A fuel supply port device includes a tubular main member portion where a fuel supply nozzle is inserted from a tube-upper-end side; a cover member covering a side portion on the tube-upper-end side of the tubular main member portion from an outside; an earth member electrically connecting a fuel-supply-nozzle side to be inserted and a body-panel side; and a seal member sealing a pass-through portion of the earth member formed in the cover member. The seal member includes an insert-through portion allowing a one-end-portion side of the earth member to be inserted to pass through from the outside of the tubular main member portion.

A work vehicle includes a fuel tank, a control module, a fuel access detection device, a fuel level sensor, and a reaction assembly. The fuel access detection device detects the accessibility of the fuel, and transmits a first signal indicative of the accessibility of the fuel to the control module. The fuel level sensor detects a volume of the fuel, and transmits a second signal related to the volume of the fuel to the control module. The reaction assembly is coupled to the control module and performs a first reaction and a second reaction after the first reaction. In the first reaction the reaction assembly is commanded by the control module based on the first signal, and in the second reaction the reaction assembly is commanded by the control module based on the second signal when the volume of the fuel is changed.

A container that provides for control of fluid flow in the event of a failure of the container is disclosed. In accordance with embodiments of the present invention, a container is presented that includes a container wall; and one or more flow impeding structures coupled to the container wall, wherein at least one of the one or more flow impeding structures is a multi-sheet layer that deforms to impede flow in a failure of the container wall. In some embodiments, the multi-sheet layer includes cavities formed between individual sheets.

A work vehicle includes a fuel tank, a control module, a fuel access detection device, a fuel level sensor, and a reaction assembly. The fuel access detection device detects the accessibility of the fuel, and transmits a first signal indicative of the accessibility of the fuel to the control module. The fuel level sensor detects a volume of the fuel, and transmits a second signal related to the volume of the fuel to the control module. The reaction assembly is coupled to the control module and performs a first reaction and a second reaction after the first reaction. In the first reaction the reaction assembly is commanded by the control module based on the first signal, and in the second reaction the reaction assembly is commanded by the control module based on the second signal when the volume of the fuel is changed.

A vehicle safety system is for preventing child abandonment in a vehicle. The vehicle safety system may include a flow sensor for fuel in the vehicle, and a controller coupled to the flow sensor and a seat sensor. The controller may be configured to detect when the vehicle is in a fueling state based upon the flow sensor, and detect occupancy of a child safety seat based upon the seat sensor. The controller may be configured to if the vehicle does not enter the fueling state within a first time period, then cause the vehicle to enter a first alert state, and if the vehicle does not enter the fueling state within a second time period greater than the first time period, then cause the vehicle to enter a second alert state.

The vehicle body rear structure includes a floor panel 2, a subframe 3 which is provided below the floor panel 2, an impact absorbing member 4 which is provided behind the subframe 3 and extends in the front-rear direction, and a bracket which detachably attaches the impact absorbing member 4 to a lower surface of the floor panel 2. The front end portion 38 of the impact absorbing member 4 is disposed to be at the same height as the subframe 3 in the vertical direction and is disposed with the spacing S from the subframe 3 in the front-rear direction.

A fuel tank in a vehicle. The fuel tank includes a protective outer shell and an inner shell. The protective outer shell has an inner shell receiving area. The inner shell, which holds fuel, is housed in the inner shell receiving area of the outer shell. The inner shell cooperates with the outer shell to maintain the position of the inner shell relative to the outer shell and relative to the vehicle during normal operation. During an impact to the vehicle, the inner shell moves independent of the outer shell and the vehicle, allowing a portion of the energy or the forces associated with an impact to be absorbed by the outer shell, reducing the energy or force transferred to the inner shell.

A vehicle includes a plurality of tanks storing gas in the tanks and arranged in a longitudinal direction of the vehicle, and each of the tanks includes: a pressure relief device configured to open when a temperature of the tank becomes a predetermined temperature or more; and a release part releasing the gas in the tank in a predetermined direction by the opening of the pressure relief device, wherein the release direction of the gas released from the release part of the front tank located at a frontward position among the plurality of tanks is defined to be a direction directly facing a space between the pressure relief devices of the rear tanks disposed more rearward than the front tank, and a ground.

A protective structure includes: a base including a base main wall attached to a vehicle body wall defining a part of an engine room and extends vertically, a stay fixed to the base main wall to hold a fuel line, and a base extension wall extending from an upper part of the base main wall in a direction away from the vehicle body wall; a cover including a cover main wall disposed to oppose the base main wall and to be located in front of the stay and the fuel line, a cover extension wall extending from the cover main wall along the base extension wall, and a leg extending from the cover main wall toward the base main wall below the cover extension wall; and a fastening member extending vertically through overlapping parts of the base extension wall and the cover extension wall to fasten the base and cover.

A fuel storage system is provided for storing dimethylether (DME), a blend including DME, or other similar highly volatile fuel at a vehicle. The fuel storage system including a main storage tank, an expansion tank, a fuel filling receptacle configured to receive a fuel filling nozzle of a filling station, and a valve arrangement having at least a normal operating setting and a fuel filling setting. The valve arrangement in the normal operating setting provides a fuel passage between the main storage tank and the expansion tank, and the valve arrangement in the fuel filling setting both provides a fuel passage between the fuel filling receptacle and the main storage tank and prevents fuel flow between the main storage tank and the expansion tank. The fuel storage system is configured to mechanically prevent disconnection of the fuel filling nozzle from the fuel filling receptacle unless the valve arrangement is in the normal operating setting. A corresponding method, as well as a further example embodiment of the fuel storage system, are also provided.