A locking system for a fuel compartment assembly of a work vehicle, the locking system having a housing at least partially defining a fuel access compartment, a door pivotally coupled to the housing and movable between an opened position, at which the door provides access to the fuel access compartment, and a closed position, at which the door blocks access to the fuel access compartment, and a locking assembly configured to lock the door at the closed position. The locking assembly includes a catch fixed to the housing and positioned within the fuel access compartment, and a latch arm pivotably coupled to the door at a pivot point defined between first and second ends of the latch arm, the pivot point defining a first pivot axis, where the latch arm is configured to be pivoted about the first pivot axis to be selectively engaged and disengaged with the catch.

It is provided an adjustment mechanism, comprising a closure flap for at least partially closing a closure opening on a vehicle, via which, when the closure flap is opened, a connection element for connecting a line and/or a port for topping up a liquid, in particular a fuel, is accessible, a drive for adjusting the closure flap by external force in response to an operator control event, and an electronic control unit which is coupled to the drive and by means of which the drive is activated to open the closure flap in response to an operator control event which is detected in a contactless manner, and, on the other hand, is automatically stopped or reversed in so far as, when the closure flap closes, a possible obstacle is detected in a contactless manner in the adjustment path of the closure flap by means of an anti-pinch mechanism.

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 vehicle security system may be automatically activated when a vehicle (e.g., car or truck) is temporarily stopped. Specifically, if a car is stopped at a gas station or other type of temporary stop (e.g., where a car would not be fully closed and locked) the vehicle security system may engage (e.g., based on opening of a gas cap cover). The vehicle security system monitors for theft of contents from inside a vehicle in a temporary stopped state. Sensors monitor if a passerby reaches into an open (or partially open) window to grab a parcel, handbag, phone, etc. from inside the vehicle. In a temporary stop condition, a vehicle may not be fully locked to engage a standard anti-theft security system. If a driver's attention is diverted away from the vehicle during the temporary stopped condition a quick and quiet theft scenario (e.g., a reach and grab) may be attempted.

A transport refrigeration system (200) including: a first engine (26) configured to power a refrigeration unit (22); a first fuel tank (330) fluidly connected to the first engine (26) through a first fuel line (332); a first shut off valve (450) located within the first fuel line (332) proximate the first fuel tank (330); a second shut off valve (72) located within the first fuel line (332) proximate the first engine (26); a sensor system (80) configured to detect at least one of a crash of the transport refrigeration system (200), a crash of the first fuel tank (330), a fuel leak in the first fuel line (332), and an engine stall in the first engine (26); and a controller (30) configured to close the first shutoff valve (450) and second shutoff valve (72) when at least one of a crash of the transport refrigeration system (200), a crash of the first fuel tank (330), a fuel leak in the first fuel line (332), and an engine stall in first engine (26) is detected.

A motor vehicle has a pressure relief device that can be thermally activated, for the pressure relief of at least one pressure vessel. A body floor element is arranged at least partially between the passenger compartment or the cargo area and the pressure vessel. A pressure relief triggering device is designed to directly or indirectly bring about the pressure relief. The pressure relief triggering device is designed to absorb thermal energy from the passenger compartment or the cargo area in order to trigger the pressure relief device, without the thermal energy absorbed for the triggering having previously been transmitted to the pressure relief triggering device through the body floor element.

A tank holding device is adapted to be mounted to a vehicle. The vehicle includes a mounting frame, a holding frame that is disposed on the mounting frame, and a tank that is disposed between the mounting frame and the holding frame. The tank holding device includes a positioning unit that is adapted to be connected to the holding frame and adapted for pushing the tank tightly against the mounting frame so as to secure the tank on the mounting frame.

A transport refrigeration system having: a refrigerated cargo space (119); a refrigeration unit (22) in operative association with the refrigerated cargo space, the refrigeration unit providing conditioned air to the refrigerated cargo space; a first engine (150) configured to power the vehicle; a second engine (26) configured to power the refrigeration unit; a first plurality of fuel tanks (350) fluidly connected to first engine, the first plurality of fuel tanks configured to supply fuel to the first engine; a second plurality of fuel tanks (330) fluidly connected to second engine, the second plurality of fuel tanks configured to supply fuel to the second engine; and a single filling point (310) fluidly connected to the first plurality of fuel tanks and second plurality of fuel tanks. The single filling point (310) is configured to receive fuel.

A supporting assembly for a hollow tank body includes a supporting body (2) and supporting ends (1) provided at two ends of the supporting body. The supporting ends are provided with stepped transition assemblies (4) connected to the supporting body. The supporting body is configured with a hollow structure. The supporting body includes a supporting main body (5) and a base (6). The supporting main body is configured with a cylindrical structure or a cylindrical structure with a corrugated structure in the middle. With this structure, the deformation of the hollow tank body under the relatively high overpressure and the low negative pressure can be avoided, and the shape stability of the whole product can be enhanced. Meanwhile, the supporting structure needs less material, and has a light weight and lowered cost.

A vehicle safety system is for preventing child abandonment in a vehicle. The vehicle safety system may include a controller coupled to a flow sensor, a temperature 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, detect occupancy of a child safety seat based upon the seat sensor, and detect when a driver side door is in an open state based upon a driver side door sensor in the vehicle. The controller may be configured to when the driver side door has entered the open state, when the child safety seat is occupied, and when the vehicle does not enter the fueling state within a time period, then cause the vehicle to enter an alert state.