RU2476944C2 - Communication cable - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: communication cable has at least one pair of conductors configured to transmit a signal, insulated from each other by inner insulation and twisted into a spiral which is coated by outer insulation such that it fills all the empty space between the insulated conductors, wherein the conductors are twisted into a spiral with pitch distance of 10-80 mm, and the inner and outer insulation is in form of high-frequency polymeric dielectric materials selected from polyolefins, which are similar to each other, with addition of a heat stabiliser - 0.05-0.2% diaphene NN and a light stabiliser - 1-3% technical carbon to the outer insulation.

EFFECT: longer service life of the cable, high reliability of the cable by endowing it with high resistance to cross talk, high versatility of the cable owing to high breaking resistance, resistance to unfavourable external factors, design of a structure which makes cabling easy at any suitable surface and structures.

9 cl, 4 dwg

Description

The invention relates to telephone communications and electronic equipment, namely, conductors and cable connections, and may find application in the manufacture of cables for subscriber broadband access networks, Internet telephony, and in cable operation in urban, corporate, rural, and similar communication networks.

Known cable telephone and radio communications according to the certificate of the Russian Federation No. 217878 for utility model dated 07/19/2001, IPC7 H01B 11/00. This cable, which is an analogue of the claimed cable, is single-pair, with copper or aluminum conductors, with a polyethylene insulation and protective sheath, designed for use on subscriber telephone lines and distribution networks of wire broadcasting up to 250 V with a frequency of up to 10 kHz. In its design there is no sheath superimposed on insulated conductors, thereby expanding the range of cables for telephone communications and radio communications. But the described analogue has several disadvantages. The main one is the weak resistance of the cable to continuous cracking, as well as the absence of spiral twisting, which, as studies have shown, significantly affects the resistance of subscriber lines to external electrical and radio interference.

Also known is a single-pair communication cable according to the patent of the Russian Federation No. 39734 for utility model dated 08/10/2004, IPC7 H01B 11/00. This cable contains two insulated conductive wires twisted in a pair and placed in an inner sheath, over which a braid of steel galvanized wires is laid, covered with an outer protective sheath of polyethylene. The insulation of the conductive conductors is made of three concentric layers of continuous, porous (foamed) and continuous polyethylene, the conductors are twisted in a multidirectional manner with an arbitrary step, and water-blocking threads are placed between conductive veins when twisted, and the inner shell is made of water-blocking polyethylene. But this cable is quite laborious to manufacture, in addition, it has a rather high cost price, which, in general, is not economically profitable for the implementation of the goals.

The closest set of essential features to the claimed invention (prototype) is a vapor-tight cable for high-speed data transmission according to item 21 of the RF patent No. 2262146 for the invention of 05/14/2001, IPC7 H01B 7/28, H01B 11/02 and H01B 13/32. This cable contains at least two conductors through which the signal is transmitted, twisted in the form of a spiral structure, a drawable vapor-proof core filler, stretched between these two conductors, through which the signal is transmitted, compressed and deformed so that it hermetically filled at least the internal voids between the specified at least two conductors, and vapor-tight peripheral material deposited by extrusion under pressure so that it fills the peripheral voids around the indicated at least two conductors through which the signal is transmitted, said drawable core filler and the extruded peripheral filler form an airtight jacket for said conductors through which the signal is transmitted, all over length, whereby vapor flow along the cable is prevented. This prototype cable is partially devoid of the disadvantages of the two analogues described above. But nevertheless, the following main disadvantages are inherent in it: the complexity of manufacturing and short service life, as well as the low reliability of its operation when laying outdoors (in street conditions).

The task set by the author of the development is to increase the service life of the cable by increasing the resistance of the cable to rupture and cracking under adverse environmental conditions, for example, with increased humidity, solar radiation, dry air, severe temperature conditions and the like. Also, the task posed by the author is to increase the reliability of the cable by making it more resistant to transient interference. In addition, the task facing the developer was to increase the versatility of the cable due to tear resistance, adverse external factors, as well as creating a structure that is convenient when installing the cable on any suitable surfaces and structures.

The technical result achieved in solving the tasks was the exclusion of cracking of the cable during operation in adverse external conditions due to the use of materials with greater elasticity and increased resistance to changes in external factors. In addition, the cable's resistance to crosstalk has increased, since it is the applied twisting steps that are most optimal for protecting digital subscriber lines (DSCs) from external interference. At the same time, the technical result of the development is the stability of the proposed cable to rupture and ease of installation due to the addition of a jumper and a support cable, which strengthen the cable and at the same time leave it with the necessary elasticity for operation and installation. This also eliminates the need for additional mounting materials, such as mounting brackets.

The essence of the invention lies in the fact that in a communication cable containing 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 a spiral, which is covered by an external insulator so that it fills everything voids between insulated conductive conductors, the conductors are twisted into a spiral with a pitch of 10 to 80 mm, and the inner and outer insulators are high-frequency polymer dielectrics from a number of polyolefins, homogeneous to each other, with the addition of m to the external insulator of the thermostabilizer - NI diaphen from 0.05% to 0.2% and the light stabilizer - carbon black from 1% to 3%. This provides the necessary level of parameters of mutual influence between the circuits.

In addition, the invention consists in the fact that the communication cable has an external bearing cable from one or more single strand cores, which is coated with a material of an external cable insulator and connected to it by a jumper of the same material.

At the same time, the essence of the invention lies in the fact that the communication cable consists of two pairs twisted into a spiral, insulated from each other, conductive conductors, each pair covered with an external insulator, and the pairs themselves contain insulated conductors twisted in pairs in a spiral with a pitch of no more than 80 mm.

Also, the essence of the invention lies in the fact that in a new cable, the twisting steps of individual pairs are not equal and not multiple to each other.

In addition, the essence of the invention lies in the fact that in the new cable the ratio of the twisting steps is in the range of 1.2-1.3.

However, the essence of the invention lies in the fact that the external insulators of each pair in this cable are interconnected with a partial intersection of circles.

In addition, the essence of the invention lies in the fact that the new cable has a remote bearing cable from one or more single strand cores, which is coated with an external insulator material and connected to the cable with a jumper of the same material.

Also, the invention consists in the fact that the foamed polyolefin is used as a material of the internal and external insulators in the new cable.

The invention also consists in the fact that foamed polyethylene is used as a foamed polyolefin in a new cable.

The invention is illustrated graphically, where:

figure 1 shows a cross-sectional view of a single-pair communication cable;

figure 2 is a view of a cross-cut single-pair communication cable with a carrier cable;

figure 3 is a view of a cross-cut two-pair cable;

figure 4 is a view of a cross-cut double-pair cable with a supporting cable.

The design of a single-pair cable is shown in figure 1. This cable includes one pair of conductive conductors 1 made, in particular, of a copper alloy, each of which covers the inner insulator 2. The material of the inner insulator 2 is a high-frequency polymer dielectric from a number of polyolefins, in this case low-pressure polyethylene. Insulated conductors are twisted into a spiral with a pitch of 10 to 80 mm. Such a step, as shown by experimental studies and operating experience of similar cables, is the most optimal for protecting digital subscriber lines from external radioelectric interference. A continuous insulator 3 covers a pair of insulated conductive wires twisted into a spiral. The material of the external insulator 3, just like the material of the internal insulator 2, is a high-frequency polymer dielectric from a number of polyolefins. In this case, high-pressure polyethylene, with the addition of from 0.05% to 0.2% NI diaphen and from 1% to 3% light stabilizer - carbon black (soot), which is characterized by a high dispersion index and a low structural index. For example, the K-354 brand (an analogue of the foreign “Spheron-6”). The external insulator 3 is applied in such a way that it tightly fills all the voids between the insulated cores. The air space between the insulated conductive conductors 1 and the external insulator 3 is absent, thus achieving absolute moisture resistance of the cable and eliminating the need for water-blocking threads and tapes.

A single-pair cable with an external carrier cable is shown in Fig.2. It also includes a pair of 2 conductive copper conductors 1 insulated by an internal insulator, twisted into a spiral with a pitch of 10 to 80 mm. The twisted pair is surrounded by an external insulator 3, from which a coating of the support cable 4 and a jumper 5 connecting the cable with the cable are also formed. The supporting cable 4 is intended to increase the mechanical strength of the cable and provides, in particular, its suspension on the supports of overhead communication lines. The support cable 4 includes one or more single strand cores 6 of a material having a tensile strength of at least 170 kg / mm2. with a breaking force of at least 200 kgf, in this case, from a steel alloy.

A cross section of a two-pair cable is shown in FIG. The cable consists of two pairs of insulated internal insulator 2 and twisted into a spiral with a pitch of 10 to 80 mm of conductive conductors 1. The insulated conductors are twisted in pairs in a spiral with a pitch of no more than 80 mm. The twisting steps of individual pairs are not equal and not multiple to each other. The ratio of the twisting steps is in the range 1.2-1.3. This provides the necessary level of parameters of mutual influence between the chains in accordance with the standards. Each pair is covered with a layer of the external insulator 3. The pairs are interconnected so that the circumferences of the external insulators 3 of each pair are slightly crossed for easy cutting.

A two-pair cable with a remote bearing cable in cross section is shown in figure 4. It also consists of two pairs of conductive conductors 1 insulated by internal insulator 2 and twisted into a spiral with a pitch of 10 to 80 mm. Each pair is covered with a layer of external insulator 3. The pairs are interconnected so that the circumferences of the external insulators 3 pairs are slightly crossed for convenience butchering. A coating of the support cable 4 and a jumper 5 connecting the cable to the cable are formed from the external insulator 3. The supporting cable 4 is intended to increase the mechanical strength of the cable and provides, in particular, its suspension on the supports of overhead communication lines. The support cable 4 includes one or more single strand cores 6 of a material having a tensile strength of at least 170 kg / mm2. with a breaking force of at least 200 kgf, in this case, from a steel alloy.

The claimed communication cable is mounted to a surface or structure using fasteners, using a carrier cable and a jumper as attachment points. Further along the conductive cores, the signal is transmitted from the source to the receiver. Insulators 2 and 3 create a continuous coating that is resistant to adverse environmental conditions, which extends the life of the cable and prevents circuit closure.

The widespread use of the claimed cable, which has high reliability, a significant service life and versatility, will solve the urgent economic problem associated with the cost reduction and simplification of the production, installation and operation of cables for signal transmission, and therefore the total cost of supplying the masses with various technical solutions, in particular, from telephone and Internet connections to television.

Claims (9)

1. A communication cable containing at least one pair of conductive conductors 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 by an external insulator so that it fills all the voids between the insulated conductive conductors, characterized in that the cores are twisted into a spiral with a pitch of 10 to 80 mm, and the inner and outer insulators are high-frequency polymer dielectrics from a number of polyolefins, homogeneous to each other, with the addition to the outer insulator a torus of a heat stabilizer - NI diaphen from 0.05% to 0.2% and a light stabilizer - carbon black from 1% to 3%. 2. The communication cable according to claim 1, characterized in that it has an external bearing cable from one or more single strand cores, which is coated with a material of an external cable insulator and connected to it by a jumper of the same material. 3. The communication cable according to claim 1, characterized in that it consists of two pairs of conductive conductors, isolated from each other, twisted into a spiral, each pair covered with an external insulator, and the pairs themselves contain insulated conductors twisted in pairs in spirals with a pitch of no more 80 mm. 4. The communication cable according to claim 3, characterized in that the twisting steps of the individual pairs are not equal and not multiple of each other. 5. The communication cable according to claim 3, characterized in that the ratio of the twisting steps is in the range 1.2-1.3. 6. The communication cable according to claim 3, characterized in that the external insulators of each pair are interconnected with a partial intersection of circles. 7. The communication cable according to claim 3, or 4, or 5, or 6, characterized in that it has an external bearing cable from one or more single strand cores, which is coated with an external insulator material and connected to the cable by a jumper of the same material. 8. The communication cable according to claim 1, or 2, or 3, or 4, or 5, or 6, or 7, characterized in that foamed polyolefin is used as the material of the internal and external insulators. 9. The communication cable according to claim 1, or 2, or 3, or 4, or 5, or 6, or 7, characterized in that foamed polyethylene is used as a foamed polyolefin.

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