RU2750616C1 - Vibration damper for wires of overhead power lines - Google Patents

Abstract

FIELD: electric power.

SUBSTANCE: invention is used in the field of electric power on overhead power lines (PL). The device contains weights and at least one spiral strand made of at least one core, the axis of symmetry of the spiral strand coincides with the plane passing through the wire, its middle part is connected to the weights, and its extreme sections are wound on the wire, while the weights are placed inside the middle part of the spiral strand with the possibility of longitudinal movement of loads along the axis of the middle part of the spiral strand under dynamic loads.

EFFECT: limitation of the intensity of vibrations of wires of overhead power lines, increasing the efficiency of damping vibrations, reliability of the damper, efficiency of installation, reducing the cost of work.

12 cl, 2 dwg

Description

The invention relates to the electric power industry and can be used on overhead power lines (OHL) and fiber-optic communication lines as a universal device for detuning (mismatch) and damping vibrations of single wires, such as dance and vibration, resulting from wind influences. These vibrations represent periodic bending-torsional movements of the wire, mainly in the vertical plane, at the lowest resonant frequencies (when dancing from 0.5 to 2-3 Hz, with a significant amplitude, sometimes reaching the wire sag arrow; during vibration, at frequencies from 5 to 30 Hz), with bending deformations dangerous for the wire at the attachment points.

One of the urgent tasks in the power industry is to increase the reliability of overhead lines and, in particular, wires, lightning protection cables and self-supporting optical communication cables. Overhead lines (OHL) are the longest technical objects that are most vulnerable to atmospheric influences, subject to large-scale aging, degradation and damage. Wind effects play a significant role in these processes, especially when combined with precipitation in the form of snow, ice or supercooled water. A change in the shape of the wire cross-section due to ice or water flowing through it provokes the development or intensification of cyclic fluctuations, which reduces the resource of work, causes overlaps or short circuits in the network and leads one way or another to a decrease in throughput, and sometimes to partial or complete shutdown whole regions. Therefore, the task of preventing such costly and, in some cases, catastrophic damage to overhead transmission lines / power grids supplying municipal, civil and other facilities is urgent.

This task will help to effectively perform the proposed damper of low-frequency, as well as high-frequency oscillations of overhead transmission lines.

Known analogue of the proposed, - a damper of low-frequency vibrations of wires of overhead transmission lines [1], which contains a damper unit, fixed on the wire, as well as inert masses, which coincides with the essential features of the proposed. In addition, the analogue contains a sealed housing connected to the line wires and filled with an electro- or magnetorheological liquid, the dispersed phase of which is a suspension of electro- or magnetically sensitive nanoparticles, and sources of electric or magnetic fields. The damper unit is made in the form of a massive piston disk, which has the possibility of circular rotation when the wires vibrate due to the force of its own inertia and forcing the liquid to cyclically flow through the sealed channel inside the housing. Damping of oscillations of the wires of overhead transmission lines is carried out due to the viscous flow of the specified liquid, when the specified disk begins to move, and the electric or magnetic fields created by the sources, regulate the viscosity of the liquid and the force of resistance to flow, thereby ensuring the process of controlling the frequency and amplitude of oscillations of the absorber and increasing the efficiency of its action ... The disadvantages of analogue [1] include its complexity and sensitivity to temperature, as well as the fact that it has only one point of attachment of the damper unit on the wire, which does not exclude the damper getting into the unit of the standing wave of vibration vibrations of the wire. This leads to a decrease in its effectiveness as a vibration damper for wires.

Another analogue is also known - an overhead power transmission line dance absorber [2], containing a spiral strand, the axis of the middle part of which is parallel to the axis of the wire, inside the middle part of the spiral strand there is a load, and its extreme parts are wound on the wire, which coincides with the essential features of the proposed one. In addition, the weight inside the middle part of the spiral strand is made in the form of a metal rod, the ends of which are bent towards the wire, and the diameter of the metal rod is chosen to correspond to the diameter of the spiral strand.

The disadvantages of the analogue are that the implementation of the load in the form of a monolithic rod reduces the number of degrees of freedom of the system and depletes the spectrum of its resonant frequencies, which reduces the efficiency of its interaction with the spectrum of forced vibrations of the overhead transmission line wire, i.e. reduces the absorber's ability to dissipate the vibration energy of the wire. In addition, when the vibration node of the wire hits the middle part of the metal rod, the latter begins to swing, creating wear zones on the fastening spiral strands at its edges and causing the accumulation of fatigue deformations in the wires of these strands in these zones.

The closest to the claimed is a wind vibration damper adopted as a prototype [3], containing a spiral strand, the symmetry axis of which coincides with the plane passing through the wire, its middle part is connected to the weights, and its extreme sections are wound on the wire, which coincides with the essential signs of the proposed.

In addition, the prototype [3] contains a damper cable placed inside the middle part of the spiral strand, and the weights are placed at the ends of the damper cable extending beyond the middle part of the spiral strand.

The work of the prototype is based on the fact that the inertial elements of the spiral strand with weights suspended from the wire have resonant frequencies close to the oscillation frequencies of the overhead transmission lines. Therefore, the vibrational energy of the wires is partially pumped into an additional vibrational system - a spiral strand with weights, which has a high damping. As a result, the sharp resonance of the mechanical vibrations of the wires of the overhead transmission line is upset, the quality factor of the system as a whole falls, which leads to a decrease in the amplitude of the vibrations occurring in it.

The disadvantages of the prototype [3] are the same as those of the analogue [2].

These disadvantages are overcome in the proposed damper, a photo of which is shown in Fig. 1, and the diagram is shown in FIG. 2.

It contains a spiral strand 1, the axis of symmetry of which coincides with the plane passing through the wire 2, its middle part 3 is connected to the weight 4, and its extreme sections 5 and 6 are wound on the wire 1, which coincides with the features of the known device.

In this case, the weights 4 are placed inside the middle part 3 of the spiral strand 1.

In addition, the middle part 3 of the spiral strand 1 under operating conditions is located (in various versions) below, above or at the level of the wire 2.

In addition, the middle part of the spiral strand is made in the form of two segments (in the form of a "butterfly"), and the first segment of the middle part 3 of the spiral strand 1 is located below the wire 2, and the second segment is above the wire 2.

In addition, the weights 4 are made in the form of ellipsoids of revolution, elongated along the axis of the spiral strand, made in the form of a cylindrical spring, and the cross-sectional diameter of the weights is greater than the inner diameter of the spiral strand in the free state, and the cross-sectional diameter of the wire 2 is greater than the inner diameter of the outermost sections 5 and 6 spiral strand 1 in a free state, and the ratio of the wire diameter and the inner diameter of the outermost sections of the spiral strand in the free state is selected in the range 1: (0.99 ... 0.5), the ratio of the cross-sectional diameters of the weights and the inner diameter of the spiral strand is selected in the range 1: (0.99 ... 0.5), and the ratio of the distance between the centers of the weights inside the spiral strand to their length is chosen in the range (1.1 ... 3.5): 1.

In addition, several spiral strands are located along the wire, while the middle part of the previous spiral strand is located at the level of the wire on one side of the wire, and the middle part of the next spiral strand is located at the level of the wire on the opposite side of the wire.

In addition, several spiral strands are located along the wire, while the plane of the middle part of the previous spiral strand is located in the range of angles 90 ° ± 30 ° relative to the middle part of the subsequent spiral strand.

In addition, the direction of winding of the extreme sections of the spiral strand is opposite to the direction of winding of the wires of the upper strand of the protected wire, or coincides with it.

In addition, the direction of winding of the leftmost part of the spiral strand is opposite to the direction of twisting of the rightmost part of the spiral strand.

In addition, the spiral strand is made in the form of two oppositely wound spirals placed one inside the other, and the inner diameter of the outer spiral in the free state is less than the outer diameter of the inner spiral in the free state, and each of the spirals is made of at least one spring element, moreover, the ratio of the diameters of the weights and the inner diameter of the inner spiral of the spiral strand is selected in the range 1: (0.99 ... 0.5).

In addition, the extreme parts of the spiral strand, when wound on the wire, are divided into two separate bundles, wound in opposite directions.

The technical result is achieved by eliminating the above disadvantages in the proposed damper and consists in reducing the amplitude of oscillations of the wires of overhead transmission lines, increasing the reliability of overhead transmission lines, increasing the safety of overhead transmission lines, reducing the cost of implementing the device while simplifying the design and reducing the time of installation work.

The essence of the invention is illustrated by drawings.

List of drawing shapes

FIG. 1. Photo of the model of the damper, according to claim 1 of the formula.

FIG. 2. Scheme of the absorber, according to claim 12 of the formula,

where the notation is used:

1 - spiral strand,

2 - overhead power line wire,

3 - the middle part of the spiral strand

4 - cargo

5 - left extreme section of the spiral strand,

6 - the right extreme section of the spiral strand,

7 - the first bundle of the extreme section of the spiral strand

8 - the second bundle of the extreme section of the spiral strand

9 - an intermediate section of the middle part of the spiral strand.

FIG. 1 shows a photo of the current layout of the proposed damper according to claim 1 of the formula, where it is shown that the extreme sections of the spiral strand are wound on the wire and separated on opposite sides of the middle part. In this layout, weights 4 are not visible, because placed inside the spiral strand 1, the intermediate section 9 is not used.

FIG. 2 shows a diagram of the proposed absorber according to claim 12 of the formula, according to which both the left 5 and the right 6 extreme sections of the spiral strand 1 are divided into the first 7 and second 8 bundles and wound on wire 2.

The work of the proposed damper, like the prototype, is based on the fact that the inertial elements of the spiral strand 1 suspended from the wire 2 with weights 4 have resonant frequencies that are different from the vibration frequencies of the wires 1 of the overhead transmission line. Therefore, the vibrational energy of the wires is partially pumped into an additional oscillatory system - a spiral strand 1 with weights 4. In contrast to the analogue [2], the weight 4 is not made in the form of a single metal rod, and not in the form of weights outside the spiral strand 1, as in the prototype [3 ], and in the form of a set of individual weights 4, interconnected by elastic ties - intermediate sections 9 inside the middle part 3 of the spiral strand 1. This further expands the spectrum of vibrations of the suspension resonant system, since elastic elements are added that respond to external influences at their own resonant frequencies. This expands the vibration spectrum of the vibration system of the damper as a whole. This is additionally facilitated by the intermediate sections of the middle part 3 of the spiral strand 1, which additionally enrich the specified spectrum. The absence of rigid fastening of weights 4 inside the middle part of the spiral strand 1 and the possibility of their slight movement with friction inside the spiral strand ensures the achievement of the above effect. As a result, the detuning of the initially acute resonance of the mechanical vibrations of the overhead transmission line wires increases in comparison with the prototype, the drop in the quality factor of the system as a whole increases, which leads to an even greater decrease in the amplitude of the oscillations occurring in the overhead transmission line wire.

At the same time, the proposed damper overcomes the disadvantages of the prototype - compensates for oscillations of the overhead transmission line wire in an increased range of wind speeds, increases functional flexibility - the ability to adapt to specific operating conditions for a given area. The latter is explained by the presence of many additional control parameters (the direction of winding of spiral strands and separated beams of their end sections, as well as the mass and shape of loads, their number and distance between them), capable of providing the required result on overhead transmission lines of various scales and operational characteristics. In addition, the simplicity of implementation provides increased reliability and economic efficiency of the damper.

Next, we will show that the essential features of the proposed absorber do indeed provide the required technical result.

The fact that the damper contains at least one spiral strand 1 made of at least one spring element, the axis of symmetry of the spiral strand 1 coincides with the plane passing through the wire 2, its middle part 3 is connected to weights 4, and its extreme sections 5 and 6 are wound on the wire, and the weights 4 are placed inside the middle part 3 of the spiral strand 1 contributes to the appearance of resonant frequencies that are different from the vibration frequencies of the wires 2 of the overhead transmission line. When the wires 2 vibrate, the weights 4 move inside the spiral strand 1 with a coefficient of friction specified by the materials of the strand and weights and the degree of their pressing at the point of contact. Therefore, the vibration energy of wires 2 is partially spent on friction in the "load-spiral" system, and is also pumped into an additional oscillatory system - a spiral strand 1 with weights 4, complicated by the presence of intermediate sections 9. The quality factor of the oscillatory system as a whole falls, which leads to a decrease in the amplitude vibrations occurring in the wire 2 of the overhead line.

This is also facilitated by the introduction of parasitic resonances by adding additional elastic connections between the weights, as well as in the intermediate sections 9, which leads to an additional drop in the quality factor of the system as a whole.

The use of a spiral strand when winding it on a wire simplifies installation, speeds up it and reduces the cost.

The fact that in the damper the middle part 3 of the spiral strand 1 is located below wire 2, at the level of the wire or above wire 2, or consists of two segments - one above and the other below wire 2, expands the arsenal of possible characteristics of the damper that are optimal for suppressing wire vibrations 2 specific overhead transmission lines with their characteristic parameters (wire length, linear mass, wire type, etc.) and operating conditions (wind load, temperature, icing, etc.).

The fact that the weights in the absorber are made in the form of ellipsoids of rotation, elongated along the axis of the spiral strand, made in the form of a cylindrical spring, and the diameter of the weights is larger than the inner diameter of the spiral strand in the free state, adds another degree of freedom associated with the movement of weights by inertia inside the middle parts of the spiral strand and the manifestation of the friction effect. This further reduces the Q-factor of the oscillating system of the overhead transmission line as a whole and provides the desired positive effect of the invention. The range of the ratios of the wire diameter and the inner diameter of the outermost sections of the spiral in the free state, the dimensions of the load and the spiral, as well as the ratios of the distances between the loads and their own lengths, indicated in the claims, provides a positive effect in the required range of operating conditions.

The fact that in the damper along the wire there are several spiral strands 1, while the middle part 3 of the previous spiral strand 1 is located at the level of wire 2 on one side of the wire 2, and the middle part 3 of the next spiral strand 1 is located at the level of wire 2 on the opposite side , reduces the swing of wire 2, since spiral strands 1 located on opposite sides of wire 2 twist wire 2 in different directions, limiting its total twist, which could pump its energy into large-scale galloping effects.

The fact that several spiral strands 1 are located in the damper along the wire 2, while the plane of the middle part 3 of the previous spiral strand 1 is turned through an angle in the range of 90 ° ± 30 ° relative to the middle part of the next spiral strand 1, causes effects close to those previously considered. Indeed, when the weights 4 of one damper are located eccentrically relative to the wire 2 and they are suspended in one direction from the wire, and in the subsequent damper - in the opposite direction, etc. along the entire span of the line, the natural frequencies of the bending-torsional vibrations of the wire change and thus effective damping of the dance of single wires of overhead power lines is achieved.

The fact that the direction of winding of the extreme sections of the spiral strand in the damper is opposite to the direction of winding of the wires in the upper strand of the wire increases the strength of the fastening of the spiral strand on wire 2, since its unwinding during galloping leads to the twisting of the spiral strand 1, i.e. to tighter contact and increased frictional forces between the spiral strand and the wire.

The fact that in the damper the direction of winding of the leftmost part 5 of the spiral strand 1 is opposite to the direction of twisting of the rightmost part 6 of the spiral strand, increases the reliability of fastening the spiral strand 1 on the wire 2, since with multidirectional twists of wire 2 on one of the sides, the friction forces between the spiral strand 1 and the wire 2 will weaken, then on the opposite side of the spiral strand 1 the friction force will be increased. With the opposite phase of the periodic twisting of wire 2, the original friction force will be restored.

The fact that in the damper the spiral strand 1 is made in the form of two oppositely wound spirals placed one inside the other, and the inner diameter of the outer spiral in the free state is less than the outer diameter of the inner spiral in the free state, and each of the spirals is made of at least one of the spring element, provides blocking of the development of the springs in time due to the axial turns of the wire 2, since the development (weakening of the coils) of one of the springs will be accompanied by the coiling (compression of the coils) of the other spring. As a result, the fastening of the spiral strand 1 on the wire 2 will not be weakened.

The fact that in the damper the extreme parts 5 and 6 of the spiral strand 1, when wound on wire 2, are divided into two differently directed separate bundles, leads to the fact that the fastening of the spiral strand on the wire will not be weakened taking into account the various characteristics of the wires and cores of the spiral strand 1.

It should also be answered that the simplicity of the design ensures its reliability, shortens the installation time and reduces the cost of the device. The proposed damper is compact and its high-rise installation is possible using one support platform, which is impossible when using long-geometry damper.

So, the claimed damper for the dance of wires of overhead power lines is simple in its design, accordingly, it has increased reliability of operation, does not require significant costs in manufacturing, does not adversely affect the wire due to the fact that almost all elements of the damper are made using spiral reinforcement, it is effective in terms of achieving high performance.

The experiments carried out have confirmed the efficiency of the proposed damper. After extensive testing, it will be recommended for serial production.

List of sources of information:

1. RU No. 2570347 Danilin A.N. and other Damper of low-frequency oscillations of wires of overhead transmission lines (options) Publ. 10.12.2015 Bul. No. 34.

2. RU No. 2365009 / S. V. Ryzhov and other Dancing damper for wires of overhead power transmission lines. Publ. 20.08.2009 Bul. No. 23

3. RU No. 2575918 / S. V. Ryzhov and other Universal wind vibration damper (options) Publ. 02/27/2016 Bul. No. 6.

Claims (13)

1. An absorber of wind vibrations of the overhead power line wire, containing weights and at least one spiral strand made of at least one spring element, the symmetry axis of the spiral strand coincides with the plane passing through the wire, its middle part is connected to the weights, and its extreme sections are wound on a wire, characterized in that the weights are placed inside the middle part of the spiral strand with the possibility of longitudinal movement of the weights along the axis of the middle part of the spiral strand under dynamic loads. 2. The damper of wind vibrations of the wire according to claim 1, characterized in that the middle part of the spiral strand is located below the wire. 3. The damper of wind vibrations of the wire according to claim 1, characterized in that the middle part of the spiral strand is located at the level of the wire. 4. The damper of wind vibrations of the wire according to claim 1, characterized in that the middle part of the spiral strand is located above the wire. 5. The damper of wind vibrations of the wire according to claim 1, characterized in that the middle part of the spiral strand is made in the form of two segments, and the first segment of the middle part of the spiral strand is located below the wire, and the second - above. 6. The damper of wind vibrations of the wire according to claim 1, characterized in that the weights are made in the form of ellipsoids of revolution, elongated along the axis of the spiral strand, made in the form of a cylindrical spring, and the cross-sectional diameter of the wire is greater than the inner diameter of the extreme sections of the spiral strand 1 in a free state , moreover, the diameter of the cross-section of the weights is greater than the inner diameter of the spiral strand in the free state, and the ratio of the wire diameter and the inner diameter of the outermost sections of the spiral strand in the free state is selected in the range 1: (0.99 ... 0.5), the ratio of the diameters of the weights and the inner diameter of the spiral strand is selected in range 1: (0.99… 0.5), and the ratio of the distance between the centers of the weights inside the spiral strand to their length is selected in the range (1.1… 3.5): 1. 7. The damper of wind vibrations of the wire according to claim 1, characterized in that there are several spiral strands along the wire, while the middle part of the previous spiral strand is located at the level of the wire on one side of the wire, and the middle part of the next spiral strand is located at the level of the wire from the opposite sides of the wire. 8. The damper of wind vibrations of the wire according to claim 1, characterized in that several spiral strands are located along the wire, while the plane of the middle part of the previous spiral strand is turned through an angle in the range of 90 ° ± 30 ° relative to the middle part of the subsequent spiral strand. 9. The damper of wind vibrations of the wire according to claim 1, characterized in that the direction of winding of the extreme sections of the spiral strand is opposite to the direction of winding of the wires in the upper winding of the wire. 10. The damper of wind vibrations of the wire according to claim 1, characterized in that the direction of winding the extreme sections of the spiral strand coincides with the direction of winding the wires in the upper layer of the wire. 11. The damper of wind vibrations of the wire according to claim 1, characterized in that the direction of winding of the left extreme portion of the spiral strand is opposite to the direction of winding of the right extreme portion of the spiral strand. 12. The damper of wind vibrations of the wire according to claim 1, characterized in that the spiral strand is made in the form of two spirals wound in opposite directions, placed one inside the other, and the inner diameter of the outer spiral in the free state is less than the outer diameter of the inner spiral in the free state, and each of the spirals is made of at least one spring element, and the ratio of the diameters of the weights and the inner diameter of the inner spiral of the spiral strand is selected in the range 1: (0.99 ... 0.5). 13. The damper of wind vibrations of the wire according to claim 1, characterized in that the extreme sections of the spiral strand, when wound on the wire, are divided into first and second bundles directed in opposite directions.

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