A UTV spare fuel tank is provided. The spare fuel tank includes a main body and a lid coupled to the main body. The main body may include a storage compartment and a fueling compartment accessible by opening the lid. The spare fuel tank include a fuel reservoir formed between an outer wall and an inner wall of the main body. The outer wall forms the outer dimension of the main body and the inner wall forms the storage compartment and the fueling compartment. The spare fuel tank may also include brackets and lift members coupled to the main body and extending below a bottom surface of the main body to lift the main body off of a storage shelf to form a gap between the bottom surface and the storage shelf.

An open cabin vehicle is equipped with a fuel cell unit having a hydrogen tank for storing hydrogen to be used as fuel and has a simple structure. An upper end of each of a hydrogen tank, a fuel cell stack, and a hydrogen supply pipe is located farther upward than a floor in a state in which the hydrogen tank, the fuel cell stack, and the hydrogen supply pipe are disposed in a fuel-cell-unit arrangement space which is provided below a space being present farther backward than at least a part of the floor in a vehicle-body inner space, and which borders the vehicle-body inner space, thereby being connected to a vehicle-body outer space which is a space around the open cabin vehicle, via the vehicle-body inner space.

A low floor road vehicle, in the form for example of a passenger bus, includes a front module that includes the front load-carrying axle at its front, a rear module including the rear load-carrying axle, a central module having a flat floor and lateral side walls that longitudinally extend beyond both longitudinal ends of the flat floor so as to define front and back module attaching portions, and a roof mounted to both lateral side walls so as to extend beyond the floor both towards the front and back, which brings rigidity to the overall structure. The vehicle being modular, the central module can be configured to a specific application, for example by varying the length thereof, while same configurations of the front and rear modules can be used in all applications. Also, the front axle being located at the front of the front module, the access to the passenger area defined by the flat floor is improved.

A vehicle includes a body including a beltline and a rear wheelhouse, an input line assembly packaged about the rear wheelhouse, a component packaged about the rear wheelhouse rearward of the input line assembly, and a spare wheel stowed rearward of the rear wheelhouse. The component is secured by a permanent beltline-side attachment and a semi-permanent rear wheelhouse-side attachment. In response to rear impact, the body is configured to allow forward movement of the spare wheel, under which the spare wheel has a trajectory relative to which the component is between the spare wheel and the input line assembly, and relative displacement between the beltline-side attachment and the rear wheelhouse-side attachment, under which the rear wheelhouse-side attachment breaks against the beltline-side attachment, and the beltline-side attachment thereafter carries the component from between the spare wheel and the input line assembly relative to the trajectory of the spare wheel.

A system for reducing risk of fuel leakage of a vehicle during a collision includes a vehicle main body configured to support and at least partially enclose a passenger. The system further includes a fuel inlet box configured to house a fuel inlet. The system further includes a rear bracket coupled to the vehicle main body at a location aft of the fuel inlet box. The system further includes a center shaft coupled to the rear bracket and extending forward from the rear bracket. The system further includes a forward bracket coupled to the vehicle main body at a location forward relative to the rear bracket and coupled to the center shaft, the forward bracket configured to deform in response to a rear collision of the vehicle to actuate the fuel inlet box in order to reduce the likelihood of a fuel leak from the fuel inlet.

The present disclosure relates to a gas consumer system for a vehicle, the gas consumer system being configured to generate power by consuming gas, the gas consumer system comprising a gas consumer comprising an inlet configured to receive a flow of gas, at least one gas tank, the gas tank comprising a gas tank outlet, a conduit connecting the gas tank outlet of the tank to the inlet of the gas consumer, and an elongated sleeve attached to the inlet of the gas consumer and to the gas tank outlet of the gas tank, wherein the conduit is housed within the elongated sleeve, the elongated sleeve comprising a sleeve outlet configured to convey leakage of gas between the gas consumer and the gas tank away from the gas consumer system.

A gas tank arrangement for an internal combustion engine of a vehicle is provided. In particular, a gas tank arrangement comprising a gas tank for containing a combustible fuel and an electrically propelled gas burning arrangement provided downstream the gas tank.

A fuel tank cover attachment assembly includes a fuel pump cover and an attachment ring. The fuel pump cover has an attachment flange configured to overlay a surface surrounding a fuel tank opening such that with the fuel pump cover overlaying the surface, the fuel tank opening is covered. The attachment ring is dimensioned to cover the attachment flange of the fuel pump cover and attach to attachment features protruding from the surface. The attachment ring has a first flange member and a second flange member. The first flange member is fixedly attached to the attachment ring and extends upwardly therefrom. The second flange member is removably attached to the attachment ring and extending upwardly therefrom.

It is an object of the invention is a fuel cell system architecture provides a good weight distribution, improved trunk space without reducing the security against front-end and rear end collision. The above objective is accomplished by a fuel cell vehicle comprising:—A rear vessel for hydrogen gas located in the rear part of the vehicle,—A front vessel for hydrogen gas located in the front part of the vehicle,—A hydrogen dosing unit,—A hydrogen control unit connected to the hydrogen dosing unit, to the rear vessel and to the front vessel, the hydrogen control unit being provided with first means for equalizing the pressure between the first rear vessel and the front vessel, the hydrogen control unit being provided with second means for transferring hydrogen at a predetermined pressure level to the hydrogen dosing unit from the two vessels,—An air supply,—A fuel cell connected to the hydrogen dosing unit and the air supply, the air supply being provided with means for providing the fuel cell with air, the hydrogen dosing unit providing the fuel cell with hydrogen,—A battery,—A DC/DC-converter,—The fuel cell being connected to the battery so as to provide the battery with energy, the battery and the DC/DC-converter being interconnected so as to exchange energy, the fuel cell and the battery, being located at the bottom of the vehicle.

A motor vehicle with a pressure vessel system includes at least a first pressure vessel arranged in a first region of the motor vehicle and at least one second pressure vessel arranged in a second region of the motor vehicle having a lower intrusion probability than the first region. Fuel is preferentially removed first primarily from the at least one first pressure vessel. When the lower limit of fuel level or fuel temperature is reached in the at least one first pressure vessel, fuel is removed from the at least one second pressure vessel. If the fuel supply rate from the at least one first pressure vessel is lower than an overall fuel supply rate for an energy converter, fuel is removed from the at least one second pressure vessel to meet the overall fuel supply rate needed by the energy converter.