RU2269834C2 - Reinforced polymeric sheath covered geophysical load-carrying cable and its application process - Google Patents

Abstract

FIELD: geophysical investigations; cables for oil and gas wells.

SUBSTANCE: proposed reinforced polymeric sheath covered geophysical load-carrying cable whose specific mass and cost are comparable with mass produced ones but whose armor wires are reliably protected against detrimental impact of chemically active liquid of wells has one or more insulated conductors and is provided with at least two steel-wire armor lays permitting intermediate sheaths and polymeric sheath overall; the latter is reinforced by steel wire net with longitudinal and transversal sizes of cell amounting to 1 - 10 diameters of wire. Armor of cable armor and/or of polymeric-filler reinforcing member may be produced from steel wire free from zinc coat provided overall sheath is used. Reinforcing materials are polypropylene, polyamide, or self-curing material threads. Air gaps between armor wires and/or reinforcing members of sheath are filled with self-curing sealing compound, such as thiokol or silicone compound. Proposed method for investigating wells, including those where hydrogen sulfide content and wellhead pressure are high involves tripping of geophysical instruments and pieces of equipment by means of cable; in the process tripping operations are conducted using reinforced polymeric sheath covered geophysical cable. Work in wells using cable of proposed mechanical design is identical to technology with mass-produced geophysical cables, but in the former case work can be done with minimal cost in wells containing hydrogen sulfide and those where wellhead pressure is high.

EFFECT: minimized cost and ability of using proposed cable in hydrogen sulfide environment of wells at high wellhead pressure.

5 cl, 4 dwg

Description

The invention relates to the field of geophysical exploration and can be used for cable work in oil and gas wells.

Known commercially available load-bearing geophysical cables for logging, swabbing, perforation of oil and gas wells, having a structure of 1-7 electrically insulated conductive cores and two or four armwinds of galvanized steel wire, each of which has a direction opposite to the previous one, in accordance with OST153 -39.1-005-00.

Special cables are known for work in wells with aggressive, mainly hydrogen sulfide and acid, medium, the armor of which is made of special alloys of steel. The disadvantage of this cable design is its extremely high cost, 15-20 times the cost of a serial cable.

Also known are cables for aggressive media having an outer sheath of polymeric materials. With this design of the cable, the shell can slide due to insufficient adhesion of the polymer material with the armor wires, especially during tripping operations through the stuffing box under the influence of borehole pressure.

The closest in design is the cable described in patent No. 2209450 from 01/14/2002. This cable consists of three or more insulated current-carrying conductors, covered with two or three pairs of armor layers with oppositely directed coils of wires in each pair, moreover, in the upper armor layer the wires can be laid with up to 50% reduction in the density of laying wires in the layer, and the gaps between wires filled with polymer material. The disadvantage of this cable design is its large outer diameter and, accordingly, weight and dimensions, primarily associated with the intended use of the cable for the study of horizontal and horizontally directed wells.

The aim of the invention is to obtain a cable design that is close in specific gravity and comparable in cost to commercially available geophysical cables, but having reliable protection of the armor wires from aggressive well fluid, the ability to work through stuffing boxes at high wellhead pressure, and also preventing the removal of well fluid and gas with armor wires when lifting the cable to the surface.

To achieve this goal, the following cable design is proposed.

A load-bearing geophysical cable with a reinforced polymer sheath, containing one or more electrically insulated conductive veins, having at least two armor wires made of steel wire, allowing for intermediate shells and an outer sheath of polymer material, while the outer sheath is reinforced with a steel wire mesh with mesh sizes Lxy in longitudinal and transverse dimensions, equal to 1-10 wire diameters.

The choice of the specific design of the reinforced cable sheath and the size of the cell formed by the steel wire is determined by a number of operational factors, which include: the specific gravity of the cable, the depth of its descent, the required breaking force. So, the traditionally used load-carrying armored cables manufactured in accordance with OST 153-39.1-005-00 have wire armor made of galvanized steel wire laid in two multidirectional coils. The main mechanical properties of the cable are determined mainly by the used wire armor: the number of wires, their diameter and the geometry of the arrangement of wires in the coils. The operational characteristics of each winding are provided by the following values:

- The breaking strength of the cable Nk for each coil is:

Nк = n · d / cos (α) · δ / 1000, (kN),

where n is the number of wires in the midwife,

d is the diameter of the wire in the midwife, mm,

cos (α) is the cosine of the angle of inclination of the wire to the center line of the cable,

δ is the breaking strength of a single wire, N / mm ² .

- The fill factor KZ midwire wire is determined by the following expression:

Kz = n · d / cos (α) / (π · (D + d)),

where n is the number of wires in the midwife,

d is the diameter of the wire in the midwife, mm,

cos (α) is the cosine of the angle of inclination of the wire to the center line of the cable,

D is the inner diameter of the midwave, mm.

- The specific weight of the wire armor of the Ru cable for each layer is:

Ru = ρ · n · π · d ² / (4 · cos (α)), (kg / km),

where ρ is the specific gravity of the material of the armor wires, kg / cm ³ ,

n is the number of wires in the midwife,

d is the diameter of the wire in the midwife, mm,

cos (α) is the cosine of the angle of inclination of the wire to the center line of the cable.

The cell dimensions Lxy formed by the armor wires can be approximately expressed in terms of the fill factor Кз as follows: Lxy≈1 / Кз-1.

The Lxy parameter is dimensionless and characterizes the ratio of the visible and actual measured gap between the wires to the diameter of the wire and is more convenient for presenting the overall picture of the resulting wire mesh in the cable manufacturing process. The fill factor Kz of the wire is used mainly in the design of cable structures and technological calculations.

Based on the above ratios, one can compare the operational characteristics of the traditionally used three-core cable KG3 × 0.75-60-150 and a cable similar in electrical parameters to the cable with a polymer-steel sheath KG3 × 0.75-35-150-OA.

KG3 × 0.75-60-150 cable has the following characteristics: diameter - 10.2 mm, specific gravity - 432 kg / km (of which armor wires are 350 kg / km), breaking strength - 75 kN, duty factor KZ = 0 , 97-0.99. When lowering the cable to a depth of 6000 m with a geophysical instrument weighing 100 kg, the load on the geophysical winch on the surface, taking into account the buoyancy of the borehole fluid, will be 2100 kg, which is 28% of the breaking load of the cable and only 4.7% of the payload (geophysical instrument) )

The cable KG3 × 0.75-35-150-OA has the following characteristics: diameter - 11.0 mm, specific gravity - 280 kg / km (of which armor wires are 170 kg / km), breaking strength - 38 kN, duty factor KZ = 0.4-0.45. When lowering the cable to a depth of 6000 m with a geophysical instrument weighing 100 kg, the load on the geophysical winch on the surface, taking into account the buoyancy of the borehole fluid, will be 1120 kg, which is 29% of the breaking load of the cable and 9% of the payload (geophysical instrument).

Thus, the use of both cable designs provides more than three times the margin in tensile strength, but the proposed cable design has a higher efficiency of tripping and lower loads on ground-based geophysical equipment - reducing the pulling force of the winch by almost 1000 kg.

In addition, the above ratios, in particular, the fill factor of the cove with wire, affect the following operational and technological parameters of the cable:

- filling the gaps between the armor wires with polymer material increases the axial stiffness of the cable, which leads to an increase in the pushing force on the geophysical instrument, which is especially important when the cable is used in horizontal and horizontally directed wells. Testing of cable structures was carried out at the Axial Compression Testing Plant of Pskovgeokabel LLC in a pipe with a diameter of 150 mm and a length of 6 m by comparing the forces applied to the cable at the beginning of the pipe and the force received at the end of the pipe. For cables of traditional design, the transfer of force to the end of the pipe stopped after the application of a force of 15 ÷ 25 kg. For similar cables with a polymer-steel sheath, this indicator was 45–70 kg.

- The presence of a polymer-steel sheath on the cable plays a positive role during cable operation through stuffing box devices at high wellhead pressures. A traditional cable with round wire armor has interwire clearances through which leakage of well fluid or gas occurs and at pressures at the wellhead of more than 1 MPa, it is practically impossible to achieve complete cable sealing by clamping the cable in the stuffing box. The polymer-steel shell helps prevent downhole material emissions at wellhead pressures of up to 15 MPa.

- The proposed polymer-steel sheath protects the cable armor wires, which are also load-bearing elements, from the effects of a well fluid, which may contain water, solutions of acids, alkalis, causing premature corrosion of the steel wire and cable failure.

- It is especially advisable to use the proposed cable design in wells with a high content of hydrogen sulfide, because if traditional design cables are used in these wells, the mean time between failures is one tripping operation. The proposed OST 153-39.1-005-00 for operation in hydrogen sulfide wells, cables with armor made of special stainless wire have a cost 8-12 times higher than the cost of a cable with armor made of steel wire.

The fill factor KZ or the mesh size of the wire mesh has an important role in the manufacture of the cable and is limited by the technological capabilities of the equipment and the technical requirements for the cable (stiffness, breaking strength, weight, etc.). So, for example, when the size of the mesh cell formed by coils of wires is less than one diameter of the wire, filling these gaps with polymeric material becomes difficult, because this operation is carried out on extrusion lines and the polymer melt under pressure fills the gaps of the wires. With small wire meshes, premature cooling of the melt and incomplete filling of the gaps occurs, which subsequently can lead to delamination of the shell, penetration of gas or liquid under the shell and its subsequent damage during rapid rise from the well due to the difference in external and internal pressures.

The mesh cell size Lxy, equal to 5 ÷ 10 wire diameters, is used in cases where it is necessary to provide increased tensile strength and / or increased axial stiffness and to ensure them the mesh is formed not from two windings of wire, but from three or four, which leads to an increase in thickness layer required to fill with polymer.

Variants of the proposed cable design are also possible.

The armor of the cable and / or the reinforcing element of the polymer aggregate in the presence of an outer sheath can be made of steel wire without zinc coating.

In order to reduce the specific gravity of the cable, polypropylene, polyamide or CBM threads are used as reinforcing material.

The air gaps between the armor wires and / or the reinforcing elements of the sheath are filled with a self-vulcanizing sealant, for example thiol or silicone.

Reinforcement of the outer sheath increases the longitudinal and transverse strength of the polymer coating, and the use of wire without zinc coating as armor cable reduces the cost of materials. Filling the air gaps of the armor wires with sealing material provides longitudinal sealing of the cable and prevents the emission of well fluid or gas through armor wires, increases the pushing force on the geophysical instrument, and protects the armor wires of the cable.

The proposed cable design allows you to perform the full range of geophysical work in wells, including logging, swabbing, perforating and blasting, etc.

The method of research wells, including with a high content of hydrogen sulfide and high wellhead pressure, includes the descent on the cable of geophysical instruments and equipment, while hoisting operations are carried out using a geophysical cable with a reinforced polymer sheath.

Figures 1 and 3 show cable structures with a polymer sheath made according to OST 153-39.1-005-00, where 1 is a one- or three-core cable core, respectively, 2 is a two-drinker cable armor, 4 is a protective sheath. Figure 2 and 4 shows the design of similar cables containing reinforcing elements 4 in the composition of the polymer sheath.

The technology for conducting work on wells with the proposed cable designs is identical to the technology for using serial geophysical cables and is given in the “Technical Instructions for conducting geophysical research and cable work in oil and gas wells”, Moscow, 2001, but at the same time, work is carried out in hydrogen sulfide wells and wells with high wellhead pressure at minimal cost.

Claims (5)

1. A load-bearing geophysical cable with a reinforced polymer sheath, containing one or more electrically insulated conductive cores, having at least two armor wires made of steel wire, allowing for intermediate shells and an outer sheath of polymer material, characterized in that the outer sheath is reinforced with a mesh of steel wire with cell dimensions in longitudinal and transverse dimensions equal to 1-10 wire diameters. 2. The cable according to claim 1, characterized in that the armor of the cable and / or the reinforcing element of the polymer aggregate is made of steel wire without zinc coating. 3. The cable according to claim 1, characterized in that polypropylene, polyamide or CBM threads are used as the reinforcing material. 4. The cable according to claim 1, characterized in that the air gaps between the armor wires and / or the reinforcing sheath elements are filled with a self-vulcanizing sealant, for example, thiol or silicone. 5. A method of researching wells, including with a high content of hydrogen sulfide and high wellhead pressure, including the descent on the cable of geophysical instruments and equipment, characterized in that the hoisting operations are carried out using a geophysical cable with a reinforced polymer sheath according to any one of claims 1 to 4.

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