A modular pressure vessel suitable for housing, storage, and/or supplying a pressurized fluid is disclosed. In one aspect, the modular pressure vessel comprises removable end-caps attached to each end of a center section. The center section includes longitudinal rails. In another aspect, methods for manufacturing the modular pressure vessel are described, including extrusion processes for the center section. The modular pressure vessel allows for various components to be easily swapped out or changed, such as the end-caps, or components easily installed and removed from inside the pressure vessel, such as a compressor and related components.

Reinforcement layers are each formed in a belt shape set with a smaller width than a diameter dimension of a container body. Each reinforcement layer has its length direction along an axial direction of the container body and spans between one axial direction side end and another axial direction side end of the container body, including at caps. Moreover, the reinforcement layers span across the caps and the container body at locations other than maximum diameter portions, these being locations where the diameter dimensions of the cap and the container body are greatest in a direction orthogonal to a direction of adjacency of the container body with other container bodies as viewed along the axial direction.

A composite vessel assembly includes a circumferentially continuous wall and an end cap. The wall includes a plurality of layers, and the end cap includes a plurality of steps. Each step of the plurality of steps is engaged to a respective layer of the plurality of layers.

A sealed and thermally insulated tank for storage of a fluid, having a plurality of multilayer walls. A first of the walls has a secondary thermally insulating barrier including a first insulating panel along the intersection between the load-bearing structure of first wall and the load-bearing structure of an adjacent second wall. A second insulating panel is juxtaposed with the first insulating panel along one edge of the first panel opposing the second wall. The first wall has a secondary sealing membrane including a first corrugated metal sheet welded to a small metal plate of the first insulating panel; and a second corrugated metal sheet welded to the small metal plate of the second insulating panel. The first metal sheet and the second metal sheet are welded together via a joggled edge permitting the first and the second metal sheets to be lap welded to one another.

A method for producing a stabilizer composition for a polymer, particularly a polymer containing halogen such as polyvinyl chloride, in which components for forming the stabilizer composition are mixed in an extruder and continuously discharged therefrom, in which an impact modifier is admixed. A correspondingly produced stabilizer composition and the use of a planetary roller extruder to produce a stabilizer composition.

A tank has a generally prismatic shape, and is capable of containing a pressurized gas. The tank comprises a composite shell, which has fibrous reinforcements and a matrix extending continuously over the six faces of the prism and delimits a sealed internal cavity comprising a plurality of open cells. The tank comprises continuous fibrous reinforcements extending into and bonded to the composite shell and further extending through the internal cavity between two opposite faces of the tank. The tank is advantageously integrated into the floor of a vehicle, in particular to the structure of an aircraft.

The invention relates to a tank valve (4) for installation at a pressure gas tank (3), having a base body (5), including a first base body section (5.1), which in the assembled state projects into the pressure gas tank (3) and is sealingly connected with the same, and which includes a second base body section (5.2), which in the assembled state remains outside the pressure gas tank (3), further having a plurality of functional sub-groups (9, 11, 12, 13, 14, 16, 17, 22, 23, 26, 27) for refueling the pressure gas tank (3) via a refueling path, for the extraction of gas from the pressure gas tank (3) via an extraction path and for implementing safety and operating functions, at least some of the functional sub-groups (9, 11, 12, 13, 14, 16, 17, 22, 23, 26, 27) at least partially being disposed in the base body (5). The tank valve according to the present invention is characterized by the fact that in the first base body section (5.1) or on the side facing the interior of the pressure gas tank (3) functional sub-groups (13, 22, 23, 26, 27) are disposed at the first base body section (5.1).

The invention relates to a tank valve (4) for installation on a compressed gas container (3), having a base body (5), having a shared gas connection (16) for refueling/extraction, which is divided inside the base body (5) into a refueling line (24) and an extraction line (25) as part of an extraction path, and having an extraction valve (9) in the extraction line (25). The tank valve according to the invention is characterized in that a check valve (26) is arranged in the extraction path in series with the extraction valve (9), blocking the flow against the flow direction (A) when gas is extracted.

A pressure vessel includes: a barrel part disposed in a predefined square area and having a diameter corresponding to a length of one side of the square area; a first nozzle member disposed at one end of the barrel part; a second nozzle member disposed at an opposite end of the barrel part; and clamp rings disposed in the square area, positioned outside the barrel part, and configured to lock the first and second nozzle members to the barrel part, thereby improving spatial utilization and a degree of design freedom.

A structural component with at least two side members has a support structure that includes a partition with multiple curved portions forming cells. The partition connects to the side members and extends between the side members at least partially along straight lines. The partition may extend along one or more straight lines from one side member to the other. One structural component is a container with a wall about the internal support structure. The container cells may be formed with a core structure. The core can include a permeable storage material and may be retained after formation, or may be removed. In some cases the container wall has generally planar surfaces, which may include surface undulations. Core structures are also provided for forming structural components. Formation can include casting a material about a core structure within a mold to form a partition extending between two or more sides.