A fuel tank in a vehicle. The fuel tank includes a protective outer shell, an inner shell and a crush sleeve. The protective outer shell defines an outer tank. The inner shell defines an inner tank which holds fuel. The inner shell is housed in the outer shell and is isolated from the outer shell by a space. The crush sleeve is provided in the space between the outer shell and the inner shell. The crush sleeve supports the inner shell and maintains the inner shell in position relative to the outer shell. Wherein during an impact to the vehicle, the force of the impact causes the outer shell and the crush sleeve to deform and the inner shell to move relative to the outer shell.

There is provided a fuel cell vehicle, including a high voltage system disposed in a front compartment of the vehicle, and a first protruding portion that protrudes in a left-right direction of the vehicle toward a vehicle body of the vehicle further than a portion of the high voltage system that is closest to the vehicle body, and is fixed to the high voltage system, in which, when the vehicle is placed on a horizontal plane, the first protruding portion is arranged such that a position of a first most-protruded portion of the first protruding portion that protrudes most toward the vehicle body in a height direction is located at the same position or higher than a center of gravity of the high voltage system.

A two-track multi-axle motor vehicle including at least two fuel tanks in which a fuel for producing driving energy for a vehicle drive unit can be stored under high pressure of the order of magnitude of 300 bar and more is provide. Each tank includes a safety valve device having a temperature-sensitive element monitoring only a partial region of the tank surface. The safety valve device allows at least a partial quantity of the stored fuel to escape from the respective tank at a higher temperature, which can occur, for example, in the case of a fire. The temperature-sensitive elements of at least two tanks are arranged here in such a manner that the distance between a left-side wheel (RL) of that vehicle axle, in the vicinity of which the at least two fuel tanks are arranged in the vehicle, and the temperature-sensitive element closest to the left-side wheel (RL) does not significantly differ from the distance of the other of the two temperature-sensitive elements from the right-side wheel (RR) of the vehicle axle.

A fuel cell vehicle includes fuel tanks, a first support mechanism, and a restricting member. The fuel tanks are disposed in a vehicle width direction to have longitudinal directions along a vehicle longitudinal direction. The fuel tanks include first and second fuel tanks. The first fuel tank is provided on an outer side in the vehicle width direction. The second fuel tank is adjacent to the first fuel tank. The second fuel tank has an axial center positioned higher than an axial center of the first fuel tank. In a case where a collision load acts from outside in the vehicle width direction, the first support mechanism supports the first fuel tank while allowing the first fuel tank to move toward a lower side of the second fuel tank. The restricting member is provided above the second fuel tank and restricts an upward movement range of the second fuel tank.

In a method and a corresponding system for identifying a fuel loss event, periodic measurements of a measured volume of fuel stored in a fuel tank (mobile or stationary) are received, and a measurement of a dispensed volume of fuel dispensed into the fuel tank is received from a fueling station. A total volume of fuel is determined equal to the sum of the dispensed volume of fuel and the measured volume of fuel last measured prior to receiving from a fueling station. A difference is determined between the total volume and the measured volume of fuel first measured subsequent to determining the total volume. If the difference exceeds a predetermined threshold indicating a fuel loss event, an alert is generated indicating that there is a fuel loss event.

Systems are provided for refueling a fuel tank of a motor vehicle via a funnel including an insert. In one example, a system may include a funnel including an insert coupled to an inner circumference of the funnel, the insert including a plurality of projections positioned on an inner perimeter of the insert. The plurality of projections may include a first projection spanning a first axial length, a second projection spanning a second axial length, and a third projection spanning a third axial length.

The invention relates to an operating-fluid container (1) for a motor vehicle, comprising a container body which is assembled from two mutually complementary injection-molded shells (2a, 2b) which consist of thermoplastic material and are welded together in an encircling manner to form a substantially closed hollow body, wherein at least one shell (2a, 2b) is at least in regions formed from thermoplastic materials having different strengths, wherein at least one part-region consists of a thermoplastic material having a fibrous filling, wherein the shell (2a, 2b) has been obtained by way of a co-injection process during injection molding.

A pressurized container system for a motor vehicle includes a pressurized container configured to store a fuel, wherein the pressurized container system has a shut-off valve which is configured to interrupt, in a currentless state, a fluid connection between the pressurized container and at least one fuel gas consumer. A safety switch is configured to interrupt a power supply to the shut-off valve, where the safety switch is not an ignition switch of the motor vehicle.

A fuel tank in a vehicle. The fuel tank includes a protective outer shell, an inner shell and a crush sleeve. The protective outer shell defines an outer tank. The inner shell defines an inner tank which holds fuel. The inner shell is housed in the outer shell and is isolated from the outer shell by a space. The crush sleeve is provided in the space between the outer shell and the inner shell. The crush sleeve supports the inner shell and maintains the inner shell in position relative to the outer shell. Wherein during an impact to the vehicle, the force of the impact causes the outer shell and the crush sleeve to deform and the inner shell to move relative to the outer shell.

A fuel tank includes a port and an open-cell foam. The open-cell foam is configured to retain a liquid fuel by an interfacial surface tension between the open-cell foam and the liquid fuel. The open-cell foam is configured to selectively release the liquid fuel when a surfactant is applied to the open-cell foam to reduce the interfacial surface tension between the open-cell foam and the liquid fuel.