RU205630U1 - OIL SUBMERSIBLE CABLE - Google Patents

Abstract

The utility model relates to cable technology, namely to the structures of cables designed to supply electrical energy to submersible electric motors for oil production, water lifting and pumping liquids from pits, reservoirs and reservoirs. a polyimide-fluoroplastic film in the form of a two-layer winding and insulation made of fluorinated ethylene-propylene with a melting temperature of at least 250 ° C, a winding, a common cushion for armor and armor, characterized in that the winding is made individually for each conductive core with an overlap of at least 50% ...

Description

The utility model relates to cable technology, namely to the structures of cables designed to supply electrical energy to submersible electric motors for oil production, water lifting and pumping liquids from pits, reservoirs and reservoirs.

Known cable for installations of submersible electric pumps, containing copper conductive cores, each of which is covered with insulation from a polyimide-fluoroplastic film, and polymer insulation, a pillow under the armor, made in the form of a winding, and armor made of steel tape, characterized in that the polyimide- The fluoroplastic film is made in the form of a two-layer winding with an overlap of at least 50%, and the polymer insulation is made of fluorinated ethylene-propylene with a melting point of at least 250 ° C (Patent RU 198147, published on June 22, 2020, bull. No. 18).

The features of the known cable, which are common with the features of the claimed utility model, are that the cable contains three conductive cores twisted or laid in parallel in one plane, each of which is covered with two layers made of polyimide-fluoroplastic film winding and fluorinated ethylene insulation. propylene and also contains general armor.

The difference and disadvantage of the prototype is the use of a common winding as a cushion under the armor. The lack of an individual winding for each conductor reduces the reliability of the oil submersible cable. When working in aggressive oil and gas liquids at temperatures close to the maximum permissible, exposure to liquids leads to swelling of the insulation, its deformation and a decrease in electrical resistance.

The technical task is to improve the design and increase the reliability of the oil submersible cable.

The technical result is achieved by the fact that the oil submersible cable containing three conductive cores, each of which is covered with insulation from a polyimide-fluoroplastic film in the form of a two-layer winding and insulation from fluorinated ethylene-propylene with a melting temperature of at least 250 ° C, a winding, a common cushion under the armor and armor, characterized in that the winding is made individually for each conductive core with an overlap of at least 50%.

During the operation of oil submersible cables, due to the influence of the well fluid, the cable insulation swells, because the armor forms a closed space for insulated conductors, the insulation deforms to fill the free space. The insulation of the outer cores squeezes the middle core, and the profile of the latter acquires a square shape, and the thickness of the insulation at the points of contact of the cores wears out and decreases. This can lead to electrical breakdown of the insulation and, as a consequence, to the failure of the installation.

To solve this problem, in the proposed cable design, in addition to the general cushion under the armor, an individual winding is used over the fluoroplastic insulation layer of each conductive core, which acts as a damper during swelling or thermal expansion of insulation materials.

When the insulation swells, the damper layer deforms, while the insulation profile does not lose its shape.

Thus, the additional use of winding over the insulation of the cable cores to power the motors of submersible electric pumps will increase the reliability of cable operation, increase the service life of the insulation and the cable as a whole, and increase the overhaul period of wells by reducing the failure of oil submersible cables.

The proposed utility model is implemented as follows.

The conductive cores of the oil submersible cable are made of single-wire or multi-wire, of copper or aluminum (or aluminum alloy) wires. The conductors are covered with a two-layer insulation made of polyimide-fluoroplastic film in the form of a two-layer winding superimposed with an overlap of at least 50%. The top is insulated with fluorinated ethylene-propylene. Insulated conductors are laid in parallel. On top of the layer of insulation made of fluoroplastic, a winding made of nonwoven fabric or other equivalent material with an overlap of at least 50% is applied individually to each conductive core. A general cushion under the armor is placed on top, made of non-woven fabric or PVC tape. On top of it is applied armor made of profiled galvanized steel or corrosion-resistant stainless steel tape.

The proposed design of an oil submersible cable has been successfully tested in production conditions.

Claims (8)

1. An oil submersible cable containing three conductive cores, each of which is covered with polyimide-fluoroplastic film insulation in the form of a two-layer winding and fluorinated ethylene-propylene insulation with a melting temperature of at least 250 ° C, a winding, a common cushion for armor and armor, which is different the fact that the winding is made individually for each conductor with an overlap of at least 50%. 2. A cable according to claim 1, characterized in that the conductive cores are made of copper wire. 3. Cable according to claim 1, characterized in that the conductors are made of aluminum or aluminum alloy. 4. The cable according to claim 1, characterized in that the conductors are single-wire or multi-wire. 5. The cable according to claim 1, characterized in that the cushion for the armor is made of non-woven fabric or PVC tape. 6. Cable according to claim 1, characterized in that the armor is made of profiled galvanized steel tape or corrosion-resistant stainless tape. 7. The cable according to claim 1, characterized in that the winding along the core is made of non-woven fabric. 8. Cable according to claim 1, characterized in that the winding along the core is made of PVC tape.