RU57046U1 - FLEXIBLE CABLE FOR SEISMIC WORKS (OPTIONS) - Google Patents

Abstract

The utility model relates to flexible geophysical cables intended for the transmission and reception of high frequency electrical signals during seismic work in the field at an ambient temperature of minus 60 ° to plus 55 ° C with permissible heating in summer to plus 70 ° C. The cable in both cases contains two power conductive conductors insulated with polyethylene or polypropylene and conductive conductors twisted in pairs to transmit electrical signals with a frequency of up to 12 MHz, which differ in color in a pair. According to the second variant, the cable also contains conductive conductors twisted in pairs insulated with polyethylene or polypropylene for receiving electrical signals with a frequency of up to 1 kHz. In the center of the cable there is a reinforcing core in a sheath made of polyethylene or polypropylene, twisted from high-modulus technical threads (according to the first embodiment), or a reinforcing element formed by one of a pair of conductive wires twisted with two reinforcing bundles also from high-modulus technical threads (according to the second version) . All pairs and power conductors are twisted into a cable around a reinforcing core or reinforcing element. Over the general twist, a winding of a polyethylene terephthalate film is applied, and then a sheath of thermoplastic elastomer or thermoplastic polyurethane, or polyvinyl chloride plastic compound. The twisting steps of all pairs are mutually agreed. All conductive wires are made of copper or tin-plated copper wires. The consistency of the twisting steps of the pairs, as well as the manufacture of conductive cores from copper wires having a low resistance, make it possible to exclude the influence of high-frequency electrical signals on each other, to ensure low electrical losses and low attenuation of the signals, thereby increasing noise immunity. Due to the use of high-modulus technical yarns with high tensile strength, the cable is characterized by low linear tension under the influence of mechanical stress. These filaments, soft, light and ductile copper provide flexibility to the cable, low weight and dimensions.

Description

The utility model relates to the cable industry, and more specifically to flexible geophysical cables, designed to transmit and receive high frequency electrical signals during seismic work in the field at ambient temperatures from minus 60 ° to plus 55 ° C with acceptable heating in summer period up to plus 70 ° С.

Geophysical cables for the study of deviated and horizontal wells are known in the art. As a rule, such cables should have a high breaking force, since they simultaneously carry the load-bearing and pushing roles along with the role of the information channel. It is possible to increase their breaking strength either by increasing the number of conductors in the core and insulation layers, which significantly increases the dimensions of the cable, or by using multilayer armor, which in turn reduces the flexibility of the cable and complicates winding it onto the drum. (RF patents for inventions No. 2087929, 2138834, 2105326).

In the well-known geophysical cable according to the patent of the Russian Federation for invention No. 2248594, each core is made armored, and the gaps between them and the central part are filled with wires. All veins and wires are interconnected, and on these scrolls are layered multilayer wound armor. This cable design is robust and has increased axial stiffness, which is very important when pushing the cable into the well. However, this design negatively affects the flexibility of the cable. In addition, due to the stiffness of the outer armor, the bending radii of such a cable are limited. All of the listed design features of the cable do not allow its use for field seismic exploration. For field seismic exploration, geophysical cables must be strong and at the same time as flexible as possible and withstand a wide temperature range of operation, since their operation occurs during repeated bends in any climatic zones on the earth's surface.

The closest in technical essence and purpose to the claimed cable for both versions is the design of a multicore cable for working with digital seismic stations of the KTSPV-74 brand (Technical conditions TU-16-505.776-75, Podolskkabel). It is designed to work in the field

conditions in the temperature range from minus 40 ° to plus 60 ° C for transmission of signals with a frequency of up to 800 Hz. Contains from 70 to 74 conductive cores in polyethylene insulation 0.3 mm thick. The cores are made of one bimetallic wire (steel-copper) with a diameter of 0.5 mm and twisted in pairs with a twisting step of no more than 100 mm and differ in color by pair. The pairs are twisted into a cable according to a twist system. Midwives have mutually opposite directions and in each midwife, the pairs differ in color from other pairs. The twisting steps for adjacent pairs in each layer are mutually agreed. A winding of polyethylene terephthalate tape with overlapping was applied over the top winding, and a sheath of 2.0 mm thick PVC with a minus deviation of 10% was applied over the winding. The outer diameter of the cable is not more than 19.5 cm + 5%, and the weight of 1 km of cable is 330 kg. The design of the known cable through the use of bimetallic wire has an increased tensile strength, not less than 4.9 kN. However, veins made of bimetallic wire, having high strength and elasticity, are not very flexible, which makes it difficult to wind them onto a drum during field work. Since the twisting steps of adjacent pairs are agreed upon, the necessary noise immunity is provided when transmitting signals at a frequency of up to 800 Hz. However, at higher frequencies, the consistency of the twisting steps of only adjacent pairs is insufficient, and the influence of the transmitting channels on each other is not ruled out. In addition, the presence of only transmitting channels in the cable eliminates the simultaneous transmission of high electrical power and providing power to the devices.

The task is to expand and improve cable performance, which is very important in the field, as well as to provide reliable results when transmitting high-frequency signals.

The technical result consists in eliminating the influence of the transmitting channels on each other, that is, in protecting against the effects of internal interference, and thereby increasing the noise immunity in the transmission of high-frequency signals, as well as in ensuring high operational reliability of the cable during repeated rewindings in the field.

The technical result is achieved as follows. In common with the prototype for both options is that the inventive cable contains insulated polyethylene or polypropylene conductive conductors twisted into pairs, and then these pairs are twisted into a cable. In each pair of veins

differ in color. The cable also contains a winding of polyethylene terephthalate film, applied over the general twisting of the pairs, the color of each of which differs from the color of the other pairs, and a sheath of elastic material on top of the winding. Unlike the prototype, the inventive cable according to the first embodiment further comprises a reinforcing core in a sheath made of polyethylene or polypropylene, twisted from high-modulus technical threads, for example NSVM (GOST 28007) or RUSAR ^R (TU 2272-001-51605609), and two insulated with polyethylene or polypropylene power conductors located symmetrically relative to the core and differing in color. The pairs and these power conductors are twisted into a cable around the reinforcing core, while the insulated conductive conductors are twisted into pairs by unidirectional twisting, and the twisting steps of all pairs are mutually agreed. All conductive wires are made of copper or tin-plated copper wires.

The difference is also that the cable according to the first embodiment may contain two pairs of conductive wires for transmitting electrical signals with a frequency of up to 12 MHz with an insulation thickness of at least 0.4 mm and four pairs of conductive conductors for receiving electrical signals with a frequency of up to 1 kHz with an insulation thickness of less than 0.25 mm.

In the second embodiment, the claimed cable differs from the prototype in that one of the pairs of conductive conductors is twisted with two reinforcing plaits of high modulus technical threads, for example NSVM (GOST 28007) or RUSAR ^R (TU 2272-001-51605609), and forms a central reinforcing element, the cable additionally contains two insulated polyethylene or polypropylene power conductive conductors located symmetrically relative to this reinforcing element and differing from each other in color. The pairs and these power conductors are twisted into a cable around the reinforcing element, in addition, the insulated conductive conductors are twisted into pairs by unidirectional twisting, the twisting steps of all pairs are mutually agreed. All conductive wires are made of copper or tin-plated copper wires.

In special cases, the cable according to the second embodiment contains 5 pairs of conductive wires for transmitting electrical signals with a frequency of up to 12 MHz with an insulation thickness of at least 0.4 mm.

In addition, the cable sheath in both cases is made of a single or double layer of thermoplastic elastomer or thermoplastic polyurethane, or of polyvinyl chloride plastic compound. Power conductors have a cross section of 1.34 mm ² and an insulation thickness of 0.4-0.05 mm to 0.4 + 0.05 mm.

The introduction of two power conductive conductors into the cable design, the cross section of which is much larger than the transmitting conductors, made it possible to use it not only as a transmitting signal (measuring), but also power when dimensions allow it to be used in the field. The optimal insulation values, the consistency of the twisting steps of the pairs, as well as the fact that the resistance of conductive wires from copper wires is less than from bimetallic wires, eliminates the influence of high-frequency electric signals on each other, ensures low electrical losses and low signal attenuation, thereby increasing noise immunity and get reliable results. The inventive cable due to the reinforcing core of high-modulus technical yarns (according to the first embodiment) and the reinforcing element formed by twisting a pair with bundles of high-modular technical yarns (according to the second embodiment), is characterized by low linear tension under the influence of mechanical stress when pulling the cable, including and in difficult operating conditions, for example, in swamps, that is, the cable has a high tensile strength, which due to the use of these technical threads is higher than that of protot pa High tensile strength, in turn, makes it possible to use small-diameter copper conductors as conductive conductors for transmitting high-frequency signals. The use of technical threads and soft, light and ductile copper provide flexibility (and therefore easy winding on the winch drum), less weight and dimensions. All this positively affects the operational reliability of the cable.

Both proposed cable options form a single creative concept, since they have the same purpose and the same technical result is achieved when they are implemented, eliminating the influence of the transmitting channels on each other when transmitting high-frequency signals, as well as providing flexibility and high tensile strength . All this has a positive effect on the operational reliability of the cable during its multiple rewinds in the field.

The specified set of essential features of the claimed utility model is not found in the prior art, which confirms the novelty of the claimed cable.

Next, the utility model is illustrated by drawings. In Fig.1 shows a cross section of a cable according to the first embodiment. Figure 2 - cross section of the cable according to the second embodiment

The cable contains power conductive conductors 1, insulated with polyethylene or polypropylene, and conductive, also insulated with polyethylene or polypropylene, conductors 2, twisted into pairs 3 (Fig. 1, 2), and conductors 4, twisted into pairs 5 (Fig. 1). Two pairs of 3 conductive conductors 2 and four pairs of 5 conductors 4 (Fig. 1) are twisted together with power conductive conductors 1 around a reinforcing core 6, which is twisted from high-modulus technical threads NSVM (GOST 28007) or RUSAR ^R (TU 2272-001-51605609 ) The reinforcing element according to the second embodiment (Fig. 2) is formed of one of five pairs of 3 conductive wires twisted with two reinforcing plaits 7, also made of high-modulus technical threads NSVM or RUSAR ^R The remaining four pairs 3 of five pairs of conductive conductors 2 (Fig. 2 ) are twisted together with power conductive conductors 1 around this reinforcing element. It is possible to use other equivalent materials from the range of high-modulus technical threads for the manufacture of a reinforcing core 6 and bundles 7. The core 6 (Fig. 1) is made in a shell of polyethylene or polypropylene. Over the general twist of pairs 3, 5 and power conductive conductors 1 (Fig. 1) or pairs 3 and conductors 1 (Fig. 2) a winding 8 of a polyethylene terephthalate film is applied, and over a winding 8 is a sheath 9 made of thermoplastic elastomer or thermoplastic polyurethane, or PVC compound. The shell can be single-layer or two-layer, but its nominal thickness should be at least 1.5 mm. The lower permissible deviation from the thickness shall not exceed 0.15 from this value.

All transmitting conductive conductors are made with a cross section of 0.12 mm ² from copper or copper tin-tinned wires and correspond to class 4 according to GOST 22483. The insulation thickness of conductors 2 is not less than 0.4 mm, and that of conductors 4 - not less than 0.25 mm. The insulation of conductive wires 2, 4 in each pair 3, 5 is different in color. In addition, pairs 3, 5 differ from each other in the color of at least one insulated conductive core. Each pair 3, 5 has its own twist step and these steps are mutually

matched for all couples. Power conductors are twisted from 19 copper wires with a diameter of 0.3 mm with a twisting step of no more than 16 diameters per twist and have a cross section of 1.34 mm ² and an insulation thickness of 0.4-0.05 mm to 0.4 + 0.05 mm Core insulation is different in color. The nominal cable diameter with the above parameters is 10 mm, and the weight of 1 km of cable is up to 114 kg. As you can see, its dimensions and weight are much lower than that of the prototype. The design parameters of the cable are determined based on the requirements for electrical parameters according to well-known methods.

The utility model is industrially applicable. The manufacturing technology of the inventive cable is simple and affordable and does not require complex special equipment. It is manufactured in cable factories using standard technological equipment for typical technological processes. The ends of the cable reinforcing elements are fixed with cold curing adhesive, which includes, for example, epoxy resin, polyethylene polyamine, dibutyl phthalate and talc. The cable is unwound during operation from the winch drum with a diameter of at least 150 mm. The design of the inventive cable and the insulation materials used make it possible to use it on the soil surface with traces of oil, organic acids and salt marshes, as well as to arrange separate sections in water at a depth of not more than 1 m. Cable termination in connecting devices is carried out by methods and methods that exclude shell damage and isolation veins.

Cable samples were tested and showed good results when transmitting electrical signals with a frequency of up to 12 MHz at an ambient temperature of minus 50 to plus 70 ° C. The cable withstands 100 bending cycles at an angle of ± π radians in a radius equal to (50 ± 5) mm with a tensile force of 50 N at temperatures up to minus 45 ° С.

Claims (12)

1. A flexible cable for seismic work, containing conductive conductors insulated with polyethylene or polypropylene, twisted into pairs, and then into a cable that differs in color by pair, a winding of polyethylene terephthalate film, laid on top of the general twisting of the pairs, the colors of each of which are different from the colors other pairs, and a sheath of elastic material made on top of the winding, characterized in that it further comprises a reinforcing core in a sheath of polyethylene or polypropylene, twisted from high modulus technical threads, two insulated conductive conductors, polyethylene or polypropylene, located symmetrically with respect to the core and differing in color, while the pairs and these conductors are twisted into a cable around the reinforcing core, and the insulated conductors are twisted in pairs by unidirectional twisting, and the steps twisting of all pairs is mutually agreed, except that all conductive wires are made of copper or tin-tinned copper wires. 2. The cable according to claim 1, characterized in that it contains two pairs of conductive conductors for transmitting electrical signals with a frequency of up to 12 MHz with an insulation thickness of at least 0.4 mm and four pairs of conductive conductors for receiving electrical signals with a frequency of up to 1 kHz with a thickness insulation not less than 0.25 mm. 3. The cable according to claim 1, characterized in that the core is twisted from high-modulus technical threads NSVM (GOST 28007) or RUSAR ^R (TU 2272-001-51605609). 4. The cable according to claim 1, characterized in that the power conductive conductors have a cross section of 1.34 mm ² and the insulation thickness is from 0.4-0.05 mm to 0.4 + 0.05 mm. 5. The cable according to claim 1, characterized in that the cable sheath is made of one or two layers of thermoplastic elastomer or thermoplastic polyurethane. 6. The cable according to claim 1, characterized in that the cable sheath is made of a single or double layer of polyvinyl chloride plastic compound. 7. Flexible cable for seismic work, containing conductive conductors insulated with polyethylene or polypropylene, twisted into pairs, and then into a cable that differs in color by pair, a winding of polyethylene terephthalate film, laid on top of the general twisting of the pairs, the color of each of which differs from the color other pairs, and a sheath of elastic material made on top of the winding, characterized in that one of the pairs of conductive wires is twisted with two reinforcing plaits of high-modulus technical threads and forms a center a reinforcing element, the cable additionally contains two insulated polyethylene or polypropylene power conductive wires located symmetrically relative to this reinforcing element and differing from each other in color, and the pairs and these power conductors are twisted into a cable around the reinforcing element, in addition, insulated conductive the strands are twisted in pairs by unidirectional twisting, the twisting steps of all pairs are mutually agreed, and all conductive strands are made of copper or tinned tinned copper wires milk. 8. The cable according to claim 7, characterized in that it contains 5 pairs of conductive wires for transmitting electrical signals with a frequency of up to 12 MHz with an insulation thickness of at least 0.4 mm. 9. The cable according to claim 7, characterized in that the reinforcing ropes are made of high-modulus technical threads NSVM (GOST 28007) or RUSAR ^R (TU 2272-001-51605609). 10. The cable according to claim 7, characterized in that the power conductive conductors have a cross section of 1.34 mm ² and an insulation thickness of from 0.4-0.05 mm to 0.4 + 0.05 mm. 11. The cable according to claim 7, characterized in that the cable sheath is made of one or two layers of thermoplastic elastomer or thermoplastic polyurethane. 12. The cable according to claim 7, characterized in that the cable sheath is made of a single or double layer of PVC compound.