RU89276U1 - HIGH FREQUENCY LOCAL COMMUNICATION CABLE (OPTIONS) - Google Patents

Abstract

1. High-frequency local communication cable, including insulated copper conductors twisted into a core filled with a hydrophobic filler, belt insulation overlaid on top of the core, an aluminum-polymer tape shield, armor and an outer sheath, characterized in that it additionally contains a central power element and optical modules, In this, the optical modules and copper conductors are twisted around the central power element by multidirectional twisting. ! 2. The high-frequency local communication cable according to claim 1, characterized in that one or more optical modules are replaced by filler cores. ! 3. A high-frequency local communication cable according to claim 2, characterized in that a copper-tin core is laid under the screen of the aluminum-polymer tape. ! 4. High-frequency local communication cable according to claim 3, characterized in that the central power element is made of fiberglass. ! 5. High-frequency local communication cable according to claim 4, characterized in that an additional tape made of water-blocking material is additionally superimposed on top of the screen from the aluminum-polymer tape. ! 6. High-frequency local communication cable according to claim 5, characterized in that the armor is made of corrugated steel-polymer tape. ! 7. High-frequency local communication cable according to claim 5, characterized in that the armor is made of galvanized steel round wires. ! 8. Local communication cable high-frequency according to any one of paragraphs.6 and 7, characterized in that the insulation of copper conductors, waist insulation and the outer sheath are made of polyethylene. ! 9. High-frequency local communication cable, including insulated copper conductors twisted into a core, filled with a hydrophobic filler, laid on top of the heart�

Description

The utility model relates to cable technology, namely, cables intended for inter-office and subscriber lines with transmission systems with time division of channels and pulse-code modulation with a transmission speed of up to 2048 kBit / s with a remote supply voltage of up to 500 V DC.

Known high-frequency single-channel cable for digital rural communications networks (RF patent for utility model No. 27263). This cable consists of twisted copper conductive cores insulated with polyethylene in the form of a concentric film-porous-film layer, belt insulation of extruded polyethylene, a screen of aluminum-polymer tape. A polyethylene separation layer is applied over the screen, on top of which the armor is made of corrugated steel tape with a double-sided polymer coating.

The disadvantages of the known cable include:

- Lack of reinforcing and load-bearing elements

- A small range of transmitted frequencies and the number of connected subscribers

The purpose of this utility model is to develop a cable design with increased load resistance and an increased range of transmitted frequencies.

In this utility model, two high-frequency cable designs are proposed. The cable manufactured in the first embodiment can be used for laying in the ground. A cable made according to the second embodiment can be used for suspension on the supports of overhead communication lines.

The first version of the cable contains insulated copper conductors and optical modules with optical fibers. The cores and optical modules are twisted around the central power element by multidirectional twisting. The core is filled with a hydrophobic aggregate, on top of which a belt insulation is applied. On top of the belt insulation, a screen of aluminum-polymer tape is longitudinally applied. Over the screen, the armor and outer shell are superimposed. The armor can be made of corrugated steel-polymer tape or of steel round galvanized wires.

The second version of the cable design contains insulated copper conductors and optical modules with optical fibers. The cores and optical modules are twisted around the central power element by multidirectional twisting. The core is filled with a hydrophobic aggregate, on top of which a belt insulation is applied. A screen of aluminum-polymer tape is superimposed on top of the waist insulation. A load-bearing element of aramid threads and an outer shell are superimposed on top of the screen.

Depending on the required number of optical fibers in the cable, the optical modules can be replaced with filler cores made of polymer material.

For additional protection against moisture, a tape made of water-blocking material can be applied over the screen made of aluminum-polymer tape.

In addition, a copper-tin core can be laid under the screen made of aluminum-polymer tape, designed to connect the metal parts of the electrical device to which the cable is connected that are not under operating voltage with a protective ground loop.

Insulation of copper conductors, belt insulation and the outer sheath can be made of polyethylene.

The central power element may be made of fiberglass.

Figure 1 shows in section one of the manufacturing options for the cable, where:

1. Insulated copper core

2. Depending on the cable design variant, the optical module or the filler core

3. The outer shell

4. Belt insulation

5. Screen made of aluminum-polymer tape

6. Depending on the design of the cable, the armor or the load-bearing element of aramid threads

7. Hydrophobic aggregate

8. Central power element

In the proposed cable, insulated copper conductors 1 and optical modules with optical fibers 2 are twisted around the central power element 8 by multidirectional twisting. The core is filled with a hydrophobic aggregate 7, on top of which a belt insulation 4 is applied. On top of the belt insulation, a screen 5 of aluminum-polymer tape is longitudinally laid under which a copper-tin core is laid. On top of the screen is superimposed, depending on the cable design, armor or a load-bearing element of aramid threads 6 and the outer sheath 3.

Due to the use of optical modules with optical fibers in the proposed design, the range of frequencies transmitted via cable and the number of connected subscribers are significantly increased. The use of a central reinforcing fiberglass element and a load-bearing element of high-modulus technical aramid threads provides the cable with a load resistance of up to 8 kN. An additional advantage of using a central reinforcing fiberglass element is the reduction of capacitive coupling in the core.

Cable manufacturing technology includes the following technological operations:

Conductors in the form of soft (annealed) copper wire, obtained by drawing from copper wire with a diameter of 2.5 mm. The drawing operation is combined with the annealing and isolation operation in the extrusion insulation line.

The twisting of insulated conductors and optical modules or filler corners around the central power element from fiberglass to the cable core is performed on a combined SZ-twisting machine (multidirectional, reversible).

The introduction of a hydrophobic aggregate into the core is performed under pressure in a special installation combined with an extrusion line.

The inner sheath of the cable is superimposed on an extruded line of extruded polyethylene over an impregnated core.

The extrusion line also contains devices for longitudinally applying an electric shield, armor and an external polyethylene sheath.

Claims (14)

1. High-frequency local communication cable, including insulated copper conductors twisted into a core filled with a hydrophobic filler, belt insulation overlaid on top of the core, an aluminum-polymer tape shield, armor and an outer sheath, characterized in that it additionally contains a central power element and optical modules, In this, the optical modules and copper conductors are twisted around the central power element by multidirectional twisting. 2. The high-frequency local communication cable according to claim 1, characterized in that one or more optical modules are replaced by filler cores. 3. A high-frequency local communication cable according to claim 2, characterized in that a copper-tin core is laid under the screen of the aluminum-polymer tape. 4. High-frequency local communication cable according to claim 3, characterized in that the central power element is made of fiberglass. 5. High-frequency local communication cable according to claim 4, characterized in that an additional tape made of water-blocking material is additionally superimposed on top of the screen from the aluminum-polymer tape. 6. High-frequency local communication cable according to claim 5, characterized in that the armor is made of corrugated steel-polymer tape. 7. High-frequency local communication cable according to claim 5, characterized in that the armor is made of galvanized steel round wires. 8. Local communication cable high-frequency according to any one of paragraphs.6 and 7, characterized in that the insulation of copper conductors, waist insulation and the outer sheath are made of polyethylene. 9. A high-frequency local communication cable, including insulated copper conductors twisted into a core filled with a hydrophobic filler, belt insulation overlaid on the core, an aluminum-polymer tape screen and an outer sheath, characterized in that it additionally contains a central power element and optical modules, while optical modules and copper conductors are twisted around the central power element by multidirectional twisting, while a load-bearing element made of ar amide filaments. 10. High-frequency local communication cable according to claim 9, characterized in that one or more optical modules are replaced by cordes. 11. High-frequency local communication cable according to claim 10, characterized in that a copper-tin core is laid under the screen from the aluminum-polymer tape. 12. High-frequency local communication cable according to claim 11, characterized in that the central power element is made of fiberglass. 13. The high-frequency local communication cable according to claim 12, characterized in that an additional tape made of water-blocking material is additionally superimposed on top of the screen from the aluminum-polymer tape. 14. The high-frequency local communication cable according to claim 13, characterized in that the insulation of the copper conductors, the waist insulation and the outer sheath are made of polyethylene.