A sender gauge adaptor includes an adaptor body pressed against a bottom wall of a fuel tank by a spring. The adaptor body includes a suction inlet part having a hollow cylindrical shape that opens downward. Recesses allowing fluid communication between the interior and the exterior of the suction inlet part and projection parts having a polygonal-shaped lower surfaces are alternately arranged in the circumferential direction along a lower end of the suction opening. The adaptor body includes a seat part in surface contact with the bottom wall of the fuel tank at a position below the lower surfaces of the projection parts.

The invention relates mainly to a fuel tank (10) that can be adapted to several types of motor vehicle engines, comprising: —a casing (11) defining a fuel filling space, —a fuel filler pipe (12), and —a gauge/pump module (13), characterized in that the casing (11) has a shape that is suitable for covering different types of gasoline and diesel engines, and in that the casing (11) comprises passages (15) for routing and holding pipes and/or wiring harnesses, the passages (15) formed in advance in the casing (11) being capable of covering routes for pipes and/or wiring harnesses of different types of gasoline and diesel engines, such that some passages (15) used for the pipes and/or wiring harnesses of a given engine are present for an engine of another type but not used.

A method for producing a compressed gas tank for a motor vehicle includes inserting a bundle of heat-conducting elements through an opening in a housing of the compressed gas tank and exerting a force on the bundle that radially expands the bundle within the housing beyond the size of the opening. The heat-conducting elements may be helically wound about a central axis when inserted through the opening with a torsional force applied to unwind the elements while radially expanding and reducing axial length of the bundle. A compressed gas tank for a motor vehicle includes a plurality of heat-conducting elements including at least one tube within a tank housing that extend axially along the tank and radially within the housing to a size exceeding an opening of the housing. The tube is configured to circulate coolant to cool compressed gas within the tank.

A vehicle mounted fuel filler pocket and hingedly attachable door assembly, having a housing with an upper rim edge defining a pocket shaped body to which is communicated a fuel filler tube. A door overlays the upper rim edge in a closed position. A hinge bracket secures to an underside location of the door at a first end, the hinge bracket having a widthwise extending pin at a second end which is pivotally supported within circular capture recesses defined in a subset area of the pocket shaped body to permit the door to be pivoted from the upper rim edge to an open position. A detent cam mechanism is provided for biasing the door at each of the closed and open positions.

The invention relates to a polyamide composition comprising: a. A semi-crystalline polyamide; b. An impact modifier in an amount ranging from 1 wt % to 50 wt %; c. A branching agent in an amount ranging from 0.01 to 6.0 wt %; d. An inorganic stabilizer in an amount ranging from 0.01 wt % to 2.0 wt %; e. An organic stabilizer E1 comprising a primary antioxidant group in an amount ranging from 0.01 wt % to 2.0 wt and an organic stabilizer E2 comprising a hindered amine group in an amount ranging from 0.01 wt % to 4.0 wt %; or an organic stabilizer E3 comprising a primary antioxidant group and a hindered amine group in an amount ranging from 0.02 to 6.0 wt %; or a combination of E1, E2 and E3 in a total amount of 0.02 to 6.0 wt %; wherein all wt % are based on the total amount of polyamide composition. The invention also relates to a process for preparing a container by blow molding this composition, as well as use of the container in various applications.

A method for forming a dome used in a launch vehicle includes cutting a disk from a plate, the disk having a first disk diameter. The method also includes forming a bend in the disk, the bend applying a curvature to at least a portion of the disk, the disk having a second disk diameter after the forming. The method further includes performing a first heat-treating process to the disk. The method also includes performing a second heat-treating process to the disk. The method further includes machining the disk to remove at least a portion of a thickness of the disk.

A partially annulated flexible tubular structure located at least partially inside the fuel tank, of a vehicle, the structure being capable of being at least partially submerged in the tank and being intended for transporting the fuel into the tank, the tubular structure including at least one layer (1) including a composition including: a. between 39% and 100% by weight, in particular between 41% and 100% by weight, of at least one aliphatic polyamide of formula W/Z, b. between 0% and 4% by weight, and preferably between 0 and 2%, of at least one plasticizer, c. between 0% and 20% of at least one impact modifier, d. between 0% and 37% by weight of at least one additive, the sum of a.+b.+c.+d. being equal to 100% of the total weight of the composition, excluding a fuel transport structure running from the tank to the motor of the vehicle.

The disclosure relates to a fuel tank including a tank wall which has at least two wall sections opposite one another and a stiffening device situated between the two opposite wall sections. The disclosure further relates to a method for manufacturing such a fuel tank. According to the invention, it is provided that the stiffening device includes at least one connecting strut, each end of which has a profile section, which engages with one complementary profile section each on the two opposite wall sections of the container wall in a tension-resistant manner in such a way that the connecting strut absorbs compressive forces acting on the container wall. The method according to the disclosure for manufacturing a fuel tank including a stiffening device of the aforementioned type is characterized by the following steps: shaping the tank from a thermoplastic material in a blow mold, at least two coupling sections being created on opposite wall sections and an opening being created in one of the wall sections; removing the container from the blow mold; manual or mechanical insertion of at least one connecting strut via the opening into an interior of the container, the ends of at least one connecting strut each including a profile section, which may be coupled to one of the coupling sections of the wall sections in a tension-resistant manner; and manual or mechanical coupling of the profile sections of the connecting strut to the coupling sections of the wall sections.

A fuel tank for a motor vehicle, a method for producing the fuel tank, and a single-track motor vehicle including the fuel tank, where the fuel tank includes at least two parts that are joined together where the parts delimit a receiving chamber for receiving a fuel. At least one of the two parts is produced by a co-injection moulding process.

The present disclosure relates to a fuel tank including a tank wall which has at least two wall sections opposite one another and a stiffening device situated between the two opposite wall sections, and a method for manufacturing such a fuel tank. According to the present disclosure, it is provided that the stiffening device includes at least one connecting strut, each end of which has a profile section, which engages with one complementary profile section each on the two opposite wall sections of the container wall in a tension-resistant manner in such a way that the connecting strut absorbs compressive forces acting on the container wall.