RU65684U1 - HIGH FREQUENCY ELECTRIC COMMUNICATION CABLE - Google Patents

Abstract

The utility model relates to communication and signaling cables. Insulated conductors are twisted into pairs, which are twisted into electric beams and a core. The free space in the core is filled with a hydrophobic aggregate with evenly distributed pieces of foil not more than 5 mm in size with a content of not more than 10% of the aggregate volume.

The proposed cable design provides protection against mutual electromagnetic influences when transmitting signals with a frequency of more than 1 MHz.

Description

The utility model relates to the cable industry and can be used in the construction of communication and signaling cables.

A telephone cable according to a utility model is known for patent No. 32920, class Н01В 11/00, having the following structure: insulated conductive conductors, comprising pairs or fours, twisted into elementary bundles or core, with free space in the core filled with a hydrophobic filler, waist insulation and a layer of hydrophobic filler on top of it, with an aluminum-polyethylene screen and a sheath of polyethylene. Such a cable, as a rule, is used to transmit analog or low-frequency signals. Protection from mutual electromagnetic influences of neighboring pairs is sufficiently ensured by twisting the cores in pairs or fours with a pitch of not more than 100 mm.

However, to transmit signals with a frequency of 1 MHz or more, this is no longer enough.

Known electric communication cable, designed to transmit high-frequency signals according to the utility model patent No. 51782, MKI Н01В 11/00, in which, in order to protect against mutual electromagnetic influences of neighboring pairs, each pair has an individual electromagnetic screen and its own shell. This solution provides protection against mutual electromagnetic influences, but the cable becomes very expensive.

In the article “WARP technology - a little foil will have a huge effect” in the magazine “Connect! Communication World »No. 3 (March) 2006, S. Loginov announces a decision regarding protection against external mutual influences (between adjacent cables) for high-frequency cables for structured cable systems: small pieces are introduced into the cable sheath in order to ensure protection foil so that between them there are basically no electrical contacts. This solution provides protection against mutual influences between cables, but does not provide protection for electromagnetic influences between pairs in the core of one cable.

As a prototype, we select a telephone cable according to the utility model No. 32920, class Н01В 11/00.

The technical task of the proposed utility model is the creation of a high-frequency electric communication cable providing protection against mutual electromagnetic influences when transmitting signals with a frequency of more than 1 MHz.

The technical problem is solved by the fact that an electrical communication cable is proposed, consisting of several polymer conductive cores isolated in pairs twisted together, the pairs are twisted into elementary bundles, and the bundles into the core, or the pairs are twisted directly into the core, the free space in the core is filled with a hydrophobic filler, belt insulation and another layer of hydrophobic aggregate are applied over the core, a screen is made of a longitudinally overlapping aluminum overlapping tape and a moisture-proof polyethylene a bog in which it is new that pieces of foil with a size of not more than 5 mm and constituting no more than 10% of the volume of the filler are uniformly introduced into the hydrophobic aggregate.

The electromagnetic field of the influencing pair when it enters into pieces of the foil randomly scattered around the exposed pair (in the surrounding hydrophobic filler), partially reflects from the elements of the conducting medium, and partially dissipates, undergoing multiple reflections and only an insignificant part reaches the affected pair, but not in the form signal, but in the form of electromagnetic noise.

For laying the cable directly into the ground, it is desirable that the cable additionally contains a layer of water-blocking material superimposed on the said moisture-proof sheath, armor made of steel laminated with polyethylene tapes, imposed longitudinally corrugated or by winding in a spiral, or from round steel

galvanized wires laid in the form of a braid or winding in a spiral and a moisture-proof polyethylene hose.

To suspend the cable on poles and communication supports with spiral clamps of a curling type, it is advisable that the cable additionally contains a cable in the center of the core in polymer insulation.

To suspend the cable on poles and communication supports with gripper-type clamps, it is advisable that the cable and cable be enclosed in an additional common sheath, with the cable parallel to the central axis of the cable.

For laying cables in conditions that are required to not spread combustion and low smoke emission, cables with a sheath of special PVC compound with an oxygen index of at least 35 or a halogen-free composition with an oxygen index of at least 45 are provided.

In this case, the screen is made of aluminum-polymer tape, and the polymer of the tape is chosen homogeneous with the shell material.

For laying armored cables in conditions that are required not to spread combustion and low smoke emission, cables with a moisture-proof sheath and a hose made of special PVC compound with an oxygen index of at least 35 or from a halogen-free composition with an oxygen index of at least 45 are provided.

In this case, an aluminum-polymer tape is used for the screen, and steel-polymer tape for armor, in which the polymer of the tapes is chosen homogeneous with the material of the sheath and hose, respectively.

In the future, the proposed utility model is illustrated by specific examples of implementation and the accompanying drawings, in which:

figure 1 - depicts a cross section of an armored cable;

figure 2 - depicts a cross section of a cable with a cable embedded in the core;

figure 3 - depicts a cross section of a cable with a cable embedded in the protective sheath.

A high-frequency electric communication cable 1 (Fig. 1) consists of several polymer-conductive conductors 2 insulated in pairs twisted together, the pairs are twisted into elementary bundles, and the bundles into the core or pairs are twisted directly into the core, the free space in the core is filled with a hydrophobic filler, on top core insulation is applied 3 and another layer of hydrophobic aggregate 4, a screen made of longitudinally overlapping aluminum plastic tape 5, moisture-proof polyethylene sheath 6, a layer of water blocks material 7, armor 8 from steel laminated with polyethylene tapes, laid longitudinally corrugated or by winding in a spiral, or from round galvanized steel wires and a moisture-proof polyethylene hose 9. At the same time, pieces of foil no larger than 5 mm in size are introduced into the hydrophobic filler uniformly in volume and components no more than 10% of the filler volume.

A high-frequency electric communication cable 10 (Fig. 2) designed for suspension on poles and communication supports with spiral clamps of a curling type consists of a cable 11 laid in the center of the core, insulated with polymer material 12, from several conductive cores 2 insulated with polymer, twisted in pairs, the pairs are twisted into elementary bundles twisted around the cable into the core, or the pairs are directly twisted around the cable into the core, the free space in the core is filled with a hydrophobic filler, in which uniformly in volume introduced foil pieces with a size of no more than 5 mm and constituting no more than 10% of the volume of the aggregate, belt insulation 3 and a layer of hydrophobic aggregate 4 on top of it, a screen 5 of longitudinally overlapping with overlapping aluminum tape 5, and a moisture-proof polyethylene sheath 6.

A high-frequency electric communication cable 13 (Fig. 3), designed to suspend the cable on poles and communication supports with gripping-type clamps, consists of several polymer conductive conductors 2, twisted together in pairs, the pairs are twisted into elementary bundles, and the bundles into a core, or the pairs are twisted

directly into the core, the free space in the core is filled with a hydrophobic aggregate, into which uniformly inserted foil pieces no larger than 5 mm in size and constituting no more than 10% of the aggregate volume, belt insulation 3 and a layer of hydrophobic aggregate 4 on top of it, are longitudinally applied with overlapping alumina tape 5, a moisture-proof polyethylene sheath 6 and an additional sheath 14 superimposed simultaneously on the cable 11 and the cable in the moisture-proof sheath 6.

Cable manufacturing technology according to the claimed utility model includes the following operations.

Conducting cores 2 for cables described in this utility model are made, as a rule, in the form of soft (annealed) copper wire, obtained from copper wire "wire rod" mainly with a diameter of 8 mm by drawing method. Two operations are usually used: rough and medium drawing. Moreover, the operation of medium drawing in modern equipment is combined with the operation of annealing and isolation in the extrusion line.

The core insulation can be made of continuous polyethylene or foamed with an internal continuous adhesive layer and an external continuous (protecting from penetration of hydrophobic aggregate) layer on an automatic extrusion line.

To ensure smooth insulation in continuous polyethylene, from 6% to 48% polypropylene is added, the mixture is obtained in the form of a mixture of granules in a special container before loading into the hopper of the extruder. In order to obtain foamed polyethylene in modern lines, an installation of physical foaming is built in, for obtaining each layer of insulation a separate extruder is used. The mass of materials from all extruders enters a special head, where insulation is applied.

The twisting of isolated conductors in pairs and pairs into an elementary bundle or the cable core equivalent to it in terms of the number of pairs is performed on a combined twisting machine according to the method of unidirectional or multidirectional (reverse) twisting.

The introduction of a hydrophobic filler into the cable core is performed under pressure on a special installation built into the extrusion line for applying a moisture-proof sheath 6. Foil pieces of mainly copper or aluminum are pre-kneaded in the installation hopper until the entire mass of the hydrophobic filler is uniformly filled with them. A layer of aggregate 4 over the belt insulation 3 is superimposed on the same installation.

The extrusion line for applying a moisture-proof sheath 6 also contains devices for longitudinally applying a tape waist insulation 3 and a shield 5. The waist insulation 3 can be polymer or paper, a screen in the form of a metal-polymer tape with aluminum or copper base.

The water blocking layer 7 is made by applying a winding in a spiral butt-to-butt water blocking tape on a winding machine.

Also, a tape of water blocking material may be allowed under armor 8 for cable booking operations.

The application of tape armor 8 can be done by winding tapes in a spiral fashion on a winding machine or longitudinally on a unit combined with an extrusion line for applying a moisture-proof hose with preliminary corrugation of the tape.

The imposition of round wire armor 8 can be carried out by the method of braiding on a braiding machine or winding in a spiral on a reservation machine.

A moisture-proof hose 9 is laid on the extrusion line.

The cable 11 is usually bought ready-made, twisted from metal wires, glass fibers or strong synthetic threads. Polymer insulation 12 of the cable is made of any polymer material by extrusion.

To confirm the technical result, cable samples were made according to the claimed utility model of three groups, in each group of five samples. The length of each cable was 100 m.

The experiment used aluminum foil.

In the first group, pieces of aluminum foil accounted for about 1% of the volume occupied by the hydrophobic aggregate, in the other 5%, in the third 10%.

Near-end crosstalk measurement (known as NEXT) was performed. The measurement results are summarized in table.

Controlled parameter Measured values for cables with percentage of foil pieces in the core one% 5% 10% Near end crosstalk B / 100 m 47-50 53-59 57-61

As can be seen from the results presented in the table, an increase in the transient attenuation at the near end of the cable depending on the degree of filling of the medium surrounding the working couple (hydrophobic filler) with pieces of aluminum foil is observed up to about 10% volume filling. Further, increasing the filling volume does not make sense, since the growth of the transient attenuation at the near end stops, but the cable working capacity and, accordingly, the attenuation coefficient increase significantly, which significantly worsens the transmission of communication signals over the cable.

Claims (6)

1. A high-frequency electric communication cable, including several polymer-insulated conductive conductors twisted in pairs, pairs are twisted into elementary bundles, and elementary bundles into a core, or pairs twisted directly into a core, free space in the core filled with a hydrophobic filler, a waist band applied over the core insulation and a layer of hydrophobic aggregate on top of the belt insulation, aluminum-polyethylene screen and polyethylene moisture-proof shell, characterized in that the composition idrofobnogo filler uniformly by volume administered foil pieces no larger than 5 mm, of not more than 10% by volume of aggregate. 2. The cable according to claim 1, characterized in that the moisture-proof sheath is made of polyvinyl chloride plastic compound with an oxygen index of at least 35 and low smoke emission, or from a halogen-free composition with an oxygen index of at least 45, and the screen is made of metal-polymer tape, the polymer being chosen homogeneous with moisture proof material. 3. The cable according to claim 1, characterized in that it further comprises a cable located in the middle of the core along the Central axis of the cable, and around it are twisted pairs or elementary bundles of the core. 4. The cable according to claim 1, characterized in that it is enclosed in an additional sheath and contains an additional cable placed in said additional sheath parallel to the central axis of the cable. 5. The cable according to claim 1, characterized in that it further comprises a layer of water-blocking material superimposed on the moisture barrier, armor made of metal wires or steel tapes, laminated with polyethylene, and a moisture barrier made of polyethylene. 6. The cable according to claim 5, characterized in that the moisture-proof sheath and hose are made of polyvinyl chloride plastic compound with an oxygen index of at least 35 and low smoke emission or from a halogen-free composition with an oxygen index of at least 45, the screen is made of metal-polymer tape, and the armor is made of steel-polymer tapes or from metal wires, moreover, the polymer in the screen or tape armor is chosen homogeneous with the material of the moisture-proof sheath and hose, respectively.