RU196042U1 - Communication cable - Google Patents

Abstract

The utility model relates to the cable industry, namely to multi-pair electrical communication cables designed to transmit high-frequency signals. The technical result is to expand the field of operation of the cable. The communication cable is a core covered with a polymer moisture-proof sheath. The core includes several elementary beams twisted together, containing from 3 to 5 pairs of conductive wires with a nominal diameter of 0.51 to 0.52 mm, insulated with polymer and twisted together. The twisting of the pairs was performed with agreed steps, mutually non-multiple and not exceeding 35 mm. Unlike the closest analogue, the twisting steps of all twisted pairs inside each elementary beam and pairs in adjacent elementary beams differ from each other by at least 1 mm. 14 s.p. f-ly, 3 Fig., 3 tables.

Description

The utility model relates to the cable industry, namely to multi-pair electrical communication cables, designed to transmit high-frequency signals.

The prior art electric communication cable containing a core with twisted pairs of conductive conductors with insulation, a belt insulation of dielectric material, a common screen and an outer sheath are applied over the core, characterized in that each pair of twisted together conductive conductors with a three-layer film porous-film polyethylene insulation is made with its own twisting step, of which five-pair bundles are formed, while the twisting step of each five-pair bundle differs from the twisting step in other five-pair bundles that are part of the core, the belt insulation of each five-pair bundle is made of polyethylene terephthalate tape, and the common screen is made of aluminum-polymer tape, the outer shell is made of polyvinyl chloride plastic compound or low combustibility plastic compound. [Patent No. 81373, publication date 03/10/2009]

Also known from the prior art is a telephone communication cable consisting of a core comprising several conductive cores insulated with polymer, twisted together in pairs and then twisted into a core, and a polymer moisture-proof sheath, characterized in that the copper conductive cores are single-wire with a nominal diameter of 0 , 51 mm or 0.52 mm, the insulation is continuous and / or foamed, or from radially alternating named layers of a composition based on polyethylene and / or polypropylene, and / or its block copoly pa, the isolated conductors are twisted in pairs with coordinated steps, the twisting steps of the pairs being individual, mutually non-multiple and not exceeding 35 mm, the pairs are twisted into elementary bundles containing no more than 4 pairs that are twisted into a core or into main bundles, which in turn twisted into a core. [Patent No. 82921, publication date 05/10/2009]

The closest analogue of the claimed utility model is a high-frequency local communication cable for digital transmission systems on broadband access networks in the frequency range up to 100 MHz with copper conductors twisted into pairs of unidirectional twisting, with continuous polyethylene or solid insulation from polymer compositions that do not contain halogens, or a three-layer film-porous-film polyethylene insulation, shielded, with or without water blocking elements, in polyethylene or polyvinyl chloride plastic sleeve (including reduced flammability and reduced fire hazard), or a shell made of polymer compositions, halogen-free, with or without a protective coating, characterized in that the insulated conductive wires are twisted in unidirectional twisted pairs with coordinated steps within 10-30 mm , each pair inside three (four, five) pair bundles is made with its own twisting step: the first 12 ± 0.05 mm, the second pair 15 ± 0.05 mm, the third pair 17 ± 0.05 mm, the fourth pair 21 ± 0, 05 mm, fifth pair 29 ± 0.05 mm. [Patent for No. 98628, publication date 10/20/2010]

The main disadvantage of the known communication cables is the inability to use them for a digital Ethernet signal transmission system, at which a data transfer rate of up to 250 Mbps is achieved.

The technical problem, which the claimed model is aimed at, is to increase the noise immunity of neighboring twisted pairs.

The technical result is to expand the field of cable operation.

The essence of the claimed device is as follows.

The communication cable is a core coated with a polymer moisture-proof sheath. The core includes several elementary beams twisted together, containing from 3 to 5 pairs of conductive conductors with a nominal diameter of 0.51 to 0.52 mm, insulated with polymer and twisted together. The twisting of the pairs was performed with agreed steps, mutually non-multiple and not exceeding 35 mm. Unlike the closest analogue, the twisting steps of all twisted pairs inside each elementary beam and pairs in adjacent elementary beams differ from each other by at least 1 mm.

The selected diameter of the conductive conductors is due to production standards and the high prevalence of cables with conductive conductors with a diameter of 0.51 to 0.52 mm. The core is made of pre-twisted elementary bundles containing from 3 to 5 pairs of insulated conductive wires twisted together, due to the optimization of the production process, namely, the optimal ratio of the speed of the twisting machines and the maximum number of twisted pairs in the cable. Thus, twisting into elementary bundles and subsequent twisting into the core of the required cable is the most optimal. Additionally, elementary bundles can be twisted into main bundles, and then twisted into a core. The most optimal ratio of noise immunity of neighboring twisted pairs and production costs is provided when the number of pairs in the cable is from 10 to 25.

Depending on the conditions of use of the cable, the conductive conductors can be made single-wire or multi-wire, for example, for the use of the cable in conditions of movable installation, the conductive conductors can be made multi-wire.

Various materials can be used as insulation materials, depending on the cable operating conditions and the corresponding requirements for dielectric constant, moisture permeability, hardness, resistance to mechanical damage and fire protection requirements, such as, for example, polyethylene, polypropylene, polypropylene block copolymer. These materials can be used both independently and as part of multilayer compositions of them, for example, as part of a three-layer composition, while the central layer can be made foam, and the inner and outer layers can be continuous, due to which the dielectric constant of the materials is further reduced, this, due to the inner layer of solid material, the low adhesion of the foamed material to the conductive core is compensated, in general, the foam layer is waterproofed and protected against excess uktsii.

Additionally, to ensure fire safety, belt insulation with overlapping of polyethylene terephthalate or polyvinyl chloride tape can be applied over the core, thereby reducing the likelihood of fusion of the insulation of conductive conductors. On top of the belt insulation, the cable can be equipped with a thermal barrier made of glass tape or a glass-mica tape, which prevents the cable insulation from spreading in a fire under indirect fire.

In addition, in order to preserve the intrinsic attenuation indicators in the presence of requirements for non-proliferation of combustion and smoke and gas emissions, materials such as, for example, polyvinyl chloride plastic compound, special polyvinyl chloride plastic compound with a low smoke and gas index of at least 28, a halogen-free polymer composition with an oxygen index of at least 2, while the cable sheath can be made of materials such as, for example, polyvinyl chloride plastic compound, special polyvinyl chloride plastic compound with reduced smoke emission and an oxygen index of at least 30, a halogen-free polymer composition with an oxygen index of at least 35.

In order to protect the cable core from external electromagnetic influences, the cable can additionally be equipped with a metal-polymer screen located under the moisture-proof sheath with the polymer facing upward, with a copper or tinned wire additionally located under the screen. Aluminum or copper can be used as the screen metal, and tinned copper wire or copper wire, respectively, can be selected as the material of the wire, depending on the metal. For shielding from external electromagnetic signals of a cable of a movable installation, the screen can be made of a flexible braid of tinned copper or copper wires at low-frequency signals, or two-layer for a wide frequency range, the first layer can be made of metal-polymer, and the second can be made of copper or tinned copper wire depending on the metal in the composition of the first layer.

Additionally, when using a cable by laying in the ground and cable ducts, the core can be filled with a hydrophobic aggregate. If there is a waist insulation and a shield, the space between the waist insulation and the shield can also be filled with a hydrophobic aggregate.

For the purposes of the correct subsequent disassembly of the cable at the near and far ends, the cable can be made with individual colors of insulation, which allows you to identify any pair in the core of the cable, as well as to distinguish between the cores in pairs.

The twisting of adjacent pairs in the cable with a pitch difference of at least 1 mm provides an increase in the transient attenuation between pairs of neighboring elementary beams by at least 5 dB, thereby ensuring noise immunity of the circuits from the influence of signals transmitted through neighboring pairs and, as a result, expanding the region cable operation, namely, the use of a digital Ethernet signal for various types of transmission systems, at which a data transfer rate of up to 250 Mbps is achieved.

The above distinguishing essential features provide a solution to the problem of increasing the noise immunity of neighboring twisted pairs, due to which a technical result is achieved by expanding the field of cable operation, which allows us to conclude that the claimed utility model meets the patentability criterion of "novelty".

The inventive utility model can be performed by known methods from known materials, which ensures its compliance with the patentability criterion of "industrial applicability".

The essence of the claimed utility model is illustrated by the following drawings:

FIG. 1 is a cross-sectional view of a ten-pair communication cable.

Table 1 - distribution of the pitch of the twist of a ten-pair communication cable.

FIG. 2 is a cross-sectional view of a sixteen-pair communication cable.

Table 2 - distribution of the pitch of the sixteen-pair communication cable.

FIG. 3 is a cross-sectional view of a twenty-pair communication cable.

Table 3 - Twist pitch distribution of a twenty-pair communication cable.

Example 1. The communication cable is a core 1 coated with a polymer moisture-proof sheath 2. The core includes 3 elementary bundles twisted together. Elementary bundle III contains 4 pairs of conductive conductors, and elementary bundles I and II - three pairs of conductive conductors in each, while conductive conductors 3 are isolated by polymer 4 and twisted together. Conducting cores 3 are made with a nominal diameter of 0.51 to 0.52 mm, the twisting of the pairs is made with agreed steps, mutually non-multiple and not exceeding 35 mm. Twisting step of twisted pairs inside the elementary beam I - 10 mm, 13 mm, 15 mm; inside the elementary beam II - 12 mm, 16 mm, 20 mm; inside the elementary beam III - 11 mm, 14 mm, 17 mm, 22 mm.

Example 2. The communication cable is a core 1 coated with a polymer moisture-proof sheath 2. The core includes 4 elementary bundles twisted together, each of which contains 4 pairs of conductive wires 3, twisted together and insulated with polymer 4. The conductive wires 3 are made with with a nominal diameter of 0.51 to 0.52 mm, the twisting of the pairs is performed with agreed steps, mutually non-multiple and not exceeding 35 mm. Twisting step of twisted pairs inside the elementary beam I - 10 mm, 15 mm, 18 mm, 24 mm; inside the elementary beam II - 12 mm, 16 mm, 20 mm, 25 mm; inside the elementary beam III - 11 mm, 14 mm, 17 mm, 22 mm; inside the elementary IV beam - 9 mm, 13 mm, 19 mm, 23 mm.

Example 3. The communication cable is a core 1 coated with a polymer moisture-proof sheath 2. The core includes 7 elementary bundles twisted together, containing 3 conductive pairs of pairs, twisted together and isolated by polymer 4. In this case, elementary bundles II, IV, VI contain 3 pairs of conductive conductors, elementary bundles I, III, V, VII contain 4 pairs of conductive conductors. Conducting cores 3 are made with a nominal diameter of 0.51 to 0.52 mm, the twisting of the pairs is made with agreed steps, mutually non-multiple and not exceeding 35 mm. Twisting step of twisted pairs inside the elementary beam I - 10 mm, 15 mm, 18 mm, 24 mm; inside the elementary beam II, IV, VI - 12 mm, 16 mm, 20 mm; inside the elementary beam III, V, VII - 11 mm, 14 mm, 17 mm, 22 mm.

A single-wire conductive core of the required diameter is obtained by drawing wires on drawing machines. The multiwire conductive core is twisted from several wires on cigar machines or frame type machines. Insulation 4 and sheath 2 are applied on automatic extrusion lines. The twisting of 3 lived in pairs and in elementary bundles I-VII is performed on twisting machines of a frame type. The twisting of elementary bundles I-VII into the core 1 is carried out on a twisting machine of general twisting.

Communication cable

Elementary Beam Number The pitch of a pair of conductive wires, mm I 10 thirteen fifteen II 12 16 20 III eleven 14 17 22

Table 1

Communication cable

Elementary Beam Number The pitch of a pair of conductive wires, mm Elementary Beam Number The pitch of a pair of conductive wires, mm I 10 III eleven fifteen 14 18 17 24 22 II 12 IV 9 16 thirteen 20 19 25 23

table 2

Communication cable

Elementary Beam Number The pitch of a pair of conductive wires, mm Elementary Beam Number The pitch of a pair of conductive wires, mm I 10 V eleven fifteen 14 18 17 24 22 II 12 VI 12 16 16 20 20 III eleven VII eleven 14 14 17 17 22 22 IV 12 16 20

Table 3

Claims (15)

1. Communication cable, which is a core covered with a polymer moisture-proof sheath, including several elementary bundles twisted together, containing from 3 to 5 pairs of conductive conductors with a nominal diameter of 0.51 to 0.52 mm, which are insulated with polymer and twisted among themselves, the twisting of pairs is performed with agreed steps, mutually non-multiple and not exceeding 35 mm, characterized in that the steps of twisting all twisted pairs inside each elementary bundle and pairs in adjacent elementary bundles differ from each other in k at least 1 mm. 2. The communication cable according to claim 1, characterized in that the conductive conductors are multi-wire. 3. The communication cable according to claim 1, characterized in that a belt insulation with overlapping is applied over the core. 4. The communication cable according to claim 3, characterized in that the overlap of the waist insulation is made of polyethylene terephthalate tape. 5. The communication cable according to claim 3, characterized in that the overlap of the waist insulation is made of polyvinyl chloride tape. 6. The communication cable according to claim 3, characterized in that on top of the belt insulation, the cable is equipped with a thermal barrier. 7. The cable according to claim 6, characterized in that the thermal barrier is made of glass tape. 8. The cable according to claim 6, characterized in that the thermal barrier is made of glass-mica tape. 9. The communication cable according to claim 1, characterized in that the core is filled with a hydrophobic aggregate. 10. The communication cable according to claim 1, characterized in that it contains a metal-polymer screen located under the moisture-proof sheath with the polymer upward with overlapping. 11. Cable according to claims 3, 10 characterized in that the space between the belt insulation and the metal-polymer screen is filled with a hydrophobic aggregate. 12. The communication cable according to claim 1, characterized in that a three-layer polymer composition is used as the insulating material, the central layer being made foam and the inner and outer layers solid. 13. The communication cable according to item 12, characterized in that the polymer used is polyethylene. 14. The communication cable according to claim 12, characterized in that polypropylene is used as the polymer. 15. The communication cable according to item 12, characterized in that the polymer is a block copolymer of polypropylene.

Images