RU82922U1 - CABLE FOR COMMUNICATION AND TREATMENT OF WELL (OPTIONS) - Google Patents

Abstract

1. An electric cable containing at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, characterized in that at least one protective layer of elastic and abrasion resistant material. ! 2. An electric cable containing at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, characterized in that at least one protective layer of elastic and abrasion resistant material, and between the conductive core and the specified protective layer there is an additional porous layer with damping properties, resistant to external mechanical shocks. ! 3. An electric cable containing at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, characterized in that at least one protective layer of flexible and abrasion resistant material, and between the specified protective layer and the armor is an additional porous layer with damping properties, resistant to external mechanical shocks. ! 4. An electric cable containing at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, characterized in that at least one protective layer of elastic and

Description

The utility model relates to the oil industry, namely, devices for communication during drilling, for the study of vertical wells, in particular for lowering and raising instrumentation in a tubing or tubing, during development, operation of wells and can be used for processing wells, productive formations, etc.

Known electric armored cable, consisting of three insulated cores parallel to the same plane, a protective cushion and steel tape armor, while the armor, when applied to the protective cushion, forms a profile lock, and under the lock a screw gap / RU 2324245 C2, MPK8 Н01В 7 / 18, publ. 06/19/2006 /.

A disadvantage of the known cable is the low efficiency due to the lack of protection of conductive cores from shocks that occur when the cable is lowered into the well about the pipe coupling joints. In addition, the cable does not have load-bearing properties, it is attached to the tubing with the help of clamps and therefore often breaks if it is poorly fixed with clamps.

Known load-bearing geophysical cable with a reinforced polymer sheath, which contains one or more electrically insulated conductive cores having at least two wound armor made of steel wire and an outer sheath of polymer material reinforced with a mesh of steel wire with mesh sizes in the longitudinal and transverse dimensions / RU 2269834 MPK8 Н01В 7/18, publ. 02/10/2006 /.

The disadvantage is the conflict between the armor and the conductive core (s) arising from repeated pressure tests and alternating loads acting on the cable lowered into the well. Since the armor is presented in the form of coils of steel wire around the conductive cores (s) and during lateral compression during crimping starts to significantly straighten-lengthen. In this case, the conductive core (s) located rectilinearly in the axial part of the cable, due to the reinforced coupling of the sheath with the armor, also stretches and thins out with an increase in the ohmic resistance of the core until the copper conductive core breaks. With the external integrity of the cable, breaks in the conductive core are often observed. In addition, if the cable is lowered from the tubing in the clamp, i.e. in an unstressed state, cable bends with pinching often occur during crimping

conductive core between armor wires, leading to damage to the insulation or conductive core itself.

Known flexible load-carrying cable containing an insulated current-carrying conductor made of twisted copper and steel wires, a load-carrying element of high-modulus technical threads SVM, an outer sheath, while the load-carrying element is made in the form of a braid and superimposed on an insulated sheath of a current-carrying vein and is slagged with an outer sheath / RU 2212721, IPC7 Н01В 7/04, Н01В 7/18, publ. 09/20/2003 /.

The disadvantage is the low ability to withstand lateral compression shocks when lowering the cable simultaneously with the tubing with the possibility of mounting or not on the clamps. Often after strikes, the cable armor is connected to a conductive core.

In addition, if the cable is lowered from the tubing in the clamp, i.e. in an unstressed state, often in the bends of the cable there is a pinching of the conductive core between the armor wires, leading to damage to the insulation of the conductive core and, accordingly, to a short circuit with the armor.

Known load-bearing geophysical cable containing one electrically insulated conductive core, at least two layers of armor made of steel wire and an outer reinforced sheath of polymeric material / RU 75892 U1, MPK8 Н01В 7/17, publ. 08/27/2008 / one or more electrically insulated conductive cores is additionally included in the armor layers, part of the armor wires and threads for reinforcing the polymer shell are made of basalt and / or glass roving, and / or Kevlar.

A disadvantage of the known load-bearing geophysical cable is that when using clamps with a clasifier and a tensioner to install the cable on the tubing, the insulation of the conductive core is often crushed with steel armor wires.

The task to which the claimed technical solution is directed is to develop a cable design that, when used together with the tubing for launching into the well, especially in its annulus, where mechanical effects on the tubing couplings are noted, will be able to withstand lateral compressive mechanical stresses from the impact tubing weights and high pressure crimping. In addition, the use of a buffer layer will prevent pinching of the conductive core between the wires of the armored braid.

When carrying out the invention, the task is solved by achieving a technical result, which consists in improving the operational characteristics / properties of the cable.

The specified technical result according to the first embodiment is achieved by the fact that the electric cable contains at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, at least between the conductive core and the armor One protective layer of elastic and abrasion resistant material.

The specified technical result according to the second embodiment is achieved in that the electric cable contains at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, at least between the conductive core and the armor , one protective layer of elastic and abrasion resistant, and between the conductive core and the specified protective layer there is an additional porous layer with damping properties resistant to external mechanical shock am

The specified technical result according to the third embodiment is achieved in that the electric cable contains at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, at least between the conductive core and the armor , one protective layer of elastic and durable to abrasion, and between the specified protective layer and the armor is an additional porous layer with damping properties resistant to external mechanical shocks.

The specified technical result according to the fourth embodiment is achieved in that the electric cable contains at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, at least between the conductive core and the armor , one protective layer of elastic and abrasion resistant, while the conductive core is a copper wire.

The specified technical result according to the fifth embodiment is achieved in that the electric cable contains at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, at least between the conductive core and the armor , one protective layer of elastic and abrasion resistant, while the conductive core is made in the form of a twist of steel and copper wires.

The specified technical result according to the sixth embodiment is achieved in that the electric cable contains at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, at least between the conductive core and the armor , one protective layer of elastic and durable to abrasion, while the conductive without sheath or with insulation is woven, at least one winding around a tube made of metal or polymer core ovy.

The specified technical result according to the seventh embodiment is achieved by the fact that the electric cable contains at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, at least between the conductive core and the armor , one protective layer of elastic and durable to abrasion, while the cable is additionally equipped with a fiber optic wire.

The specified technical result according to the eighth embodiment is achieved by the fact that the electric cable contains at least one conductive core made without sheath or with insulation, armor and an external reinforcing sheath of polymer material, while at least at least one conductive core and armor are placed , one protective layer of elastic and durable to abrasion, while at least one conductive core has an external solid metal or metal-polymer screen in the form of a metal tape or foil or lgirovannogo Dacron.

The specified technical result according to the ninth embodiment is achieved by the fact that the electric cable contains at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, at least between the conductive core and the armor , one protective layer of elastic and abrasion resistant, and to increase the load-bearing properties of the cable, the armor is made in the form of at least one layer consisting of steel wires or kevlar or corrugation threads metal or steel polymer tape.

The specified technical result according to the tenth embodiment is achieved by the fact that the electric cable contains at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, at least between the conductive core and the armor , one protective layer of elastic and abrasion resistant, while

the outer and / or inner surface of the protective layer and / or conductive cores are covered with self-vulcanizing sealant.

The inventive cable, which is power or geophysical for communication, made load-bearing, is designed to increase reliability when descending into the annular space simultaneously with the tubing string and for passing through packers and disconnectors of columns where there are local lateral compressive pressures to prevent destruction of insulation and short circuit during the connection of the conductive core with the armor, is power or geophysical for communication, and is made load-bearing. Improving the efficiency and reliability of the cable under crushing and squeezing side loads is provided due to the possibility of reliable trouble-free descent of the load-carrying or not-very-load-bearing cable simultaneously with the tubing into the annulus, for example, between the tubing and the casing.

The presence in the cable of a protective layer with damping properties, located between the conductive core (s) and armor (metal), provides protection against internal damage to the conductive core during lateral compression. In addition, the protective layer eliminates (reduces) the conflict between the conductive core and the armor and acts as a compensator for various extensions of the conductive core and armor due to the increased visco-plastic extension.

Possible cable designs are illustrated in the drawings.

Figure 1 shows a section of a cable, where the conductive core is made in the form of a copper wire, and the protective layer is located between the conductive core and the armor.

Figure 2 - conductive core is presented in the form of a twist of steel and copper wires.

Figure 3 - conductive conductors are made with insulation.

Figure 4 presents a section of a cable with a porous layer with damping properties.

Figure 5 - conductive conductors without a sheath are made in the form of a single-layer wound around the tube.

Figure 6 - conductive conductors are made in the form of a single-layer coil around a fiber optic wire, protected by armor with a double coil, for example, from Kevlar threads.

The electric cable contains one or a number of conductive conductors 1, made without a sheath or with insulation 2 (a current-insulating sheath), armor 3, and an external reinforcing sheath 4 made of a polymer material. Between the conductive core 1 and the armor 2 is a protective layer 5 made of elastic and

abrasion resistant material, for example, from rubber or rubber, or rubberized fabric, from a copolymer of propylene or polyethylene.

To exclude or evenly redistribute the transmitted mechanical stresses from the armor 3 to the conductive core 1 and insulation 2 in the cable, an additional porous layer 6 with damping properties resistant to external mechanical shocks may be located between the conductive conductors 1 and the outer protective layer 5 (Figs. 4-6) . Perhaps the location of the porous layer 6 between the protective shell 5 and the armor 3.

The conductive core can be a copper wire for communication and transmission of electric current, or can be made in the form of a twist of steel 7 and copper wires 11 to prevent their pulling.

The conductive core without sheath or with insulation 2 is woven in at least one coil around a tube 8 (Fig. 5) made of a metal or polymer base to transmit a hydraulic impulse or high pressure, resistant to lateral compression and aggressive environment .

For communication and information transfer from the measuring sensors, the cable may have a fiber optic wire 9 (Fig.6).

At least one conductive core 1 may have an external continuous metal or metal-polymer screen in the form of a metal tape or foil or foil lavsan (not shown in FIG.). An external continuous metal layer is necessary to reduce exposure to external electromagnetic interference and to shield the electromagnetic field of a conductive core.

To increase the load-bearing properties, the cable can be equipped with additional armor 10. Armor 3 and additional armor 10 are made in the form of at least one layer consisting of steel wires or Kevlar threads or corrugated metal or steel-polymer tape (Fig.6).

The outer and / or inner surface of the protective layer and / or conductive veins can be covered with a self-vulcanizing sealant (thiokol or silicone) - to remove air gaps between the layers and shells and to give the plastic mobility of the shells relative to each other during tensile and compressive external forces.

When the electric cable is lowered into the well, for example, together with the tubing with the last clamp attached to its outer surface, a periodic mechanical shock impact on it of tubing couplings and coupling recesses in the production string occurs. In this case, the protective layer 5 experiences stress during

squeezing the cable with pipes and / or tubing couplings, especially when passing through the coupling recesses in the production string when the cable is caught between the production string and tubing. The protective layer 5 inside the electric cable prevents the mechanical compressive effects of the hard wires of the armor 3 on the conductive cores 1. In cases of failure in the coupling recesses in the production casing, the protective layer 5 in the broken / bent part prevents the conductive core 1 between the wires of the armor 3 and, accordingly, saves him from being crushed and damaged. In addition, if the cable has more than one conductive core 1, then it is possible to use at least one porous layer 6 with damping properties, for example, of porous rubber, resistant to external mechanical shocks, which prevents disturbance of conductive conductors when squeezing among themselves.

Claims (10)

1. An electric cable containing at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, characterized in that at least one protective layer of elastic and abrasion resistant material. 2. An electric cable containing at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, characterized in that at least one protective layer of elastic and abrasion resistant material, and between the conductive core and the specified protective layer there is an additional porous layer with damping properties, resistant to external mechanical shocks. 3. An electric cable containing at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, characterized in that at least one protective layer of flexible and abrasion resistant material, and between the specified protective layer and the armor is an additional porous layer with damping properties, resistant to external mechanical shocks. 4. An electric cable comprising at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, characterized in that at least one protective layer of flexible and abrasion resistant material, while the conductive core is a copper wire. 5. An electric cable comprising at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, characterized in that at least one protective layer of flexible and abrasion resistant material, while the conductive core is made in the form of a twist of steel and copper wires. 6. An electric cable comprising at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath made of a polymer material, characterized in that at least one protective layer of flexible and abrasion-resistant material, while the conductive core without a sheath or with insulation is woven, at least in the form of one winding around a tube made of a metal or polymer base. 7. An electric cable containing at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath made of a polymer material, characterized in that at least one protective layer of flexible and abrasion resistant material, while the cable is additionally equipped with a fiber optic wire. 8. An electric cable containing at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, characterized in that at least one protective layer of flexible and abrasion resistant material, at least one conductive core has an external continuous metal or metal-polymer screen in the form of a metal tape, or foil, or foil lavsan. 9. An electric cable comprising at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, characterized in that at least one protective layer of flexible and abrasion resistant material, and to increase the load-carrying properties of the cable, the armor is made in the form of at least one layer consisting of steel wires or Kevlar threads, or corrugated metal or steel-polymer linen you. 10. An electric cable containing at least one conductive core made without a sheath or with insulation, armor and an external reinforcing sheath of polymer material, characterized in that at least one protective layer of flexible and abrasion resistant material, while the outer and / or inner surface of the protective layer and / or conductive cores are covered with a self-vulcanizing sealant.