RU156353U1 - COMMUNICATION CABLE - Google Patents

Abstract

1. A communication cable containing at least one pair of conductive conductors with the possibility of transmitting a signal through them, insulated by an internal insulator and twisted into a spiral that is covered by an external insulator, the inner and outer insulators being high-frequency polymer dielectrics, characterized in that twisting steps range from 80 to 300 mm. 2. A communication cable according to claim 1, characterized in that a foamed polyolefin is used as the material of the internal and external insulators. 3. The communication cable according to claim 2, characterized in that foamed polyethylene is used as a foamed polyolefin. 4. The communication cable according to claim 1, characterized in that the material of the internal insulators is low-pressure polyethylene. The communication cable according to claim 1, characterized in that the material of the internal insulators is high-pressure polyethylene. The communication cable according to claim 1, characterized in that the material of the external insulators is low-pressure polyethylene. The communication cable according to claim 1, characterized in that the material of the external insulators is high-pressure polyethylene. Communication cable 1, characterized in that the twisting steps of the individual pairs are not equal to each other. Communication cable 1, characterized in that the twisting steps of individual pairs are not multiple of each other. 10. Communication cable 1, characterized in that the ratio of the pitch of the twist is in the range of 1.01 - 4.0.11. The communication cable according to claim 1, characterized in that the twisting steps of the individual pairs are not equal and not multiple to each other, and their ratio is in the range 1.01 - 4.0.12. The communication cable according to claim 1, characterized in that the external insulators of at least two pairs are interconnected

Description

The inventive utility model relates to telephone communications and electronic equipment, namely, conductors and cable connections and can be used in the manufacture of cables for subscriber broadband access networks, Internet telephony, in the operation of cables on urban, corporate, rural and the like communication networks, including the use of digital and analogue subscriber line transmission systems, for example, TsAL JV (xDSL).

The communication cable according to the patent of the Russian Federation No. 2476944 of 09/23/2011 for the invention is the closest analogue (prototype) of the claimed cable, which contains at least one pair of conductive wires with the possibility of transmitting a signal through them, isolated from each other by an internal insulator and twisted into the spiral, which is covered with an external insulator so that it fills all the voids between the insulated conductive cores, while the cores are twisted into a spiral with a pitch of 10 to 80 mm, and the internal and external insulators are high-frequency polymeric dielectrics from a number of polyolefins, homogeneous to each other, with the addition of a thermal stabilizer - LV diaphene from 0.05% to 0.2% and light stabilizer - carbon black from 1% to 3% to the external insulator. However, this cable has several disadvantages, the main ones being the high cost, high linear attenuation coefficient of the signal and lack of versatility, since this cable is often disadvantageous to use on subscriber communication lines with an analog signal, where there is no need for transient immunity.

The task posed by the author of the development is the creation of such a cable design that would reduce its cost and linear attenuation of the signal, and increase its versatility.

The technical result is to reduce the material consumption of the cable and the linear attenuation of the signal.

The essence of the utility model is that in a communication cable containing at least one pair of conductive cores with the possibility of transmitting a signal through them, isolated from each other by an internal insulator and twisted into a spiral, which is covered with an external insulator, moreover, internal and external insulators are high-frequency polymer dielectrics; values of twisting steps are in the range from 80 to 300 mm.

Also, the essence of the utility model is that in the claimed cable, foamed polyolefin, for example, foamed polyethylene, is used as the material of the internal and external insulators.

However, the essence of the utility model is that in the claimed cable material of the internal insulators is polyethylene of low or high pressure.

In addition, the essence of the utility model is that in the claimed cable, the material of the external insulators is low or high pressure polyethylene.

In addition, the essence of the utility model is that the claimed cable can have a load-bearing element, which can be made of one or more steel wires, or of Kevlar, or of aramid, or of polyamide threads, or of a fiberglass dielectric rod. Moreover, the load-bearing element can be coated with the material of the external insulator and connected to it by a jumper of the same material or located inside the external insulator.

Also, the essence of the utility model is that the claimed cable can be made in such a way that the external insulators of each pair are interconnected with a partial intersection of circles.

However, the essence of the utility model is that the claimed communication cable can be made with fastening in the form of a jumper between the external insulators; or fastening in the form of a jumper between the external insulators and the petal on one side; or a petal mount on one side; or in the form of petals on both sides.

Also, the essence of the utility model is that the claimed cable may contain 4 pairs of conductive cores.

In addition, the essence of the utility model is that in the new cable, the twisting steps of the individual pairs are not equal to each other.

At the same time, the essence of the utility model is that in the new cable, the twisting steps of individual pairs are not multiple of each other.

Also, the essence of the utility model is that in the new cable the ratio of the twisting steps is in the range of 1.01-4.0.

In addition, the essence of the utility model is that in any version of the new cable, the twisting steps of individual pairs may not be equal and not multiple to each other, their ratio is between 1.01-4.0, and the range of twisting steps is from 80 up to 300 mm.

The utility model is illustrated graphically, where:

in FIG. 1 shows a cross-sectional view of a single-pair cable

in FIG. 2 is a view of a cross-cut single-pair cable with a load-bearing element coated with an external insulator material and connected to it by a jumper of the same material.

in FIG. 3 is a view of a cross-cut single-pair cable with a load-bearing element located inside the outer insulator.

in FIG. 4 is a view of a cross-cut double-pair cable, in which the external insulators of each pair are interconnected with a partial intersection of circles.

in FIG. 5 is a view of a cross-cut double-pair cable made with a mount in the form of a bridge between the external insulators.

in FIG. 6 is a cross-sectional view of a two-pair cable with jumpers between the outer pair insulators and the load-bearing element.

The communication cable shown in FIG. 1, includes one pair of conductive conductors 1 made, for example, of a copper alloy, each core is insulated by an internal insulator 2. The material of the internal insulators 2 is a high-frequency polymer dielectric from a number of polyolefins, for example, low-pressure polyethylene. Insulated conductors are twisted into a spiral with a pitch of 80 to 300 mm. An external insulator 3 is applied on top of the spiral. The material of the external insulator 3, just like the material of the internal insulator 2, is a polymer dielectric, from a number of polyolefins, for example, high-pressure polyethylene with the addition of a heat stabilizer - LV diaphene from 0.05% to 0.2 % and light stabilizer - carbon black from 1% to 3%.

However, the inventive cable can be made as shown in FIG. 3. It includes one pair of conductive conductors 1, insulated with internal insulators 2. The conductors are twisted into a spiral with a pitch of 80 to 300 mm. An external insulator 3 is applied on top of the spiral. The cable has a load-bearing element 5 made, for example, of several steel galvanized wires twisted into a cable coated with an external insulator material and connected to it by a jumper 6 of the same material.

The inventive communication cable may be made as shown in FIG. 4. It includes one pair of conductive conductors 1, insulated by internal insulators 2. The conductors are twisted into a spiral with a pitch of 80 to 300 mm. An external insulator 3 is applied on top of the spiral. The load-bearing element 5 is located inside the external insulator.

In addition, the inventive cable can be made as shown in FIG. 5, which shows a cable that includes two pairs of conductive conductors 1, insulated with internal insulators 2. The conductors are twisted in a spiral with a pitch of 80 to 300 mm so that the twisting steps of the pairs are not equal and not multiple to each other, and the ratio of steps is in the range of 1.01-4.0. Outer insulators 3 are applied on top of the spirals, so that the outer insulators of each pair are connected to each other with a partial intersection of circles.

However, the inventive cable can be made as shown in FIG. 6, which shows a cable that includes two pairs of conductive conductors 1, insulated by internal insulators 2. The conductors are twisted in a spiral with a pitch of 80 to 300 mm so that the twisting steps of the pairs are not equal and not multiple to each other, and the ratio of steps is in the range of 1.01-4.0. External insulators 3 are applied on top of the spirals. Between the external insulators a fastening in the form of a jumper 6 made of the same material is made.

Also, the inventive cable can be made as shown in FIG. 7, which shows a cable that includes two pairs of conductive conductors 1, insulated by internal insulators 2. The conductors are twisted in a spiral with a pitch of 80 to 300 mm so that the twisting steps of the pairs are not equal and not multiple to each other, and the ratio of the steps is the range of 1.01-4.0. external insulators 3 are applied to the spirals. Between the external insulators a fastening in the form of a bridge 6 of the same material is made. The cable has a load-bearing element 7, coated with a material of the external insulator 3 and connected to it by a jumper 8 of the same material.

The claimed communication cable is mounted to the surface or structure using nails, brackets or any other fixing devices. Although it can be mounted on the surface or in the structure and using the currently widely used cable channels. The conductors of the inventive cable transmit the signal from the source to the receiver.

Using the claimed cable will allow solving urgent economic and technical problems associated with cheaper and simplified production, installation and operation, since an increase in the twisting steps leads to significant savings in the cost of the cable by reducing the cost of copper and reducing the linear attenuation of the signal.

Claims (25)

1. Communication cable containing at least one pair of conductive cores with the possibility of transmitting a signal through them, insulated by an internal insulator and twisted into a spiral that is covered by an external insulator, the internal and external insulators being high-frequency polymer dielectrics, characterized in that the values twisting steps range from 80 to 300 mm. 2. The communication cable according to claim 1, characterized in that foamed polyolefin is used as the material of the inner and outer insulators. 3. The communication cable according to claim 2, characterized in that foamed polyethylene is used as a foamed polyolefin. 4. The communication cable according to claim 1, characterized in that the material of the internal insulators is low-pressure polyethylene. 5. The communication cable according to claim 1, characterized in that the material of the internal insulators is high pressure polyethylene. 6. The communication cable according to claim 1, characterized in that the material of the external insulators is low pressure polyethylene. 7. The communication cable according to claim 1, characterized in that the material of the external insulators is high-pressure polyethylene. 8. Communication cable 1, characterized in that the twisting steps of the individual pairs are not equal to each other. 9. Communication cable 1, characterized in that the twisting steps of the individual pairs are not multiple of each other. 10. Communication cable 1, characterized in that the ratio of the steps of the twist is in the range of 1.01 to 4.0. 11. The communication cable according to claim 1, characterized in that the twisting steps of the individual pairs are not equal and not multiple to each other, and their ratio is in the range of 1.01 - 4.0. 12. The communication cable according to claim 1, characterized in that the external insulators of at least two pairs are interconnected with a partial intersection of circles. 13. The communication cable according to claim 1, characterized in that it contains 4 pairs of conductive conductors. 14. Communication cable 1-13, characterized in that it has a load-bearing element. 15. The communication cable according to claim 14, characterized in that the load-bearing element is made of one steel wire. 16. The communication cable according to claim 14, characterized in that the load-bearing element is made of several steel wires twisted into a cable. 17. The communication cable according to claim 14, characterized in that the load-bearing element is made of Kevlar, aramid or polyamide threads twisted into a cable. 18. The communication cable according to claim 14, characterized in that the load-bearing element is made of a fiberglass dielectric rod. 19. The communication cable according to claim 14, characterized in that the load-bearing element is coated with a material of the external insulator and connected to it by a jumper of the same material. 20. The communication cable according to claim 14, characterized in that the load-bearing element is located inside the external insulator. 21. The communication cable according to p. 14, characterized in that it is made with fastening in the form of a jumper between the external insulators and a jumper between the external insulator and the load-bearing element 22. Communication cable 1-13, characterized in that it is made with a mount in the form of a jumper between the external insulators. 23. Communication cable 1-13, characterized in that it is made with a mount in the form of a jumper between the external insulators and the petal on one side. 24. Communication cable 1-13, characterized in that it is made with a mount in the form of a petal on one of the sides. 25. Communication cable 1-13, characterized in that it is made with mounting in the form of petals on both sides.

Images