Spoolable composite pipes for oil and gas flowlines may include an inner extruded tubular liner, a reinforcement layer surrounding the inner extruded tubular liner, and an outer extruded tubular cover surrounding the reinforcement layer. In these spoolable composite pipes, the inner extruded tubular liner may include an aliphatic polyketone. Internally lined pipes for oil and gas flowlines for oil and gas flowlines may include inner extruded tubular liner containing an aliphatic polyketone, and a carbon steel pipe surrounding the inner extruded tubular liner. The spoolable composite pipes and the internally lined pipes may be configured to operate at temperatures of up to about 110° C., and to carry hydrocarbons having an aromatic content of up to about 35% by volume of the total hydrocarbons content.

Various fittings capable of preventing distortion are disclosed. The fitting comprises a metal member configured to have at least two sub metal members and a body. Here, the sub metal members are included in the body, and the body is formed of plastic.

A bioinert pipe includes a flow path inside, an inner wall of the flow path is composed of a resin tube and an outer peripheral surface of the resin tube is covered with a metal tube. The bioinert pipe includes an end portion extension member attached to an end portion of the metal tube, and the end portion extension member is made from a material harder than the resin tube and has a first surface and a second surface. The first surface is facing and in contact with an end surface of the metal tube and the second surface is directed opposite to the first surface. a through hole having an inner diameter substantially the same as an inner diameter of the metal tube is provided so as to pass from the first surface to the second surface in the end portion extension member. An edge of the through hole on the second surface of the end portion extension member has a chamfered shape, and the resin tube is inserted into the through hole. An end portion of the resin tube forms a flange portion by being by being bent outward in a radial direction of the flow path along the chamfered shape of the edge of the through hole.

A bioinert pipe includes a flow path inside, an inner wall of the flow path is composed of a resin tube and an outer peripheral surface of the resin tube is covered with a metal tube. The bioinert pipe includes an end portion extension member attached to an end portion of the metal tube, and the end portion extension member is made from a material harder than the resin tube and has a first surface and a second surface. The first surface is facing and in contact with an end surface of the metal tube and the second surface is directed opposite to the first surface. a through hole having an inner diameter substantially the same as an inner diameter of the metal tube is provided so as to pass from the first surface to the second surface in the end portion extension member. An edge of the through hole on the second surface of the end portion extension member has a chamfered shape, and the resin tube is inserted into the through hole. An end portion of the resin tube forms a flange portion by being by being bent outward in a radial direction of the flow path along the chamfered shape of the edge of the through hole.

An improved pipe liner and associated methods, including a method of manufacturing the improved pipe liner and a method of lining a host pipe with such a pipe liner. The invention solves the problem of gas permeation through a polymer liner in hydrocarbon service which can result in corrosion of the host pipe and can also cause liner collapse. Corrosion occurs due to contact between corrosive species and the host pipe itself. Gases (307) can also accumulate in an annulus between or within the liner (305) and the host pipe (303) and expand during operational de-pressurisation of the pipeline, causing collapse of the liner. The improved pipe liner comprises a barrier layer (311), which prevents permeation through the liner, surrounding an inner polymer pipe (305A) and optionally covered by an outer polymer pipe (305B). The inner polymer pipe is porous which permits free movement of gas between the internal bore (302) of a lined pipe and the barrier layer, so as to prevent accumulation of gases anywhere in the lined pipe, while ensuring that gases do not permeate to, and damage, the host pipe. The liner can be inserted using Swagelining, roll-down, or any other suitable close-fit lining techniques, without compromising the effectiveness of the barrier layer.

An improved pipe liner and associated methods, including a method of manufacturing the improved pipe liner and a method of lining a host pipe with such a pipe liner. The invention solves the problem of gas permeation through a polymer liner in hydrocarbon service which can result in corrosion of the host pipe and can also cause liner collapse. Corrosion occurs due to contact between corrosive species and the host pipe itself. Gases (307) can also accumulate in an annulus between or within the liner (305) and the host pipe (303) and expand during operational de-pressurisation of the pipeline, causing collapse of the liner. The improved pipe liner comprises a barrier layer (311), which prevents permeation through the liner, surrounding an inner polymer pipe (305A) and optionally covered by an outer polymer pipe (305B). The inner polymer pipe is porous which permits free movement of gas between the internal bore (302) of a lined pipe and the barrier layer, so as to prevent accumulation of gases anywhere in the lined pipe, while ensuring that gases do not permeate to, and damage, the host pipe. The liner can be inserted using Swagelining, roll-down, or any other suitable close-fit lining techniques, without compromising the effectiveness of the barrier layer.

A system and method for a process to prepare piping such that it has a reduced chance of having biological organisms developing or growing within it by means of the addition of a metal structure to at least a portion of the inner wall of the piping. The system utilizes a limited amount of metal on or close to the inside wall of the piping to retard or suppress the growth of biological organisms within the piping. The limited amount of metal inside the pipe does not materially interfere with the structural aspects or performance of the pipe, nor does it significantly increasing the material costs of the pipe, while providing a unique and novel improved anti-biologic organism performance. The system is suitable for residential or commercial use.

A system and method for a process to prepare piping such that it has a reduced chance of having biological organisms developing or growing within it by means of the addition of a metal structure to at least a portion of the inner wall of the piping. The system utilizes a limited amount of metal on or close to the inside wall of the piping to retard or suppress the growth of biological organisms within the piping. The limited amount of metal inside the pipe does not materially interfere with the structural aspects or performance of the pipe, nor does it significantly increasing the material costs of the pipe, while providing a unique and novel improved anti-biologic organism performance. The system is suitable for residential or commercial use.

A bioinert piping (1) that has a flow path (2) provided inside and a main body portion (10) between end portions (8, 8) includes a resin tube (4) that forms an inner wall of the flow path (2) over an entire length of the flow path (2), and a metal tube (6) that accommodates the resin tube (4) inside so as to cover the outer peripheral surface of the resin tube (4) over at least an entire length of the main body portion (10). The metal tube (6) is plastically deformed toward an inner side so that the outer peripheral surface of the resin tube (4) and an inner peripheral surface of the metal tube (6) are in liquid-tight contact with each other.

One aspect of the invention provides a composite refrigeration line set including at least one selected from the group consisting of: a suction line and a return line, characterized in that one or more of the suction line and the return line are a composite refrigeration line set tube include: an inner plastic tube; a first adhesive layer positioned about the inner plastic tube; an aluminum layer positioned about the first adhesive layer and coupled to the inner plastic tube via the first adhesive layer; a second adhesive layer positioned about the aluminum layer; and an outer plastic layer positioned about the aluminum layer coupled to the aluminum layer via the second adhesive layer. The inner plastic tube is polyethylene of raised temperature. The outer plastic tube is polyethylene of raised temperature. The aluminum layer comprises AL 3005-O.