A non-metallic cabling continuous oil pipe, relating to the technical field of oil mining in oil fields, comprises: an inner liner tube, the inner liner tube being used to form a passageway for medium transportation; from inside to outside, an outer wall of the inner liner tube being provided with a cable embedded layer and a protection sleeve in sequence thereon, the cable embedded layer including cables and a plurality of reinforcement belts, the reinforcement belts being used to resist torsional deformation and to bear an axial tension; the protection sleeve being used to prevent the cables from being worn.

A non-metallic cabling continuous oil pipe, relating to the technical field of oil mining in oil fields, comprises: an inner liner tube, the inner liner tube being used to form a passageway for medium transportation; from inside to outside, an outer wall of the inner liner tube being provided with a cable embedded layer and a protection sleeve in sequence thereon, the cable embedded layer including cables and a plurality of reinforcement belts, the reinforcement belts being used to resist torsional deformation and to bear an axial tension; the protection sleeve being used to prevent the cables from being worn.

An electric-resistance-welded stainless clad steel pipe or tube that is excellent in both the fracture property of the weld and the corrosion resistance of the pipe or tube inner surface as electric resistance welded without additional welding treatment such as weld overlaying after electric resistance welding is provided. An electric-resistance-welded stainless clad steel pipe or tube comprises: an outer layer of carbon steel or low-alloy steel; and an inner layer of austenitic stainless steel having a predetermined chemical composition, wherein a flatness value h/D in a 90 flattening test in accordance with JIS G 3445 is less than 0.3, and a pipe or tube inner surface has no crack in a sulfuric acid-copper sulfate corrosion test in accordance with ASTM A262-10, Practice E, where h is a flattening crack height (mm), and D is a pipe or tube outer diameter (mm).

An electric-resistance-welded stainless clad steel pipe or tube that is excellent in both the fracture property of the weld and the corrosion resistance of the pipe or tube inner surface as electric resistance welded without additional welding treatment such as weld overlaying after electric resistance welding is provided. An electric-resistance-welded stainless clad steel pipe or tube comprises: an outer layer of carbon steel or low-alloy steel; and an inner layer of austenitic stainless steel having a predetermined chemical composition, wherein a flatness value h/D in a 90 flattening test in accordance with JIS G 3445 is less than 0.3, and a pipe or tube inner surface has no crack in a sulfuric acid-copper sulfate corrosion test in accordance with ASTM A262-10, Practice E, where h is a flattening crack height (mm), and D is a pipe or tube outer diameter (mm).

The invention is a mold (100) of an apparatus to produce plastic pipe that consists of the body (2) that has been supported to its place, the roll like roll organs (1.1) that have been supported to the body by the roll organs (3) that have been set to move the plastic pipe axially in its production process, additionally, it consists of at least four chain organs (1) the chains (1) of each of which consist of the mentioned roll organs and joints (1.4) between them where each chain has been set to go round at least two chain wheels (1.2, 1.3) and each joint has been supported at the ends of its axis (1.6) to at least two like conductors (1.7) that have been set to conduct the mentioned circular motion of the chain and the conductors of each chain organ contain a part that is essentially in the same direction as the center axis (C) of the mold and the roll organ center axes that are in the place of these parts are in the same center line as the mold center axis and the mentioned roll organs have been set to be in contact with the inside surface or the outside surface of the plastic pipe during the production of the plastic pipe and at least one chain wheel of each chain organ has been set to be powered to rotate by motor power around its axis at such a speed and in such a direction that the roll organs that are in chain in the before mentioned position are able to move in the direction of the production of the plastic pipe at its production speed.

The invention is a mold (100) of an apparatus to produce plastic pipe that consists of the body (2) that has been supported to its place, the roll like roll organs (1.1) that have been supported to the body by the roll organs (3) that have been set to move the plastic pipe axially in its production process, additionally, it consists of at least four chain organs (1) the chains (1) of each of which consist of the mentioned roll organs and joints (1.4) between them where each chain has been set to go round at least two chain wheels (1.2, 1.3) and each joint has been supported at the ends of its axis (1.6) to at least two like conductors (1.7) that have been set to conduct the mentioned circular motion of the chain and the conductors of each chain organ contain a part that is essentially in the same direction as the center axis (C) of the mold and the roll organ center axes that are in the place of these parts are in the same center line as the mold center axis and the mentioned roll organs have been set to be in contact with the inside surface or the outside surface of the plastic pipe during the production of the plastic pipe and at least one chain wheel of each chain organ has been set to be powered to rotate by motor power around its axis at such a speed and in such a direction that the roll organs that are in chain in the before mentioned position are able to move in the direction of the production of the plastic pipe at its production speed.

Tube forming methods can be used for efficient transition in the production of tubes having varying thickness. Material used to form consecutive tubes may have the same thickness along a separation plane separating a first discrete section from a second discrete section of the material, and the first discrete section and the second discrete section may each have varying thickness in a feed direction of the material. With such a thickness profile, the first discrete section of the material may be formed into a first cylinder having varying thickness and separated from the second discrete portion as the second discrete section is formed into a second cylinder having varying thickness. In particular, the transition between the first cylinder and the second cylinder may be achieved without scrap and/or interruption, resulting in cost-savings and improvements in production throughput associated with forming tubes having varying thickness.

An electric-resistance-welded stainless clad steel pipe or tube that is excellent in both the fracture property of the weld and the corrosion resistance of the pipe or tube inner surface as electric resistance welded without additional welding treatment such as weld overlaying after electric resistance welding is provided. An electric-resistance-welded stainless clad steel pipe or tube comprises: an outer layer of carbon steel or low-alloy steel; and an inner layer of austenitic stainless steel having a predetermined chemical composition, wherein a flatness value h/D in a 90 flattening test in accordance with JIS G 3445 is less than 0.3, and a pipe or tube inner surface has no crack in a sulfuric acid-copper sulfate corrosion test in accordance with ASTM A262-10, Practice E, where h is a flattening crack height (mm), and D is a pipe or tube outer diameter (mm).

An electric-resistance-welded stainless clad steel pipe or tube that is excellent in both the fracture property of the weld and the corrosion resistance of the pipe or tube inner surface as electric resistance welded without additional welding treatment such as weld overlaying after electric resistance welding is provided. An electric-resistance-welded stainless clad steel pipe or tube comprises: an outer layer of carbon steel or low-alloy steel; and an inner layer of austenitic stainless steel having a predetermined chemical composition, wherein a flatness value h/D in a 90 flattening test in accordance with JIS G 3445 is less than 0.3, and a pipe or tube inner surface has no crack in a sulfuric acid-copper sulfate corrosion test in accordance with ASTM A262-10, Practice E, where h is a flattening crack height (mm), and D is a pipe or tube outer diameter (mm).

A thermoplastic product includes a fabric-based reinforcing sheet and a polymerized thermoplastic material. The fabric-based reinforcing sheet is wound about a mandrel to form a plurality of layers having a cross-sectional shape that corresponds to the mandrel. The fabric-based reinforcing sheet includes a plurality of fiber bundles, which may have a bidirectional orientation or configuration. A polymerized thermoplastic material is disposed within each layer of the fabric-based reinforcing sheet. The polymerized thermoplastic material bonds each layer of the fabric-based reinforcing sheet to an adjacent layer.