A pressure vessel system for a motor vehicle for storing fuel includes a plurality of pressure vessels that are combined to form a pressure vessel assembly. The pressure vessels, when mounted, are arranged substantially in parallel relative to one another, and the pressure vessels are fluidically interconnected via a common fuel line. The technology further relates to a fuel line comprising thermal insulation.

A motor vehicle tank comprises a main tank that includes at least one main extraction unit that has a main flow line for extracting fuel from the main tank; an auxiliary tank arranged adjacent to and connected with the main tank, the auxiliary tank including: an auxiliary extraction unit having an auxiliary flow line for extraction of fuel from the auxiliary tank, and a filler connection for direct filling of the auxiliary tank; a partition wall which separates the auxiliary tank from the main tank by a partition wall, the partition wall having a lower partition wall region without an opening in an installation position, and an upper partition wall region having at least one opening to form an overflow between the auxiliary tank and the main tank.

A fueling system is disclosed for use with a service vehicle with a fuel tank and a main engine, and an auxiliary system. A fuel distribution system can include at least one fuel pump and at least one fuel nozzle. A compound fuel extractor can be configured to engage the main fuel tank of the service vehicle to provide first and second overlapping flow paths out of the main fuel tank. The first overlapping flow path can direct fuel from the main fuel tank to the main engine, and the second overlapping flow path can direct fuel from the main fuel tank to the auxiliary system.

The present disclosure relates to a valve assembly adapted to be located at least partially in a body of fluid for controlling fluid flow from the body of fluid to a fluid outlet port. The valve assembly has an extension in a first direction and includes a fluid inlet port having an extension at least partially in the first direction. The valve assembly further includes a valve member being movable in the first direction relative to the fluid inlet port between an open position, in which the fluid inlet port is adapted to provide a fluid communication between the body of fluid and the fluid outlet port, and a closed position, in which the valve member covers the fluid inlet port such that fluid communication between the body of fluid and the fluid outlet port via the fluid inlet port is prevented.

Provided is a fuel tank made of resin, including: a fuel tank body that is enclosed by a bottom wall, side walls, and an upper wall, the fuel tank body including a first storage portion, a second storage portion, and a coupling portion, the coupling portion communicating an upper portion of the first storage portion and an upper portion of the second storage portion; a pump module disposed in the first storage portion; an open portion formed in the first storage portion; a strut provided in the first storage portion; a separator provided on the strut; a suction portion disposed in the second storage portion; a fuel transfer line that communicates the suction portion to the pump module; a holding portion and a provisional holding portion provided at the separator, the provisional holding portion being configured to removably hold the extra-length portion of the fuel transfer line.

A fuel tank made of resin includes: a fuel tank main body enclosed by a bottom wall, side walls, and a top wall, and configured to internally store fuel, the fuel tank main body including a pair of storage portions and a joining portion, the joining portion enables the pair of storage portions to mutually communicate with each other, and a distance from the bottom wall to the top wall of the joining portion is shorter than in the storage portions; and plural stand-offs formed at the joining portion by bonding together a portion of the top wall and a portion of the bottom wall.

The disclosure relates to liquid tank arrangement for a vehicle. The liquid tank arrangement includes at least a first tank volume and a second tank volume fluidly connectable to each other. The at least first and second tank volumes form a single combined tank volume when fluidly connected to each other. The at least first and second tank volumes form fluidly separate first and second tank volumes when fluidly disconnected from each other. The disclosure also relates to vehicle including the liquid tank arrangement.

A connection structure for pressure vessels is configured such that respective mouth pieces are connected to at least one ends of the pressure vessels, and when adjacent mouth pieces are connected to each other in an intersection direction intersecting with the axial direction, the pressure vessels placed in parallel can be connected to each other. The mouth piece includes a connecting portion along the intersection direction intersecting with the axial direction. The connecting portion includes an external screw thread portion formed on a first side thereof, and a nut rotatably locked to a second side thereof and having an internal screw thread portion threadedly engageable with the external screw thread portion.

A gas tank arrangement for an internal combustion engine is provided, the gas tank arrangement including a gas tank configured to contain a combustible gas, and a first additional gas tank positioned in downstream fluid communication with the gas tank, wherein the gas tank arrangement further includes a second additional gas tank positioned in downstream fluid communication with the gas tank and in upstream fluid communication with the first additional gas tank. A vehicle including such a gas tank arrangement is also provided.

A method and a control arrangement for determining the status of a primary fluid tank or one or more secondary fluid tanks, each of the fluid tanks being arranged to contain a fluid or a mixture of fluids available in liquefied form and vaporised form and be connected to a second pressurized fluid conduit arrangement. The control arrangement determines a pressure drop (?p) associated with the fluid flow through the second pressurized fluid conduit arrangement. When the pressure drop (?p) exceeds a threshold, the control arrangement blocks the fluid flow from one of the fluid tanks to the second pressurized fluid conduit arrangement. Based on a subsequently determined pressure drop (?p), the control arrangement determines whether said one of the primary and secondary fluid tanks is empty of liquefied fluid.