RU53811U1 - MULTI-PAIR ELECTRIC COMMUNICATION CABLE - Google Patents

Abstract

The utility model relates to cable technology, namely to multi-pair electrical communication cables. The cable contains copper or tinned copper single-wire or multi-wire conductors insulated in pairs twisted between each other with a twisting step of not more than 100 mm, insulated with PVC compound. Each pair of cores has a belt insulation, a screen made of laminated copper or laminated aluminum tape and a sheath of polyvinyl chloride plastic compound with an oxygen index of at least 21 or a halogen-free polyolefin composition with an oxygen index of at least 35. These pairs are twisted into a core over which the belt insulation is applied, the screen made of laminated copper or aluminum laminated tape and a sheath made of PVC compound with an oxygen index of at least 21 or a halogen-free polyolefin composition with an oxygen index of at least 35. The diameter of the conductors and the thickness of the insulation are pairs of values, respectively, in mm of 1.62 and 1.25 or 1.32 and 1.0 or 1.05 and 0.8 or 0.78 and 0.6 or 0.54 and 0.4; or 0.3 and 0.2. The technical result is the minimization of the overall dimensions of the cable, improved shielding and reduced combustibility.

Description

The utility model relates to cable technology and can be used mainly in the construction of industrial communication cables for transmitting signals in the frequency range up to 2500 Hz, in particular for systems operating according to the HART protocol, as well as in cable designs for communication systems and general purpose signaling.

Known electrical communication cable brand TSV, containing copper conductive conductors with a diameter of 0.4 or 0.5 mm with insulation made of PVC compound 0.25 or 0.3 mm thick, respectively, twisted together in pairs with a twisting step of not more than 100 mm, indicated the pairs are twisted into a core, on top of which a belt insulation of dielectric material is sequentially applied, a common screen of aluminum tape, superimposed with overlapping, with screen wire under it and an external plastic sheath (N.I. Belorussov and others. Electrical cables , wires and cords. Reference book. M. "Energoatomizdat", 1987, p. 469).

This technical solution for the totality of features is the closest to the proposed cable.

The disadvantages of the known cable include the fact that its parameters are not optimized for use in cable communication lines of various lengths in the range from 3000 m to 500 m or less, as well as low electromagnetic immunity of individual pairs. high fire hazard.

It is known that the maximum allowable attenuation coefficients of cables for length subbands in the specified interval are normalized in the range from 6 dB / km to 1 dB / km.

At the same time, it is known that the value of the attenuation coefficient simultaneously depends on the diameter of the conductive cores, the thickness of the insulation, the design of the elements under the screen and the additional materials included therein.

The task was to create the optimal communication cable for systems operating according to the HART protocol, which allows minimizing the weight and size characteristics of the cable, while increasing the working length of the cable and expanding the scope in terms of improving shielding and reducing flammability, suitable for use in hazardous areas (Device Rules electrical installations. 6th edition, clauses 7.3.102. Moscow. Energoatomizdat. 1985), as well as providing the possibility of wiring individual pairs to the connection and installation unit ithout breaking the loop.

The technical result is achieved in that in an electric communication cable containing at least two pairs of copper or tinned copper single-wire or multi-wire conductive strands twisted together with a pitch of not more than 100 mm with insulation made of PVC compound, the core formed by twisted together these pairs, on top of which a common belt insulation of dielectric material is sequentially applied, a common screen and an outer plastic shell, on each pair twisted together conductive conductors on top of the insulation are additionally coated with individual belt insulation made of dielectric material, a screen made of laminated copper or laminated aluminum tape with a screen wire under it or braided with copper or tinned copper wire, and a sheath made of PVC compound with an oxygen index of at least 21 or a halogen-free polyolefin composition with an oxygen index of at least 35, and the diameter of the conductors and the insulation thickness are pairs of values, respectively, in mm of 1.62 and 1.25 or 1.3 2 and 1.0 or 1.05 and 0.8 or 0.78 and 0.6 or 0.54 and 0.4 or 0.3 and 0.2, the common screen is made of laminated

copper or laminated aluminum tape with a screen wire underneath or braided with copper or tinned copper wire, and the outer shell is made of PVC compound with an oxygen index of at least 21 or a halogen-free polyolefin composition with an oxygen index of at least 35.

Pairs of values of the core diameter and insulation thickness are selected depending on the specified attenuation value in the cable.

A layer of water-blocking material, for example, in the form of a tape, can be laid inside the core and over the screen.

For any of the above embodiments, a synthetic thread, a rep cord, can be laid under the outer sheath of the cable to facilitate removal of the sheath during installation.

The cable may also additionally contain a layer of water-blocking material sequentially applied to the sheath, for example, in the form of a tape, armor made of metal wires and a protective hose made of polyvinyl chloride material with an oxygen index of at least 21 or a halogen-free polyolefin composition with an oxygen index of at least 35.

The utility model is illustrated in the drawing, which shows a cable in cross section.

The electric communication cable contains conductive conductors 1 with insulation 2, twisted into a pair of 3, which in turn are twisted into a core 4, individual belt insulation 5 superimposed on each pair, a shield 6 with a shield wire 7, and a sheath 8 laid on top of the core 4 common belt insulation 9, common screen 10. screen wire 11, layer of water blocking material 12, rep cord 13, outer shell 14, armor 15 made of metal wires and a protective hose 16.

The specific number of pairs of insulated cores is not an essential sign, since it is well known that multi-pair electrical communication cables, in particular telephone, depending on the number of switched subscribers, can contain a completely different number of pairs of insulated cores from 2 to 100 or more, which does not change , both the structural features of the cable and the essential features of the claimed technical solution, according to which the proposed cable may contain any number of pairs of 2 or more.

The following is evidence of the industrial applicability of the utility model.

Cable manufacturing technology is as follows.

Conducting cores 1 are made of copper wire rod by drawing. Depending on the diameter of the finished conductive core, the following operations can be used: coarse and medium drawing or coarse, medium and thin drawing. Cores 1 can be tinned copper or copper, single-wire or multi-wire.

Single-wire copper conductors are annealed to provide softness. Tinned veins are obtained in a hot way, as a result of which the vein is annealed and becomes soft during tinning.

For multi-wire cores, wires are produced in the required quantity according to the described technology, after which they are twisted on cigar, frame or lantern machines.

Insulation 2 on the core 1 is applied by extrusion from granular polyvinyl chloride plastic compound.

The twisting of conductive insulated conductors 1 into a pair of 3 is carried out on frame type machines, and steam 3 into the core 4 is carried out on lantern type machines.

Belt insulation 9 can be applied to the core 4 in the form of a winding with a spiral overlap on tape machines or using a special

coagulation device when applying the sheath 14, provided that the screen 10 has a dielectric layer glued to the sheath 14.

The screen 10 can be applied in the form of a winding tape in a spiral with overlapping on special winding machines or devices combined with torsion machines or longitudinally, using special devices built into the extrusion line.

The screen 10 in the form of a braid is imposed on braiding machines, and in the form of a winding - on special winding machines.

The screen wire 11 is made in the form of a soft copper or tinned copper wire. The technology of its manufacture is similar to that used in the manufacture of cores 2.

The outer shell 14 is applied by extrusion. A durable synthetic thread, rep-cord 13, is longitudinally laid under the shell during its application.

A layer of water blocking material 12 over the core of the cable is imposed by a spiral winding on tape machines.

In a similar manner, 3 individual belt isolation 5, a screen 6 with a screen wire 7 and a sheath are applied superimposed on each pair 3.

In the manufacture of an armored cable, a layer 12 of a water-blocking material, for example, a tape of non-woven material, is applied to the sheath 14 by winding in a spiral winding machine, and then, armor 15 is applied, for example, in the form of a braid with galvanized steel wires on a braid machine or in a braid on the armor the car. A protective hose 16 is applied over the armor by extrusion.

Samples of the proposed cable with a different number of pairs of insulated cores were made and tested.

The test results confirmed that the obtained cables correspond to the calculated value of the attenuation coefficient and have a minimum weight compared to the known cables used for these purposes, as well as reduced combustibility.

Claims (4)

1. An electric communication cable containing at least two pairs of copper or tinned copper single-wire or multi-wire conductive conductors twisted together with a pitch of not more than 100 mm with insulation made of PVC compound, a core formed by twisted by the indicated pairs, over which sequentially applied common belt insulation of dielectric material, a common screen and an external plastic shell, characterized in that for each pair of conductive conductors twisted together on top of the insulation, individual belt insulation is additionally applied from dielectric material, a screen made of laminated copper or laminated aluminum tape, with a screen wire under it, or braided with copper or tinned copper wire, and a sheath made of PVC compound with an oxygen index of at least 21 or a halogen-free polyolefin composition with an oxygen index of at least 35, the diameter of the conductors and the insulation thickness are pairs of values, respectively, in mm of 1.62 and 1.25 or 1.32 and 1.0 or 1.05 and 0.8 or 0.78 and 0.6 or 0.54 and 0.4 or 0.3 and 0.2, the common screen is made of laminated copper or laminated aluminum tape, with a screen wire under it, or braided with copper or tinned copper wire, and the outer shell made of
PVC compound with an oxygen index of at least 21 or from a halogen-free polyolefin composition with an oxygen index of at least 35. 2. The cable according to claim 1, characterized in that a layer of water-blocking material is laid inside the core and over the common screen. 3. The cable according to claim 1 or 2, characterized in that under the outer sheath is laid a synthetic thread - rep-cord, providing removal of the sheath. 4. The cable according to claim 1 or 2, characterized in that it further comprises a layer of water-blocking material sequentially applied to the outer sheath, armor made of metal wires and a protective hose made of PVC compound with an oxygen index of at least 21 or a halogen-free polyolefin composition with an oxygen index of at least 35.