RU2209450C1 - Load-carrying logging cable ( variants ) and process of investigation of inclined and horizontal wells - Google Patents

Abstract

FIELD: oil geophysics, geophysical investigation of inclined and horizontal wells. SUBSTANCE: cable includes two parts: lower part working is horizontal sections of well and upper part operating in vertical section. Armor consisting of three layers of steel zinc-plated wire as minimum is used in upper part, spaces between layers and wires in layers are filled with polymer material with weighting filling agent. Lower part of cable is so made that portion of wires starting from second or third layer is cut off with uniform distribution of cutting points over length of part. Wires in upper layer of armor can be laid without cutting over entire cable length with up to 50% reduction of density of wire laying in layer. EFFECT: enhanced pushing capability with maintenance of large load-carrying capacity. 6 cl, 3 dwg

Description

 The invention relates to geophysics and can be used in the study of oil and gas wells.

 Known commercially available load-bearing geophysical cables for geophysical research, shooting and blasting in wells drilled for oil, gas, ore, coal and other minerals in one-, three- and seven-core versions, with slightly different parameters in breaking strength, diameter, electrical insulating materials and other differences, but with one mandatory design - the use of a two-layer armor coating. See catalogs of cable products of factories: Tashkent, Pskov (CJSC Pskovgeofizkabel), Perm (CJSC Permgeokabel). Magnitogorsk (SPC "Galva") and others.

 Known designs of special geophysical cables for the study of deviated and horizontal wells (patents 2087929 from 03/12/96 and 2105326 from 01/20/97), with a multilayer armor coating and shell made of a polymeric material.

 The closest in design is the cable described in patent 2105326. 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, characterized in that the second and third pairs of armor layers are made from a wire, the diameter of which is 1.3-2.5 times larger than the diameter of the wires of the first pair of layers of the armor, while over each pair is applied under pressure a coating of plastic material filling the gaps between the wires of the armor, and the outer diameter of the cable along the entire length is 15-32 mm.

 The aim of the claimed invention is to obtain a technical result. The technical result is the provision of the possibility of conducting well logging in horizontal and deviated wells by creating new geophysical cables that optimally meet the technical parameters - the number of conductors, diameter, tensile strength, constructive use for conducting well research and special work on swabbing, testing of formations with cable formation testers, cleaning the borehole zone of reservoirs with special devices requiring the use of cables with high fracture nd strength to carry out works at the mouth of the sealed both in vertical and in horizontal wells, permits the use of devices is pushed.

This goal is achieved by the fact that it is proposed:
1. A load-bearing geophysical cable containing one or more electrically insulated conductive cores and at least three or more layers of armor made of steel wire with sheaths of polymer material between the layers of armor or only on top of it, while on the cable section designed to work in inclined and horizontal parts of the well, starting from the second or third armor layer, up to 75% of the wires are cut off with a uniform shift of the cut-off points along the length of the section when moving from the lower layer to the upper, and the remaining wires form a reinforcing cage for polymer shells with a reduction in cable specific gravity in this section by at least 20% with respect to cable specific gravity in a section designed to work in the vertical part of the well, and in the upper armor layer the wires can be laid without clipping the entire length of the cable with uniform gaps between the wires with a decrease of up to 50% in the density of laying the wires in the layer, and the gaps between the wires are filled with polymer material during the application of external limernoy shell.

 2. A cable with a weighting filler, for example, from lead or its compounds, in order to increase the pushing force to ensure the cable with the connected geophysical instrument in inclined and horizontal sections of the studied wells.

 3. A cable in which the armor wires are applied with an adhesive.

 4. A load-bearing geophysical cable containing one or more electrically insulated conductive cores, armor made of steel wire and a sheath of polymeric material, the cable being made of two parts: the upper one is a load-carrying one with three- or four-layer armor having a diameter of 12 to 22 mm and tensile strength from 100 to 250 kN, and lower - load-bearing, with up to 6 layers of armor, at least two polymer shells between the armor layers and the outer polymer shell, and in the area of the load-carrying part of the cable, intended for In the vertical part of the well, starting from the second or third armor layer, up to 75% of the wires are cut off with a uniform shift of the cut-off points along the length of the section when moving from the lower layer to the upper one, and the remaining wires form a reinforcing frame for polymer shells with a decrease in cable specific gravity in this section, at least by 30%, and in the upper layer of the armor the wires can be laid without clipping along the entire length of the cable with uniform gaps between the wires with a reduction of up to 50% of the laying density wires in the layer, and the gaps between the wires are filled with polymer material in the process of applying the outer polymer shell. The decrease in specific gravity to 30% is due to the cutting off of a larger number of wires from a larger number of armor layers during the subsequent replacement of these wires with a lighter polymeric material.

 5. A cable in which a weighting filler, for example, from lead or its compounds, is introduced into the polymer shells in a section of the load-bearing part intended for operation in the vertical part of the well.

 6. A method for researching deviated and horizontal wells involves delivering geophysical instruments to deviated and horizontal parts of wells using a load-bearing geophysical cable according to claim 1, or 2, or 3, or 4, or 5.

 Cutting off part of the wires reduces the specific gravity of the cable operating in horizontal sections of the well while maintaining sufficient rigidity and strength of the polymer coating due to the wires of the reinforcing cage, while the upper part of the cable has a higher specific density, thereby increasing the pushing capabilities of the cable for delivering devices to horizontal sections wells.

 To ensure the sealing of the armor wires in order to prevent the penetration of liquid or gas when the cable is operating in borehole conditions, the armor wires are applied with an adhesive that ensures the tightness of the cable.

 The execution of the outer layers of the armor with uniform intervals while reducing the wire-laying density and filling the gaps with polymer material up to 50% increases the mechanical strength of the outer shell, prevents the shell from “sliding” and the formation of thickenings that prevent passage through the stuffing box, while maintaining the necessary cable flexibility and its pushing and carrying ability. The presence of such a monolithic armored polymer shell armor provides tightness, resistance to mechanical stress, allows for work in aggressive environments and in wells with high pressure at the wellhead using stuffing box devices and technical means for forcing the cable into the well.

 In FIG. 1 shows an example of a geophysical cable. Here: 1 - current-carrying core, 2 - insulating polymer sheath, 3 - wires of the first armor layer, 4 - wires of subsequent armor layers, 5 - outer polymer shell reinforced with wires of the upper armor layer.

 2). The execution of the cable sheath of a polymeric material with a weighting filler increases the weight, thereby increasing the pushing force with a smaller cable diameter for delivering devices to horizontal sections of the well. As a weighting filler, elements of heavy metals or their salts can be used.

 3), 4). The cable is combined lengthwise, while on the cable section intended for operation in the inclined and horizontal sections of the well, part of the wires is cut off, which reduces the weight of the cable and, consequently, the friction force, and a weighting filler is introduced into the polymer shells in the vertical part of the cable. This increases the pushing power of the cable.

 5). Geophysical work on the well has a very wide range. This is perforating blasting, cleaning, well testing, various types of research.

 The proposed cable allows you to perform work with remote devices in water-oil and gas-aggressive environments, including the delivery of instruments and research in wells under pressure through the stuffing box. The monolithic polymer shell reinforced with armor wires is resistant to scuffing and allows research through stuffing box devices at high wellhead pressures and with forced cable feed into the well.

 The way to perform the above work in the wells is to use a geophysical cable made according to one of the above items.

 Figure 2 shows an example of work in an open well with a cable according to claim 3, 4. Here: 1 - load-carrying part of the geophysical cable, 2 - pipe string, 3 - load-carrying part of the geophysical cable, 4 - geophysical device or perforator.

 Figure 3 shows an example of work in the well using stuffing box with cable according to claim 3, 4. Here: 1 - wellhead equipment, 2 - drill pipe string, 3 - load-carrying part of the cable, 4 - load-carrying part of the cable, 5 - geophysical instrument or punch.

 The technological scheme of work in wells with the proposed cable designs is absolutely identical to serial geophysical cables, but at the same time providing a solution to a fundamentally new problem - conducting geophysical and other types of oilfield work in deviated and horizontal wells with minimal time, comparable with the time of studying vertical wells of various categories of construction and arrangement both during construction and operation with a significant reduction in mat 'an and labor.

Claims (6)

 1. A load-bearing geophysical cable containing one or more electrically insulated conductive cores and three or more layers of armor made of steel wire with sheaths of polymer material between the layers of armor or only on top of it, characterized in that in the cable section designed to work in inclined and horizontal parts of the well, starting from the second or third layer of armor, up to 75% of the wires are cut off with a uniform shift of the cutoff points along the length of the section when moving from the lower layer to the upper, and the remaining wires a reinforcing cage for polymer shells is provided to ensure that the specific gravity of the cable in this section is reduced by at least 20% with respect to the specific gravity of the cable in the section designed to work in the vertical part of the well, and in the upper armor layer the wires can be laid without clipping the entire length of the cable with uniform gaps between the wires with a decrease of up to 50% in the density of laying the wires in the layer, while the gaps between the wires are filled with polymer material during external application th polymer shell.  2. The cable according to claim 1, characterized in that in the cable section intended for operation in the vertical part of the well, a weighting filler, for example, of lead or its compounds, is introduced into the polymer shells.  3. The cable according to claim 1, characterized in that the armor wires are applied with an adhesive composition.  4. A load-carrying geophysical cable containing one or more electrically insulated conductive cores, armor made of steel wire and a sheath made of a polymer material, characterized in that the cable is made of two parts: the upper carrying one with three or four-layer armor having a diameter of 12 - 22 mm and breaking strength of 100 - 250 kN, and the lower load-bearing, with up to 6 layers of armor, at least two polymer shells between the layers of armor and the outer polymer shell, and in the area of the load-carrying part of the cable, intended for work in the vertical part of the well, starting from the second or third armor layer, up to 75% of the wires are cut off with a uniform shift of the cut-off points along the length of the section when moving from the lower layer to the upper, and the remaining wires form a reinforcing frame for polymer shells with a decrease in cable specific gravity in this area, at least by 30%, and in the upper layer of the armor the wires can be laid without clipping along the entire length of the cable with uniform gaps between the wires with a decrease of up to 50% in the laying density and wires in a layer, and the gaps between the wires are filled with polymeric material during the deposition of the outer polymeric shell.  5. The cable according to claim 4, characterized in that in the portion of the load-bearing part, designed to work in the vertical part of the well, a weighting filler, for example, from lead or its compounds, is introduced into the polymer shells.  6. A method of researching deviated and horizontal wells, including the delivery of geophysical instruments to deviated and horizontal parts of the wells, characterized in that the instruments are delivered using a load-bearing geophysical cable according to any one of claims 1 to 5.

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