RU2549204C2 - Device limiting dancing of wires, ground wires of overhead transmission lines and fibre optic cables of overhead lines, and passage equipped with such devices (versions) - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: device consists of torsion limiter installed eccentrically in regards to a wire and torsional vibrations exciter installed at the wire through a spiral protector so that its centre of mass is placed sideways from the wire longitudinal axis and located in horizontal plane. The torsion limiter is made as a closed body with guides and springs installed in it with rigidity of C=c₁, c₂, …, c_n and loads with mass of M=m₁+m₂…+m_n and shaped openings, at that the body is filled with gas or antifreeze. The torsional vibrations exciter is made as per the similar design; the exciter is placed at the distance of 1.5-5.0 m from the torsion limiter.

EFFECT: intensive torsional vibrations of a wire, ground wire or cable with torsion limiters and torsional vibrations exciters installed at them are active dampers promoting intensive aerodynamic damping of their vibrations at dancing.

21 cl, 6 dwg

Description

The invention relates to the field of electric power industry, in particular to devices for limiting the dancing of wires, lightning protection cables of overhead power transmission lines and fiber optic cables of overhead communication lines, as well as spans equipped with such devices. These devices allow us to solve the problem of limiting the intensity and reducing the combined effects of low temperatures, wind and ice, which can cause vibrations of wires, lightning protection cables and fiber optic cables, the prolonged action of which can cause numerous damage, as well as damage to linear fittings, linear insulation, and in the worst cases of destruction of both individual supports, and cascade destruction of several supports of the whole anchor span of an overhead power line.

To combat various vibrations (dancing, vibration, etc.) that occur on wires, lightning protection cables of overhead power lines and fiber optic cables of communication lines, accordingly, special devices (dampers) of various design options that are mounted on wires or cables according to precisely calculated installation diagrams.

Known overhead power line containing single wires, on which the main eccentric loads are rigidly fixed, the centers of gravity of which are located outside the vertical plane passing through the longitudinal axis of the wire, and neighboring loads are placed on different sides from the specified vertical plane, while between each two adjacent eccentric the weights installed additionally introduced twisting limit weights, each of which is rigidly fixed to the wire by means of a traction and an exce is located en- under the wire [1].

When wire vibrations occur in the vertical plane, eccentric weights installed in the horizontal plane and directed alternately in different directions excite multidirectional torsional vibrations of adjacent sections of the wire, changing the aerodynamics of the wire with icy sediment and helping to reduce the intensity of vibrations. To prevent tipping of the dance damper and the loss of stability of the wire system at certain intervals between eccentric weights, it is planned to install limiters for twisting the wires around its longitudinal axis, which, with a proper arrangement of them, can play the role of dance damper such as vertical pendulums, upsetting the frequencies of vertical and torsional vibrations of the wire .

The disadvantage of such devices is the lack of active damping elements in their design, which would provide the possibility of more efficient dissipation of vibrational energy than that due to the properties of self-damping of the wire’s vibrations upon activation of its multidirectional torsional vibrations excited by dance dampers in its process. In addition, another disadvantage of this device is its non-ergonomic nature, the essence of which is the inconvenience associated with the need to fix two end clamps located at the ends of the devices when installing dance absorbers and pendulum-type swing restraints in the form of a bracket on an overhead power line wire.

Also known is a limiter of icing and vibrations of the wires of overhead power lines, containing an elastic damper element, loads made in the form of curved rods rigidly fixed at the ends of an elastic damper element, and a clip intended for suspension on a wire, fixed at one end in the middle of the elastic damper element, and others connected to the wire line, while the straight sections of curved rods located under the elastic damper element are made of such a length that they are gloss portions extending beyond each other such that both the load and the resilient damper element form a loop oval, runs as a single weight weight [2].

The icing limiter is set so that the elastic element and the center of mass of the load are located below the central longitudinal axis of the wire and are in a vertical plane passing through this axis. In the event of unilateral deposits on the wire in the form of wet snow or ice, the limiter should help to limit the torsion of the wire under the influence of the formed deposits and thereby create favorable conditions for partial shedding of wet snow, reducing the size and mass of ice deposits. However, the practice of using such a limiter on overhead power transmission lines has shown its insufficient work in terms of reducing the mass of ice on the wire lines, since in conditions of intense icing, the elastic damper element freezes and loses the flexibility necessary for damping vibrations. If wire vibrations occur, such a device should also contribute to its limitation, working like a common Stockbridge vibration damper within the vibration frequency range of 20-60 Hz and above. Nevertheless, the range of low-frequency oscillations (dances) within 0.2-2 Hz remains outside the scope of the functional purpose of this icing limiter and the vibrations of the wires of overhead power lines, which makes its use ineffective as a vibration damper.

A known method of extinguishing the dancing of wires in the span of the power transmission line by affecting the torsional vibrations of the wire, the wire in the span sections being twisted relative to the longitudinal axis, so that the direction of the twist of the wire in each of the sections is opposite to the direction of the twist of the wire in the neighboring sections, is fixed in this state, for example using eccentric weights [3], [4].

The dance damper in the form of an eccentric load is installed in a position as close as possible to the horizontal plane passing through the longitudinal axis of the wire. Thanks to the blind attachment to the wire, when the vertical components of the wire movements occur in the conditions of dancing, the damper causes the wire to torsion and performs torsional vibrations with it. Since the dampers of the dance are installed at a predetermined distance from the limiter of icing and vibrations of the wires, the presence of the latter contributes to an increase in the torsional stiffness of the wire, preventing tipping of the dampener of the dance during intense torsional vibrations. Since neighboring dampers of dances are installed on opposite sides of the vertical plane passing through the central axis of the wire, torsional vibrations caused by dances lead to multidirectional twisting of adjacent sections of wire with one-side ice, contributing to the destabilization of the flutter phenomenon, which causes the wire to dance with one-side icing. The use in the design of the damper damper of the elastic element should contribute to the damping of the vibrations of the eccentric load due to the mutual movements of the wires from which the elastic element is twisted.

However, this technical solution has the following disadvantages:

- the elastic element of the dance damper at a low vibration frequency characteristic of dancing (in the range of 0.2-2 Hz) is not able to dissipate a significant amount of vibration energy, the influx of which under flutter conditions of the wire with one-sided ice deposition is caused by the action of the wire following the process of wire movement the direction of movement of the lifting force and the high aerodynamic quality of the wire profile with ice crest;

- cantilever mounting the elastic element of the dance damper to the blind clamp for fixing on the wire under conditions of intense torsional vibrations creates a mode of repeated cyclic deformations unfavorable for the root section of the flexible element, which may result in fatigue damage to the elastic element and termination of the effective operation of the dance damper.

The applicant set himself the task of developing a device for limiting the dancing of wires, lightning protection cables of overhead power transmission lines and fiber-optic cables of overhead communication lines, as well as a span equipped with such devices, which effectively reduces the intensity of low-frequency vibrations characteristic of dancing and significantly limits its duration. This positive technical result was achieved due to a new set of essential design features of the claimed device for limiting the dancing of wires, lightning protection cables of overhead power lines and fiber optic cables of overhead communication lines, as well as the span equipped with such devices, set forth in the following claims: “limiting device dances of wires, lightning protection cables of overhead power lines and fiber optic cables of overhead communication lines, content a torsion limiter mounted eccentrically with respect to the wire, lightning protection cable, cable so that its center of mass is below the longitudinal axis of the wire, lightning protection cable, cable and is located in a vertical plane passing through or near their longitudinal axis, and the torsional vibration exciter mounted on a wire, lightning protection cable, cable or on a wire, lightning protection cable, cable through a spiral protector so that its center of mass is on the side of the longitudinal axis wire, lightning protection cable or cable and was located in a horizontal plane passing through or near their longitudinal axis, the said torsion limiter and torsional vibration exciter are each made in the form of a closed case in the form of any body geometry located inside it of at least one guide with springs fixed by them with stiffness C = c ₁ , c ₂ , ..., c _n and at least one load of mass M = m ₁ + m ₂ ... + m _n , which can move along the rails, while in each load and attached to n profiled openings are made for it and horizontal ribs located horizontally between the side walls of the enclosure, and the enclosure is completely or partially filled with gas or non-freezing liquid, which can flow through shaped openings of weights and / or annular ribs when moving goods from one part to another inside the enclosure; the torsion limiter housing is connected to a wire, lightning protection cable, cable by means of a vertical rod with a die clamp at its end; the body of the causative agent of torsional vibrations is connected to a wire, lightning protection cable, cable by means of horizontal traction with a die clamp at its end; the internal cavity of the housing is completely or partially filled with non-freezing viscous fluid or brake fluid for cars or transformer oil; the torsional vibration pathogen is fixed on the wire, lightning protection cable, cable by means of blind fastening and cantilever rod at a distance S from the torsion limiter; the torsional vibration causative agent is fixed to the wire, lightning protection cable, cable at a distance S from the torsion limiter, equal to S = 1.5 ÷ 5.0 m; the stiffness of the spring and the mass of the load of the torsion limiter are chosen so that the frequency ω = C / M of the load oscillations is in the range of 0.2 ÷ 2 Hz, which is the frequency range of the dancing of the protected wires, lightning protection cable, cable; the stiffness of the spring and the mass of the load of the causative agent of torsional vibrations are chosen so that the frequency ω = C / M of the oscillations of the load is in the range 0.2 ÷ 2 Hz, which is the frequency range of the dancing of the protected wires, lightning protection cable, cable; the spiral protector located under the clamp for fastening on a wire, lightning protection cable, cable of the exciter of torsional vibrations is made of wire spirals made of galvanized steel or aluminum alloy; the diameter of the wires of the outer layers of the spiral protector is larger than the diameter of the wires of the inner layers of the spiral protector so that the outer part of the spiral protector has a relief spiral shape that provides high aerodynamic qualities of the wire, lightning protection cable, cable due to the optimal ratio of their drag coefficients and lifting force or their acquisition non-uniformity properties, contributing to a decrease in dance-exciting aerodynamic lift forces and therefore lower burning the intensity of the dance; the wires of each spiral tread at their ends are made with bends located at the same or different angles to the longitudinal axis of the tread, providing, under conditions of icing, unequal values of the diameter of the tread with a wire, lightning protection cable, cable and uneven deposition of ice on the tread with bent wires; a device for limiting the dancing of wires, lightning protection cables of overhead power transmission lines and fiber optic cables of overhead communication lines, comprising a torsion limiter mounted eccentrically relative to the wire, lightning protection cable, cable so that its center of mass is below the longitudinal axis of the wire, lightning protection cable, cable and was located in a vertical plane passing through or near their longitudinal axis, and the torsional vibration exciter mounted on the lightning protection wire cable, cable or wire, lightning protection cable, cable through a spiral protector so that its center of mass is located on the side of the longitudinal axis of the wire, lightning protection cable or cable and is located in a horizontal plane passing through or near their longitudinal axis, the mentioned limiter torsion and the causative agent of torsional vibrations each is made in the form of a closed case in the form of any body geometry located inside it, at least one guide with spring stiffness C fixed to them = c ₁ , c ₂ , ..., c _n and at least one load of mass M = m ₁ + m ₂ ... + m _n , with the ability to move along the rails, while in each load and attached to them and located horizontally between the side profiled openings are made by the walls of the casing of the annular ribs, and the casing is completely or partially filled with gas or non-freezing liquid, which can flow through the profiled openings of the loads and / or annular ribs when moving goods from one part to another inside the casing, and the device is equipped with at least one stabilizer made in the form of a strand of wire spirals of the same diameter with a shielded wire, lightning protection cable or cable, wound with variable pitch on them in free areas between the torsion limiter and the torsional vibration exciter in such a way that the total length of the lightning protection wire protected by the indicated stabilizers a cable or cable was 20% of the span of the line; the pitch of winding the wire spirals of stabilizers is chosen equal to from 0.3 m to 2 m; polyvinyl chloride is taken as a material for the manufacture of stabilizers; stabilizers are made of a ferromagnetic material characterized by a low Curie point and eddy current heating in conditions of lowering the ambient temperature to + 2 ° C, and helping to prevent icing and dancing in places where such stabilizers are installed; span of an overhead power transmission line or overhead communication line, on a single wire, lightning protection cable or fiber optic cable of which at least one torsion limiter and at least two torsional vibration exciters located on opposite sides of the torsion limiter and passing through the axis are rigidly fixed wires, lightning protection cable, vertical plane cable in a position close to the horizontal plane position; span of an overhead power transmission line with at least two wires in a split phase, on each wire or through one wire in each of the sub-spans, between which there are at least one torsional vibration exciter fixed on two adjacent sub-span wires and two adjacent sub-spans, different sides from vertical planes passing through the longitudinal axis of each of the wires of the split phase, in a position close to the position of the horizontal plane; a span in which, with a span of up to 200 m, one torsion limiter and four torsional vibrations are installed; span in which, with a span of 200 m to 500 m, two to four torsion limiters and six to eight torsional vibration exciters are installed ”

The invention is illustrated by drawings, where figure 1 shows a General view of the torsion limiter, made according to the present invention, a view perpendicular to the wire (lightning protection cable, cable) line; figure 2 is the same, General view of the causative agent of torsional vibrations; figure 3 is the same, General view of the line with installed on it a torsion limiter and causative agents of torsional vibrations; figure 4 - installation options torsion limiters in figure 1 and the causative agents of torsional vibrations in figure 2 in the spans of overhead lines; figure 5 is the same, the option of installing the causative agent of torsional vibrations on a spiral protector; figure 6 is the same, the variant of the section of the span of the line with installed changing the aerodynamics of the wire, lightning protection cable, cable stabilizer.

The inventive device for limiting the dancing of wires, lightning protection cables of overhead power lines and fiber optic cables of overhead lines provides for the presence of the structure of the so-called torsion limiter and the causative agent of torsional vibrations.

The torsion limiter (Fig. 1) is a closed case 1 in the form of a body of any geometric shape, which is mounted, for example, on the wire 2 by means of a rod 3 and a blind clamp 4 so that the center of mass of the limiter is below the longitudinal axis of the wire 2 and is located in a vertical plane passing through the longitudinal axis of the wire 2 or near it. Due to this position, the torsion limiter mounted on the wire 2 increases the torsional stiffness of the wire 2 in a section of length S, the value of which depends on the design of the wire 2 and its diameter, and is (for different wires) ranging from 1.5 m to 5 m and more.

Inside the housing 1, a guide 5 and a load 6 of mass M or several loads (mass m ₁ , m ₂ , ..., m _n , the sum of the masses of which are equal to M) are fixed. The load 6 is fixed on the guide 5 with the possibility of movement along the guide 5 in a vertical plane. The load 6 is connected to the upper and lower walls with end caps 7, 8 of the housing 1 by a spring 9 of stiffness C / 2 (in the case of several loads by springs of stiffness c ₁ , c ₂ , ..., c _n , the total stiffness of which is equal to C).

The internal cavity of the housing 1 is completely or partially filled with gas or non-freezing fluid 10 (brake fluid for cars or transformer oil), and in the load 6 and / or in the annular ribs 11 attached to the load 6, profiled openings 12 are made through which, when the load 6 is moved in a vertical plane, fluid 10 or gas flows.

The causative agent of torsional vibrations (figure 2) is a closed body 13 in the form of a body of any geometric shape, which is mounted, for example, on the wire 14 by means of the rod 15 and the blind clamp 1 6 so that the center of mass of the pathogen is on the side of the longitudinal axis of the wire 14 and located in a horizontal plane passing through the longitudinal axis of the wire 14 or near it. When vibrations of the wire 14 occur in a vertical plane on a section of length S, the value of which depends on the design of the wire 14 and its diameter, and is (for different wires) in the range from 1.5 m to 5 m, torsional vibrations of the wire 14 are excited. Inside the case 13 cargo 17 is placed with mass M or several cargoes (mass m ₁ , m ₂ , ..., m _n , the sum of the masses of which is equal to M), fixed on the guide 18 with the possibility of moving along it in a vertical plane. The load 17 is connected with the upper and lower walls (end caps) 19, 20 by a spring 21 (in the case of several loads with springs of stiffness c ₁ , c ₂ , ..., c _n , the total stiffness of which is equal to C).

The internal cavity of the housing 13 is completely or partially filled with gas or non-freezing fluid 22 (brake fluid for cars or transformer oil), and profile openings 24 are made in the load 17 or ring ribs 23 attached to the load 17, through which, when the load 17 is moved in a vertical plane fluid 22 or gas flows.

The principle of placement on the wire (lightning protection cable, cable) of torsion limiters and torsion agents is illustrated in Fig. 3, where it is shown how torsion oscillators designed for torsional stiffness of a wire (lightning protection cable, cable) are placed at distances S excitation of torsional vibrations of a wire (lightning protection cable, cable), the result of which are the multidirectional action of aerodynamic lifting force, that is, a decrease in intensity Laski.

In flights of relatively short length (up to 200 m), one torsion limiter and four torsional vibration pathogens can be sufficient to prevent intense dancing (Fig. 6, a). In spans up to 300 m and up to 500 m long, the number of torsion limiters can be increased to two to three, and the number of torsional vibration pathogens to six to eight, respectively (Fig.6, b) and (Fig.6, c).

To protect the wire, lightning protection cable, cable from wear and fatigue damage, the torsion limiter and the torsional vibration exciter can be installed not directly, but on the protective spiral protectors 25 (Fig. 5).

The aerodynamic protective characteristics of spiral treads 25 are significantly enhanced if part or all of the tread wires are bent at the ends, creating an additional effect of the heterogeneity of the drag coefficients and the lifting force along the length of the wire, lightning protection cable, cable (protected object).

The effect of the inhomogeneity of the coefficients of lift and drag can be significantly enhanced by installing on long sections of the wire (lightning protection cable, cable) between torsion limiters and torsional vibrations that change their aerodynamics, additional devices (so-called stabilizers) 26, made in the form of wire segments or cable (from aluminum, steel or composite materials), wound on the protected object with a variable pitch. Ice formations in the areas of installation of stabilizers 26 (Fig. 6) will also have an uneven character, which allows the aerodynamics of the protected object to be disturbed with deposits in the form of wet snow, hoarfrost or pure ice, helping to prevent or at least reduce the intensity of dancing.

The stabilizers 26 can be made in the form of factory-made extended wire spirals from plastic materials, for example, polyvinyl chloride, and can also be made from ferromagnetic materials with a low Curie point. Such materials have the ability to heat by eddy currents while lowering the temperature of the air and, accordingly, the material of the device to a temperature below + 2 ° C. Due to this property, the stabilizer 26 heats up itself and heats the protected object on which it is fixed, preventing or reducing the intensity of ice deposits and dancing during combined ice-wind influences.

The invention works as follows.

When dancing occurs, wire 2 moves along rather complex paths, the envelope of which has the shape of an ellipse; the most significant and intense component of the vibrations can be simplistically represented as vibrations in the vertical plane. These vibrations through the clamp 4 and the rod 3 are transmitted to the housing 1, causing vertical oscillations of the load 6 inside the housing 1 with a frequency ω = C / M, and the parameters C and M are chosen so that the oscillation frequency of the load ω is in the range 0.2 ÷ 2 Hz , the most characteristic of dancing wire 2 overhead power lines. Due to the presence of liquid or gas in the internal cavity of the housing 1, the oscillations of the load 6 are damped, since in the process of movement it is affected by the forces of dry and viscous friction. The oscillations of a wire equipped with torsion limiters, which are active dampers, are also damped, since wire 2 has a self-damping property, which is amplified by one or more active dampers, namely torsional vibration drivers installed in the span of an overhead power line.

When dancing wire 14, its oscillations in the vertical plane excite oscillations of the torsional vibration causative agent, rigidly connected to the wire 14 by the clamp 16 and the rod 15. The position of the housing 13 eccentric with respect to the longitudinal axis of the wire 14 and the load 17 located inside the housing 13 excite with vertical vibrations of the wire 14 his torsional vibrations. Torsion of the torsional vibration exciters eccentrically fixed on the wire 14 does not occur when the torsional vibrations of the wire 14 are excited due to the fact that the torsional vibration paths are installed at a predetermined distance S of the torsion limiter limiting the torsion of the wire 14. Thus, the joint installation of torsion limiters and torsional vibration pathogens ensures stability wires 14 to overturn when excited by torsional vibrations by intense torsional vibrations wires 14 when dancing.

Due to the torsional vibrations of the wire 2, 14 in sections of length S from the attachment point of the torsion limiter to the attachment point of the torsional vibration pathogen, the intensity of the distributed lifting forces exciting the dance decreases sharply in the area where the wire is subject to torsional vibrations. Since adjacent torsional vibration pathogens are installed on opposite sides of wire 2, 14, torsional vibrations of wire 2, 14 in these adjacent sections are multidirectional, which further contributes to the damping of the dance.

Oscillations of a wire (lightning protection cable, cable) equipped with torsion limiters, which are active dampers, are also damped, because the wire, lightning protection cable, cable have the property of self-damping, which is amplified by one or more active dampers, that is, torsion limiters and torsional oscillators installed in the span of an overhead power line or overhead line. In addition, intense torsional vibrations of a wire, lightning protection cable, cable with torsional vibration pathogens installed on them contribute to intensive aerodynamic damping of the dance.

Devices for limiting the dancing of wires, lightning protection cables, cables, made in accordance with the present invention, after comprehensive testing will be serially manufactured at ZAO MZVA and delivered to overhead power lines and overhead communication lines with fiber optic cables.

Information sources

[1] Description of the invention to copyright certificate No. 1584021 "Overhead power line", H02G 7/14, claimed 02.09.88, published 07.08.90. Bulletin No. 29.

[2] Description of the invention to the patent of the Russian Federation No. 2249893 “Limiter of icing and vibrations of wires of overhead power lines”, H02G 7/14, filed July 30, 2003, published April 10, 2005.

[3] Description of the invention to the certificate of authorship No. 364274 “Method of extinguishing the dancing of wires”, H02G 7/14, claimed 05.05.66, published on 07.25.77. Bulletin No. 27.

[4] Recommendations on the use of ice and vibration limiters (OGKs), dance dampers (GLP and GPR). СО 34.20.263-2005. Branch "Engineering Center UES" "Firm ORGRES". Moscow, Center for Industrial Technical Information and Technical Training ORGRES, 2005.

[4] Description of the invention to the patent of the Russian Federation No. 2365009 “Damper dances of wires of overhead power lines”, H02G 7/14, claimed 08.07.2008, published 20.08.2009. Bulletin No. 23.

[5] US Patent No. 4,159,393, class 174-42 (H02G 7/14), published 06/26/1979.

[6] US Patent No. 3,400,209, class 174-42 (H02G 7/14), published 03.09.1968.

[7] US Patent No. 2,469,167 “Vibration Absorber”, H02G 7/14 (174-42), published 03/05/1949.

[8] US Patent No. 3,662,084 “Vibration Absorber”, H02G 7/14 (174-42), published on 05/09/1972.

[9] Golovin V.M. New solutions for equipping VL and PS with linear insulation and fittings. - The third Russian scientific and practical conference of the power transmission line 2008, Novosibirsk.

Claims (21)

1. A device for limiting the dancing of wires, lightning protection cables of overhead power transmission lines and fiber optic cables of overhead communication lines, comprising a torsion limiter mounted eccentrically relative to the wire, lightning protection cable, cable so that its center of mass is below the longitudinal axis of the wire, lightning protection cable, cable and was located in a vertical plane passing through or near their longitudinal axis, and the torsional vibration exciter mounted on the wire is lightning-protective m cable, cable or wire, lightning protection cable, cable through a spiral protector so that its center of mass is on the side of the longitudinal axis of the wire, lightning protection cable or cable and is located in a horizontal plane passing through or near their longitudinal axis, mentioned the torsion limiter and the torsional vibration causative agent are each made in the form of a closed case in the form of any body geometry located inside it, at least one guide with stiffness fixed to them C = c _1, c _2, ..., c _n, and at least one load mass M = m ₁ + m ₂ ... + m _n, having the possibility to move along the guide, while in every load and attached thereto and arranged horizontally between the side walls of the housing, the annular ribs are formed by profiled openings, and the enclosure is completely or partially filled with gas or non-freezing liquid, which can flow through the profiled openings of the goods and / or annular ribs when moving goods from one part to another inside the enclosure. 2. The device according to claim 1, in which the body of the torsion limiter is connected to a wire, lightning protection cable, cable by means of a vertical rod with a die clamp at its end. 3. The device according to claim 1, in which the body of the causative agent of torsional vibrations is connected to a wire, lightning protection cable, cable by means of horizontal traction with a die clamp at its end. 4. The device according to claim 1, in which the internal cavity of the housing is completely or partially filled with a non-freezing viscous fluid or brake fluid for cars or transformer oil. 5. The device according to claim 1, in which the causative agent of torsional vibrations is mounted on a wire, lightning protection cable, cable by means of blind fastening and cantilever rod at a distance S from the torsion limiter. 6. The device according to claim 5, in which the causative agent of torsional vibrations is mounted on a wire, lightning protection cable, cable at a distance S from the torsion limiter, equal to S = 1.5 ÷ 5.0 m 7. The device according to claim 1, in which the stiffness of the spring and the mass of the load of the torsion limiter are selected so that the frequency ω = C / M of the load oscillations is in the range 0.2 ÷ 2 Hz, which is the frequency range of the dancing of the protected wire, lightning protection cable, cable . 8. The device according to claim 1, in which the stiffness of the spring and the mass of the load of the causative agent of torsional vibrations are selected so that the frequency ω = C / M of the oscillations of the load is in the range of 0.2 ÷ 2 Hz, which is the frequency range of the dancing of the protected wire, lightning protection cable, cable. 9. The device according to claim 1, in which the spiral protector located under the clip for mounting on a wire, lightning protection cable, cable of the exciter of torsional vibrations, made of wire spirals made of galvanized steel or aluminum alloy. 10. The device according to claim 9, in which the diameter of the wires of the outer layers of the spiral protector is larger than the diameter of the wires of the inner layers of the spiral protector so that the outer part of the spiral protector has a relief spiral shape that provides high aerodynamic qualities of the wire, lightning protection cable, cable due to the optimal ratio their drag and lift coefficients or their acquisition of uneven properties, helping to reduce dance-raising aerodynamic lift forces and therefore reduce the intensity of dancing 11. The device according to claim 9, in which the wires of each spiral tread at their ends are made with bends located at the same or different angles to the longitudinal axis of the tread, providing, under conditions of icing, the tread diameter with the wire, lightning protection cable, cable and uneven deposition icing on a protector with bent wires. 12. A device for limiting the dancing of wires, lightning protection cables of overhead power lines and fiber optic cables of overhead communication lines, comprising a torsion limiter mounted eccentrically relative to the wire, lightning protection cable, cable so that its center of mass is below the longitudinal axis of the wire, lightning protection cable, cable and was located in a vertical plane passing through or near their longitudinal axis, and the torsional vibration exciter mounted on the wire is lightning m cable, cable or wire, lightning protection cable, cable through a spiral protector so that its center of mass is on the side of the longitudinal axis of the wire, lightning protection cable or cable and is located in a horizontal plane passing through or near their longitudinal axis, mentioned the torsion limiter and the torsional vibration causative agent are each made in the form of a closed housing in the form of any body geometry located inside of it by at least one guide with stiffness springs fixed to them C = c ₁ , c ₂ , ..., c _n and at least one load of mass M = m ₁ + m ₂ ... + m _n , with the ability to move along the rails, while in each load and attached to them and located horizontally between profiled openings are made in the side walls of the annular rib casing, and the casing is completely or partially filled with gas or non-freezing fluid that can flow through the profiled openings of cargo and / or annular ribs when moving goods from one part to another inside the casing, and the device is equipped with at least one stabilizer, made in the form of a strand of wire spirals of the same diameter with a protected wire, lightning protection cable or cable, wound with variable pitch on them in free areas between the torsion limiter and the torsional vibration exciter in such a way that the total length of the wire protected by the indicated stabilizers, lightning protection cable or cable was at least 20% of the line span. 13. The device according to item 12, in which the step of winding the wire spirals of the stabilizers is selected equal to from 0.3 m to 2 m 14. The device according to item 12, in which the material for the manufacture of stabilizers is taken polyvinyl chloride. 15. The device according to item 12, in which the stabilizers are made of a ferromagnetic material characterized by a low Curie point and eddy current heating in conditions of lowering the ambient temperature to + 2 ° C, and helping to prevent icing and the occurrence of dancing in the places of installation of such stabilizers. 16. Span of an overhead power transmission line or overhead communication line, on a single wire, lightning protection cable or fiber optic cable of which at least one torsion limiter and at least two torsional vibration exciters located on opposite sides of the torsion limiter and from passing through the axis of the wire, lightning protection cable, cable of the vertical plane, in a position close to the position of the horizontal plane. 17. The span according to clause 16, in which, with a span of up to 200 m, one vibration limiter and four torsional vibration exciters are installed. 18. The span according to clause 16, in which, with a span of 200 m to 500 m, two to four vibration limiters and six to eight torsional vibration exciters are installed. 19. Span of an overhead power transmission line with at least two wires in a split phase, on each wire or through one wire in each of the sub-spans, between which there are at least one torsional vibration exciter fixed on two adjacent sub-span wires and two adjacent sub-spans on different sides of the vertical planes passing through the longitudinal axis of each of the wires of the split phase, in a position close to the position of the horizontal plane. 20. The span according to claim 19, in which, with a span of up to 200 m, one vibration limiter and four torsional vibration exciters are installed. 21. The span according to claim 19, in which, with a span of 200 to 500 m, two to four vibration limiters and six to eight torsional vibration exciters are installed.

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