RU66843U1 - CABLE LINE - Google Patents

Abstract

The utility model relates to the field of the oil industry, in particular, to cable technology. The technical task of the utility model is to simplify the design and increase the reliability of the cable line. The cable line of the claimed utility model contains three insulated conductive conductors, each of which has an insulating sheath, inside which are bimetallic strands made continuous, of equal length corresponding to the length of the core, and evenly twisted together along the entire length. In this case, one part of the threads is made of metal with high conductivity, the other part of the threads of metal with low conductivity. Copper or aluminum may be selected as the metal with high conductivity, and steel may be selected as the metal with low conductivity. The cable line armor laid on a pillow and connecting the cores to each other is formative, so that the formed convex-concave or flat surfaces make it possible to form a cable line with a single armor geometry, both along the length of the cable line and along its cross section, with uniform mechanical properties, which increases the strength and bearing capacity of the cable line, and hence the reliability of the cable line.

Description

The utility model relates to the field of the oil industry, in particular, to cable technology, and can be used as well equipment for track heating of a highly viscous oil and gas mixture of wells equipped with sucker rod pumps, submersible pumps to prevent freezing of water pipes in hazardous areas of oilfield equipment, and also asphalt-resin-paraffin deposits in wells with a high gas factor, as well as in water injection systems, oil and gas transport.

The practice of operating oil wells has shown that the main cause of asphalt-resin-paraffin deposits in oil and gas wells is the directional cooling of the produced fluid. Of all types of combating these complications, the most universal and effective means today is to compensate for heat losses in the well by electric heating with heating cable lines. The experience with braided armored heating cables has proven successful. The advantage of this method of maintaining and cleaning wells is that the producing company does not need to maintain sufficiently expensive equipment, staff for its operation, and conduct staff training on its balance sheet.

The heating cable line is designed for the path heating of fluid along the trunk of production and injection wells in order to prevent asphalt-resin-paraffin deposits.

It is known that an armored power cable, for example, is used as a heating cable line. ESP Kppbp 3 × 16 or armored heating cable, for example, KNPpBP 3 × 8. The use of a heating cable line with such a cable on the complicated well stock of fields ensures uninterrupted operation of the wells for no more than 1 year.

A well-known geophysical cable with a core of seven multiwire conductive conductors, with an insulating winding made of polyethylene tetraflate tape applied to each core as a pillow under the common frame is armor made of round steel wires (see A. Malyshev et al. “Use of heating cables for warning paraffin hydrate formation in oil wells. ”Oil Industry, 1990, No. 6, p. 58-60).

The disadvantage of a geophysical cable with a core is the complex cable construction, which is why it is ineffective to use it to prevent the formation of asphalt-resin-paraffin deposits in oil and gas wells, especially in cases of high paraffin fractions in oil.

It is known “Device for preventing the formation and elimination of hydrated and paraffin formations in the lifting pipes of oil and gas wells” (patent No. 2272893, RU, priority date 05/28/2004, patent holder of PermNIPIneft Limited Liability Company). The device contains a heat radiator connected to a source of thermal energy, the emitter has a load-bearing element, a sealant and a mechanism for reciprocating movement of the heat emitter, heated scrapers are installed on the heat emitter. The disadvantage of an analogue is the complex design of the device.

Known device "Cable line" (patent No. 61935, RU, priority date 11/16/2006, patent holder LLC Perm

design and technological bureau of technical design of the organization of production "Techproject", RU).

The cable line according to patent No. 61935 contains interconnected low-temperature and heating bends of the cable, which consist of insulated conductive cores of material with different resistivities, on which a cushion is placed under armor and armor, the cores of the free end of the cable line are interconnected to form a closed electrical chains and are isolated, the heating tap of the cable line is made of three consecutive sections of cable, each of which includes three conductive wires of different phases, one of which, heating, is made with greater resistance than two adjacent low-temperature conductors.

The disadvantage of the analogue is the low operational reliability due to interruption of insulation at the junction of the conductive conductors, which leads to the formation of plugs in the wells from asphalt-resin-paraffin deposits.

The closest to the claimed technical solution for the technical essence and the achieved effect is the cable line device (patent No. 2192679, RU, priority date 09/29/2000, patent holder of PermNIPIneft limited liability company), this analogue is taken as a prototype of the claimed useful models.

The prototype cable line consists of low-temperature and high-temperature taps, with different conductivity, containing insulated conductive conductors in a common shape-forming insulating sheath, on which a pillow and armor are laid.

The disadvantage of the prototype is the low operational reliability due to interruption of insulation at the junction

conductive conductors of low-temperature and high-temperature branches, as a result - lack of continuity (integrity) of insulation along the length of the cable line, which leads to the penetration of liquid and gas from the environment into the cavity between the insulation and the conductive core, accompanied by mechanical destruction of the insulation, violation of its dielectric properties, electrochemical corrosion of conductive conductors, breakdown of insulation between conductors and premature failure of the cable line.

Another disadvantage is the uneven heating of the cable line along its entire length, which leads to the formation of plugs in the wells from asphalt-resin-paraffin deposits. The consequence of uneven heating is the overheating of the cable line in some areas, which leads to softening of the insulation and, ultimately, to the failure of the cable line.

The technical task of the utility model is to simplify the design and increase the reliability of the cable line.

The technical problem is solved by a known cable line containing insulated conductive cores made of conductive threads, a pillow for armor and armor made of at least one wound, according to a utility model, the cable line consists of at least three cores, which are made as bimetallic conductors, each core has an insulating sheath, while the conductive threads located inside the insulating sheath are continuous, have the same length corresponding to the length of the core, and uniformly twisted together along the entire length, while one part of the threads is made of metal with high conductivity, the other part of the threads of metal with low conductivity, and the armor laid on the pillow and connecting the cores to each other is forming for the cable line, and junction

lived continuously along the entire length of the cable line. The cable line can have convex-concave surfaces, while the centers of the cross-sections of the conductive wires are located on the same arc with a constant radius of curvature, or flat surfaces, while the centers of the cross-sections of the conductive wires are located on one straight line parallel to flat surfaces. Copper or aluminum may be selected as the metal with high conductivity, and steel may be selected as the metal with low conductivity.

The essence of the utility model is illustrated by drawings:

figure 1 shows a cable line stirrup wires;

figure 2 shows a cable line, which illustrates the core, consisting of twisted with each other threads;

figure 3 shows a cross section of a cable line with a flat surface of the armor AA, in which the centers of the sections of the conductive conductors are located on one straight line;

figure 4 shows a cross section of a cable line with a convex-concave surface of the armor BB, in which the centers of the sections of the conductive conductors are located on the same arc with a constant radius of curvature.

Cable line 1 (Fig. 1), designed for track heating of a highly viscous oil and gas mixture of wells, contains three insulated conductive conductors 2, 3, 4 (Fig. 1), which are made as bimetallic conductors, with each core having an insulating sheath 5 (Fig. 1). .3) made, for example, of low-density polyethylene of high-density grade, inside which are conductive threads (Figs. 3, 4) made of metal with high conductivity 6, for example, copper or aluminum, and of metal with low specific conductivity conducted 7. Strongly e.g., steel. The threads are continuous and have the same

length corresponding to the length of the core. The number of threads and their cross section is selected from the calculation and taking into account the parameters of a particular well. The threads are located without a gap and evenly twisted together along the entire length (figure 2). The cores are interconnected by armor 8 (Figs. 3, 4) laid on a pillow (not shown conditionally in Fig.), And the junction of cores is continuous along the entire length of the cable line (Fig. 1). The pillow is made, for example, from a nonwoven fabric for technical chains, in one layer, and serves as a substrate for the next protective layer - armor. Armor made, for example, of galvanized steel tape, in at least one coil, is forming for the cable line, so that the cable line can have convex-concave surfaces B (Fig. 3), when the cross-sectional centers of the conductive wires are located on one an arc with a constant radius of curvature, or flat surfaces G (figure 4), when the centers of the cross-sections of the conductive conductors are located on one straight line parallel to the flat surfaces.

During the preparatory operation at the oil and gas well, the boundaries of the paraffin formation in the well are measured, and therefore, the length of the cable line, the temperature in the zone of the lower end of the cable line, the flow rate of the well, and the temperature parameters before the cable line is introduced into the well are set. The heating power of the cable line is chosen in such a way as to ensure that all produced oil and associated water and gases are heated to a temperature that excludes paraffin deposits, while the cable line is heated to such an extent as to prevent melting of the insulating material, taking into account the borehole temperature in the area of the lower end of the cable lines. Thus, when using the claimed utility model, paraffin deposition on the walls of oil compressor pipes is almost completely eliminated.

To ensure more reliable and efficient operation of the well with the declared cable line, it is advisable to additionally control the flow rate and temperature of the output stream of the product from the well.

The cable line power is selected depending on the parameters of the well, for example, in a well with a paraffin deposition depth of 650 m, the length of the heating cable line is 820 m, the power consumption is 27.21 kW.

When operating the cable line in the well, the cable line is oriented so that the centers of the cross-sections of the conductive wires are adjacent to the tubing with a flat or concave surface. The cable line is connected to a power source, and the free lower ends of the cable line are connected to each other at one common point, while the cable line is attached with pipe clamps to the outer surface of the cable line.

Tests of a cable line composed of three bimetallic cores with a cross section of a core S = 6 mm ² at a phase current of 1ph = 42.12 A showed that the temperature of the fluid at the wellhead increased by 8-10 ° and paraffin deposition in the well stopped.

Tests have shown high operational reliability of the cable line, the duration of operation is more than 1 year.

The technical result of the claimed utility model is as follows.

The implementation of the conductors of conductive filaments continuous and of the same length, located along the entire length of the cable line, makes it possible to form the wires in a continuous insulating sheath, which simplifies the design of the cable line as a whole, ensures continuity and integrity of the insulation throughout

cable line, increases the reliability of the declared cable line.

The execution of conductors from conductive threads twisted together along the entire length, from a material with different conductivities, for example, from copper and steel, located continuously along the entire length of the cable line, makes it possible to form a cable line with uniform insulating properties along the length of the cable line, and along its cross section, and also provides uniform heating of the cable line along its entire length, which is a preventive action in the formation of plugs from asphalt-resin-paraffin deposits. This feature of the claimed utility model also improves cable line reliability.

The implementation of the armor, which sets the required shape of the cable line, makes it possible to form a cable line with a single geometry of the forming armor, both along the length of the cable line and its cross section, with uniform mechanical properties, which increases the strength and bearing capacity of the cable line.

The implementation of the cable line with a flat or convex-concave shape in cross section rather than round makes it possible to more closely fit the cable line to the pipe surface, which ensures uniform and sufficient heating of the produced fluid and eliminates the formation of plugs from asphalt-resin-paraffin deposits in oil and gas wells.

The obtained technical result completely solves the problem of the claimed utility model.

Claims (4)

1. A cable line containing insulated conductive cores made of conductive threads, a pillow for armor and armor made of at least one wound, characterized in that the cable line consists of at least three cores, which are made as bimetallic conductors, each core has an insulating sheath, while the conductive threads located inside the insulating sheath are continuous, have the same length and are evenly twisted together along the entire length, while one part of the threads is made of metal with a high conductivity, the other part of metal filaments with low thermal conductivity, and armor, laid on a cushion and connecting wires to each other for forming a cable line, wherein the junction lived continuously along the length of the cable line. 2. The cable line according to claim 1, characterized in that the armor has convex-concave surfaces, while the centers of the conductive conductors are located on the same arc with a constant radius of curvature. 3. The cable line according to claim 1, characterized in that the armor has flat surfaces, while the centers of the sections of the conductive conductors are located on one straight line parallel to the flat surfaces. 4. The cable line according to any one of claims 1 to 3, characterized in that one part of the threads with high conductivity is made of copper or aluminum, and the other part of the threads with low conductivity is made of steel.