RU33257U1 - CABLE LINE AND HEATING CABLE - Google Patents

Description

CABLE LINE AND HEATING CABLE

The useful model refers to the oil industry and can be used as equipment for oil and gas wells for powering submersible pumps and at the same time for track heating of a highly viscous oil and gas mixture of wells equipped with sucker rod pumps, submersible electric pumps to reduce the viscosity of the produced fluid and eliminate paraffin-hydrate plugs in the wells with a high gas factor. The device can also be used to prevent freezing of water pipes in hazardous areas of oilfield equipment, in water injection systems, oil and gas transport, etc.

Known cable line, designed to power submersible pumps and at the same time for track heating of a highly viscous oil and gas mixture in a well, consisting of a low-temperature (power) cable and a high-temperature (heating) cable having different electrical resistance. Low-temperature and heating cables contain conductive conductors insulated by a heat-resistant sheath. The conductive conductors of the heating cable from one end are connected in pairs with the conductors of the low-temperature cable by an integral connection, for which a metal sleeve is installed at the junction of each pair, which is crimped from the outside. The free ends of the low-temperature cable are designed to be connected to a power source, and the free

the ends of the conductive conductors of the nafeway cable are interconnected, for example, in a "star for the formation of a closed electrical circuit. Outside, insulated conductive conductors are sequentially stacked with a common insulating form-forming shell, armor cushion and armor. The insulation and sealing of the end of the heating cable in the cable line at the junction of the conductive conductors is performed as follows: on the ends of the conductive conductors inserted into a metal sleeve on both sides (towards each other), at least one core of which is bent by 180 ° and inserted into a metal sleeve towards the other cores, laid sequentially with overlapping on both sides on the surface of the insulating heat-resistant shells of the conductive conductors of at least two insulating layers, on which a heat-shrinkable tube was laid on top of which a protective metal casing was installed with overlapping armor (see utility model certificate No. 14474, room H 01 B 7/18, dated March 23, 2000)

A disadvantage of the known cable line is its low operational reliability in borehole conditions due to unreliable insulation at the junction of conductive conductors: in areas of intergrowth of a low-temperature cable with a heating cable, and even more so at the end of the heating cable, where conductive conductors are connected between themselves to form a closed electrical circuit. The inability to provide sealing of the cable line for its operation in borehole conditions: in an aggressive environment, at high pressure, etc., leads to the ingress of borehole fluid and gas into existing cavities inside the cable: between conductive conductors and their insulation, between the insulation shells of the conductors inside the common forming shell in the cavity

end section. As a result, an electrical breakdown of the cable and its failure.

This is explained by the following.

1. The protective casing of the junction of the cores at the end of the cable line is not able to protect the internal insulation from the ingress of the well fluid, since under high pressure the cavity under the guard is freely filled with the well fluid, since Cable armor is not hydraulic protection.

2. In the bend zone of the conductive core by 180 ° with an extremely small radius of curvature, the insulation coating of the bent core is unacceptably deformed and weakened, which leads to insulation failure primarily in this weakened place.

3. In multi-wire cores, it is impossible to ensure full fit (without air cavities) of the insulating heat-resistant sheath. As a result, free air space is formed between the wires of the core inside the insulating heat-resistant sheath, which facilitates the penetration of hydrogen ions, then gas and well fluid, into these cavities under conditions of a large pressure drop. There is a destruction of insulation in the zone of its extension, electrochemical corrosion of conductive conductors, and, consequently, electrical breakdown and violation of the continuity of insulation along the length of the cable line.

4. Does not provide complete sealing of the end section and heat shrink tube; during heat shrinkage of this tube, a channel appears between adjacent cylindrical surfaces of insulating heat-resistant shells of conductive conductors.

5. The permanent connection of the low-temperature cable and the heating cable with metal sleeves pressed tightly at the cable connection prevents air from flowing out of the cavities of the heating cable with multi-wire cores when

the descent of the cable line into the well, which creates a risk of breakdown of isolation in the splice.

Thus, the known cable line at the junction of conductive conductors does not have reliable insulation.

A heating cable is known for traveling electric heating of a highly viscous oil and gas mixture of wells equipped with sucker rod pumps, submersible electric pumps to reduce the viscosity of the produced fluid, to eliminate paraffin-hydrate plugs in wells with a high gas factor, containing conductive cores insulated with a heat-resistant sheath, each of which is made stranded, laid on top of conductive wires in series

- a general insulating forming shell,

- a pillow under armor and armor,

- in this case, the conductive wires from one end are free to connect to a power source,

conductive conductors at the free end are interconnected to form a closed electrical circuit

-and isolated, (see, for example, RF patent 2186943, class E 21 B 36/04, dated 03/27/2000).

This device, for the reasons stated earlier in the description of the cable line, also has low operational reliability due to the high probability of breakdown at the end of the cable, where the insulation of conductive wires connected to each other is unreliable.

Inspection and analysis of failed cable lines and heating cables showed that in 100% of cases failure occurred as a result of electrical breakdown due to the penetration of well fluid into the cavity of the cable conductors and its movement along the cable.

The proposed utility models solve the problem of eliminating electrical breakdown of the cable at the junction of conductive conductors when placing the cable in borehole conditions by ensuring tightness of the insulation of the end section of the heating cable from liquid and gas penetration and by ensuring free air exit from the cavities of the heating cable along the entire cable length at his descent into the well.

To obtain such a technical result in the proposed cable line, including a low-temperature cable and a heating cable, consisting of conductive conductors insulated by a heat-resistant sheath, having different electrical resistance, while the conductive conductors of the nafeway cable are multi-wire and are connected in pairs with one end of the low-temperature cable core by an integral connection by means of a metal sleeve, and the conductive wires of the free end of the heating cable are connected They are interconnected to form a closed electrical circuit and are isolated, while a common insulating shape is sequentially laid on insulated conductive wires of the cable line along its entire length) A sheath, a cushion for armor and armor are offered on the inner surface of a metal sleeve for permanent connection of a low-temperature cable and heating cable to make longitudinal non-through grooves, in each conductive core of the heating cable in the zone of connection of the cores to each other to form mknutoy circuit free air space between the wire strands within the insulating heat-resistant casing filled with the end face of said shell insulating plugging material to a depth greater than the distance to the end of the common insulating molding shell, and the insulation of conductors in place of their connection to each other at the end of the heating cable, run in

in the form of a solid tip, made at the end portion of the heating cable in a mold under pressure, with the insulating layer of the tip symmetrically relative to the conductive conductors and overlapping the common insulating forming shell of the cable line, while the material for the insulating heat-resistant sheath of the core, for a solid tip and to isolate the space between the wires in the core inside the insulating heat-resistant sheath, choose the same one.

Advantageously, with insulating material for conductive conductors, for a solid tip and for isolating the space between the wires in the core within the insulating heat-resistant jacket, polypropylene or a block copolymer composition of propylene with ethylene can be selected.

The insulation of conductive conductors interconnected at the end of the heating cable can be made in the form of a solid tip made on the end section of the heating cable in a mold under pressure, and an additional protective casing with perforated walls mounted on top of it, the perforated holes of which are filled in the execution process of the specified tip of the insulating material of the tip.

The permanent connection of the low-temperature cable and the heating cable can be made in two layers: first, a copper cylindrical braid is laid, then a copper sleeve.

To achieve the named technical result in a heating cable containing insulated heat-resistant sheath

conductive conductors, each of which is multi-wire, laid sequentially on top of conductive conductors with a common insulating forming shell, a pillow for armor and armor, while conductive conductors from one end are free for

connections to the power source, and at the free end are interconnected to form a closed electrical circuit and isolated, it is proposed in each conductive core in the zone of connection of the wires between each other to form a closed electrical circuit the space between the conductive core and the insulating heat-resistant shell to be filled from the end of the specified shell with an insulating cementing material to a depth exceeding the distance to the end face of the general insulating forming shell, and the insulation of conductive conductors in place their connections at the end of the heating cable, in the form of a solid tip made on the end portion of the heating cable in a mold under pressure, with the insulating layer of the tip symmetrically relative to the conductive cores and overlapping the common forming shell of the heating cable, while the material for insulating heat-resistant sheath of the core, for a solid tip and for isolating the space between the wires in the core inside the insulating heat-resistant sheath glasses choose the same one.

Advantageously, with insulating material for conductive conductors, for a solid tip and for isolating the space between the wires in the core within the insulating heat-resistant jacket, polypropylene or a block copolymer composition of propylene with ethylene can be selected.

The insulation of conductive conductors interconnected at the end of the heating cable can be made in the form of a solid tip made on the end section of the heating cable in a mold under pressure, and an additional protective casing with perforated walls mounted on top of it, the perforated holes of which are filled in the process

the execution of the specified tip of the insulating material of the tip.

Due to the fact that the insulation of the end section of the heating cable is made on conductive conductors laid in one plane and without 180 ° kinks, and sections of conductors with a stretched and compressed insulating heat-resistant sheath that are mechanically weakened and are punched electrically under pressure of the formation fluid are excluded. electrically equally reliable insulation of all conductive conductors at the place of their connection.

Due to the fact that the free air space between the wires of the core inside the insulating heat-resistant sheath is filled from the end of the specified sheath with insulating grouting material, the possibility of gas and liquid being pushed through the cable and the cable damage and its failure due to a short circuit are completely eliminated.

Insulation of the end portion of the heating cable in the form of a continuous insulating tip, filled into the junction of the cores under pressure in a mold; it has a mold with an overlap on the mold; the sheath of the cable completely eliminates the air cavities surrounding the conductive wires that can freely fill the borehole liquid under high pressure through the armor of the cable and thereby eliminate the subsequent forcing of liquid and gas through the cable through mechanically weakened sections of heat-resistant oh shell curved veins.

Insulation of the conductive conductors and the end portion of the heating cable from the same insulating material makes it possible to apply insulation to the conductors evenly, and also to prevent the formation of free air cavities in a continuous insulation layer and thereby ensure good electrical and mechanical properties of the insulation.

The implementation of the protective casing with perforated walls provides the ability to jointly fill the insulating tip and the casing with insulating material, which ensures a strong connection between the casing and the tip. Installing a cover over the lug gives the cable end piece extra protection.

Due to the fact that the channels (in the form of longitudinal grooves or in the form of a braid layer) are made in the one-piece connection of the conductive conductors of the low-temperature and heating cables, unhindered passage of gas at the junction of the low-temperature and heating cables to the surface of the cable cavities along its entire length is ensured, which excludes electrical breakdown in this place.

The proposed constructions of the cable line and heating cable have high reliability of hydraulic sealing and electrical isolation of the junction of conductive conductors, which eliminates electrical breakdown at the junction of the conductors, and thereby ensure high operational reliability of the cable.

The essence of the utility model is illustrated by the drawing, where in FIG. 1 shows an end portion of a heating cable; in FIG. 2 - cable line in the area of intergrowths of low-temperature and heating cables; in Fig.3 - section of a conductive core, view A of Fig.1; in FIG. 4 section of the knot splices veins, view B of FIG. 2,

The cable line consists of low temperature 1 and heating 2 cables, each of which consists of conductive cores 3 and 4 (respectively), each of which is insulated with a heat-resistant sheath 5, cores 4 of heating cable 2 are multi-wire, steel, and have a higher electrical resistance, than the wires 3 of the low temperature cable 1, which are made, for example, copper, conductive wires 3 and 4 of the low temperature 1 and heating 2 cables are connected in pairs

by means of a copper sleeve 6, due to which the connection of cores 3 and 4 is made integral. On the inner surface of the copper sleeve 6, longitudinal non-through grooves are made 7. The permanent connection of cores 3 and 4 can be made two-layer: first, a copper cylindrical braid is laid, on top of it is a copper sleeve 6.

A common insulating forming shell 8, a cushion for armor, for example, a non-woven fabric, and armor 9, for example, of galvanized steel tape, are sequentially laid on insulated conductive conductors 3 and 4 of the cable line along its entire length sequentially. The cable line or heating cable is flat or with a convex-concave outer surface.

Conducting cores 3 on the free end of the low-temperature cable 1 are free to connect to a power source, and the cores 4 of the free end of the heating cable 2 are interconnected, for example, in a "star to form a closed electrical circuit. For this, the ends of the conductive conductors 4 freed from the insulating heat-resistant shell 5 are inserted into a metal sleeve 10 and crimped. In each core 4 from the end 11, the free air space between the wires 12 of the core 4 inside the heat-resistant sheath 5 is filled with insulating cement material 13 to a depth not exceeding the distance to the end of the general forming sheath 8 (of the order of 10-15 mm), thereby compressing each core 4 from the end of the insulating sheath 5 to eliminate air gaps between the wires 12 in the core 4.

The insulation of the interconnected conductive conductors 4 at the end portion of the heating cable 2 is made in the form of a solid tip 14, poured onto the junction of the conductors 4 in a mold under pressure, the insulating layer of the tip 14 being symmetrically with respect to the conductive conductors and overlapping the common mold insulating sheath 8.

The insulation material for the heat-resistant sheath 5, the material 13 for plugging the space between the wires 12 inside the sheath 5 and the tip material 14 are used the same, for example, polypropylene or a block copolymer composition of propylene with ethylene.

To increase the protective properties of the end section of the heating cable 2, a protective casing 15 with perforated walls is installed over the insulating solid tip 14, the perforation holes 16 of which are filled during the formation of the solid tip 14 in the mold under pressure with the insulating material of the tip 14.

Installation of a cable line or heating cable is carried out in workshop conditions on the cable section, and the device is intended for use only after conducting workshop tests for electrical breakdown in a water-salt chamber.

When operating a cable line or heating cable in a well, a cable of the required length (exceeding the depth of paraffin deposition in the pipes) is attached with clamps to the outer surface of the pump-compressor pipes. The ends of the low temperature cable are connected on the surface to a power source. The device is ready to work as a heater for the track heating of the well fluid.

March 20, 2003

Claims (7)

1. A cable line including a low-temperature cable and a heating cable, consisting of conductive conductors insulated by a heat-resistant sheath, having different electrical resistance, while the conductive conductors of the heating cable are multi-wire and are connected in pairs with the conductors of the low-temperature cable in one piece by a metal sleeve, and from the free end of the heating cable, the conductive wires are interconnected to form a closed electrical They are insulated and insulated, while on the insulated conductive wires of the cable line along its entire length a common insulating forming shell, an armor cushion and armor are successively laid, characterized in that longitudinal non-through grooves are made on the inner surface of the metal sleeve for the integral connection of the low-temperature cable and the heating cable , in each conductive core of the heating cable in the zone of connection of the wires to each other to form a closed electrical circuit the space between the wires of the core inside the insulating heat-resistant sheath is filled from the end of the specified sheath with insulating cement material to a depth greater than the distance to the end of the general insulating forming sheath, and the insulation of the conductive wires at the junction of each other at the end of the heating cable is made in the form of a solid tip made at the end of the heating cable in the mold under pressure, the insulating layer of the tip is located symmetrically with respect to the conductive conductors and overlapping the common insulating formative sheath of the cable line, the same material is chosen for the insulating heat-resistant sheath of the core, for the solid tip and for isolating the space between the wires in the core inside the insulating heat-resistant sheath. 2. The cable line according to claim 1, characterized in that the insulating material for conductive conductors, for a solid tip and for isolating the space between the wires in the core inside the insulating heat-resistant sheath is polypropylene or a block copolymer composition of propylene with ethylene. 3. The cable line according to claims 1 and 2, characterized in that the insulation of the conductive conductors interconnected at the end of the heating cable is made in the form of a solid tip made on the end portion of the heating cable in a mold under pressure, and additionally installed on top of it a protective casing with perforated walls, the perforations of which are filled during the execution of the specified tip of the insulating material of the tip. 4. The cable line according to claim 1, characterized in that the one-piece connection of the low-temperature cable and the heating cable is made in two layers: first, a copper cylindrical braid is laid, then a copper sleeve. 5. A heating cable containing conductive conductors insulated by a heat-resistant sheath, each of which is multi-wire, laid sequentially on top of the conductive conductors with a common insulating formative sheath, a cushion under armor and armor, while the conductive conductors are free from one end to connect to a power source, and on the free end of the conductive conductors are interconnected to form a closed electrical circuit and isolated, characterized in that in each conductive core in the zone connecting the cores to form a closed electrical circuit, the space between the conductive core and the insulating heat-resistant sheath is filled from the end of the specified shell with insulating cement material to a depth exceeding the distance to the end of the general insulating forming sheath, and the insulation of the conductive conductors in the place of their connection at the end of the heating cable, made in the form of a solid tip, made at the end portion of the heating cable in a mold under pressure , Wherein the insulating layer of the tip is located symmetrically with respect to the conductive cores and with an overlap on the total the forming shell of the heating cable, the material for insulating heat resistant shell core for the continuous tip for isolation space between the wires in the core within the insulating heat-resistant envelope is selected the same. 6. The heating cable according to claim 5, characterized in that the insulating material for conductive conductors, for a solid tip and for isolating the space between the wires in the core inside the insulating heat-resistant sheath is polypropylene or a block copolymer composition of propylene with ethylene. 7. The heating cable according to claims 5 and 6, characterized in that the insulation of the conductive conductors interconnected at the end of the heating cable is made in the form of a solid tip made on the end portion of the heating cable in a mold under pressure, and additionally installed on top of it a protective casing with perforated walls, the perforations of which are filled during the execution of the specified tip of the insulating material of the tip.