A high-pressure tank comprises a liner, a strengthening layer including a first helical layer and a first hoop layer each including a carbon fiber, and a protective layer including a second helical layer and a second hoop layer each including a glass fiber, in this order. The high-pressure tank is provided with a stress-generating portion, a reinforcement layer includes a first area α overlapping the stress-generating portion in a stacking direction and a second area β that is an area except for the first area, and a one-round portion including a final crossing portion at an end of winding of the glass fiber constituting the second hoop layer overlaps the second area in the stacking direction.

A high-pressure container that includes a cylinder composed of a plastic, at least one half-shell composed of a plastic, a sleeve, a valve, and a seal member. The cylinder is to serve as a central member. The at least one half-shell is arranged at one axial end of the cylinder, and includes a substantially rotationally symmetrical insert as a boss member and a foot member at the end thereof facing an interior of the high-pressure container and which is embedded in the plastic of the at least one half-shell to substantially form a hollow cone or hollow cylinder. The sleeve is arranged within an inner circumference of the foot member such that the plastic of the half-shell is arranged between the sleeve and the inner circumference of the foot member. The valve is arranged in the boss member, and includes a stem portion arranged in the sleeve. The seal member includes a ring seal forming a seal between the stem portion of the valve and the sleeve.

A high-pressure container includes a cylinder composed of plastic, at least one half-shell composed of plastic, a substantially rotationally symmetrical insert as a boss member, and a sleeve. The cylinder is to serve as a centre member, while the at least one half-shell is at an axial end of the cylinder. The insert as a boss member, the insert having a foot member at an end thereof facing the container interior. The foot member is embedded in the plastic of the half-shell to substantially form a hollow cone or hollow cylinder. The sleeve is pressed into the inner circumference of the foot member at least in a pressing portion of the sleeve. The plastic of the half-shell is arranged between the sleeve and an inner circumference of the foot member so that in a pressing portion, a thin plastic layer of the plastic of the half-shell is pressed between the sleeve and the inner circumference of the foot member.

The present disclosure provides systems and methods for producing a hydrogen storage vessel that is lightweight. The hydrogen storage vessel may comprise an inner body and an outer body structured as concentric rings with a conic interface. The vessel may have four material layers, including a barrier layer, an insulation layer, a fiber knit, and an abrasion layer. The fiber knit may be braided to trap the hydrogen, as the barrier layer may not be completely impermeable. Additionally, the fiber braid may be clamped to the outer body, enabling pressure pushing on the inner body to wedge and seal the storage vessel.

A high-pressure tank that enables end portions of a first reinforcing layer wound around a body of a liner to sufficiently contribute to the strength of dome portions of the tank. In the high-pressure tank, a reinforcing layer includes the first reinforcing layer that covers the body and a second reinforcing layer that covers the first reinforcing layer and side end portions of the liner. The first reinforcing layer includes a hoop reinforcing layer formed through hoop winding of a resin-containing fiber bundle in a midsection of the body, and a helical reinforcing layer arranged in parallel with the hoop reinforcing layer along the axis direction of the high-pressure tank and formed through helical winding of the fiber bundle in a section on at least one end side of the midsection, the helical reinforcing layer forming a part of the dome portions.

A composite pressure vessel that includes a monolayer liner and a reinforcing structure arranged on top of the liner. The liner is made by injection moulding and includes at least two shells weldable together. Each shell is made of a polymer composition including at least 45% by weight of an aromatic polyamide relative to the total weight of the polymer composition, and at least 10% by weight of an aliphatic polyamide relative to the total weight of the polymer composition.

The present disclosure provides a pressure vessel 10 (sometimes known as a composite overwrapped pressure vessel or “COPV”) comprising carbon fiber 20 (such as carbon fiber 20 filaments) wrapped around a tank liner 30.

The present invention is a pressure tank comprising a tubular part and two bottoms (5) with the bottoms (5) positioned at the ends of the tubular part. The tubular part comprises a cylindrical wall (1) and a ply of circumferential reinforcing elements (2) wound around cylindrical wall (1). The elastic modulus of the material of cylindrical wall (1) is less than the elastic modulus of the material of the first ply of circumferential reinforcing elements (2). The invention also relates to an energy storage and recovery system comprising a compressor, an expansion device, a heat storage and a compressed air tank according to the aforementioned characteristics.

A pressure vessel includes a liner including a cylinder part and side parts provided at both ends of the cylinder part, each side part having a dome shape, and a carbon fiber layer including a first hoop layer surrounding a part of an outer circumferential surface of the cylinder part and second hoop layers surrounding other parts of the outer circumferential surface of the cylinder part, each of the second hoop layers having a thickness different from a thickness of the first hoop layer.

An embodiment pressure vessel includes a liner including a cylinder part and dome-shaped side parts at both ends of the cylinder part, and a carbon fiber layer including a first hoop layer surrounding a part of an outer circumferential surface of the cylinder part, and second hoop layers surrounding remaining parts of the outer circumferential surface of the cylinder part, each of the second hoop layers having a thickness that gradually decreases in a direction from the cylinder part to a respective one of the side parts.