RU190074U1 - ELECTRICAL CABLE - Google Patents

Abstract

The utility model relates to cable technology and can be used to power submersible electrical systems, mainly electric motors of submersible oil pumps when extracting oil from wells with high gas factors. The technical result, which this utility model aims to achieve, is to increase the service life of the cable, by increasing its reliability, due to a significant improvement in the mechanical characteristics of the insulation during high-speed cable rises after a long stay in the well at depths d about 3000 meters with the temperature of the reservoir fluid from 90 to 250 °. The indicated technical result is achieved by the fact that the electric cable containing three isolated from each other copper conductor 1, parallel in the same plane, covered with a protective cushion 5 of nonwoven material and steel armor 6. The insulation of the core 1 is made in the form of a film coating 2 comprising a polyimide on which a thermoplastic sheath is applied 3. According to the utility model, between the film coating 2 deposited on the copper core 1 and the thermoplastic An additional covering 4 made of basalt yarns with a nominal linear density of 54 to 140 tex and with an average diameter of the elementary fiber of 8-13 microns is placed in the primary shell 3. Moreover, this technical result is achieved in that the coating 4 of basalt yarns can be made in the form of a woven mesh sheath with a packing density of 5 to 240 threads per cm. In addition, this technical result is achieved in that the coating 4 of basalt threads can be made in the form of threads laid along a conductor stranded conductor at a distance of 0.5 to 3 mm from each other. In addition, this technical result is achieved by the fact that the thermoplastic casing is made of two layers, with a coating of basalt threads placed between the layers. , by increasing its reliability, due to a significant improvement in the mechanical characteristics of the insulation during high-speed cable rises after a long stay in the well at depths of up to 3000 meters with temperature Second fluid reservoir 90 to 250 °.

Description

The utility model relates to cable technology and can be used to power submersible electrical systems, mainly electric motors of submersible oil pumps when extracting oil from wells with high gas factor

The performance of cables of electric motors of submersible oil pumps is influenced by many factors, including:

- high temperatures, often leading to melting of cable insulation;

- aggressive effect on cable insulation of a downhole fluid consisting of a mixture of oil, water, salts and acids;

- gas dissolved in the polymer under high pressure, which, when rising from a well, may expanding to destroy the polymer sheath of the cable.

Known electrical cable to power the electric motor of submersible electric pumps containing insulated conductors and sheath of thermoplastic elastomer, located on each core and / or common on all together, and the insulation of the cores is made of oxygen-free radiation-modified high density polyethylene through the thermoplastic elastomer. The location of the thermoplastic elastomer shell on each core and / or all together, according to the authors, allows oxygen-free radiation modification of high-density polyethylene to be carried out, because after coating a thermoplastic elastoplast with insulation of conducting conductors, air access to the insulation is excluded , 2006).

The main disadvantage of the prototype is the low life of the cable, especially in wells with a high content of water and acids in the downhole fluid at temperatures from 100 ° C and above. In wells with marked operation features, cases of complete destruction of the thermoplastic elastomer shell were noted. This is explained by the fact that the shell, protecting the surface of the insulation of the conductive core from oxygen during radiation modification, itself undergoes a deep radiation-oxidative destruction from the outside. As a result of radiolysis under the action of ionizing radiation, abundantly formed hydroxyl groups are combined with the molecular structure of the shell material, thus increasing its hydrophilicity. In wells, the process of diffusion of fluid into the cable jacket was so intense that in some cases it led to a loss of its structural integrity.

Another disadvantage of the known cable is the poor adhesion between the insulation and sheath materials due to differences in their molecular structure. Poor adhesion leads to the formation of cavities between the insulation and the shell. In these cavities there is also oxygen in the air and irradiation of the cable with poor adhesion between the insulation materials and the sheath, strictly speaking, is not oxygen-free. In these places, the cable insulation is oxidized. During operation, these cavities are filled with a downhole fluid, which speeds up the process of cable destruction.

In addition, the cable with insulated conductors in a common sheath of thermoplastic elastomer contains air-filled cavities in areas close to the contact points of the insulated cores, where the viscous melt of the thermoplastic elastomer is not able to penetrate during extrusion.

In addition, since the depth of oil production increases every year and increases the pressure and temperature inside the well, in the process of oil production, the gas dissolved under high pressure diffuses into the polymer material and saturates it. When the pump is lifted from the well, the dissolved gas begins to exit the thermoplastic and rushes to the zone of minimum pressure, i.e. into the gap between the polyimide coating of the conductor and the thermoplastic cable sheath. The volume of gas is so large that it does not have time to come to the surface and the developing pressure in the gap leads to the destruction of the shell of the core.

This cable has a low life for the above reasons.

The closest in technical essence and the achieved result is an electric cable containing three insulated copper conductor wires arranged parallel in the same plane, covered with a protective cushion of nonwoven material and steel armor, the insulation of the cores is made in the form of a film coating including polyimide, on which applied thermoplastic shell (RU, patent No. 2302049, CL HB 7/08, 2007).

The disadvantages of the known electric cable is that, since the depth of oil production increases every year and increases pressure and temperature inside the well, in the process of oil production, the gas dissolved under high pressure diffuses into the polymer material and saturates it. When the pump is lifted from the well, the dissolved gas begins to exit the thermoplastic and rushes to the zone of minimum pressure, i.e. into the gap between the polyimide coating of the conductor and the thermoplastic cable sheath. The volume of gas is so large that it does not have time to come to the surface and the developing pressure in the gap leads to the destruction of the shell of the core.

The technical result on the achievement of which this utility model is aimed is to increase the service life of the cable, by increasing its reliability, by significantly improving the mechanical characteristics of the insulation during high-speed cable lifts after a long stay in the well at depths of up to 3000 meters with a temperature of formation fluid from 90 to 250 °

This technical result is achieved by the fact that in an electric cable containing three isolated from each other copper conductive wires located parallel in the same plane, covered with a protective cushion of nonwoven material and steel armor, and the insulation of the wires is made in the form of a film coating including polyimide, on which according to the utility model, a thermoplastic casing is applied between the film coating deposited on the copper core and the thermoplastic casing an additional coating is placed, made and with basalt filaments with a nominal linear density of 54 to 140 tex and with an average diameter of elementary fiber of 8-13 microns.

In addition, this technical result is achieved by the fact that the coating of basalt filaments can be made in the form of a woven mesh shell with a packing density of from 5 to 240 filaments per cm ² .

In addition, this technical result is achieved by the fact that the coating of basalt filaments can be made in the form of filaments laid along the conductor at a distance of 0.5 to 3 mm from each other.

In addition, this technical result is achieved by the fact that the thermoplastic shell is made of two-layer, while the coating of basalt filaments is placed between the layers.

The application of a mesh of basalt filament with a nominal linear density of 54 to 140 tex and an average filament diameter of 8–13 μm makes it possible to form a conductor for the gas to reach the surface. Basalt fibers are not wetted with fluoroplastic and the space along the primary threads is free to move a large volume of gas.

Since the basalt thread does not become impregnated with the melt when the sheath is applied (due to the high viscosity of the polymer), during high-speed cable lifting it acts as a gas conductor.

The design of the electrical cable is illustrated by drawings, where:

in fig. 1 shows a general view of an electrical cable;

in fig. 2 shows a variant of applying a basalt thread on a conductive wire (basalt thread weaving);

in fig. 3 - a variant of the longitudinal laying of basalt threads;

FIG. 4 is a variant of a two-layer thermoplastic shell.

The electric cable contains three conductor conductors 1 insulated from each other; the core insulation includes polyimide or polyimide-fluoroplastic coating film coating 2 coated with thermoplastic sheath 3, between film coating 2 deposited on copper conductor and thermoplastic sheath 3 there is an additional coating 4 made from basalt threads with a nominal linear density of from 54 to 140 tex and with an average diameter of elementary fiber of 8-13 microns. Insulated conductors are covered with a protective cushion 5 of non-woven material and steel armor 6.

The coating 4 of basalt threads can be made in the form of a woven mesh sheath with a packing density of from 5 to 240 threads per cm ² (Fig. 2).

The coating of basalt filaments can be made in the form of filaments laid along the conductor at a distance of 0.5 to 3 mm from each other (Fig. 3).

Thermoplastic sheath 3 is made of a two-layer (7.8), with a coating of basalt filaments 4 placed between the layers (Fig. 4).

Submersible cable is used to supply power to the oil-immersion pumps. The depth of oil production increases every year and the pressure and temperature inside the well increase.

In the process of oil production, the gas dissolved under high pressure diffuses into the polymer material and saturates it. When the pump is lifted from the well, the dissolved gas is released from the thermoplastic and rushes to the zone of minimum pressure, i.e. into the gap between the polyamide coating 2 of the conductive core 1 and the thermoplastic sheath 3 of the cable. The volume of gas is so large that it does not have time to come to the surface and the developing pressure in the gap leads to the destruction of the shell of the core.

The application of basalt filament 4 allows you to form a conductor for the gas to the surface. Basalt fibers are not wetted with fluoroplastic and the space along the elementary fibers is free to move a large volume of gas.

The most effective coating made of basalt filaments with a nominal linear density of from 54 to 140 Tex and with an average diameter of the elementary fiber of 8-13 microns.

The coating of basalt filaments can be made in the form of a woven mesh sheath with a packing density of 5 to 240 filaments per cm ² , or in the form of filaments laid along the conductor at a distance of 0.5 to 3 mm from each other.

Thus, the use of the proposed technical solution will increase the service life of an electric cable, by increasing its reliability, by significantly improving the mechanical characteristics of the insulation during high-speed cable lifts after a long stay in the well at depths of up to 3000 meters with a temperature of formation fluid from 90 to 250 °.

Claims (4)

1. Electric cable containing three insulated copper conductors arranged parallel in one plane, covered with a protective cushion of nonwoven material and steel armor, the insulation of the cores is made in the form of a film coating comprising a polyimide on which a thermoplastic sheath is applied, characterized by that between the film coating deposited on the copper conductor and the thermoplastic sheath there is an additional coating made of basalt filaments with a nominal linear density of 54 to 140 tex and with an average diameter of elementary fiber of 8-13 microns. 2. Electrical cable according to claim 1, characterized in that the coating of basalt filaments is made in the form of a woven mesh sheath with a packing density of from 5 to 240 filaments per cm2. 3. Electrical cable according to claim 1, characterized in that the coating of basalt filaments is made in the form of filaments laid along the conductor at a distance of 0.5 to 3 mm from each other. 4. Electrical cable according to claim 1, characterized in that the thermoplastic sheath is made of two-layer, with a coating of basalt filaments placed between the layers.

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