Collapsible containers are an attractive alternative to surface-tension propellant management devices (PMDs) for handling cryogenic liquids, as the collapsible container comparatively may 1) allow higher expulsion flow rates than vanes and sponges, 2) significantly reduce operational complexity, and 3) thermally insulate the propellant from environmental heat leaks. Furthermore, while historical cryogenic collapsible containers suffered from the low ductility of polymer films at cryogenic temperatures, the technology disclosed herein shows that the incorporation of folded patterns into the collapsible container substantially increases the reusability of the cryogenic PMD.

A pressure vessel includes a vessel body, a first rib and a second rib. The vessel body includes a first surface and a second surface. The first rib projects in a second direction from the first surface and extends in a first direction. The second rib provided in series with the first rib, projects in the first direction from the second surface, and extends in the second direction. A width in the second direction of the internal space is smaller than a width in the first direction of the internal space. A maximum value of a projection amount of the second rib from the second surface to the outside of the vessel body in the first direction is smaller than the maximum value of a projection amount of the first rib from the first surface to the outside of the vessel body in the second direction.

A method for making a container for retaining anesthetic agent. The method includes creating two or more parts each having a mating surface, where the container is formed when the mating surfaces of the two or more parts are coupled together, and where a first part of the two or more parts is formed of a material having pores defined within the mating surface thereof. The method further includes processing the mating surface of the first part via friction stir welding to reduce the pores defined therein. The method further includes coupling the two or more parts together such that the mating surfaces contact to create the container configured to retain the anesthetic agent therein.

A pressurized gas containment liner includes a first part comprising a first shell with a first peripheral edge, and a second part comprising a second shell with a second peripheral edge. The first peripheral edge is rigidly connected to the second peripheral edge, and the first shell and the second shell delimit between them an interior volume. The first part comprises at least one pillar that passes through the interior volume, is formed integrally with the first shell, and is elongated between a proximal end, connected to the first shell, and a distal end, rigidly connected to the second part. A transverse section of the pillar decreases from the proximal end to the distal end.

Provided is a tank that can improve the adhesion between a mouthpiece and a liner. The tank includes: a liner; and a mouthpiece disposed at an opening part of the liner, the mouthpiece having a hole, wherein the liner has an inner face part that is a part extending around an inner face of the hole of the mouthpiece from an opening part of the hole of the mouthpiece, and an outer face part that is a part extending around an outer face of the mouthpiece from the opening part of the hole of the mouthpiece, and at an end part of the inner face part, crystallinity of the liner distributes in a dispersing state but not in a form of layer.

Provided is a tank that can lead to suppressed corrosion on a mouthpiece. The tank includes: a liner; and a mouthpiece disposed in an opening part of the liner, wherein a surface of the mouthpiece is aluminum, an anodized layer is provided over the surface of the mouthpiece, the anodized layer is partially a sealing part where a sealing layer is formed, and a rest of the anodized layer is partially a non-sealing part where the sealing layer is not formed, and the liner is disposed so as to straddle a boundary between the sealing part and the non-sealing part.

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.

A high-pressure gas container (100) includes an inner layer (11) configured such that high-pressure gas is filled inside, a boss part (13-1, 13-2) provided at least at one position of the inner layer and configured to cause the gas to flow in and out, and an outer layer (12) configured to cover an outer periphery of the inner layer to reinforce the inner layer and having a higher gas barrier property than the inner layer. A gas discharge port (15-1, 15-2) is provided between the boss part and the outer layer, and a gas ventilation part (14) is formed between the inner layer and the outer layer such that the gas having permeated through the inner layer is discharged into atmosphere through the gas discharge port.

A pressure vessel is disclosed. The pressure vessel may include a boss, a liner, an O-ring, and a composite overwrap of shell. A boss may comprise a through aperture, a first groove encircling the through aperture, and a first engagement mechanism. A liner may comprise an interior surface, exterior surface, and a second engagement mechanism. The interior surface may define an interior cavity of the pressure vessel. The second engagement mechanism may mechanically engage the first engagement mechanism to secure the liner to the boss. An O-ring may be positioned within the first groove of the boss and abut the exterior surface of the liner. A composite overwrap may surround the liner and at least a portion of the boss.

Provided a multi-layered pressurized gas container, for example one containing carbon dioxide for use in a device or system for the preparation of a carbonated drink, and processes for its manufacture.