RU171487U1 - COMBINED MULTIFUNCTION CARRYING CABLE - Google Patents

Abstract

The combined multifunctional load-carrying cable can be used to transmit electrical energy, information and electrical monitoring and control signals through numerous communication channels during special work in the open air in the temperature range from minus 30 (for cable bends) and from minus 50 (in a fixed state) up to plus 70 ° С. The cable contains a fiber optic group of conductors and four power conductive conductors with a cross section of 6.0 mm, which, together with the central load-bearing element, are twisted into the first coil. As a fiber group, a multimode of four fibers of the type G62.5 / 125 or G50 / 125 optical cable was used. The central load-bearing element is made in the form of a cable of ultra-high modular threads type NSVM, over which a braid of polyester threads is applied. The free space of the first coil is filled with filler of polypropylene fibrillated filaments. Four power conductive conductors with a cross section of 1.0 mm, two shielded pairs of conductive conductors with a cross section of 0.50 mm, four shielded pairs of conductive conductors with a cross section of 0.35 mm four four coaxial pairs, the inner and outer conductors of which are made of tinned copper wires, are twisted around the first winding. Conductors are made of copper wires and insulated with low-pressure polyethylene. The insulation of the conductors and the sheath over the external conductors of the coaxial pairs and the belt insulation over the shielded pairs are made of high pressure polyethylene. A fastening winding of polyethylene terephthalate film was applied over the general cable twist. A protective sheath of elastollan 1175A or elastollan 1180A is applied on top of the winding. The breaking strength of the cable is at least 4000 kgf. The cable, along with high strength, provides high speed data transfer. 5 cp f-ly, 1 ill.

Description

The utility model relates to cable technology, and more specifically to the design of load-bearing cables with versatility and multifunctionality, which can be used to transfer electrical energy to electrical devices, to transmit various information and electrical control signals through numerous communication channels during special operations on open air in a wide range of temperatures.

Known load-carrying cable for underwater operations according to the patent for utility model RU 71471, IPC НВВ 7/02, publ. 03/10/2008, designed to transmit communication signals and electrical power in underwater conditions when exposed to tensile forces and hydrostatic pressure. The cable contains at least two insulated conductive conductors for the transmission of electrical power, one shielded pair of insulated conductors for the transmission of communication signals, twisted in the core, filling elements, a fastening element, an inner sheath, a load-bearing element in the form of two mutually opposite windings of high-strength strands and protective sheath from elastic polymeric material. The core of the cable is made of two insulated conductive cores located in the recesses between the two filling elements twisted together, made in the form of cordels having a diameter larger than the mentioned insulated cores. The cores for the transmission of electrical power are placed between the bundles of threads of the first coil of the load-bearing element in diametrically opposite places. The cable according to RU 71471 allows you to expand the transmission range of communication signals, reduce the weight and size characteristics of the cable, increase its operational reliability. The disadvantage is the narrow scope of its application.

Known combined load-carrying marine cable according to the patent for utility model RU 48667, IPC НВВ 11/12, publ. 10.27.2005, which contains a central power element made of aramid filaments in a polyethylene sheath, around which copper conductive cores insulated with polyethylene insulation are twisted, and an optical module in the form of a polymer tube, inside which an optical fiber is located. The intramodular space is filled with a hydrophobic aggregate, and the space between the conductive conductors is sealed. The cable contains a common sheath of the polymer composition. The cable according to RU 48667 has increased mechanical strength and wider functionality in comparison with the previous analogue. The cable according to RU 48667 refers to the category of special cables designed to transmit electrical signals in sea water and air, for connecting and suspending apparatuses, lowering systems, towing objects behind a vessel.

Known cable sealed combined reinforced protection according to the patent for utility model RU 165636, IPC НВВ 11/02, publ. 10.27.2016, which is adopted as a prototype of the claimed cable. The cable according to RU 165636 contains a central load-bearing element made of synthetic high-modulus threads twisted into a core and power copper conductive wires, as well as copper conductive wires twisted in pairs and having a common sheath on which a screen of copper wires is superimposed. All conductive cores are insulated with a polyethylene composition, and the common shell of the pairs of conductive cores is made of a composition of a copolymer of ethylene with vinyl acetate. The interwire space and the free spaces of the core are filled with a sealing filler. All elements are fastened with a winding of synthetic film (polyethylene terephthalate film or of a water blocking tape) and are protected externally by a protective sheath made of a polymer elastomer (thermoplastic polyurethane composition). The prototype cable is intended for use in sea water and for transmitting low-voltage (up to 100 V) signals in the frequency range up to 100 MHz. The presence of a central load-bearing element made of synthetic high-modulus threads can withstand large longitudinal loads. The disadvantages include a narrow scope.

The technical problem solved by the utility model is to increase the versatility of the load-carrying cable, expand its functionality and scope while at the same time high resistance to longitudinal loads.

The technical result when operating the cable is a high breaking force and cable strength, which is very important for a load-carrying cable, and a reliable and high data transfer rate.

To solve a technical problem, a combined multifunctional load-carrying cable was proposed, which, like the prototype, contains a central load-bearing element made of synthetic high-modulus threads, multi-wire power conductors made of copper wires and insulated with polyethylene, a filler for free cable gaps and shielded twisted pairs of conductive wires, isolated by polyethylene. The screens of shielded twisted pairs are made in the form of a braid of copper wires, and the waist insulation on top of the shielded pairs is made of a polymer material. Like the prototype, the inventive cable contains a fastening winding of a polyethylene terephthalate film, overlaid on top of the general twist of all cable elements, and a protective sheath of polymer elastomer, superimposed on top of the fastening winding.

In contrast to the prototype, in the combined multifunctional load-carrying cable according to the utility model, the central load-bearing element is made in the form of a cable of ultra-high modulus NSVM threads, and a braid of polyester threads is laid over the central load-bearing element. Unlike the prototype, the inventive cable additionally contains a fiber optic group of cores, which, together with four power conductive conductors with a cross section of 6.0 mm ^{2, are} twisted with a central load-bearing element, forming the first coil. The free space in the first layer is filled with filler of polypropylene fibrillated filaments. In addition, the cable further comprises four coaxial pairs evenly spaced around the first coil. The internal conductors of coaxial pairs have a cross section of 0.08 mm ² and are made of tinned copper wires coated with high-pressure polyethylene insulation. The external conductors of the coaxial pairs are braided from tinned copper wires, and the sheath on top of the external conductor of the coaxial pair is made of high pressure polyethylene. Between the coaxial pairs are four power conductive conductors with a cross section of 1.0 mm ² , two conductors in two diametrically opposite places, two diametrically opposite twisted pair of conductive conductors with a cross section of 0.50 mm ² and four twisted conductive pairs of conductive conductors with a cross section of 0.35 mm ² , also located diametrically in two between coaxial pairs. Coaxial pairs and conductive conductors located between them and twisted shielded pairs are twisted around the first coil. The insulation of all conductive cores is made of low-pressure polyethylene, the belt insulation of shielded-pair screens is made of high-pressure polyethylene, and the protective sheath is made of thermoplastic elastomer.

In special cases, the cable winding is made of PET-E film, the cable sheath is made of elastollan 1175A or elastollan 1180A. As a fiber optic group of cores, a multimode of four fibers optical cable of the type G62.5 / 125 or G50 / 125 can be used.

The central load-bearing element, made in the form of a cable from ultra-high modulus threads of the type НСВМ and with a braid from polyester threads, provides high tensile strength and thereby high resistance to longitudinal loads and increased strength of the load-carrying cable. The fiber-optic group of cores (optical cable) with its low weight has a high bandwidth that provides maximum data transfer speed. In addition, the optical cable is immune to electromagnetic interference, since light pulses are not used for data transmission. The use of the inventive cable multimode optical cable allows you to transfer a large amount of data. The presence of coaxial cables allows you to transmit signals over communication channels in a wide range of technical fields. Thus, as a utility model, a universal copper carrying cable is proposed, which can be used to transmit video signals, voice signals, in computer networks, remote control systems, measurement, control, to power electrical devices, lowering and raising equipment, etc. The multifunctional cable is economical for the consumer, since it excludes the purchase of additional power and communication wires and their installation.

The drawing shows a combined multifunctional load-carrying cable in the context.

The combined multifunctional load-carrying cable contains a fiber optic group of conductors 1 and four power conductive conductors 2 with a cross section of 6.0 mm ² twisted with a central load-carrying element 3 in the first coil. As a fiber optic group of cores 1, a multimode four-fiber optical cable of type G62.5 / 125 or type G50 / 125 was used. As the central load-bearing element 3, a cable made of ultra-high-modulus NSMF threads with a braid 5 of polyester threads was used. The free spaces in the first layer are filled with filler 4 of polypropylene fibrillated yarns. Four power conductive conductors 6, 7, 8, 9 with a cross section of 1.0 mm ² , two shielded pairs of 10, 11 conductive conductors with a cross section of 0.50 mm ² , four shielded pairs of 12, 13, 14, 15 conductive conductors with a cross section are twisted around the first winding 0.35 mm and four coaxial pairs 16, 17, 18, 19. The inner conductors of the coaxial pairs 16, 17, 18, 19 are made of tinned copper wires and coated with high-pressure polyethylene insulation. The external conductors of the coaxial pairs are made in the form of a braid of tinned copper wires with insulation of high pressure polyethylene. The insulation of conductive conductors 2, 6, 7, 8, 9 and conductive conductors of shielded pairs 10, 11, 12, 13, 14, 15 is made of low-pressure polyethylene, and the waist insulation of the screens of all shielded pairs is made of high-pressure polyethylene. All cable elements are fastened by a winding 20 of a polyethylene terephthalate film, for example, PET-E film. On top of the cable, a protective sheath 21 is made of thermoplastic elastomer (elastollan 1175A or elastollan 1180A).

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. Наложение изоляции из полиэтилена низкого давления на все токопроводящие жилы 2, 6, 7, 8, 9 и токопроводящие жилы экранированных пар 10, 11, 12, 13, 14, 15 осуществляют на стандартном экструзионном оборудовании. Наложение поясной изоляции из полиэтилена высокого давления на экраны экранированных пар 10, 11, 12, 13, 14, 15 и внешние проводники коаксиальных пар 16, 17, 18, 19 тоже осуществляют на стандартном экструзионном оборудовании. В качестве экструзионного оборудования используют, например, экструзионные линии МЕ-1-90, ME-1-60. Оплетку 5 из полиэфирных нитей с шагом 21,0 мм и толщиной 0,14 мм выполняют на оплеточной машине, например «Унитекс-24». Общую скрутку всех элементов кабеля и скрепляющую обмотку 20 из полиэтилентерефталатной пленки с шагом 44,7 мм и толщиной 0,02 мм осуществляют на крутильной машине фонарного типа, например марки МКРД. Наложение защитной оболочки 21 из эластоллана 1175А или эластоллана 1180А плотностью 1,14 г/см³ выполняют на экструзионной линии МЕ-1-160. Готовый комбинированный многофункциональный грузонесущий кабель перематывают на кабельный барабан на перемоточном станке, например КПС-2000.In the information sources, no cables were found that possess the entire set of essential features characterizing the claimed utility model. This confirms the novelty of the inventive combined multifunctional load-carrying cable. The utility model is industrially applicable. In the manufacture of a combined multifunctional load-carrying cable, well-known materials produced by the industry are used, and the cable manufacturing technology is based on the use of industrial cable equipment. Tinning of copper wire for coaxial pairs is carried out on a hot tinning unit at a temperature of 400-440 ° C. The twisting of copper wires of all conductive cores and internal conductors of coaxial pairs 16, 17, 18, 19 is carried out on frame twisting machines, for example brands

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. The insulation of low pressure polyethylene on all conductive conductors 2, 6, 7, 8, 9 and conductive conductors of shielded pairs 10, 11, 12, 13, 14, 15 is carried out on standard extrusion equipment. Overlay insulation of high pressure polyethylene on the screens of shielded pairs 10, 11, 12, 13, 14, 15 and the external conductors of coaxial pairs 16, 17, 18, 19 are also applied on standard extrusion equipment. As extrusion equipment, for example, extrusion lines ME-1-90, ME-1-60 are used. A braid 5 of polyester yarns with a pitch of 21.0 mm and a thickness of 0.14 mm is performed on a braiding machine, for example, Unitex-24. The general twisting of all cable elements and the fastening winding 20 of polyethylene terephthalate film with a pitch of 44.7 mm and a thickness of 0.02 mm is carried out on a torsion-type machine of a flashlight type, for example, MKRD brand. The application of a protective shell 21 of elastollan 1175A or elastollan 1180A with a density of 1.14 g / cm ^{3 is} performed on the extrusion line ME-1-160. The finished combined multifunctional load-carrying cable is rewound to a cable drum on a rewinder, for example KPS-2000.

Cable tests showed that with an outer diameter of the cable of not more than 32 mm, the breaking force is not less than 4000 kgf. Resistance to increased tensile force of the combined multifunctional load-carrying cable is provided by the central load-bearing element of ultra-high modulus NSVM filaments capable of withstanding large longitudinal loads. The presence of fiber-optic cable and coaxial pairs in the cable allows, along with power supply to devices and equipment, to provide high-speed data transmission and expand the functionality and scope of the load-carrying cable. The use of heat-resistant materials allows the cable to be used at temperatures from minus 30 (for cable bends) and from minus 50 (in a fixed state) to plus 70 ° C.

Claims (6)

1. Combined multifunctional load-carrying cable, including a central load-bearing element made of synthetic high-modulus filaments, multi-wire power conductors made of copper wires and insulated with polyethylene, filler for free cable gaps, shielded twisted pairs of conductive wires insulated with polyethylene, the screens of which are made in the form of a braid made of copper wires, and the belt insulation on top of the shielded pairs is made of a polymeric material fastening the winding of polyethylene an enterephthalate film overlaid on a common cable twist and a protective sheath made of a polymer elastomer overlaid on top of the fastening winding, characterized in that the central load-bearing element is made in the form of a cable from ultra-high modulus HCBM threads, and a braid made of polyester threads is laid over the central load-bearing element, the cable additionally contains a fiber optic group of conductors, which, together with four power conductive conductors with a cross section of 6.0 mm ^2, is twisted with a central load-bearing element, The first coil, the free gap of which is filled with filler made of polypropylene fibrillated filaments, in addition, the cable additionally contains four coaxial pairs evenly spaced around the first coil, the inner conductors of which have a cross section of 0.08 mm ² and are made of tinned copper wires coated with insulation from high-pressure polyethylene, the outer conductors of the coaxial pairs are made in the form of a braid of tinned copper wires, and the sheath on top of the outer conductor of the coaxial pair is made of polyethylene Exposure to extreme pressure, wherein between coaxial pairs are four power conducting core cross-section 1.0 mm ^2, two wires in two diametrically opposite positions, two diametrically opposite shielded twisted pairs of conductors section of 0.50 mm ^2, and four twisted pairs of conductors shielded a cross-section of 0.35 mm ² also arranged diametrically in two between coaxial pairs; the coaxial pairs and the conductive conductors and twisted shielded pairs between them are twisted around the first coil, in addition, the insulation of all conductive veins is made of low-pressure polyethylene, the waist insulation of the screens of the shielded pairs is made of high-pressure polyethylene, and the protective sheath is made of thermoplastic elastomer. 2. The cable according to claim 1, characterized in that the cable winding is made of PET-E film. 3. The cable according to claim 1, characterized in that a multimode four-fiber optical cable of the type G62.5 / 125 is used as a fiber optic group. 4. The cable according to claim 1, characterized in that a multimode four-fiber optical cable of the G50 / 125 type is used as a fiber group of cores. 5. The cable according to claim 1, characterized in that the cable sheath is made of 1175A elastollan. 6. The cable according to claim 1, characterized in that the protective sheath of the cable is made of elastollan 1180A.

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