel unit around a pivot, an air-cooled type fuel cell unit supported by the vehicle body frame on a rear side of the head pipe and including an outside air intake port facing forward, and a vehicle body cover defining a front of an intake air space that is connected to the intake port. The vehicle body cover includes a traveling air passage changing a direction of traveling air that flows in from a front. Accordingly, it is possible to efficiently supply traveling air to a fuel cell unit that includes a fuel cell.

An apparatus for reducing hydrogen concentration in exhaust gas of an exhaust system of a fuel cell vehicle includes a bumper cover disposed at a rear portion of the fuel cell vehicle, the bumper cover forming a streamlined exterior surface, and an exhaust gas guiding unit interconnecting the exhaust system and the bumper cover, the exhaust gas guiding unit guiding the exhaust gas to the streamlined exterior surface of the bumper cover.

A power generating arrangement, including a power generator, a housing and a supporting structure, wherein the housing is attached to the supporting structure, and a center of gravity of the power generator is arranged between at least one of a first and second geometric rotation axes and a downward facing side of the housing.

A power generating arrangement, including a power generator, a housing and a supporting structure, wherein the housing is attached to the supporting structure, and a center of gravity of the power generator is arranged between at least one of a first and second geometric rotation axes and a downward facing side of the housing.

The disclosure relates to a drive device for a motor vehicle, with a primary power network and a secondary power network, wherein a fuel-cell device is provided in the primary power network, and a battery is provided in the secondary power network, and a drive unit of the drive device is electrically connected to the secondary power network, and wherein the battery provides, within an operating voltage range delimited downwards by a minimum voltage and upwards by a maximum voltage, electric current for proper operation of at least one electrical consumer over an operating current range delimited downwards by a minimum amperage and delimited upwards by a maximum amperage. It is provided in this respect that an open-circuit voltage of the fuel-cell device correspond at most to the maximum voltage, and that the fuel-cell voltage provided by the fuel-cell device across the operating current range be higher than the minimum voltage. The disclosure furthermore relates to a method for operating a drive device for a motor vehicle.