RU2575918C2 - Universal wind oscillation damper (versions) - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: wind oscillation damper comprises a damper rope, on which a pair of weights is fixed, and at least one spiral strand, which connects the damper rope with a wire, so that one part of the spiral strand or strands is mounted on the wire, and the other part - on the damper rope, at the same time the damper rope is connected to the wire in two points of fixation by means of at least one spiral strand to form a power frame, two opposite sides of which are formed by the spiral strand or strands, and two other opposite sides - by parts of the wire and the damper rope between the points of fixation, at the same time end parts - branches of the spiral strand or strands fixed on the wire are made with the power frame internal or external bending.

EFFECT: increased efficiency of damper operation.

28 cl, 3 dwg

Description

The invention relates to the electric power industry and can be used on overhead power transmission lines and fiber-optic communication lines as a universal device for damping and upsetting vibrations due to wind effects, such as dancing and vibration.

One of the urgent tasks in the energy sector is to increase the reliability of overhead lines in general and wires, lightning protection cables and self-supporting optical communication cables in particular. Overhead power lines (VL) power transmission lines are extended objects that pass through different climatic zones of Russia, ranging from northern latitudes with flat wetlands to mountainous areas in the south, crossings through rivers and other bodies of water, from open spaces to taiga forest areas. A significant impact on the reliability of wires and cables has a wind effect. In combination with climatic factors, wind exposure leads to cyclical vibrations of overhead line wires: a decrease in the service life, a decrease in throughput, and partial or complete destruction of the wire.

The cyclic movements of the wires are divided into three categories: aeolian vibration, dance of wires and vibrations caused by the aerodynamic trail.

The aforementioned cyclic movements of the wires differ from one another in different mechanisms of energy transfer, types of movement, huge differences in the frequencies and amplitudes of oscillations, as well as in the different nature of their effect on the clamps, wires and other elements of the overhead line. In particular, the dance of wires refers to low-frequency oscillations - 0.1-1 Hz with an amplitude of 0.1-1 from the arrow of sagging wires, due to the interaction of vertical and torsional vibrations of the wire as a result of wind exposure at speeds of 4-20 m / s. In the presence of ice deposits, the center of mass of the wire cross section shifts from its axis and in case of vertical vibrations, an inertia force arises whose vector is displaced relative to the wire axis. This force creates a torque that supports torsional vibrations. Vertical and torsional vibrations mutually support each other and at a wind speed exceeding a certain critical value, they can develop to significant amplitudes.

To reduce the negative impact of wind exposure, various designs of vibration dampers and wire dance dampers are used.

Known vibration dampers of wires based on the principle of operation of the Stockbridge vibration damper, which is used in power lines and / or fiber-optic communication lines. Stockbridge vibration dampers contain a pair of weights connected by a multicore steel carrier cable (damper cable), and a clip attached to the rope at a location located between the weights for attaching the power line to the aerial wire (cable). The shape and mass of the loads mounted at the ends of the rope is chosen so that they enter into resonance at frequencies determined in accordance with the vibrations that occur in the cable of the power line or (and) fiber-optic communication line. Vibration dampers based on this principle include technical solutions according to the USSR copyright certificate SU 1621108 A1, according to RF patents for invention RU 2107373 C1, RU 2180765 C1, RU 2412510 C1, according to RF patent for utility model RU 16572 U1, according to German applications DE 2033921 A1, DE 3535778 A1, according to US patents US 3,711,624 A, US 4,527,009 A, according to international application WO 0122549 A1 according to European patent for the invention EP 1315263 B1.

In addition, various dampers of wire dancing are known, in particular, German patent for invention DE 632509 C, German patent application DE 4400617 A1, German utility model DE 29916513 U1, RF patent for invention RU 2365009 C1.

Known analogues do not allow equally effective damping of dancing and vibration of wires resulting from wind exposure.

The closest analogue of the claimed invention is the German application DE 2211507 A1, publication date 02.22.1973. This technical solution relates to dampers of wind fluctuations and contains two U-shaped spiral strands that are mounted on the wire with their upper part, mounted on the damper cable with the lower part, in addition, loads are fixed on the damper cable, the strands consist of several spirals glued together , from a wire made of steel or aluminum alloy, while the damper cable is made of wire and forms, together with the loads, a vibration damper, the shoulders and loads of which are the same.

The disadvantages of the closest analogue are that, in fact, there is only one point of attachment of the damper cable to the wire, which reduces its effectiveness as a vibration damper and does not exclude the damper from entering the vibration wave assembly. In addition, the presence of one point of attachment of the damper cable on the wire limits the length of the damper cable. The design of the closest analogue is not effective when working as a limiter of ice, due to the fact that the distance from the axes of the loads to the axis of the wire during the fastening method using a loop is limited by the diameter of the annular part, which cannot be increased to values that provide the required performance. Moreover, if you suspend loads of large mass to increase the moments of inertia, then due to the design features, the damper cable will bend, and the design of the closest analogue, as a vibration damper, will become significantly ineffective. For the same reason, the closest analogue cannot be used as a frustrator of wind vibrations when dancing wires. From the above it follows that the damper of wind fluctuations in some cases is not effective, i.e. not universal.

The problem to which the present invention is directed is the development of a universal device that can reduce the negative effects of wind energy pumped into the wire, that is, the task is to create in one device the functions of a vibration damper, dance damper and icing limiter.

The problem is solved due to a combination of essential features, of which the following features are common with the closest analogue indicated above: a wind damper containing a damper cable, on which a pair of loads is fixed, and at least one spiral strand connecting the damper cable to the wire so that one part of the spiral strand (or one part of each of the two strands) is mounted on the wire, and the other part on the damper cable.

Distinctive features of the invention from the closest analogue are the following features: the damper cable is connected to the wire at two points of attachment by means of at least one spiral strand by forming a spiral strand (or strands) of a power frame, the two opposite sides of which are formed by the spiral strand or strands themselves, and the other two opposite sides - the parts of the wire and the damper cable between the attachment points of the spiral strand or strands, the opposite sides of the power frame between the wire and the damper With a rope, formed by the parts of the spiral strand are oriented perpendicular to the wire or inclined to it at an angle other than 90 °, while the end parts-branches of the spiral strand or strands attached to the wire are made with a bend towards each other.

The second embodiment of the invention is the implementation of a power frame, in which, as in the first embodiment, two opposite sides are formed by a spiral strand or strands, but unlike the first embodiment, two other opposite sides are formed by a part of the damper cable and a part of the wire between the places of attachment of the spiral strand to them or strands, and the end parts, branches of a spiral strand or strands attached to a wire, are bent not towards each other, but in opposite directions.

The power frame of the wind damper can be formed from a single spiral strand wound with the middle part on a wire or damper cable, and the ends, respectively, on a damper cable or wire. In addition, the power frame can be formed of two U-shaped spiral strands, each of which is wound with its ends on the wire and damper cable, while the middle part of each of the U-shaped spiral strands forms opposite sides of the power frame.

The following private essential features are inherent in both variants of the invention. The spiral strand or strands are formed of several glued together spirals, and the spirals in the strands are made of steel wire with a protective coating of zinc or aluminum or made of aluminum alloy wire. The damper cable is made of steel wire with a protective coating of zinc. The shoulders l ₁ , l _{2 of the} vibration damper and the mass of cargo m ₁ , m ₂ can be the same in length and weight, or different, and the shoulder of the vibration damper is part of the length of the damper cable, measured from the place of its termination in the load to the place exit from a spiral lock. If the power frame is formed using one spiral strand, the opposite sides of the power frame between the wire and the damper cable, formed by parts of one spiral strand, can be oriented perpendicular to the wire or inclined to it at an angle other than 90 °. It is also possible to perform a damper in which the power frame is formed using two U-shaped spiral strands, each of which is wound with its ends on a wire and a damper cable, while the middle part of each of the U-shaped spiral strands (opposite sides of the power frame) are oriented perpendicularly to the wire or inclined to it at an angle other than 90 °.

A leveling cord may be wound on the damper cable. The number of leveling layers can be one or more than one, while the leveling layer is made of wire of the same material as the spiral strand, or of another material. As a leveling winding can be used a hollow tube, fastened with a damper cable in any known manner, in particular, by crimping in several places on the damper cable. The spiral strand or strands are preferably made with a spiral pitch S _C from 30 mm to 350 mm and with an internal spiral diameter d _C (mm), determined from the relation: d _C = (0.7 ÷ 0.98) × D _p , where D _p - wire diameter, mm. In this case, the length of the portion of the spiral strand or strands attributable to the fastening of the spiral strand or strands on the damper cable L _D and the wire L _P and which is the side of the power frame, is mainly in the range from 1.0 × S _C to 10.0 × S _C where S _С is the spiral pitch of the spiral strand. The length of the section L _{D of the} spiral strand or strands attributable to the fastening of the spiral strand or strands on the damping cable and the length of the similar section L _P falling to the fastening of the spiral strand or strands on the wire is from 1.0 × S _C to 10.0 × S _C , and the lengths of the sections L _D and L _P can be the same or different within the specified range. The height H of the opposite sides of the power frame formed by a spiral strand or strands located between the wire and the damper cable is from 0.5 × S _C to 5 × S _C.

The technical result achieved by using the invention is to increase the efficiency of the wind damper in a wide range of vibration frequencies of the wire (cable) to ensure damping of wind vibrations, including vibration and dance (the universality of the damper design).

One of the purposes of a wind damper is the mismatch of the frequencies of vertical and torsional vibrations and the exclusion of their proximity when icing the wire. The presence of cargo in the structure leads to an increase in the torsional stiffness of the wire and, as a result, to the formation of predominantly one-sided ice of elongated shape with a small mass. Another purpose is vibration damping, the functions of which are performed by the built-in vibration damper.

Thus, the present invention has properties that are not inherent in any of the analogues known from the prior art, including these properties are not inherent in the above analogues DE 2033921 A1 and RU 2365009, because the claimed device due to the proposed structural embodiment combines three functions: vibration damper, dance damper and icing limiter.

To perform the functions of a vibration damper, a wind damper has a damper cable with loads on each side.

The second function - the limitation of icing - is associated with the phenomenon of dancing wires. Dance of wires - a phenomenon that occurs when ice or frost settles on the wire. Since ice settling occurs in the wind, such ice on the wire settles unevenly around the circumference. More often the shape of the ice resembles the shape of an airplane wing or oval. It is this form of ice that leads the wire under the action of wind into vertical and rotational movements. Significant overloads occur, both in the wire itself and in the elements of its suspension. This formidable phenomenon often leads to wire breakage, damage to line supports, etc. Moreover, the longer the “wing” or oval in shape, the more intense the wire dance. In this regard, the problem arises of limiting the length of the wing or reducing the mass of ice. The presence of two goods located much lower with respect to the wire acts as a stabilizer that does not allow the wire to rotate. The wing of ice grows to a certain length, but since the wire does not turn, at some value of its length the ice breaks down, because the further it is located from the axis of the wire, the looser it is. It is this second function that is inherent in the claimed vibration damper. Due to its design limitations, a conventional vibration damper cannot perform this function. Weights should be defended at a relatively large distance below the axis of the wire. This is what the constructive frame does, which allows you to arrange loads significantly below the axis of the wire. In fact, the greater the specified distance, the more stable the wire will be to torsion.

And, finally, the third function incorporated in the design of a wind damper. If a wire dance occurs for some reason, then the vibration damper starts to work as a frustrator of vertical and torsional vibrations arising in the wire. A wire under the influence of wind has two types of movements: vertical and rotational. The frequencies of these oscillations are quite far from each other. However, in the presence of ice, torsional and vertical frequencies begin to converge. The wire is captured by these vibrations and dance occurs. With the correct ratio of cargo masses, power locks, heights “H”, the GVKU device begins to tune torsional frequencies from vertical ones, diluting them to a safe level. Both masses of wind damper weights, masses of the arms of the power strand, masses pertaining to the leveling layer, and to a greater degree moments of inertia are already working here.

To achieve the above technical result, a wind damper containing a damper cable with two weights fixed on it and one or two spiral strands connecting the damper cable to the wire has two points of attachment of the damper cable to the wire, which prevents the damper cable from turning around the attachment point to the wire, and fastening is carried out using spiral reinforcement - by means of a strand of wire spirals. The wind damper is effective as a limiter of ice and as a frustrator of wind vibrations when dancing the wires due to the presence of a power frame, which is formed by a spiral strand or strands, a damper cable and a wire zone located between the points of attachment to the damper cable. Moreover, the presence of two attachment points allows you to make the length of the damper cable sufficiently large, which allows to achieve greater efficiency in the operation of the damper.

The same technical result is achieved when the power frame is formed using one spiral strand fixed by the middle part on the wire, and by the end parts (branches) on the damper cable, and also when the power frame is formed by one or two spiral strands, in which (which) end parts are fixed on the wire with their bending inward of the power frame (towards each other) or with the bending outward of the power frame (in opposite directions).

Due to the presence of these signs, the efficiency of the vibration damper is less dependent on the damper getting into the vibration wave unit. In the process of wire vibration, a wave runs along it, i.e. the wire is a kind of conditional sine wave, which has a peak value that does not exceed the diameter of the wire and a zero value (intersection with the axis of the wire), called the node. If the installation point of the vibration damper coincides with the unit or in the immediate vicinity of it, then the efficiency of the vibration damper tends to zero. The claimed invention allows to minimize this negative effect.

In contrast to the claimed invention, the vibration damper structures (including the closest analogue) known from the prior art are characterized by the fact that the attenuation zone of the damper to the wire is limited to a width of several tens of millimeters. And, therefore, for such structures, strict calculations should be applied to select installation sites, so as not to get into the site. In this regard, if the attachment points of the damper to the wire are distributed, then the influence of this feature (getting into the node) is noticeably reduced. In the claimed invention, the design just allows you to part at relatively significant distances the attachment points of the vibration damper to the wire.

Private essential features of the invention also affect the provision of higher efficiency of the vibration damper. These signs include the execution of a spiral strand (s) of several glued together spirals of steel wire with a protective coating of zinc or aluminum. It is also possible to use aluminum alloy wire. The damper cable is also in a preferred embodiment made of steel wire with a protective coating of zinc.

In the damper, the mass of goods at the ends of the damper cable and the length of the shoulders on which these weights are located can be the same or different, which makes it possible to produce a structure that is most effective under various conditions of the damper.

In the case of a significant difference between the outer diameters of the wire and the damper cable, a tread is wound onto the latter - an equalizing layer. As a leveling coil, a hollow tube can be used, replacing the leveling coil from wire spirals, and the tube is crimped in several places on the damper cable or fastened to it in another way. The use of a leveling wire (or two or more leveling wires) on a damping cable made of wire of the same material as a spiral strand, or of another material, or, as an alternative, the use of a hollow tube fixed to a damping cable, allows creating optimal working conditions damper, providing the highest efficiency damper.

The power frame can be formed as a single spiral strand, wound in the middle part on a wire or damper cable, and ends, respectively, on a damper cable or wire, and two U-shaped spiral strands, each of which is wound ends on a wire and damper cable, while the middle part of each of the U-shaped spiral strands forms the opposite sides of the power frame. Opposite sides of the power frame can be oriented perpendicular to the wire or inclined to it at an angle other than 90 °. These features concretize in terms of the implementation of the framework of a common essential feature - the presence of a power frame that provides high efficiency of the damper.

Depending on the diameter of the wire for which the device is intended for spiral strand or strands, are performed with a spiral pitch S _C from 30 mm to 350 mm. The internal diameter of the spiral d _C (mm) is also determined depending on the diameter of the wire from the relation: d _C = (0.7 ÷ 0.98) × D _p , where D _p is the diameter of the wire, mm.

The length of the portion of the spiral strand falling on the damper cable of the power frame L _С plays an important role in achieving the effective operation of the damper - in the process of exciting natural frequencies of the goods, additional vertical movements of the damper cable in its middle part between the vertical, perpendicular to the wire or inclined parts of the spiral strands, which also helps to reduce the amplitude of vibration of the wire. The length of the plot L _{C of the} spiral strand (s) falling on the fastening of the spiral strand or strands on the damping cable and being the side of the power frame is in the range from 1.5 × S _C to 12 × S _C , where S _C is the pitch of the spiral strand spiral.

The length of the fastening sections depends on the requirements for ensuring the strength of the lock of the strand on the wire and on the damper cable, which significantly affects the efficiency of the damper and is determined by the number of active steps of the strands. On the length of the section L _{C of a} spiral lock (strands) attributable to the fastening of the spiral lock (locks) on the damper cable, and on the length of the section L _{D of the} spiral lock (locks) falling on the mount of the spiral lock (locks) on the wire, the number of steps of the spiral lock (strands) is from 1.5 to 12, and the number of steps of the spiral strand (strands) on the damper cable and wire in the preferred case, the execution of the device is the same, but may be different.

The distance "H" depends on the diameter of the wire and the total mass of the goods, and the larger the diameter of the protected wire, the greater the value of "H". The length H of the opposite sides of the power frame formed by a spiral strand or strands located between the wire and the damper cable is (0.5 ÷ 5) S _C , where S _C is the step of the spiral strand spiral.

Moreover, the design of the vibration damper has a number of distinctive features, which are an inextricable set of features that ensure the universality of the claimed wind damper:

- the possibility of forming the optimal range of natural frequencies of the absorber due to the distribution of masses along the length of the cargo, the ratio of the mass of the goods and the lengths of the working elements of the damper cable;

- the implementation of the damper cable with high ability to absorb energy;

- the execution of goods in the form of bodies of revolution, the axes of which coincide with the axis of the cable, the location of the centers of mass of the goods in the plane of vibration, as a result of which it does not matter what angular position the vibration damper frame occupies.

The invention is illustrated by drawings, which depict:

In FIG. 1 - vibration damper (first embodiment of the invention).

In FIG. 2 - a wind damper with a leveling layer (first variant of the invention).

In FIG. 3 - wind damper (second embodiment of the invention).

In the drawings, the positions shown: spiral strands 1 and 2; wire 3; damper cable 4; cargo 5; leveling cord 6.

Universal vibration damper for wires 3 of overhead power lines, as well as for self-supporting fiber optic cables of communication lines, is a structure consisting of loads 5 and an elastic damper cable 4, fixed at two points of attachment to wire 3 with the formation of a power frame, the main whose element is at least one spiral strand.

A spiral strand (“mono-strand”) or U-shaped spiral strands consist of 3 ... 10 wires with a diameter of 2 ... 5 mm. The length of the damper is 0.3 ... 1.0 m, the mass of the damper is 1.0 ... 15.0 kg.

Cargoes 5 are made in the form of a body of revolution, which may have a thickened part and a narrower part at the end at the base. In the load 5 there is a hole in which the damper cable 4 is sealed. The loads 5 are selected by weight the same or not equal to each other. In particular, the masses of goods, if they are not equal, can be in the ratio m ₁ : m ₂ = 1.2-1.3, where m ₁ and m ₂ are the masses of the first and second cargo, respectively.

The elastic damper cable 4 is a set of spiral wires of high strength steel, which is fixed in the first and second loads 5. The spiral wires of the damper cable 5 are in a strained, strained state, which is ensured by twisting the spiral segments with their further compression around the entire perimeter of the hole of the damper cable 4.

The location of the goods 5 on the elastic damper cable 4 is selected by calculation and experimental ways in order to ensure its optimal efficiency, i.e. damping ability in a wide range of resonant vibrational frequencies for specific conditions. The shoulders and mass of the damper can be either the same (length, mass), or different.

The loads 5 are fixed on the elastic damper cable at the same distance or at different distances (asymmetrically) relative to the middle of the damper cable 4. These distances (shoulders), if they are not equal, are selected, as a rule, within l ₁ : l ₂ = 1,1 -1.2, where l ₁ and l ₂ are the shoulders of the loads, and on the shoulder of a shorter length, a load of less weight is usually fixed.

The vibration damper can consist of either a power frame made of one spiral strand (for example, in the form of an inverted letter “C”) - “monoframe”, or of two U-shaped spiral strands 1 and 2 (Fig. 1), while between the wire and the damper cable, the parts of the spiral strand form the opposite sides of the power frame, oriented perpendicular to the wire or inclined to it at an angle other than 90 °

The upper part of the strand (s) is mounted on the wire 3, and the bottom - on the damper cable 4 with loads 5 (Fig. 1). The basis of the strands forming the power frame is a spiral element, characterized by a material, a spiral pitch, and also an inner diameter of d _C.

The pitch of the spiral can vary from 30 mm to 350 mm, depending on the diameter of the wire. The internal diameter of the spiral is also determined based on the diameter of the wire: d _C = (0.7 ÷ 0.98) × D _p , where D _p is the diameter of the wire, mm. The number of steps of the spiral strand spiral on the wire and on the damper cable can vary from 1.5 to 12. The length of the portion of the strand falling on the damper cable L _C (see Fig. 1) can vary from 1.5 × Sс to 12 × Sс.

The distance "H" between the wire and the damping cable depends on the diameter of the wire and on the total mass of the goods, and the larger the diameter of the protected wire, the greater the value of "H". The value of "H" can vary from 0.5 step spiral strands to 5 steps.

As in the first case ("mono-frame"), and in the other case (frame of two "P" -shaped strands), each strand consists of several wire spirals glued together. The spirals in the strands are made of steel wire with a protective coating of zinc or aluminum. Spirals can also be made of aluminum alloy.

The damper cable is made according to the applicant's own technology of steel wire with a protective coating of zinc. A damper cable with loads suspended on a power frame, in fact, forms a damper of wind vibrations.

In the case of a significant difference between the outer diameters of the wire 3 and the damper cable 4, a tread made of steel spirals is wound onto the latter - a leveling twist 6 (Fig. 2). The number of leveling coils may be more than one. The leveling wire can be made of a material different from the spiral.

In addition, the function of the leveling coil can be performed by a hollow tube, replacing the coil from wire spirals and crimped in several places on the damper cable or fastened to the cable in another way.

In contrast to the embodiment depicted in FIG. 1 and FIG. 2, where the end parts-branches of the power strand are attached to the wire and have a bend inside the frame (towards each other), a variant is possible in which the bend is made outward, i.e. end parts-branches are bent in opposite directions (Fig. 3).

The wind damper is mounted and dismantled manually without the use of additional equipment; it does not require highly qualified linear personnel. Installation quality is checked visually.

The use of spiral reinforcement significantly simplifies and speeds up both repair and restoration work on existing lines, and the construction of new lines.

Universal vibration damper designed:

- for all known types of wires, lightning cables;

- for diameter ranges of 9-37.5 mm.

Designation example: GVKU-17.1 / 17.5-4.0-500-02: Wind-wave damper - Universal: for wires having a diameter of 17.1-17.5 mm, total weight - 4.0 kg, length absorber - 500 mm; 02 - design with a leveling layer.

Claims (27)

1. A wind damper comprising a damper cable, on which a pair of loads is fixed, and at least one spiral strand connecting the damper cable to the wire so that one part of the spiral strand is mounted on the wire and the other part on the damper cable, characterized in that the damper cable is connected to the wire at two points of attachment by means of at least one spiral strand, with the formation of a power frame, the two opposite sides of which are formed by one spiral strand or different strands, and the other two opposite the living sides are the parts of the wire and damper cable on which one spiral strand or spiral strands are mounted, while one spiral strand is fixed with the middle part on the wire, and the end parts on the damper cable, or one spiral strand is fixed with the middle part on the damper cable, and the end parts on a wire with a bend inward of the power frame, or the end parts of the spiral strands are fixed on the wire with a bend inward of the power frame. 2. The vibration damper according to claim 1, characterized in that the spiral strand or strands are formed of several spirals glued together, the spirals in the strands being made of steel wire with a protective coating of zinc or aluminum or of aluminum alloy wire. 3. The vibration damper according to claim 1, characterized in that the damper cable is made of steel wire with a protective coating of zinc. 4. The damper of wind fluctuations according to claim 1, characterized in that the cargo is made equal or different in mass and placed on the shoulders l ₁ . l ₂ damper, which are made the same or different in length, where l ₁ . l ₂ - shoulders of the vibration damper - part of the length of the damper cable from the place of its termination in the load to the place of exit from the spiral strand. 5. The vibration damper according to claim 1, characterized in that an equalizing layer is made on the damper cable. 6. The vibration damper according to claim 1, characterized in that in the power frame formed using one spiral strand, the opposite sides of the power frame between the wire and the damper cable, which are parts of the same spiral strand, are oriented perpendicular to the wire or inclined to it at an angle other than 90 °. 7. The vibration damper according to claim 1, characterized in that the power frame is formed using two U-shaped spiral strands, each of which is wound with its ends on a wire and a damper cable, while the middle part of each of the U-shaped spiral strands forms opposite the sides of the power frame, oriented perpendicular to the wire or inclined to it at an angle other than 90 °. 8. The vibration damper according to claim 1, characterized in that the spiral strand or strands are made with a spiral pitch S _C from 30 mm to 350 mm and with an internal spiral diameter d _C (mm), determined from the relation: d _C = ( 0.7 ÷ 0.98) × D _p , where D _p - wire diameter, mm. 9. The wind damper according to claim 1, characterized in that the length of the plot L _{C of the} spiral strand or strands falling on the fastening of the spiral strand or strands on the damper cable and wire and which is the side of the power frame is in the range of 1.5 × S _C to 12 × S _C , where S _C is the spiral pitch of the spiral strand. 10. The dampener of wind vibrations according to claim 9, characterized in that on the length of the section L _{C of the} spiral strand or strands falling on the fastening of the spiral strand or strands on the damper cable, and on the length of the section L _{D of the} spiral strand or strands falling on the spiral fastening strands or strands on the wire, the number of steps of the spiral strand or strands is from 1.5 to 12, and the number of steps of the spiral strand or strands placed on the damper cable and the wire is the same or different. . 11. The wind oscillation damper according to claim 1, characterized in that the length H of opposing sides power frame formed spiral strand or strands, disposed between the wire rope and the damper, is from 0,5S 5S _C. to _C, where _C S - helical pitch spiral strand. 12. The vibration damper according to claim 5, characterized in that the number of leveling layers can be one or more than one, while the leveling layer is made of wire of the same material as the spiral strand, or of another material. 13. The damper of wind oscillations according to claim 5, characterized in that a hollow tube, fastened with a damper cable using glue or crimping or by any other known method, is used as a leveling winding. 14. The vibration damper according to claim 13, characterized in that the hollow tube used as a leveling layer for bonding with a damper cable is pressed in several places on the damper cable. 15. A wind damper comprising a damper cable, on which a pair of loads is fixed, and at least one spiral strand connecting the damper cable to the wire so that one part of the spiral strand is mounted on the wire and the other part on the damper cable, characterized in that the damper cable is connected to the wire at two points of attachment by means of at least one spiral strand, with the formation of a power frame, the two opposite sides of which are formed by one spiral strand or two or more spiral strands, and d e other opposite sides - part of the damper cable on which the spiral strand or strands are mounted, and part of the wire free from the spiral strand or strands and located between the places of attachment of the spiral strand or strands to it, while the end parts of the spiral strand or strands mounted on the wire , bent in opposite directions. 16. The wind damper according to claim 15, characterized in that the spiral strand or strands are formed of several spirals glued together, the spirals in the strands being made of steel wire with a protective coating of zinc or aluminum or of aluminum alloy wire. 17. The damper according to claim 15, wherein the damper cable is made of steel wire with a protective coating of zinc. 18. The damper of wind vibrations according to p. 15, characterized in that the cargo is made the same or different in mass and placed on the shoulders l ₁ . l ₂ damper, which are made the same or different in length, where l ₁ . l ₂ - shoulders of the vibration damper - part of the length of the damper cable from the place of its termination in the load to the place of exit from the spiral strand. 19. The vibration damper according to claim 15, characterized in that an equalizing winding is wound on the damper cable. 20. The vibration damper according to claim 15, characterized in that the opposite sides of the power frame between the wire and the damper cable formed by the parts of the spiral strand are oriented perpendicular to the wire or inclined to it at an angle other than 90 °. 21. The vibration damper according to claim 15, characterized in that the power frame is formed of two U-shaped spiral strands, each of which is wound with its ends on a wire and a damper cable, while the middle part of each of the U-shaped spiral strands forms opposite sides power framework. 22. The wind damper according to claim 15, characterized in that the spiral strand or strands are made with a spiral pitch S _C from 30 mm to 350 mm and with an internal spiral diameter d _C (mm), determined from the relation: d _C = ( 0.7 ÷ 0.98) × D _p , where D _p - wire diameter, mm. 23. The vibration damper according to claim 15, characterized in that the length of the portion L _{C of the} spiral strand or strands attached to the fastening of the spiral strand or strands on the damper cable and wire is in the range from 1.5 × S _C to 10.5 × S _C , where S _C is the spiral pitch of the spiral strand. . 24. The wind oscillation damper according to claim 15, characterized in that the length H of opposing sides power frame formed spiral strand or strands, disposed between the wire rope and the damper, is from 0,5S 5S _C. to _C, where _C S - helical pitch spiral strand. 25. The wind damper according to claim 19, characterized in that the number of leveling layers can be one or more than one, while the leveling layer is made of wire of the same material as the spiral strand, or of another material. 26. A dampener of wind oscillations according to claim 19, characterized in that a hollow tube fastened with a damper cable by any known method is used as a leveling winding. 27. The wind damper according to claim 26, characterized in that the hollow tube used as a leveling coil for connection with the damper cable is pressed in several places on the damper cable.

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