RU2396620C1 - Twisting method of core of multi-strand communication cables, twisting device, and multi-strand communication cable - Google Patents

Abstract

FIELD: electricity. ^ SUBSTANCE: in twisting device there provided is length measuring instrument, and distribution receptacle is active. ^ EFFECT: providing bundles of similar length. ^ 29 cl, 4 dwg

Description

The invention relates to cable technology, namely to the production of multicore communication cables, signaling, computer science and data transmission and their structures.

Multicore communication, signaling, informatics and data transmission cables (hereinafter referred to as communication cables) have the following design: several single-wire or multi-wire (twisted from several wires) conductive conductors insulated by a dielectric, previously twisted into groups of two or three, or four conductors, the groups are twisted into a core, on top of which a belt insulation is applied, extruded or made of polymer films, a metal or metal-polymer screen and a moisture-proof sheath. A hydrophobic aggregate or water blocking elements may be introduced into the core. Suspended version is possible with a cable integrated in the moisture barrier or in the cable core. Or an armored cable with protective covers applied over a moisture-proof sheath, for example, according to GOST 7006-72.

Initially, twisting into the core was carried out in a twisted manner, when pairs or triples or fours (hereinafter referred to as groups) twisted on a separate machine were installed in a so-called flashlight of a general twisting machine. The groups in the core were superimposed in concentric layers, and from each lamp - in a separate layer. But such lantern-type machines had a very small linear twisting speed and a limited cable length, depending on the length of the group placed on the giving coil.

In order to increase the linear speed of twisting and increase the length of the finished product, a transition was made to bundle twisting of the core, for which intermediate, so-called elementary bundles were used, into which groups were twisted. The core was twisted from elementary bundles by midwire twisting. The advantage of this method of twisting is a higher linear speed of twisting of the core and a large length of the finished cable core. The greater length was obtained due to the fact that the elementary beams were received on containers of large capacity, and in the twisting machines of the core from the elementary beams did not rotate volumetric transmitting devices, as was the case with flashlight machines, but relatively more compact receiving devices.

However, bundle cables have a new drawback. The electrical parameters of the groups, such as: electrical resistance of conductive conductors, working capacity, attenuation coefficient, and others in the elementary bundles of the external coil, significantly differ from the similar parameters of the groups of elementary bundles located in the central coil.

Consider a schematic illustration of a device for twisting the core of a multicore cable from elementary bundles, shown in figure 1. (Production of cables and wires. Edited by N.I. Belorussov and I. B. Peshkov. M., Energoizdat, 1981). Figure 1 shows a device for twisting one of the common cores, consisting of 25 groups grouped into seven elementary bundles: three groups are twisted in three groups, in four - four.

The device for twisting the core of elementary bundles, shown in figure 1, consists of a stationary giving device 1, including seven racks with drums 2, and elementary bundles 3 moving along the guiding devices (not shown), fixed distribution socket 4, fixed gauge 5 , tape wrapper 6, traction 7 and receiving 8 devices placed in two synchronously rotating or paired stands 9 and 10, respectively.

Elementary bundles 3, coming from the giving drums 2, pass through the eyes of the holes in the massive stationary distribution socket 4 and caliber 5, and then wrapped with polymer tapes using tape 6.

The point of application of polymer tapes is located directly in front of the cable entry into the traction device.

The core, wrapped with tapes, enters the caterpillar traction device 7, rotating around the axis of twisting, and then to the receiving drum 8, also rotating around this axis. The rotation of the stand 10, in which the receiving device 8 is located, occurs with the same frequency (synchronously) and in the same direction as the rotation of the stand 9 with the traction device 7. The elementary bundles 3 are twisted into the core in the area between the stationary gauge 5 and the rotating around the axis of twisting by the traction device 7 closer to the stationary caliber 5.

Consider separately the passage of elementary beams 3 through a fixed distribution outlet 4, which we will call the passive outlet, shown in figure 2.

A fixed socket consists of a base 11, directly of a socket 12 with seven ceramic eyes with central holes 13. The base 11 serves to fix the socket in the machine and can be any. The socket 12 can be made in the form of any flat figure and serves to fix the eyes 13 in space. Ceramic eyes 13 are used to fix in space the point of passage of elementary beams in order to avoid confusion. The eyes are made of ceramic with a polished inner surface of the hole in order to avoid abrasion of the insulation of conductive conductors when passing through the hole.

The passage of an elementary beam through the opening of the distribution socket uniquely fixes its position in the core of the core: the beam passing through the central hole definitely falls into the central core, the beam passing through one of the peripheral holes definitely goes into the next coil.

The length of the conductive veins of the groups located in the elementary bundle in the central layer is increased only by twisting the groups into the elementary bundle. And the length of the conductive veins of the groups located in the elementary bundles of the next coil, increases in addition due to the twisting of the bundles around the central coil. In reality, the difference between the lengths of the conductive cores of the central and the next tufts is several percent. In some cases, for such parameters as: electrical resistance of conductive conductors, working capacity, attenuation coefficient, this discrepancy is unacceptable. To eliminate this drawback, it is necessary to change the method of twisting the core in order to ensure approximate equality of the lengths of the conductive veins independent of which elementary bundle they are located in, that is, to achieve equality of lengths of elementary bundles.

An object of the invention is to provide a method for twisting the core of a multicore cable from elementary bundles, providing the same length of elementary bundles in the finished cable, a device for twisting the elementary bundles, providing the same length of elementary bundles in the finished cable, and a multicore cable for communication with the core of the bundle, in which the elementary bundles have same length.

The technical problem is solved by the fact that a method of twisting the core of a multicore communication cable from elementary bundles is proposed, in which elementary bundles regularly change their location in the core of the core and as a result it turns out that the lengths of all elementary bundles are equal to each other.

The implementation of the method of twisting the core from elementary bundles, ensuring equal lengths of elementary bundles in the finished cable, is performed using the device shown in Fig.3. The device for twisting the core from elementary bundles with equal lengths in the finished cable consists of a delivery device 1, including a length meter 14, seven racks with drums 2 and elementary bundles 3 moving along the guiding devices (shown), an active distribution socket 15, fixed gauge 5, tape wrapper 6, traction 7 and receiving 8 devices placed in two synchronously rotating or paired stands 9 and 10, respectively.

A schematic representation of an active distribution outlet 15 is shown in FIG. (This socket is designed for twisting the core with 25 groups combined in three groups into three elementary bundles and four groups into four elementary bundles).

The active distribution socket 15 consists of a base 11, a direct socket 12, seven ceramic eyes 13 fixed in a holder with ears 18, an actuator 16 and a control device 20.

The control device 20, according to a certain law, instructs the actuators 16 to change the positions of the peepholes 13 in the socket 12. The law can be, for example, the following: remove the peephole from the center of the next holder, insert its peephole in the clockwise direction in the center of the socket 12 in the clockwise direction.

A keypad must be provided in the control device 20 for calculating and entering a multiple length.

Actuator 16 may be a converter of any incoming energy into mechanical energy of translational motion. For example, the actuator 16 may be made in the form of an electric motor. The transmission of rotation to the rod 17 can be carried out by any known type of gear, for example, gear. For translational movement, the end of the rod can be made with a screw thread and pass through a stationary washer with the corresponding thread. The end of the rod can be rigidly connected to the inner ring of the ball bearing, and the outer ring is rigidly connected to the holder 18 of the eye 13.

Another type of actuator 16 may be an electromagnet. In this case, the upper part of the rod 17 must be made of magnetic material, and since there will be no rotational movements, the presence of cuts on the rod 17 is not required. The fastening of the rod 17 with the holder 18 of the eye 13 in this case can be rigid.

The process of twisting the core from elementary bundles is as follows.

The operator feeds the elementary bundles 3 into the twisting device, passing them sequentially from the delivery drums 2 through the active distribution socket 15, the fixed caliber 5, the tape wrapper 6, the traction device 7 and securing it to the drum of the receiving device 8 or in front of the traction device 7, connecting it with a special filling cable the so-called ramrod passed through the pulling device 7 and mounted on the drum of the receiving device 8.

Knowing the core length required by the task, the operator uses the keyboard to enter a multiple length value into the control device 20, which is the result of dividing the specified core length by the number of elementary bundles in the transfer device 1 and in the core of the cable being manufactured. The operator also enters the initial length into the length gauge 14, equal to the distance between the length gauge 14 and the fixed gauge 5.

Then the operator turns on the device for twisting the core from elementary bundles and the curled core enters the drum of the receiving device 8.

The length meter 14 measures the current length of the elementary bundle and translates the value through the connecting wires to the control device 20. The control device 20 controls the current value of the length (a specific value is set depending on the linear speed of twisting), instructs the actuators 16 to change according to the law eye positions 13.

After changing the positions of the ocelli 13, the next elementary bundle will be in the central layer.

In the finished cable, each bundle will consist of a sum of two lengths: when passing through a central winding and when passing through an external winding. Since the lengths of passage along the central layer are the same for all elementary bundles, the lengths of passage along the external layer are the same, which means that the total lengths are the same, which was required to solve the technical problem.

The core can have more than two types of twigs, while the twisting technology is preserved, but the law of the movement of the eyes 13 will be more complicated.

A multicore communication cable consists of polymer-insulated conductive conductors twisted into groups of two, three, or four isolated conductors, the groups are twisted into elementary bundles, and elementary bundles into a core, and a moisture-proof polymer sheath overlaid on the core. The cable differs from the known ones in that when twisting the core from elementary bundles, a device is used that provides a change of places in the tufts of elementary bundles, the passage of each elementary bundle in the central tuft of the same length and the same length of all elementary bundles.

Any conductive materials can be used as conductive veins, the specific choice is determined by the conditions of use. So, to ensure a minimum attenuation coefficient, single-wire soft copper conductive conductors are used, if necessary, soldering in the input devices is tinned single-wire, for ensuring flexibility, multi-wire, twisted from several soft copper wires, to provide flexibility with soldering in the input devices, multi-wire, twisted from several tinned copper wires, to ensure tensile strength - single-wire from bimetallic (steel-copper) wire, to ensure a break hydrochloric strength and flexibility - multiwire twisted from several bimetallic (steel-copper) wires.

The cable can be used for insulation of conductive cores from any polymer material used in cable technology, the specific choice is determined by the conditions of use. So, to ensure the minimum attenuation coefficient, polyolefin insulation is used - polyethylene, polypropylene, their copolymers and compositions, to ensure fire safety of different levels - polyvinyl chloride plastic compound, special polyvinyl chloride plastic compound with reduced smoke and gas index of at least 30, halogen-free polymer composition with at least oxygen index 35.

In order to protect against mutual influences in the core, a group metal electric screen can be superimposed on one or more groups.

In order to prevent the spread of moisture along the core, the air cavities in the core are filled with a viscous hydrophobic aggregate or polymer aggregate.

In order to shape the core, a belt insulation of polymer tapes is applied to it with longitudinal overlapping or spiral winding.

To protect against external electromagnetic influences, a metal electric screen is laid under a moisture-proof sheath.

Moisture-proof sheath can be made of any polymer materials used in cable technology, a specific choice is determined by the conditions of use. So, for laying in soil or in air under the direct influence of sunlight, a moisture-proof sheath made of light-stabilized polyethylene is used; when laying indoors, a moisture-proof sheath made of polyvinyl chloride plastic compound, special polyvinyl chloride plastic compound with reduced smoke and gas emission and at least 30, is used to ensure fire safety of different levels. halogen free polymer composition with an oxygen index of at least 35.

To suspend cables along fences, along the walls of buildings and on communication supports, a cable of metal or durable synthetic threads is laid in the center of the cable core or built into the sheath. If the cable is laid in the center of the core, then the elementary bundles fall into the following several types of coils.

To protect the core, the cable laid in the center of the core is coated with any polymer material.

To protect against rodents and mechanical influences of cables laid in cable ducts, street ducts, channels and directly into the ground, armor should be provided from round steel wires applied in the form of a braid or coiled wire, or from steel strips applied in a spiral winding with overlapping, or from steel, polymer-laminated tape applied longitudinally with preliminary corrugation.

On top of the armor to protect it from the effects of water, a moisture-proof hose is applied from any polymer used in the cable industry, the specific choice is determined by the conditions of use. So, for laying in cable ducts, street ducts, channels and directly into the ground, for suspension on fences, communication poles and along the walls of buildings, light-stabilized polyethylene is used, for laying in rooms, in industrial boxes and channels on the territory of enterprises, depending on the level provided for fire safety use polyvinyl chloride plastic compound, special polyvinyl chloride plastic compound with a low smoke and gas emission and an oxygen index of at least 30, a halogen-free polymer composition with ki lorodnym index at least 35.

In order to prevent the spread of moisture under the armor in case of violation of the moisture protection hose, a water-blocking material in the form of tapes is longitudinally or wound in a spiral along the shell under the armor.

The manufacturing technology of a multicore communication cable includes the following operations.

Copper wires for conductive conductors are made of copper wire "wire rod", usually with a diameter of 8 mm by drawing. Depending on the diameter of the finished wire, the following operations can be used: coarse and medium drawing or coarse, medium and fine drawing.

To ensure softness, the wire is annealed in special annealing furnaces or in a passage for drawing operations. Annealing is not required to obtain tinned wires. Tinning is done hot, making the wire soft.

Flexible multi-wire conductors are twisted from the required number of wires on twisting machines of cigar, frame or lantern types.

Bimetal wires and other conductive materials are bought ready-made. Polymer insulation is usually applied on extrusion lines.

The twisting of isolated cores in a group (a couple or three, or four) is performed on frame-type machines. The twisting of elementary groups into an elementary bundle is performed on lantern type machines. More progressive is the use of combined twisting machines, which in one pass twist the cores into groups and groups into an elementary bundle.

The core is twisted from elementary bundles using a traditional bundle twisting machine, in which the passive distribution socket 4 is replaced by an active distribution socket 15, and a length meter 14 is installed on one of the bundles and connected by connecting wires to the control device 20 of the active distribution socket 15.

The viscous hydrophobic aggregate is applied directly to the twisted core under pressure on the passage, as a rule, in combination with subsequent operations. If, after this, belt insulation of polymer tapes is applied to the core, then a layer of viscous hydrophobic aggregate is also applied on top of it.

Polymer aggregate is applied on extrusion lines.

Belt insulation made of polymer tapes is applied by spiral winding with overlapping on winding machines or longitudinally overlapping using an additional thread wrapper or tape wrapper for fastening with a bundle of threads or a narrow plastic tape in a spiral, respectively.

An electric screen, applied to individual groups or to the core, can be made in the form of a braid or winding from soft copper or tinned copper wires, in the form of a continuous layer of metal-polymer tape, applied by spiral winding with overlapping or longitudinally with overlapping, or combined, consisting of two layers, the first layer, usually longitudinally overlapping, is made of metal-polymer tape with the metal upward, and the second layer is a braid or winding made of soft copper or tinned copper wires. If the metal of the first layer is copper, then the braid is made of soft copper wires, if aluminum, then the braid is made of tinned copper wires to avoid corrosion.

Above the screen of the groups, as a rule, they impose a belt insulation of polymer tapes by winding in a spiral.

An electric shield in the form of a braid or winding is superimposed on the braid or winding machines, respectively. Pre-possible cane (combining) of wires in bundles on reed machines.

An electric screen made of metal-polymer tape is applied by spiral winding with overlapping on winding machines or longitudinally with overlapping operations for applying a moisture-proof sheath. The screen is superimposed with metal inside, and a tinned copper drainage wire is passed under it.

In the manufacture of the combined screen, the metal-polymer tape is allowed to run longitudinally with a metal layer overlapping up under the braid or winding on a braid or wrapping machine, respectively.

A moisture-proof sheath and a moisture-proof hose are applied mainly on extrusion lines.

If the cable is made to be built-in into the sheath, then the sheath is applied simultaneously to the core supplied in parallel with the waist insulation and the shield and the cable on the extrusion line. Polymer insulation on the cable is also applied on the extrusion line. The cable in the core is laid in the center for the operation of twisting the core from elementary bundles.

The water blocking layer is applied mainly by the water blocking tape by spiral winding on a winding machine.

Armor made of round galvanized steel wires is applied in the form of a braid or winding on braiding or armoring machines, of steel tapes - winding in a spiral with overlapping tape armoring machines. When using laminated steel tapes, the armor is applied longitudinally using a special corrugating and coagulation unit together with the application of a moisture-proof hose.

To confirm the achieved result, two multicore communication cables were produced containing 25 pairs in the core.

The first, 1150 m long, was made completely according to traditional technology, while a passive distribution socket was used in the device for twisting the core from elementary bundles, which uniquely fixed the location of each elementary bundle according to the lines along the entire length of the cable.

The second, 1200 m long, was manufactured using traditional technology, with the exception of the operation of twisting the core from elementary bundles. In the device for twisting the core from elementary bundles, an active distribution socket and a length meter were used on one of the elementary bundles, which ensured the implementation of core twisting according to this invention. Every 150 m, the elementary bundle of the central tuft was replaced by the previous one in the direction of twisting, as a result of which the lengths of each elementary bundle in the center were the same and equal to 150 m, and the lengths laid down in the next tuft were equal, and, therefore, were approximately equal to the lengths all elementary beams.

At the AESA CORTAILLOD measuring system, the attenuation coefficient of both cables was measured.

The measurement results of the attenuation coefficient as a function of frequency, reduced to 1 km of length and a temperature of 20 ° C, of a cable manufactured completely according to traditional technology are presented in the graph of Fig. 5, of a cable whose core is twisted according to the method that is the essence of the present invention, is presented in the graph Fig.6.

As can be seen in the graph of Fig. 5, there are two distinct groups of curves: one (lower) corresponds to the results of measuring the attenuation coefficient in pairs located in an elementary bundle of a central midwife (the value of the attenuation coefficient for them is clearly lower than that of the others), and the other - corresponding to the results of measurements of the attenuation coefficient in pairs of the remaining elementary bundles of the upper midwife.

On the graph of Fig.6 shows that all the curves are quite heaped and on average, lower than the second group of curves of Fig.5. This suggests that the lengths of the elementary bundles of the cable, the core of which is twisted according to the method described in this invention, are the same and slightly less than the lengths of the bundles lying in the upper coil of a traditional cable, which confirms the achieved result.

Claims (29)

1. The method of twisting the core of a multicore communication cable from elementary bundles having a unique affiliation with a particular core winding along the entire length, characterized in that after the manufacture of a twisted core with a multiple length equal to the ratio of the final length of the twisted core known to the start of twisting to the number of elementary bundles, regular replacement of elementary tufts of the central tuft with elementary tufts of subsequent tufts, resulting in an equal length of all elementary tufts in finished core. 2. The method according to claim 1, characterized in that for a core formed from two tufts of elementary bundles, with one elementary bundle in the central tuft, the elementary bundle from the central tuft is replaced with the previous one in the direction of twisting from the outer tuft. 3. A device for twisting the core of multicore communication cables from elementary bundles, consisting of a delivery device, a stationary passive distribution outlet with eyes through which elementary bundles, a fixed caliber, a rotating traction device enclosed in a cage, a rotating receiving device enclosed in a cage, moreover, the traction and receiving devices are rigidly connected to their stands and both stands are interconnected or rotate synchronously, characterized in that according to the method Claim 1 is one of the elementary beams pass through the meter length mounted in the pay-off, and a fixed distribution socket made active, providing change the spatial arrangement extending therethrough elementary beams. 4. The device according to claim 3, characterized in that the fixed active distribution socket included in it further comprises several actuators, quantitatively equal to the number of eyes, connecting rods between each eye and an associated actuating device, a control device connected by connecting wires to with a length meter installed in the delivery device, the eyes are mounted on movable holders with ears inserted in hidden grooves and from the point of maximum location of each th eye to the center in the socket housing made free channels to the center, enabling to move each eye from a maximum point located in the center. 5. The device according to claim 4, characterized in that the actuators included in the movable active distribution socket are made in the form of electric motors, the rotating shaft of which is connected by a transmission mechanism to the connecting rods, and the connecting rods are screwed and connected to the eye holders with using a ball bearing, and the socket is additionally equipped with fixed washers for each rod with internal screw thread, providing translation of the rotational movement of the rod into the receiver nye. 6. The device according to claim 4, characterized in that the actuators included in the fixed active distribution socket are made in the form of electromagnets, part of the rods along the length are made of magnetic material, and the rods are rigidly connected to the holders of the eyes. 7. The device according to claim 4, characterized in that the control device, which is part of a fixed active distribution outlet, is additionally equipped with a calculator and a keyboard for calculating and entering multiple lengths. 8. A multicore communication cable with several insulated conductive cores, combined in groups of two, three, or four cores, the groups are twisted into elementary bundles that are twisted into a core, and a moisture-proof sheath, characterized in that the elementary bundles are twisted into a core by claim 1 and have an equal length. 9. The cable according to claim 8, characterized in that the conductive wires are made single-wire. 10. The cable according to claim 9, characterized in that the conductive conductors are made of soft copper, or tinned copper, or bimetallic steel-copper wire. 11. The cable according to claim 8, characterized in that the conductive wires are multi-wire. 12. The cable according to claim 11, characterized in that the conductive wires are twisted from several soft copper, or tinned copper, or bimetallic steel-copper wires. 13. The cable according to claim 8, characterized in that the insulation of the conductive conductors is made of polyethylene, or polypropylene, or their block copolymers, or their composite mixtures. 14. The cable according to claim 8, characterized in that the insulation of the conductive conductors is made of polyvinyl chloride plastic compound, or special polyvinyl chloride plastic compound with reduced smoke and gas emission and an oxygen index of at least 30, or a halogen-free polymer composition with an oxygen index of at least 35. 15. The cable according to claim 8, characterized in that it further comprises at least one electric screen. 16. The cable according to clause 15, wherein the screen is made as a group, superimposed on at least one group, or common, superimposed on the core. 17. The cable according to clause 15, wherein the screen is made in the form of a braid or winding of soft copper, or tinned copper, or bimetallic steel-copper wires. 18. The cable according to clause 15, wherein the screen is made of metal-polymer tape imposed by a spiral winding or longitudinally overlapping with a metal layer inward, and under the metal layer an additional drainage soft copper or tinned copper wire is laid. 19. The cable according to clause 15, wherein the screen is made of a combined two-layer, the first layer is longitudinally superimposed with the metal polymer tape overlapping upward, the second layer is in the form of a braid or winding made of copper or tinned copper or bimetallic steel-copper wires. 20. The cable according to any one of paragraphs.8 or 15, characterized in that the air voids in the core, including inside the shielded groups, are filled with a viscous hydrophobic or polymer aggregate. 21. The cable according to claim 8, characterized in that the moisture-proof sheath is made of light-stabilized polyethylene, or polyvinyl chloride plastic compound, or special polyvinyl chloride plastic compound with reduced smoke emission and an oxygen index of at least 30, or a halogen-free polymer composition with an oxygen index of at least 35. 22. The cable according to claim 8, characterized in that metal armor and a moisture protection hose are applied over the moisture barrier. 23. The cable according to claim 22, characterized in that a layer of water blocking material is additionally laid under the armor. 24. The cable according to item 22, wherein the armor is made of round steel galvanized wires in the form of a braid or winding. 25. The cable according to item 22, wherein the armor is made of steel strips, imposed by a winding in a spiral. 26. The cable according to item 22, wherein the armor is made of steel polymer-laminated tape, applied longitudinally with preliminary crimping. 27. The cable according to claim 22, wherein the moisture-proof hose is made of light-stabilized polyethylene, or polyvinyl chloride plastic compound, or special polyvinyl chloride plastic compound with reduced smoke emission and an oxygen index of at least 30, or a halogen-free polymer composition with an oxygen index of at least 35. 28. The cable according to claim 8, characterized in that a cable made of metal wires or strong synthetic threads is integrated in the center of the core or in the moisture barrier. 29. The cable according to claim 28, wherein the cable is additionally coated with a polymer sheath.

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