RU71025U1 - TRIBOELECTRIC CABLE - Google Patents

Abstract

The invention relates to cables for perimeter security systems based on vibration detectors with cable sensors.

The cable consists of several insulated metal conductive wires twisted into pairs, of which the core is twisted. A layer of one or more polyethylene terephthalate tapes is applied along the core; on top of them there is a first cylindrical conductor of aluminum-polyethylene tape with metal overlapping inside, under which a tinned copper contact wire is laid.

A combined dielectric consisting of a first relief layer and a second layer of one or more polyethylene terephthalate tapes is superimposed on the first cylindrical conductor. Next are laid: a second cylindrical conductor of aluminum-polyethylene tape with metal overlapping inside with a tinned copper contact wire underneath and a moisture-proof sheath.

An armored version of the design is provided.

The proposed design allows its use as a sensitive element for perimeter security systems.

Description

The utility model relates to the cable industry and can be used in cable designs used in perimeter security systems based on vibration detectors with sensitive cable elements.

Known cables used as sensitive elements: a coaxial microphone cable, a combined coaxial cable with a pair of conductive wires embedded in the insulation, a low-frequency city telephone cable with a shielded core (such as TPPep 10 × 2 × 0.32 or similar with a large diameter of conductive conductors )

The microphone cable and combination cable (article by B. Vvedensky “Security systems for perimeters at IFSEC 2004” in Security Systems magazine No. 4 (58) for August-September 2004) work in the security system for the perimeter with the obligatory connection of a signal source or power, that is, in active mode. For perimeter security systems with passive sensitive cable elements, they cannot be used.

In a cable of the TPPep type with ten pairs of conductive wires, an information signal is formed between two conductive elements, a screen acts as one of them, and as a second one all conductive wires connected together at both ends of the cable, in the area where the intruder overcomes the protected part of the perimeter due to electrification of the outer conductor (screen) (Article A.I. Larin “Vibration detectors with cable sensing element” in the journal “Security Systems” No. 4 (58) for August-September 2004). The disadvantage of this cable is that it was developed as a communication cable and only the maximum outer diameter is normalized for it (N.I. Belorussov; A.E. Saakyan; A.I. Yakovleva "Electric cables, wires and cords. Reference book" M. , "Energoatomizdat", 1987), in connection with which the electric capacitance between all conductors connected together and the screen changes from sample to sample, and the receiving device must be tuned to each specific sample. In addition, two sensing elements are used in vibromagnetometric systems, for which, in the case of a cable of the TPPep type, two separate cables have to be laid, which complicates the laying, installation and operation of the system.

As a prototype, we choose a special cable described in the invention No. 22010116 from 08/10/2003. A cable containing several insulated internal conductors, on top of which concentrically

an outer conductor is laid on which a polymer spiral cord (cordel) is wound, on which a layer of a special insulator is applied concentrically (for example, a film of electret, piezocomposite), which is capable of forming charges during mechanical deformations, on which a shielding conductor is placed, closed on top with a sealed sheath . Here, under the outer and shielding conductors are meant two conductive elements of a cylindrical shape, therefore in the future we will call them cylindrical conductors.

The disadvantage of the prototype is that in the process of winding the cordel, strict constancy of the helix pitch is not ensured, which leads to unevenness of the sensing element along the length and worsens the performance of the entire system as a whole. The same drawback is also manifested during operation, when, under the influence of soil vibration, the coils move to each other in separate places, which also changes the sensitivity of the cable element along the length.

Another disadvantage of the prototype is the lack of limitation of electric capacitance between the first and second cylindrical conductors, with an unlimited increase in which, the noise begins to suppress useful signals.

The technical task of the proposed utility model is the creation of a triboelectric cable with a multi-pair core, two sensitive elements capable of generating electric charges during mechanical deformations, with a sensitivity of the external sensitive element uniform in length along the cable and a normalized noise immunity.

The technical problem is solved by the fact that a triboelectric cable is proposed, consisting of several metal conductive cores, insulated with a polymer composition, twisted into pairs, which, in turn, are twisted into a core, coated with a layer of one or more polyethylene terephthalate tapes, laid on top of them: the first cylindrical a conductor of aluminum-aluminum tape longitudinally or spirally with metal overlapping inward, a tinned copper contact wire under the first cylindrical conductor, combinations nnogo dielectric consisting of a first relief layer of polymeric material and a second layer of one or more polyethylene terephthalate belts, the second cylindrical conductor of alyumopolietilenovoy tape longitudinally or spirally lapped metal inwardly, tinned copper contact wire under the second cylindrical conductor waterproof membrane of polyethylene composition.

The first sensitive element is formed from all conductive wires connected together, a layer of polyethylene terephthalate tapes and the first

a cylindrical conductor, the second from the first cylindrical conductor, a combined dielectric and a second cylindrical conductor.

The uniformity of sensitivity of the external sensing element is provided technologically. Suppose we are going to make the first layer of a combined dielectric from a two-layer material consisting of a polymer cordelle pre-glued along the central axis of a polyethylene terephthalate tape. Then it is possible to choose such parameters of the winding operation that the edge of the tape will lie under the cord, and this will ensure uniform pitch of the spiral along the length of the cable during manufacturing and under the influence of vibration during operation.

The requirement of normalized noise immunity will be fulfilled provided that the electric capacitance between the first and second cylindrical conductors is no more than 300 nF over a length of 1 km.

Since the installation of the described cables is carried out in junction boxes in air with humidity reaching 98% at temperatures up to 35 ° C, which, when the temperature changes, can lead to condensation of moisture on the insulation of the cores with a further decrease in electrical parameters, it is advisable to use polyethylene or foamed polyethylene composition, moreover, it is advisable to make the insulation from the foamed polyethylene composition film-porous, i.e., the insulation surface should be continuous polyethylene lenok. Production of film-porous-film insulation is possible. For example: in accordance with the patent for utility model “Cable for structured cable communication systems” No. 27962 of 08/12/2002. In this case, the inner insulation surface is also made in the form of a continuous (film) layer to improve the adhesion of the insulation to the conductive core.

In order to simplify the manufacturing technology of the first layer of a combined dielectric, it is advisable to produce it by extrusion.

To lay the cable in areas infected with rodents, it is advisable to make the cable in an armored version. At the same time, a layer of water-blocking material, round wire armor and a moisture-proof hose made of a polyethylene composition are applied to the moisture-proof shell.

The proposed utility model is illustrated by specific examples and the drawing, in which Fig. 1 is a schematic illustration of an armored triboelectric cable.

Armored triboelectric cable Figure 1, consists of several metal conductive conductors 1, isolated

polymer composition 2, twisted into pairs 3, which, in turn, are twisted into a core 4, over which a layer 5 of one or more polyethylene terephthalate tapes is laid, the first cylindrical conductor 6 of aluminum-polyethylene tape, contact wire 7 laid under the first cylindrical conductor 6, the first relief layer 8 of the combined dielectric, the second layer 9 of the combined dielectric of one or more polyethylene terephthalate tapes, the second cylindrical conductor 10 of aluminum-polyethylene tape, lay contact wire 11, a moisture-proof sheath 12 made of a polyethylene composition, a layer of water-blocking material 13, armor made of round steel wires 14 and a moisture-proof hose 15 made of a polyethylene composition, located under the second cylindrical conductor.

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

Conductors 1 are made predominantly soft copper. The cores in this case are made of copper wire "wire rod", having a diameter of, as a rule, 8 mm, by the method of drawing. Drawing is carried out in two operations: rough and medium drawing.

Conducting cores 1 can be tinned and tinned, single-wire and multi-wire.

Single-wire tinned cores are annealed in special annealing furnaces. Annealing is not required to obtain tinned veins: tinning is carried out in a hot way, as a result of which the vein becomes soft.

For stranded cores, according to the same technology, wire of the corresponding diameter is produced in the required quantity, which is then twisted in the desired combination on cigar, frame or lantern machines.

If a conductive core of other metals is used, for example: steel, then the wire of the required diameter is bought ready.

Insulation 2 on conductive conductors 1 is applied by extrusion from granular polymers. For isolation, it is advisable to use high-speed automatic extrusion lines that combine three operations: medium drawing, annealing and isolation in one pass.

Foamed insulation can be applied in one of two ways: chemical or physical. In the chemical method, a blowing agent is mixed into the polymer granules, which, when leaving the extruder head, foams and spherical air bubbles form in the insulation. In the physical method, a physical foaming unit is installed in the line in front of the extruder, which introduces a metered amount of nitrogen into spherical bubbles into the hot mass of the polymer.

In the manufacture of multilayer insulation (for example: film-porous-film), the number of extruders numerically equal to the number of insulation layers is built into the line.

Twisting of insulated cores in a pair of 3 is usually carried out on frame-type machines. The twisting of pairs 3 into the core 4 is performed, as a rule, on lantern type machines. It is advisable to use machines with a combination of twisted insulated cores in a pair of 3 and a pair of 3 in the core 4 in one pass. Simultaneously with twisting, a polyethylene terephthalate tape 5 must be wound using a combined winding device. Polyethylene terephthalate tape 5 can also be applied longitudinally in the next process step. Several polyethylene terephthalate tapes can be superimposed on a separate operation, on a wrapping machine.

The first cylindrical conductor 6 is superimposed mainly longitudinally with overlapping metal inward, the contact wire 7 is also longitudinally beneath it. If the first relief layer 8 of the combined dielectric is extruded, then one or more polyethylene terephthalate tapes 5, the first cylindrical conductor 6, the contact wire 7 and the first relief layer 8 of the combined dielectric are superimposed during one operation.

If the first cylindrical conductor 6 is imposed spirally, then a winding machine is used, and the contact wire 7 is let longitudinally.

If the first relief layer 8 of the combined dielectric is not superimposed and there are fastening elements, or it is superimposed in a spiral, then a winding machine is used.

The second layer 9 of the combined dielectric is superimposed by a spiral winding on a winding machine or longitudinally. In the latter case, this is performed on the operation of applying a moisture-proof sheath 12 by extrusion with the combination of the longitudinal application of the second layer 9 of the combined dielectric and the longitudinal application of the second cylindrical conductor 10 with the contact wire feed 11.

If separate operations are used, then the second cylindrical conductor 10 is superimposed by a winding in a spiral with metal overlapping inward with a contact wire feed 11 on the winding machine.

The moisture-proof sheath 12 is applied by extrusion on an extrusion line.

The water blocking layer 13 is preferably imposed by a spiral winding with a water blocking tape on a winding machine. Also, the water blocking tape may be allowed longitudinally under armor 14 for cable booking operations.

The application of the armor 14 can be carried out in the form of a braid with galvanized steel wires on a braiding machine or winding in a spiral (coiled) on an armoring machine.

The moisture-proof hose 15 of the polyethylene composition is applied by extrusion on an extrusion line.

To confirm the technical result, three samples of an unarmored triboelectric cable and three samples of an armored triboelectric cable were made.

The cables measured the electrical capacitance between the first and second conductors. Field tests were also conducted to detect a person moving in the direction of action of the system weighing 82.5 kg, in this case, the level of the signal received by the seismic analyzer was recorded. The analyzer registers signals of five levels. A positive result is the registration of signals having levels 1; 2; 3. The test results are summarized in table.

Cable type Electrical capacitance between the first and second cylindrical conductors, nf per 1 km Signal strength Normalized Sample Number Normalized Sample Number one 2 3 one 2 3 Armored Not more than 300nF per 1 km 288 272 291 1; 2; 3 2 one 2 Not armored 277 281 263 one 2 one

As can be seen from the table, the electric capacitance between the first and second cylindrical conductors corresponds to the norm, and the level of received signals is close to the maximum value.

Claims (5)

1. A triboelectric cable consisting of several metal conductive cores, insulated with a polymer composition, twisted into pairs, which, in turn, are twisted into a core, coated with a layer of one or more polyethylene terephthalate tapes, laid on top of them, longitudinally or first of a cylindrical conductor of aluminum-polyethylene tape spirally with metal overlapping inward, a tinned copper contact wire under the first cylindrical conductor, a combined dielectric consisting of the first relief a second layer of polymeric materials and a second layer of one or more polyethylene terephthalate tapes, a second cylindrical conductor of aluminum-polyethylene tape, laid longitudinally or helically with metal overlapping inside, a tinned copper contact wire under the second cylindrical conductor, a moisture-proof sheath made of a polyethylene composition, characterized in that said first relief layer is made so that it provides uniform geometric dimensions along the cable length and minimizes the relative diameter The electrical permittivity of the dielectric composite, and the structural dimensions of the first and second coil conductors and dielectric combination is selected such that the electrical capacitance between the first and second coil conductors is not more than 300 nF per length of 1 km. 2. The cable according to claim 1, characterized in that the insulation of the conductive conductors is made of polyethylene or foamed polyethylene composition. 3. The cable according to any one of claims 1 or 2, characterized in that it further comprises a layer of water-blocking material superimposed on the said moisture-proof sheath, armor made of metal wires and a moisture-proof hose made of a polyethylene composition. 4. Cable according to any one of claims 1 or 2, characterized in that the first relief layer of the combined dielectric is extruded from a polyethylene or foamed polyethylene composition. 5. The cable according to claim 4, characterized in that it further comprises a layer of water-blocking material superimposed on the said moisture-proof sheath, armor made of metal wires and a moisture-proof hose made of a polyethylene composition.