RU2459135C2 - Method to restore pipelines and device for its realisation - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: method includes rolling shells in a pipeline, which form a circular gap filled with a solution. The solution during displacement along the pipeline is treated with rotary magnetic and electric fields. The device comprises a chamber, where a shell is placed. The end of the shell is bent and forms a cavity communicated with a system of fluid agent supply.

EFFECT: possibility to improve quality of a coating and reduce costs for pipeline restoration.

9 cl, 2 dwg

Description

The invention relates to construction and can be used in the construction and repair of pipelines.

A known method of coating the inner surface of the pipeline, when the coating composition is moved through the pipeline and the surface of the pipeline is coated with it, e.g. USSR No. 1041179, B22F 7/04, 1981 or WO 86/02425 A1, 04.24.1986

The disadvantage of this method is that they work well with adhesives with good fluidity. When using this method on cement-sand mixtures, their separation occurs.

Known devices for coating the inner surface of the pipeline, consisting of a fluid agent supply system, a coating mechanism, for example, EPO patent No. 0082212, class. F16L 55/16, 1981, A.S. No. 730379, cl. B05C 7/08, 1980, patent RU No. 20157465, B05C 7/08, C 1/08, 1992, and.with. USSR No. 1512682, cl. B05C 1/08, 1989, A.S. USSR No. 1445810, class B05C 1/08, 1988

The disadvantage of these devices is that they are not very effective when applying a cement-sand mixture.

The closest prototype is a method of cleaning pipelines, a method of coating pipelines and devices (options) for its implementation, RU No. 2358186 C2, class. 7 F16L 58/04.

The disadvantages of these methods and devices are the need to stop the pipeline during repair work.

Despite the excellent technical characteristics of the above methods and devices, these inventions also have a number of significant disadvantages: the complexity of the work; insufficient coating strength; high consumption of materials; low speed of work. Another significant drawback is that it is necessary to use two sleeves and the coating is applied in several passes.

The objective of the invention is to increase the strength of the coating with reduced costs. The problem is achieved by the combined use of the group of inventions.

A method of restoring pipelines, in which the coating of the inner surface of the pipeline is carried out by two shells rolling in the pipeline and their movement of a portion of the solution through the pipeline with the possibility of applying it to the inner surface of the pipeline, while during movement one of the shells is inflated with gas, while the second shell is made in the form a torus filled with a fluid agent.

This allows you to increase the speed of coating and cover the pipeline in one pass.

When moving the solution through the pipeline, it and the surface of the pipe are treated with rotating magnetic and electric fields, which allows to improve the quality of the coating and increase its speed.

The fact that during the movement of the rolling shell during rolling of the shell along the pipeline around the perimeter of the inner surface of the pipeline and the outer diameter of the shell form an annular gap, which is filled with solution.

This allows you to get a better coating with the highest speed.

The implementation of the device for coating the pipeline from the chamber in which the shell (sleeve) is placed, the end of which is bent and forms a cavity in communication with the fluid agent supply system, the shell is made of elastic material, and the diameter of the shell is equal to the diameter of the pipe covered with the solution, which makes it possible to obtain a more durable coating. And an additional supply of a ring, the thickness of which is equal to the thickness of the coating, while the shell before entering the pipeline is located in this ring (pipe), allows you to form a coating in one pass.

The fact that sources of creating magnetic and electric fields are installed inside the torus allows increasing the strength of the coating.

And the fact that a torus is installed in front of the shell and a solution is located between it and the shell in the pipeline simplifies the coating technology.

The fact that the sources of magnetic and electric fields are made of magnetic fluid, or of permanent magnets, or of permanent magnets and magnetic fluid, can increase the strength of the coating and simplify the design of the device.

And the fact that magnetic fluid fills the entire cavity of the torus, and permanent magnets are installed on the inner surface of the torus, provides a more durable coating.

The drawings show:

figure 1 - device for coating;

figure 2 - torus.

The device shown in Fig. 1 is made of a chamber 1, with a fluid agent supply system 2, in which a drive reversing drum 3 is installed with a sheath 4 wound on it and moving in a nozzle 5. The end of the sheath 4 is bent and fixed around the perimeter of the ring 6, installed in the pipe 7 of the chamber 1. The camera 1 has a check valve 8. The pipe 5 enters the pipeline 9, and its cavity 10 is in communication with the cement-sand mortar supply system 11. A torus 12 is installed in the pipeline 9. A chamber 13 is installed at the opposite end of the pipeline 9, which is in communication with the fluid agent supply system 2. The chamber 13 has a check valve 8. The thickness of the pipe 5 is equal to the thickness of the coating. The end of the sheath 4 is fastened with a flexible tie, which is wound on a drum 3 (not shown in the drawing).

The device shown in FIG. 2 is made of a torus 12 filled with magnetic fluid 14. On the inner surface of the shell of the torus 12, permanent magnets 16 are mounted on an endless ribbon 15.

The device depicted in figure 1, operates as follows.

By supplying compressed air to the chamber 13, the torus 12 is moved up to the nozzle 5. After that, the system 11 serves in the nozzle 5 a predetermined portion of the cement-sand mortar, which moves the torus 12 to the chamber 13. The valve 8 provides the preset pressure of the compressed air in the chamber 13. Excess pressure of compressed air is vented through valve 8 into the atmosphere. After feeding the entire portion of the cement-sand mortar to the pipe 5, the system 11 is turned off. System 2 supplies compressed air to chamber 1. Shell 4 begins to roll through pipe 5 and pushes cement-sand mortar into pipe 9. The solution moves the torus 12 through pipe 9. Shell 4 rolls out of pipe 5, begins to move through the compacted cement-sand mortar, and squeezes water out of it. A coating layer forms.

The torus 12 moves along the pipeline 9 and activates the surface of the pipeline 9 and cement-sand mortar by rotating magnetic and electric fields. This activation provides aggregated particles of the solution having a higher density and lower fluidity than the solution, which is outside the annular gap.

After the torus 12 enters the chamber 13, it is dismantled. Shell 4 squeeze out from the pipeline 9 the excess cement-sand mortar. The shell 4 is left in the pipeline until the cement-sand mortar has solidified, after which a flexible bond is wound with a drum, and then the shell 4. After the shell 4 exits the pipeline 9, the chamber 1 and the pipe 5 are disconnected.

The device (torus) shown in figure 2, operates as follows.

The torus 12 rolls through the pipeline 9. Permanent magnets 16 and the magnetic fluid 14 together with the torus 12 rotate, forming electric and magnetic fields that activate the surface of the pipeline 9 and cement-sand mortar.

Magnetic field treatment of water systems is one of the most controversial areas in science. Magnetic processing, widely used in various fields of industry, to date has no clear generally accepted theoretical basis. Basically, research in this direction is based on accumulated facts - the results of experiments and implementations, often difficult to reproduce, and hypotheses, sometimes contradicting each other.

During magnetic treatment of a cement-sand mortar, structural chemical bonds, which are characterized by the interaction of two or more atoms, which determine the formation of a stable polyatomic system, and are accompanied by a substantial rearrangement of the electron shells of the binding atoms, can be compared with the energy of thermal motion and order the internal structure. In this case, it is necessary to take into account the dynamics of the process, because all the electronic orbits that make up the shell continuously oscillate. For a stable and stable atomic bond to exist, a certain correlation is needed in the motion of the electrons, that is, the vibrations of the electron orbits of the interacting atoms must be synchronous. The synchronism of electron vibrations in atoms indicates the presence of a dispersion interaction between atoms. Dispersion forces are of an electromagnetic and quantum nature and are one of the varieties of intermolecular interaction, called Van der Waals forces. Dispersion forces arise as a result of vibrations of electrons of neighboring atoms or molecules in the same phase, while the mutual attraction leads to the convergence of these atoms or molecules and the formation of bonds between them.

If a magnetic field acts on two neighboring molecules that vibrate in accordance with their spectra (sets of natural frequencies), then immediately after applying the field the electronic orbits of these two particles will begin to precess with the same Larmor frequency around the parallel axes. The electronic orbits of different particles will have at least one common oscillation frequency - Larmorov. Oscillations will become partially synchronous in time and space, therefore a dispersion bond can arise between the molecules. For this, in addition, it is necessary to fulfill the condition for the equality of three frequencies: among the natural vibrations of two adjacent molecules, there must be two frequencies equal simultaneously to each other and to the Larmor frequency. Old interactions are destroyed, and numerous new ones arise, a dense network of which acts on each molecule, each atom and holds them in the framework of the new structure formed. This can explain the long-term preservation of the properties of water systems after their magnetic treatment.

It is known that the action of a magnetic field is multiextremal. With increasing magnetic field strength, the Larmor frequency, which depends on it linearly, also continuously increases. And since the spectrum of natural frequencies of molecules is not continuous, equality of three frequencies is possible only for individual values of the magnetic field strength. Hence the polyextremality.

Paradoxical is the fact of a noticeable effect of weak magnetic fields (with an intensity, for example, 10-30 kA / m ² ) on aqueous solutions and biological objects. This can be explained by the fact that the molecules of these substances, especially organic ones, are very massive, and, accordingly, the spectrum of their own vibrations is in the region of low and ultra-low frequencies. And this means that the condition of equality of the three frequencies is most likely to be realized in the region of weak values of the magnetic field strength, giving small Larmor frequencies.

This is just one of the hypotheses of the effect of magnetic and electric fields on cement-sand mortar. But experiments clearly established an increase in the density of the cement-sand mortar and the loss of its fluidity in the annular gap, since the cement-sand mortar layer is practically not extruded by the sheath 4. The thickness of this layer along the entire length of the pipeline 9 varies within 1-5% of the thickness of the cement sand solution.

EXAMPLE

Restored steel water 20 1020 mm and a length of 600 m. Work was carried out by the device depicted in figure 1. The shells and torus were made of silicone rubber 1 mm thick. Shell length - 605 m, torus length - 2 m.

The water supply was restored by applying a layer of cement-sand mortar to its inner surface with the addition of basalt fiber in an amount of 0.8% of the solution volume.

The thickness of the pipe 5 was 10 mm The outer diameter of the nozzle was 1000 mm. The inner diameter of the nozzle was 980 mm. The diameter of the shell 4 was equal to 980 mm, the diameter of the torus 12 was equal to 1000 mm.

A portion of cement-sand fiber reinforced mortar with a volume equal to the volume of the annular gap plus 0.25 m ^{3 was} pumped into the pipe 5. By supplying compressed air under a pressure of 1.0 MPa, sleeve 4 was moved to chamber 13.

After that, the chamber 13 was disconnected from the pipeline 9 and the excess cement was removed from it. After that, the chamber 13 was again connected to the pipeline 9. In chambers 1 and 13, the air pressure was increased to 1.2 MPa. Under this pressure, sleeve 4 was left in line 9 for 48 hours.

After that, the pressure in the chambers was reduced to 0.1 MPa. Chamber 13 was disconnected from pipeline 9. By rotating the drum 3, sleeve 4 was rolled out from pipeline 9. Then, pipe 5 and chamber 1 were disconnected from pipeline 9. A layer of fiber-reinforced concrete 10 mm thick with a very smooth surface was formed on the pipeline wall.

The invention allows to obtain cheaper and more durable coatings.

Claims (9)

1. A method of restoring pipelines, in which the coating of the inner surface of the pipeline is carried out by two shells rolling in the pipeline and their movement of a portion of cement-sand mortar through the pipeline with the possibility of applying it to the inner surface of the pipeline, characterized in that during the movement one of the shells is inflated with gas, the second shell is made in the form of a torus filled with a fluid agent. 2. The method according to claim 1, characterized in that while moving the solution through the pipeline, it and the surface of the pipe are treated with rotating magnetic and electric fields. 3. The method according to claim 1, characterized in that during the movement of the rolling shell during rolling of the shell along the pipeline along the perimeter of the inner surface of the pipeline and the outer diameter of the shell, an annular gap is formed which is filled with the solution. 4. A device for coating a pipeline with a cement-sand mortar, made from a chamber in which a shell (sleeve) is placed, the end of which is bent and forms a cavity in communication with a fluid agent supply system, characterized in that the shell is made of an elastic material, the diameter the shell is equal to the diameter of the pipeline coated with the solution. 5. The device according to claim 4, characterized in that it is additionally provided with a ring, the thickness of which is equal to the thickness of the coating, while the end of the shell is bent and fixed around the perimeter of the ring installed in the chamber pipe. 6. The device according to claim 4, characterized in that a torus is installed in front of the shell and a cement-sand mortar is located in the pipeline between it and the shell. 7. The device according to claim 6, characterized in that the sources of creating magnetic and electric fields are installed inside the torus. 8. The device according to claim 7, characterized in that the sources of magnetic and electric fields are made of magnetic fluid, or of permanent magnets, or of permanent magnets and magnetic fluid. 9. The device according to claim 8, characterized in that the magnetic fluid fills the entire cavity of the torus, and permanent magnets are installed on the inner surface of the torus.

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