Abstract: A method for loading or reloading a decomposition unit of a vehicular system, the vehicular system including a filler pipe in communication with the decomposition unit. The method includes introducing at least one capsule including at least one protein component adapted to decompose ammonia precursor through the filler pipe and which is then guided through the filler pipe towards the decomposition unit.

Abstract: A fuel tank having a wall with an opening, the wall having a fuel impermeable layer, the fuel tank comprising a component welded to the wall around the opening, the component having a fuel impermeable layer, wherein the fuel tank comprises a fuel impermeable insert, at least partially embedded in the wall around the opening and arranged in between the two fuel impermeable layers.

Abstract: A vehicular liquid containment system including a tank, a pressure sensor arranged to detect a pressure in a vapor dome inside the tank, at least two thermistors configured to detect temperatures at a plurality of levels of the tank, and leak detection logic operatively connected to the pressure sensor and the thermistors. The leak detection logic is configured to: use a first thermistor of the thermistors to perform a first measurement indicative of a temperature in the vapor dome in the tank; estimate an expected pressure evolution in function of at least the first temperature measurement; monitor pressure sensed by the pressure sensor, determine whether the monitored pressure deviates from the expected pressure evolution, and generate a leak condition signal conditional on the determining.

Abstract: The system for use in a vehicle, comprises a decomposition unit (20) for at least partial decomposition of a compound under catalysis of a biological catalyst. The system is further provided with a storage unit (30) for storage of biological catalyst, and with a dosing device (31) for transferring biological catalyst into the decomposition unit (20).

Abstract: The system for use on board of a vehicle comprises a decomposition unit (2) for decomposing a compound under catalysis of a biological catalyst (3). The compound is for instance an ammonia precursor, and the biological catalyst is in solid form. At least one transfer means is present for transferring one of said compound and biological catalyst towards and/or away from the other one. The transfer means are for instance a moving device (15), for instance in the form of a float.

Abstract: Method for stake-fastening an accessory (4) into a plastic fuel tank, whereby: the accessory (4) is equipped with at least one orifice (5) which passes right through the accessory (4); at least some of the plastic of which the wall of the tank (1) is made is melted; and some of the molten plastic is forced through the orifice (5) of the accessory without becoming detached from the remainder of the molten plastic; the protruding molten plastic is given an appropriate shape (8) to obtain a self-formed plastic rivet, and is left to solidify; the size and shape of the orifice (5) and/or of the solidified plastic (8) being such that the accessory (4) is mechanically fastened to the tank by at least some of the solidified plastic (8), the stake-fastening of the accessory (4) occurring at the time of manufacture of the tank (1) through the moulding of a split or at least two-part parison.

Abstract: The invention relates to a system (2) for storing a liquid additive to be injected into the exhaust gases of an internal combustion engine of a vehicle, comprising: an additive storage tank (4) comprising means for setting a maximum filling level of the tank, an additive retention capacity which fluidically communicates with the tank (4), said capacity being designed so as to retain the additive coming from the tank, wherein the additive retention capacity and the tank (4) are adjacent and have at least one common wall (8).

Abstract: A vehicle storage system with vapor control. The storage system includes: a vehicle tank including a vapor outlet, a filter unit including a filter inlet and outlet, a housing including a first port communicating with the vapor outlet, a second port communicating with the filter inlet, a third port communicating with the filter outlet, and a fourth port. A closure body is moveably arranged in the housing, the closure body configured to: close the third and fourth ports in a first position of the closure body, create in the housing a barrier between a first volume and a second volume in a second position of the closure body, the first volume forming a passage between the first and second ports, and the second volume forming a passage between the third and fourth ports, and close the first and second ports in a third position of the closure body.

Abstract: A heater for a plastic tank for storing urea. The heater includes a part and an electrical heating element. The part is fixed to the electrical heating element. The electrical heating element is surrounded by a plastic sheath. The part further includes a plastic material which is fusion bonded to the plastic sheath. The plastic material of the part is overmolded on the plastic sheath.

Abstract: A method for manufacturing a hollow body, typically a tank, from a plastic material. The method includes molding a preform into shells in a molding tool; joining an insert to an inner surface of a shell of said shells, the insert defining a sub volume within the hollow body to be made; joining together the shells to form the hollow body by closing the molding tool and applying a main pressure to a main volume enclosed by the shells. It is proposed to apply a sub pressure to the sub volume while applying the main pressure to the main volume, such that a pressure difference between the main volume and the sub volume is bigger than 0.20 bar (P1??P2?>0.20 bar) and smaller than 3.00 bar (P1??P2?<3.00 bar).

Abstract: A liquid delivery module including: a base plate positioned through an opening made in a wall of a liquid tank; a pump assembly configured to pump liquid from the base plate and to deliver the liquid to a supply line, via a hydraulic connector; a cover adapted to be fixed to the base plate. The pump assembly is mounted outside the tank. The hydraulic connector is partially or entirely integrated to the cover.

Abstract: System for storing an internal combustion engine exhaust gas liquid additive, the said system comprising a tank for storing the additive and an “immersed” baseplate (1) positioned through an opening made in the bottom wall of the tank, the said baseplate comprising at least one orifice through which a system for injecting the said additive into the exhaust gases can be fed, and also incorporating at least one other active component of the storage system and/or of the injection system.

Abstract: A filling nozzle of a fuel tank including a receiving pipe and a liquid-vapor separator, includes a hollow body communicating with an intake pipe for a stream of vapors from the fuel tank, an emptying pipe flowing into the receiving pipe, and a vapor outlet pipe. The hollow body includes a separation mechanism extracting droplets and including at least one wall movable between first and second configurations. In the first configuration the movable wall forms, together with walls of the hollow body, a maze in which stream of vapors passing from the intake pipe towards the outlet pipe is forced to circulate. In the second configuration the movable wall allows the stream of vapors to pass from the intake pipe to the outlet pipe following a path that avoids all or part of the path travelled by the vapors when the movable walls are in the first configuration.

Abstract: Ammonia precursor refilling device including a container storing an ammonia precursor in solid form; the container being configured to fit within a first volume during storage and to be enlarged to a second volume which is larger than the first volume; the container being provided with an opening which is closed by an opening mechanism; the second volume being measured for allowing the container to be filled through the opening with water in an amount sufficient to allow the ammonia precursor in solid form to be at least partially dissolved to form an ammonia precursor solution.

Abstract: A method for fastening an element to a wall of a tank, the wall including at least one pin made from plastic material. The method includes: (a1) mounting the element on the pin such that a traversing part of the pin passes through the element, (a2) melting at least a portion of the traversing part and pressing on the melted portion such that the melted portion wraps freely around the pin to form a pin head configured to hold the element on the pin.

Abstract: A method is provided for loading or reloading a decomposition unit of an SCR system, the SCR system being mounted on board a vehicle and including a filler pipe in communication with the decomposition unit. The method is such that at least one capsule containing at least one protein component adapted to decompose ammonia precursor is introduced through the filler pipe and is then guided through the filler pipe towards the decomposition unit.

Abstract: A method for forming a welding spout of a plastic tank from a multilayer parison, during blowing of the parison for manufacturing the tank. The method includes, in a blowing mold including two cavities and an insert, one of the cavities delimiting a recess for forming the welding spout, the recess having a mouth opening opposite the insert: providing a push member on the insert opposite the mouth of the recess of the cavity, capable of assuming a first position set hack from the recess and a second position in which the push member occupies a portion of the mouth of the recess; positioning the push member in the first position thereof; blowing the parison to match a shape of the cavities; during creeping of the parison towards the inside of the recess, moving the push member into the second position thereof.

Abstract: A method for loading or reloading a decomposition unit of a vehicular system, the vehicular system including a filler pipe in communication with the decomposition unit. The method includes introducing at least one capsule including at least one protein component adapted to decompose ammonia precursor through the filler pipe and which is then guided through the filler pipe towards the decomposition unit.

Abstract: A housing for an ammonia-sensitive component in a selective catalytic reduction pollution-control system. This housing includes a wall and a trap configured to capture gaseous ammonia emanating from the wall or which, if it were not trapped, would emanate from the wall.

Abstract: A method for assembling a tank including: providing a first shell and a second shell; putting edges of the first and second shells into contact with each other and mutually connecting the edges; providing the first shell with a first connecting member extending inwardly from an inner surface of the first shell, the first connecting member including a hole; and after the edges of the first and second shells are put into contact with each other, connecting the first connecting member to the second shell by inserting a pin shaped element through a hole in the second shell and the hole in the first connecting member.