RU81373U1 - ELECTRIC COMMUNICATION CABLE (OPTIONS) - Google Patents

Abstract

The utility model relates to the cable industry, namely to multi-pair electrical communication cables and can be used in the construction of communication cables and signaling. Eight options for electric communication cable are offered. The first version of the electric communication cable (Fig. 1) contains a core 1 with twisted pairs of conductive conductors 2 with a three-layer film-porous-film-film polyethylene insulation 3. Each pair of twisted together conductive conductors 2 is made with its own twisting step, while the pair of conductive cores 2 with insulation 3 are twisted into five-pair bundles 4. The twist step of each five-pair bundle 4 is different from the twist step in other five-pair bundles that are part of the core 1. The belt insulation 5 of each five-pair bundle 4 is made and polietilentereftolatnoy tape. On the core 1 of the electric communication cable is sequentially superimposed a common screen 6, which is made of aluminum-polymer tape and the outer shell 7. The outer shell 7 can be made of polyvinylchloride plastic compound or low flammable plastic compound. The core design described above is used for all of the proposed electrical communication cable options. The second variant of the electric communication cable (Fig. 2) is structurally different from the first variant by the presence of belt insulation 5 of polyethylene terephthalate tape at the core 1 and screen 8, which is laid on top of the belt insulation 5 of each five-pair bundle 4 and is made of alumoflex, and screen 8 is superimposed with an aluminum layer inside a five-pair beam 4.

The third variant of the electric communication cable (Fig. 3) is structurally different from the first variant in that a water blocking thread 9 is inserted into each five-pair bundle 4, while the waist insulation 5 of each five-pair bundle 4 and the waist insulation 10 of the core 1 are made of water blocking tape. On the belt insulation 10 of the core 1 are sequentially superimposed a common screen 6 of aluminum-polymer tape and an outer shell 7 made of polyethylene. The fourth embodiment of the electric communication cable (Fig. 4) is structurally different from the third embodiment in that water blocking threads 9 are introduced into each five-pair bundle 4 and core 1, while the waist insulation 5 of each five-pair bundle 4 and the waist insulation 10 of core 1 are made of water blocking tape . On top of the belt insulation 5 of each five-pair bundle 4, an aluminum-flex screen 8 is laid with an aluminum layer inside the five-pair bundle 4. The fifth embodiment of the electric communication cable (Fig. 5) is structurally different from the third version in that water blocking thread 9 is inserted into each five-pair bundle 4 and core 1 wherein the waist insulation 5 of each five-pair bundle 4 and waist insulation 10 of the core 1 is made of water blocking tape. On the waist insulation 10 of the core 1 are sequentially superimposed a common screen 6 of aluminum-polymer tape and an outer shell 7 made of polyethylene, and two anti-corrosion steel tapes 11 that protect the cable from the effects of rodents. The sixth embodiment of the electric communication cable (FIG. 6) is structurally different from the fifth embodiment in that over the belt insulation 5 of each five-pair bundle 4, a screen 8 of aluminum-flex is laid with an aluminum layer inside the five-pair bundle 4.

The seventh version of the electric communication cable (Fig. 7) is structurally different from the sixth version in that the common screen 6 is sequentially braided from galvanized steel wire 12, and then the outer sheath 7 made of polyethylene. In this embodiment, there is no screen 8 of the five-pair bundle 4. The eighth version of the electric communication cable (Fig. 8) is structurally different from the seventh version in that over the waist insulation 5 of each five-pair bundle 4, a screen 8 of aluminum-flex is laid with an aluminum layer inside the bundle 4. Braid 12 of galvanized steel wire provides protection from rodents and at the same time is a trellis screen, reducing the influence of external electromagnetic fields. Due to the presence in the insulation 3 layers of continuous polyethylene adjacent to the core 2, it allows to improve the adhesion between the conductive core and the insulation and thereby prevent the penetration of moisture. The use of water-blocking threads 9 in the center of a five-pair bundle 4 eliminates moisture penetration and maintains the correct arrangement of pairs in the bundle. High stability of physical foaming allows achieving the best readings of a coaxial capacity of 115 PF / m ± 1.5, which provides the best result of transient attenuation and protection. The use of physical foaming up to 65% reduces the level of intrinsic attenuation of the pairs in the cable and when the screens 8 are tightly placed on the five-pair bundles 4 it provides the pair capacitance necessary for normal operation of the ADSL and ADSL2 + systems no more than 50 nF / km. The structural arrangement and balance of the steps of the pairs in beam 4 makes it possible to achieve security of 100% combinations of 35 dB, 90% - 50 dB, 60% - 65 dB at a frequency of 0 to 4 MHz. Therefore, at least 90% of the pairs in the cable must be sealed by ADSL systems and

ADSL2 + at the same time allows you to achieve maximum data transfer speed. The proposed options for electric cables give a wide range of their application, in particular for laying on the inner walls of buildings and indoors, for laying in the ground, in telephone conduits, in collectors of mines, tunnels, suspension on overhead communication lines, in conditions of high humidity, in areas characterized by increased risk of damage by rodents. The use of film-porous-film polyethylene insulation with coordinated steps of twisting of conductive conductors and five-pair bundles, the introduction of aluminoflex shields for elementary five-pair bundles, and the use of water-blocking tapes in waist insulation both in five-pair bundles and for the core made it possible to create various options for communication cables with high performance and reliability. 8 sec 4 s.p. utility model formulas, 8 ill.

Description

The utility model relates to the cable industry, namely to multi-pair electrical communication cables and can be used in the construction of communication cables and signaling.

Known cables for transmitting digital high-frequency signals, which are used in modern automatic telephone exchanges and which contain conductive wires of soft copper wire, insulated with solid polyethylene of individual colors, twisted into a pair, on which is applied longitudinally or in a spiral with overlapping aluminum-lavsan tape metal inward with a feed under the screen of tinned copper wire, while on top of the screen a lavsan ribbon is applied in a spiral with overlapping (“Cable products.” 2. Cables, wires and communication cables. Part 2 "Information and technical collection", Moscow, JSC "VNIIKP").

A communication cable is known, including two conductive cores equipped with insulating sheaths and twisted into a pair, on top of which an electric screen is applied, a wire located under the screen and a moisture-proof sheath that is not spreading burning imposed on the screen, the insulation sheath of each of the wires is made of foamed polyethylene or two-layer: made of foamed polyethylene and a layer on top of it made of continuous polyethylene 0.05 mm thick or three-layer: a layer of continuous polyethylene 0.05 mm thick, located on top of it a layer of polyethylene foam and disposed on top of the last layer of the continuous polyethylene with a thickness

0.05 mm, and the thickness of the insulating sheath made of foamed polyethylene, or the total thickness of the two-layer insulating sheath or the total thickness of the three-layer insulating sheath, providing wave resistance in the range from 110 Ohms to 130 Ohms at frequencies of 1 MHz or more and each equal to d -0.05 mm for current-conducting conductors with a diameter selected from the range: from 0.3 to 0.65 mm inclusive and diameter d for conductive conductors with a diameter selected from the range: over 0.65 mm to 1.0 mm inclusive. (see RF Patent No. 57508)

The closest technical solution to the proposed options for electric communication cables is an electric communication cable containing at least two pairs of copper or tinned copper single-wire or multi-wire conductive wires twisted together with a pitch of not more than 100 mm, with insulation made of PVC compound, core, formed by these pairs twisted together, on top of which a common belt insulation of dielectric material is sequentially applied, a common screen and an external plate tmass sheath, on each pair of conductive conductors twisted together on top of the insulation, individual belt insulation of dielectric material is additionally applied, a shield made of laminated copper or laminated aluminum tape with a shield wire under it or from a braid of copper or tinned copper wire and a sheath of polyvinylchloride plastic compound with oxygen an index of at least 21 or a halogen-free polyolefin composition with an oxygen index of at least 35. (see RF patent No. 53811)

Common disadvantages of the known communication cables include the increased dielectric constant of the insulation of the conductive core, insufficient adhesion between the conductive core and insulation, the possibility of moisture penetration between the conductor and insulation,

insufficient indicators of capacitance and capacitive asymmetry in the cables and, accordingly, a high attenuation coefficient, insufficient mechanical strength.

The technical problem solved by the proposed utility model is the elimination of these shortcomings of the known electric communication cables and the creation of an electric communication cable having the smallest possible size and ensuring its use in modern communication equipment for transmitting digital high-frequency signals with the possibility of transmitting a digital information signal at a speed of 50 Mbps s in the private range up to 4 MHz.

The technical result consists in reducing the dielectric constant of the insulation of the conductive core through the use of foamed polyethylene, improving adhesion between the conductive core and insulation due to the presence of a layer of continuous polyethylene adjacent to the core, eliminating the penetration of moisture between the insulation conductor by using water blocking threads and water blocking tapes , improving capacitance and capacitance asymmetry in cables and, accordingly, reducing the attenuation coefficient And also in enhancing the mechanical strength.

The specified technical result according to the first embodiment is achieved by the fact that in a electric communication cable containing a core with pairs of conductive conductors with insulation twisted together, a belt insulation of dielectric material, a common screen and an outer sheath are laid over the core, each pair of conductive conductors twisted together 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

the beam differs from the twist step in the other five-pair bundles that make up the core, the waist 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.

The specified technical result according to the second embodiment is achieved by the fact that in a electric communication cable containing a core with pairs of conductive conductors with insulation twisted together, a belt insulation of dielectric material, a common screen and an outer sheath are laid over the core, each pair of conductive conductors twisted together 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 is about It differs from the twist step in the other five-pair bundles that make up the core, the belt insulation of each five-pair bundle and the core is made of polyethylene terephthalate tape, and on top of the belt insulation of each five-pair bundle an aluminum film screen is applied with an aluminum layer inside the beam, the common screen is made of aluminum-polymer tape, the outer the shell is made of polyvinylchloride plastic compound or low flammability plastic compound.

The indicated technical result according to the third embodiment is achieved by the fact that in a electric communication cable containing a core with pairs of conductive conductors with insulation twisted together, a belt insulation of dielectric material, a common screen and an outer sheath are laid over the core, each pair of conductive conductors twisted together with three-layer film-porous-film

polyethylene insulation is made with its own twisting step, from 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, a water blocking thread is introduced into each five-pair bundle, and the waist insulation of each five-pair bundle and the core is made of a water-blocking tape, while a common screen of aluminum-polymer tape and a polyethylene outer shell are sequentially superimposed on the waist insulation of the core.

The specified technical result according to the fourth embodiment is achieved by the fact that in a electric communication cable containing a core with pairs of conductive conductors with insulation twisted together, a belt insulation of dielectric material, a common screen and an outer sheath are laid over the core, each pair of conductive conductors twisted together 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 and differs from the twist step in the other five-pair bundles that make up the core, water-blocking threads are introduced into each five-pair bundle and core, and the waist insulation of each five-pair bundle and core is made of water-blocking tape, and an aluminum-aluminum screen is applied over the waist insulation of each five-pair bundle a layer inside the beam, and a common screen made of aluminum-polymer tape and a polyethylene outer shell are sequentially superimposed on the waist insulation of the core.

The specified technical result according to the fifth embodiment is achieved by the fact that in an electric communication cable containing a core with twisted

interconnected by pairs of conductive conductors with insulation, a belt insulation of dielectric material, a common screen and an outer shell are laid over the core, each pair of conductive conductors twisted together 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 twist step of each five-pair bundle differs from the twist step in other five-pair bundles that are part of the core, a water block is introduced into each five-pair bundle and core thread guides, and each belt insulation pyatiparnogo beam and the core is made of a water-blocking tape, while on the belt core insulation sequentially superimposed common screen alumopolymer of tape, plastic outer shell and two anticorrosive steel tape.

The specified technical result according to the sixth embodiment is achieved by the fact that in the electric communication cable comprising a core with pairs of conductive conductors with insulation twisted together, a belt insulation of dielectric material, a common screen and an outer sheath are laid over the core, each pair of conductive conductors twisted together 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 is about It differs from the twist step in the other five-pair bundles that make up the core, water-blocking threads are introduced into each five-pair bundle and core, and the waist insulation of each five-pair bundle and core is made of water-blocking tape, and an aluminum-aluminum screen is applied over the waist insulation of each five-pair bundle. inside the beam, and a common aluminum-polymer screen is sequentially superimposed on the waist insulation of the core

tapes, polyethylene outer sheath and two anti-corrosion steel tapes.

The indicated technical result according to the seventh embodiment is achieved by the fact that in a electric communication cable containing a core with pairs of conductive conductors with insulation twisted together, a belt insulation of dielectric material, a common screen and an outer sheath are laid on top of the core, each pair of conductive conductors twisted together 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 twist step in other five-pair bundles that make up the core, water-blocking threads are introduced into each five-pair bundle and core, and the waist insulation of each five-pair bundle and core is made of a water-blocking tape, and a common screen made of aluminum-polymer tape is sequentially applied to the core insulation of the core , galvanized steel wire braid and polyethylene outer sheath.

The specified technical result according to the eighth embodiment is achieved by the fact that in a electric communication cable containing a core with pairs of conductive conductors with insulation twisted together, a belt insulation of dielectric material, a common screen and an outer sheath are laid over the core, each pair of conductive conductors twisted together 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 different from the twist step in other five-pair bundles,

constituent of the core, water-blocking threads are introduced into each five-pair bundle and core, and the waist insulation of each five-pair bundle and core is made of water-blocking tape, and over the waist insulation of each five-pair bundle, an aluminum-aluminum screen is applied with an aluminum layer inside the beam, and sequentially on the waist insulation of the core imposed a common screen of aluminum-polymer tape, a braid of galvanized steel wire and a polyethylene outer sheath.

The essence of the proposed utility model is illustrated by drawings, which depict:

figure 1 - the first embodiment of an electric communication cable;

figure 2 is a second variant of an electric communication cable;

figure 3 is a third variant of an electric communication cable;

figure 4 is a fourth variant of an electric communication cable;

5 is a fifth embodiment of an electric communication cable;

6 is a sixth embodiment of an electric communication cable;

7 is a seventh embodiment of an electric communication cable;

on Fig - the eighth embodiment of an electric communication cable;

The first version of the electric communication cable (Fig. 1) contains a core 1 with twisted pairs of conductive conductors 2 with a three-layer film-porous-film-film polyethylene insulation 3. Each pair of twisted together conductive conductors 2 is made with its own twisting step, while the pair of conductive cores 2 with insulation 3 are twisted into five-pair bundles 4. The twist step of each five-pair bundle 4 is different from the twist step in other five-pair bundles that are part of the core 1. The belt insulation 5 of each five-pair bundle 4 is made and polietilentereftolatnoy tape. Per core

1 of the electric communication cable, a common shield 6 is sequentially superimposed, which is made of aluminum-polymer tape and the outer sheath 7. The outer sheath 7 can be made of polyvinyl chloride plastic compound or low combustibility plastic compound.

It should be noted that two insulated cores 2 are twisted into a pair by unidirectional twisting with coordinated steps and non-multiple to each other. The pairs are twisted into five-pair bundles 4, and with unidirectional twisting, the step is not more than 200 mm, with multidirectional twisting, the average step in one period is not more than 200 mm, transition straight sections are not more than 200 mm.

The core design described above is used for all of the proposed electrical communication cable options.

The three-layer insulation design 3 of the core 2 significantly reduces the dielectric constant of the insulation of the conductive core 2 and, as a result, improves the performance of the primary and secondary electrical parameters of the cable, improves adhesion between the conductive core 2 and insulation 3, eliminates the penetration of moisture between the conductor and insulation, and reduces the insulation thickness and the volume of materials used, improve the performance of capacitance and capacitive asymmetry in the cables and, as a result, reduce the attenuation coefficient, increase the fur nical strength.

The second variant of the electric communication cable (Fig. 2) is structurally different from the first variant by the presence of belt insulation 5 of polyethylene terephthalate tape at the core 1 and screen 8, which is laid on top of the belt insulation 5 of each five-pair bundle 4 and is made of alumoflex, and screen 8 is superimposed with an aluminum layer inside a five-pair beam 4.

The third variant of the electric communication cable (Fig. 3) is structurally different from the first variant in that a water blocking thread 9 is inserted into each five-pair bundle 4, while the waist insulation 5 of each five-pair bundle 4 and the waist insulation 10 of the core 1 are made of water blocking tape. On the belt insulation 10 of the core 1 are sequentially superimposed a common screen 6 of aluminum-polymer tape and an outer shell 7 made of polyethylene.

The fourth embodiment of the electric communication cable (Fig. 4) is structurally different from the third embodiment in that water blocking threads 9 are introduced into each five-pair bundle 4 and core 1, while the waist insulation 5 of each five-pair bundle 4 and the waist insulation 10 of core 1 are made of water blocking tape . On top of the belt insulation 5 of each five-pair bundle 4, a screen 8 of alumoflex is laid with an aluminum layer inside the five-pair bundle 4.

The fifth embodiment of the electric communication cable (Fig. 5) is structurally different from the third option in that water blocking thread 9 is introduced into each five-pair bundle 4 and core 1, while the waist insulation 5 of each five-pair bundle 4 and the waist insulation 10 of core 1 are made of water blocking tape . On the belt insulation 10 of the core 1 are sequentially superimposed a common screen 6 of aluminum-polymer tape and an outer shell 7 made of polyethylene, and two anti-corrosion steel tapes 11 that protect the cable from the effects of rodents.

The sixth embodiment of the electric communication cable (Fig. 6) is structurally different from the fifth embodiment in that over the waist insulation 5 of each five-pair bundle 4, a screen 8 of aluminum-flex is laid with an aluminum layer inside the five-pair bundle 4.

The seventh version of the electric communication cable (Fig. 7) is structurally different from the sixth version in that the common screen 6 is sequentially braided from galvanized steel wire 12, and then the outer sheath 7 made of polyethylene. In this embodiment, there is no screen 8 of the five-pair beam 4.

The eighth version of the electric communication cable (Fig. 8) is structurally different from the seventh version in that over the belt insulation 5 of each five-pair bundle 4, a screen 8 of alumoflex is laid with an aluminum layer inside the bundle 4.

The use of water-blocking elements in the proposed embodiments prevents the penetration of moisture into the core of the electric communication cable.

The braid 12 of galvanized steel wires provides protection against rodents and at the same time is a trellised screen that reduces the influence of external electromagnetic fields.

Due to the presence in the insulation 3 layers of continuous polyethylene adjacent to the core 2, it allows to improve the adhesion between the conductive core and the insulation and thereby prevent the penetration of moisture.

The use of water-blocking threads 9 in the center of a five-pair bundle 4 eliminates moisture penetration and maintains the correct arrangement of pairs in the bundle.

High stability of physical foaming allows achieving the best readings of a coaxial capacity of 115 PF / m ± 1.5, which provides the best result of transient attenuation and protection.

The use of physical foaming up to 65% reduces the level of intrinsic attenuation of the pairs in the cable and when the screens 8 are tightly placed on the five-pair bundles 4 it provides the pair capacitance necessary for normal operation of the ADSL and ADSL2 + systems no more than 50 nF / km.

The structural arrangement and balance of the steps of the pairs in beam 4 makes it possible to achieve security of 100% combinations of 35 dB, 90% - 50 dB, 60% - 65 dB at a frequency of 0 to 4 MHz. Therefore, at least 90% of the pairs in the cable must be densified by the ADSL and ADSL2 + systems, while at the same time achieving the maximum information transfer rate.

The proposed options for electric cables give a wide range of their application, in particular for laying on the inner walls of buildings and indoors, for laying in the ground, in telephone conduits, in collectors of mines, tunnels, suspension on overhead communication lines, in conditions of high humidity, in areas characterized by increased risk of damage by rodents.

The use of film-porous-film polyethylene insulation with coordinated steps of twisting of conductive conductors and five-pair bundles, the introduction of aluminoflex shields for elementary five-pair bundles, and the use of water-blocking tapes in waist insulation both in five-pair bundles and for the core made it possible to create various options for communication cables with high performance and reliability.

Claims (12)

1. An electric communication cable comprising a core with pairs of conductive conductors twisted together with insulation, a belt insulation of dielectric material, a common screen and an outer sheath are laid over the core, characterized in that each pair of conductive conductors twisted together with a three-layer porous film film polyethylene insulation is made with its own twisting step, from 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 included in 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. 2. An electric communication cable containing a core with pairs of conductive conductors twisted together with insulation, a belt insulation of dielectric material, a common screen and an outer sheath are laid over the core, characterized in that each pair of conductive conductors twisted together with a three-layer porous film film polyethylene insulation is made with its own twisting step, from 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 included in the core, the belt insulation of each five-pair bundle and core is made of polyethylene terephthalate tape, and over the belt insulation of each five-pair bundle an aluminum-flex screen is applied, the common screen is made of aluminum-polymer tape, and the outer shell is made of polyvinyl chloride plastic compound or low combustibility plastic compound. 3. The electric communication cable according to claim 2, characterized in that the screen of the five-pair aluminum-flex bundle is superimposed with an aluminum layer inside the bundle. 4. An electric communication cable containing a core with pairs of conductive conductors twisted together with insulation, a belt insulation of dielectric material, a common screen and an outer sheath are laid over the core, characterized in that each pair of conductive conductors twisted together with a three-layer porous film film polyethylene insulation is made with its own twisting step, from 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 included in the core, a water blocking thread is introduced into each five-pair bundle, and the waist insulation of each five-pair bundle and core is made of a water blocking tape, and a common screen made of aluminum-polymer tape and a polyethylene outer shell are sequentially applied to the core insulation of the core. 5. An 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 laid over the core, characterized in that each pair of twisted together conductive conductors with a three-layer porous film film polyethylene insulation is made with its own twisting step, from 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 constituents of the core, water blocking threads are introduced into each five-pair bundle and core, and the waist insulation of each five-pair bundle and core is made of water-blocking tape, moreover, an alumoflex shield is applied over the waist insulation of each five-pair bundle, and a common screen is sequentially applied to the waist insulation of the core from aluminum-polymer tape and polyethylene outer shell. 6. The electric communication cable according to claim 5, characterized in that the screen of the five-pair beam of alumoflex is superimposed with an aluminum layer inside the beam. 7. An 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 laid over the core, characterized in that each pair of twisted together conductive conductors with a three-layer porous film film polyethylene insulation is made with its own twisting step, from 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 constituents of the core, water blocking threads are introduced into each five-pair bundle and core, and the waist insulation of each five-pair bundle and core is made of water blocking tape, and a common aluminum-polymer tape screen, a polyethylene outer shell and two anticorrosion steel are sequentially applied to the core insulation of the core. tapes. 8. An electric communication cable comprising a core with pairs of conductive conductors twisted together with insulation, a belt insulation of dielectric material, a common screen and an outer sheath are laid over the core, characterized in that each pair of conductive conductors twisted together with a three-layer porous film film polyethylene insulation is made with its own twisting step, from 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 constituents of the core, water blocking threads are introduced into each five-pair bundle and core, and the waist insulation of each five-pair bundle and core is made of water-blocking tape, moreover, an alumoflex shield is applied over the waist insulation of each five-pair bundle, and a common screen is sequentially applied to the waist insulation of the core from aluminum-polymer tape, polyethylene outer shell and two anti-corrosion steel tapes. 9. The electric communication cable according to claim 8, characterized in that the screen of the five-pair aluminum-flex bundle is superimposed with an aluminum layer inside the bundle. 10. An electric communication cable comprising a core with twisted pairs of conductive conductors with insulation, a belt insulation of dielectric material, a common screen and an outer sheath are laid over the core, characterized in that each pair of twisted together conductive conductors with a three-layer porous film film polyethylene insulation is made with its own twisting step, from 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 x, which are part of the core, water-blocking threads are introduced into each five-pair bundle and core, and the waist insulation of each five-pair bundle and core is made of water-blocking tape, and a common screen of aluminum-polymer tape, a braid of galvanized steel wire, are sequentially applied to the core insulation of the core polyethylene outer shell. 11. An electric communication cable containing a core with twisted pairs of conductive conductors with insulation, a belt insulation of dielectric material, a common shield and an outer sheath are laid over the core, characterized in that each pair of twisted together conductive conductors with a three-layer porous film film polyethylene insulation is made with its own twisting step, from 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 x, which are part of the core, water-blocking threads are introduced into each five-pair bundle and core, and the waist insulation of each five-pair bundle and core is made of water-blocking tape, and over the waist insulation of each five-pair bundle, an alumoflex shield is applied, and a common aluminum belt insulation is sequentially laid on the core insulation screen made of aluminum-polymer tape, galvanized steel wire braid and polyethylene outer sheath. 12. The electric communication cable according to claim 11, characterized in that the screen of the five-pair beam of alumoflex is superimposed with an aluminum layer inside the beam.