RU2553742C1 - Method of protective corrosion resistant coating application on external and internal surface of metal pipe - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: preliminary external and internal calibration of pipe edges is performed for type of pipes connection. Then accessories are installed on both pipe edges, using them the pipe is rotated, upon the external surface protecting against external contacts, then hydrodynamic cleaning of the internal and external pipe surfaces are cleaned. The thermal cleaning of the specified pipe surfaces is performed in the furnace at temperature 390-420°C, then are held for one hour, then heated pipe is subjected to the mechanical cleaning by the abrasive out of the furnace ensuring specified roughness of the pipe surfaces. To the external and internal pipe surfaces the primer layer is applied with further drying at room temperature, at that the pipe using the accessories is rotated, then the pipe is heated in the furnace to temperature of the powder layer of the corrosion-resistant coating application, and the mentioned coating is applied simultaneously on the external and internal pipe surfaces. Then the layer polymerisation of the mentioned coating is performed by the pipe heating in the furnace, that is rotated, and further cooling by water/air mixture is performed.

EFFECT: reliable and long-time protective coating due to increased corrosion resistance of pipes, by increased quality of cleaning of the pipe surfaces and coating application to the pipe surfaces.

Description

The invention relates to the field of protection of metals from corrosion and can be used when applying a corrosion-resistant protective coating to pipes, rolled metal, made of steel and alloys.

The well-known "Method of applying an insulating coating to a metal surface" (RF patent No. 2289061, F16L 58/00, publ. 2006.12.10), in which the metal surface of the pipeline is heated, the primer is applied, then the metal surface is additionally heated to a temperature of 40-50 ° C and applying an insulating polymer tape coating with pre-heating the adhesive layer of the tape to a temperature of 55-65 ° C with hot air. The resulting insulating coating is heated to heat shrink.

The disadvantage of this method is the possible formation of "tent" zones on the weld bead and, as a result, local air voids under the coating, which provides air and moisture access to the pipeline surface and the development of corrosion phenomena, which, in turn, reduces the reliability and durability of the products .

The closest technical solution adopted for the prototype is the "Method of comprehensive protection against corrosion of steel pipelines (options)" (RF patent No. 2296817, C23F 17/00, publ. 2007.04.10). In the proposed method, the pipe edges are cut before insulation, then the pipe is dried and cleaned of contaminants: the pipe inner surface is mechanically treated, the pipe inner surface is finished cleaned, the main metal protective coating is applied near the pipe edge, an additional metal protective coating is applied to the main metal coating with partial overlapping the main metal protective coating, heat the pipe to the melting temperature of the insulating plastic coating, on osyat on the inner tube surface with a partial overlap of the base layer metallic protective coating at least one layer of an insulating plastic coating, machined surface of the outer tube, the outer surface of the pipe is purified by treatment of products, applying at least one layer of an insulating plastic covering.

The disadvantages of this method include:

- increased technological complexity and complexity;

- high costs for applying additional protective layers and inefficient use of protective material;

- receiving at the output an uneven, low-quality protective coating, the service life of which is reduced by several times, due to the fact that before coating was not provided for cleaning the pipe surfaces from oil inclusions, which contributes to the destruction of the protective coating, forming a film between the pipe surface and the protective coating, and cleaning from salt deposits and other corrosive environments, which contributes to intense corrosion of the surface of the pipe (s) when interacting with water, forming an acidic environment, leading her to emergency destruction of steel pipelines, to reduce the reliability and durability of pipes.

The present invention is aimed at eliminating the disadvantages inherent in analogues and prototype, and is a consequence of such a search.

The object of the invention is to increase the reliability and durability of pipes, by increasing the corrosion resistance of pipes, by improving the quality of cleaning of pipe surfaces and coating on the pipe surface.

The technical result from the use of the claimed invention is the creation of a reliable and durable protective coating, by increasing the corrosion resistance of pipes, by improving the quality of cleaning of pipe surfaces and coating on the pipe surface.

The technical result is achieved by the fact that in the method of applying a protective corrosion-resistant coating to the outer and inner surfaces of a metal pipe, including preliminary preparation of its edges, mechanical, thermal and abrasive cleaning of the outer and inner surfaces of the pipe, subsequent application of a powder layer of a corrosion-resistant coating to the outer and the inner surface of the pipe, according to which the outer and inner edges of the pipe are pre-calibrated to match the pipe connection, then set on both edges of the pipe snap, with which the pipe is rotated, while maintaining the outer surface from external contacts, then hydrodynamic cleaning of the inner and outer surfaces of the pipe is carried out, and thermal cleaning of these pipe surfaces is carried out in an oven at a temperature of 390-420 ° C, withstand one hour, and then the heated pipe is subjected to mechanical cleaning with an abrasive outside the furnace with a given roughness to the surfaces of the pipe, on the outer and inner surfaces of which a layer of aimer with its subsequent drying at room temperature, while the pipe is rotated using snap-ins, after which the pipe is heated in the furnace to the temperature of applying a powder layer of a corrosion-resistant coating and the specified layer is applied simultaneously to the outer and inner surfaces of the pipe, then the polymerization of the layer of said coating by heating the pipe in a rotated furnace, and then cooling it with a water-air mixture.

The novelty of this invention are:

- a certain sequence of technological processes that allows you to qualitatively clean the surface of the pipe and evenly apply a protective coating to the cleaned surfaces,

- the manufacture and installation of special snap-fittings on the edges of the pipes, allowing the pipe to rotate, with the possibility of maintaining the outer surface from external contacts, and also to apply a uniform coating on the surface of the pipes.

The implementation of the method

Initially, after the incoming pipe inspection, both edges of the pipe are calibrated for known types of connection with a special device using a calibrator. After calibration, geometric parameters are checked.

Further, in the factory, special equipment is made and installed on both pipe edges on the outer surface, designed:

- to transmit rotational movement of the pipe during cleaning, heating and applying a protective coating on the outer and inner surfaces of the pipe;

- to save the outer surface from external contacts (i.e., the movement of the pipe along the chain conveyor occurs due to special accessories installed on both edges of the pipe on the outer surface, which, in turn, are installed on the guides of the chain conveyor).

Special accessories are made of heat-resistant steel, type alloy 20X23H18, have a clamping device for installation on pipe edges. Special equipment installed on the edges of the pipes does not impede access to the inner surface of the pipe, as it has openings designed for access of hydrodynamic cleaning devices, mechanical cleaning devices for applying a primer layer and a layer (s) of protective coatings to the inner surface of the pipe.

Then produce hydrodynamic cleaning of the outer and inner surfaces of the pipe. At the same time, salt deposits, loose rust and other corrosive substances are destroyed, crushed and removed by high-pressure jets of water formed through the use of special nozzle nozzles. Hydrodynamic cleaning is carried out by high-pressure jets of a working fluid without heating and / or with chemical additives of surfactants (surfactants).

After surface treatment with surfactants, the pipe surfaces become chemically active, which improves the intermolecular bond between the pipe surface and the protective coating.

Next, perform thermal cleaning (degreasing) in the furnace at a temperature of 390-420 ° C. The pipes are heated to a temperature of 390 ° C, allowing to remove all types of grease from the surface, and to a temperature of 420 ° C, while avoiding structural changes in the metal of the pipe, and kept at this temperature for about one hour to evaporate the remaining liquid with surfactants , grease contaminants and other substances that reduce the adhesive strength between the pipe surfaces and the applied protective coating. During an exposure of about one hour, from the outer and inner surfaces of the pipe, water (surfactant) used in the hydrodynamic cleaning of the pipe surfaces, various types of grease and other substances that reduce the adhesive strength between the pipe surfaces and the applied protective coating are removed (evaporated).

During thermal cleaning of the pipe surfaces, the outer surface of the pipe is kept from external contacts, using special snap-fittings installed on both pipe edges, and the pipe is rotationally moved using these snap-on devices installed on both pipe edges. Based on this, the process of jet-abrasive cleaning (mechanical cleaning) of the pipe surfaces becomes better and more uniform over the entire surface area of the pipe.

After thermal cleaning of the pipe surfaces, the heated outer and inner surfaces of the pipe are subjected to mechanical (jet-abrasive) cleaning using one of the known methods (for example, according to RF patent No. 2353506, where the surface after mechanical (jet-abrasive) cleaning (by shot or sand, etc.) ) it turns out matte, developed, which is very important for the further application of the protective coating, the roughness parameters vary depending on the processing conditions and the granularity of the working material (abrasive). the pipe diameter for a given process is Rz = 40 ... 90 microns.

Adhesive strength - the force required to break the adhesive joint, referred to the area of the adhesive contact [N / m ² ] (Bogdanov Yu.G. “Adhesion and its role in ensuring the strength of polymer composites”, 2010). With a rough surface of the pipe, the surface area of the pipe increases significantly, which contributes to an increase in the adhesive strength between the pipe surface and the applied protective coating.

In the case of shot blasting, hardening of the pipe surfaces occurs simultaneously. Hardness on pipes increases by 20-40%, in the surface layer residual compressive stresses reach 400-800 MPa.

In the case of thermoabrasive cleaning, simultaneous cleaning, degreasing, dedusting, creating the required roughness, heating and activation of the pipe surfaces occurs. After cleaning, the surface of the pipe becomes uniformly rough, degreased, heated to 50-60 ° C and chemically active. Such surface properties provide a high degree of adhesion to the protective coating applied to it.

The method of thermal abrasive cleaning is based on the principle of simultaneous thermal and intense impact-abrasive impact on the treated surface with a two-component supersonic high-temperature jet, consisting of a gas stream of combustion products and particles of abrasive material. Abrasive particles are fed into the flow of a supersonic gas jet generated by the apparatus, accelerated to supersonic speed and, together with the combustion products, bombard the treated surface.

By subjecting the heated outer and inner surfaces of the pipe to mechanical cleaning (jet-abrasive), rust, strongly bonded oxides and other substances are removed from the surfaces, which reduce the adhesive strength between the pipe surfaces and the applied protective coating.

During mechanical cleaning (jet-abrasive) of the pipe surfaces, the outer surface of the pipe is protected from external contacts by means of special snap-fittings installed on both pipe edges, and the pipe is rotated using special snap-fit devices installed on both pipe edges. Based on this, the process of jet-abrasive cleaning of pipe surfaces becomes better and more uniform over the entire surface area of the pipe.

After mechanical cleaning (jet-abrasive) the surface of the pipe is cleaned of abrasive (fractions), fine particles and dust and the roughness of the surfaces of the pipe is controlled.

Next, on the cleaned and rough outer and inner surfaces of the pipe, a primer layer is applied by spraying, using one of the known methods. During application (spraying) of the primer layer, the outer surface of the pipe is kept from external contacts, using special snap-fittings installed on both edges of the pipe, and the pipe is rotated, using special snap-on devices installed on both edges of the pipe. Based on this, the process of applying (spraying) the primer layer on the surface of the pipe becomes more high-quality and uniform over the entire surface area of the pipe.

Then, the primer layer deposited on the outer and inner surfaces of the pipe is dried at room temperature, and the thickness of the applied primer layer is controlled. During drying of the primer layer, the outer surface of the pipe is kept away from external contacts by means of special snap-fittings installed on both pipe edges, and the pipe is rotated using special snap-fit devices installed on both pipe edges. Based on this, the process of coating formation (primer) becomes better and more uniform over the entire surface area of the pipe.

Next, the pipe is heated to a predetermined temperature for applying a protective coating, for subsequent application on the outer and inner surfaces of the pipe layer (s) of the protective coating. During heating of the pipe, the outer surface of the pipe is kept from external contacts, using special snap-fittings installed on both edges of the pipe, and the pipe is rotated, using special snap-on devices installed on both edges of the pipe. Based on this, the process of heating the pipe becomes better and more uniform over the entire surface area of the pipe. Then check the temperature of the heated pipe to meet the requirements of applying a protective coating.

Then, on the outer and inner surfaces of the pipe, where there is already a primer layer, the protective coating layer (s) is applied using one of the known methods, for example, using an electrostatic powder coating method. At the same time, during the application (spraying) of the protective coating layer (s) on the pipe surface, the outer surface of the pipe is kept from external contacts, using special snap-fittings installed on both pipe edges, and the pipe is rotated, using special snap-ins, mounted on both edges of the pipe. Based on this, the process of applying (spraying) the layer (s) of the protective coating becomes more high-quality and uniform over the entire surface area of the pipe.

Next, polymerization of the layer (s) of the protective coating deposited on the primer layer on the outer and inner surfaces of the pipe is carried out by heating the pipe in the furnace to a predetermined temperature required for the applied protective coating of the material. During the polymerization of the protective coating layer (s), the outer surface of the pipe is protected from external contacts by means of special snap-fittings installed on both pipe edges, and the pipe is rotated using special snap-fit devices installed on both pipe edges. Based on this, the process of forming a protective coating becomes better and more uniform over the entire surface area of the pipe.

Then the pipes with a protective coating are cooled, for example, with a cold water-air mixture, in order to quickly reduce the temperature of the applied protective coating and pipes.

Next, they control the dielectric continuity and thickness of the applied protective coating by one of the known methods (for example, RF patent No. 2188414).

Then, bandages are installed on the outer coating of the steel pipe to prevent the outer coating from contacting with other surfaces capable of causing a defect in the outer coating during transportation of the protective coating pipe, from a material, such as rubber, using its elastic properties to prevent a defect in the outer protective coating during transportation pipes with a protective coating.

The advantages of the proposed method in comparison with known analogues

The proposed method of applying a protective coating of pipes in comparison with analogues:

1. Increases the reliability and durability of the applied protective coating on the outer and inner surfaces of the pipe, by monitoring the stages of cleaning and applying protective coatings on the pipe surface, by increasing the corrosion resistance of the outer and inner surface of the pipe, due to:

1.1. Removal from the external and internal surfaces of the pipe of all fatty types of contaminants, rust, strongly bonded oxides, which reduce the adhesive strength between the pipe surface and the protective coating, salt deposits and other corrosive environments that increase the corrosion activity on the pipe surfaces;

1.2. Application of a primer layer on the rough pipe surface, while increasing the adhesive strength between the pipe surface and the protective coating, by increasing the pipe surface area;

2. Increases the effectiveness of the protective material due to the fact that the protective material is applied electrostatically to the outer and inner surfaces of the pipe and rotational movement is imparted to the pipes during spraying, that is, the used volume of the protective material is evenly distributed over the entire surface area to be coated, which helps to save the protective material ;

3. Eliminates the use of expensive materials as additional layers of protective coating;

4. Reduces technological complexity and laboriousness, as it eliminates the processes of applying additional layers of a protective coating to the surface (for example, a metal coating);

5. Applies protective coatings to different types of pipes, the edges of which are calibrated for known types of joints, which makes the method more technological.

The positive aspects of this method are a high degree of reliability, effectiveness of the protective material, control of the steps performed, the simplicity of the technology of surface cleaning and coating.

Claims (1)

The method of applying a protective corrosion-resistant coating on the outer and inner surfaces of a metal pipe, including the preliminary preparation of its edges, mechanical, thermal and abrasive cleaning of the outer and inner surfaces of the pipe, the subsequent application of a powder layer of a corrosion-resistant coating on the outer and inner surfaces of the pipe, characterized in that previously the outer and inner edges of the pipe are calibrated to the type of pipe connection, then they are installed on both edges of the snap pipe using a cat They rotate the pipe when storing the outer surface from the effects of external contacts, then hydrodynamically clean the inner and outer surfaces of the pipe, and heat the indicated surfaces of the pipes in an oven at 390-420 ° C, hold for one hour, and then heat the pipe mechanical cleaning with an abrasive outside the furnace with a given roughness to the surfaces of the pipe, on the outer and inner surfaces of which a primer layer is applied, followed by drying at room temperature temperature, while the pipe with the help of snap-in is rotated, after which the pipe is heated in the furnace to the temperature of applying a powder layer of a corrosion-resistant coating and the specified layer is applied simultaneously to the outer and inner surfaces of the pipe, then the layer of said coating is polymerized by heating the pipe in the furnace, which rotate, and carry out subsequent cooling with a water-air mixture.