RU2484568C1 - Wire vibration damper - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to the filed of electrical power engineering and is to be applied for protection of wires and ground-wire cables of overhead power transmission lines against wind vibration. The damper contains a resilient rod 2, a clamp 3 for the damper attachment to the wire 1 and loads 4. Each load 4 is elongated along its longitudinal axis and attached to the rod 2 end via its middle part. The loads 4 are attached crosswise to the rod 2. The clamp 3 is fixed on the rod 2 in the middle thereof and attached to the wire 1 so that the rod 2 and the longitudinal axis 5 thereof are parallel to the wire 1. One wire 1, the rod 2 and the clamp 3 are positioned within a vertical plane while the axes 6 - in a horizontal one. The design parameters of the damper (bending stiffness of the rod 2 working parts, weight of the loads 4 and moment of their inertia relative axis 6) are selected so that any proper frequency f_p of the damper satisfies either of the following conditions: f_p<0.18/d or f_p>1.4/d where d is the diameter (m) of the wire or ground-wire cable of the overhead power transmission line for damping vibrations wherein the vibration damper is intended while f_p, is the damper proper frequency (Hz). The loads 4 may be designed, in particular, in the form of a cylinder, a square cross-section bar section or a steel pipe filled with heavy meal such as lead.

EFFECT: in enhanced protection of wires and ground-wire cables of overhead power transmission lines against eolic vibration.

4 cl, 2 dwg

Description

Technical field

The proposal relates to the electric power industry and can be used to protect wires and lightning protection cables of an overhead power line from wind vibration.

State of the art

In the wires (everything described below also applies to lightning cables), under the influence of wind, a stable vibration can occur in the frequency range characteristic of a given wire (aeolian vibration). Aeolian vibration with a sufficiently large range and duration of oscillations can lead to fatigue damage to the wire. Protection against aeolian vibration is carried out using vibration dampers [Electrical Installation Rules (Electrical Installation Regulations), seventh edition, Energoservice, 2003, clause 2.5.85].

Known adopted for the prototype, vibration damper wires of an overhead power line, containing an elastic rod, a clip designed to mount an elastic rod parallel to the overhead line, and loads fixed at the ends of the elastic rod, each of which is elongated along its longitudinal axis [patent RU 2262173]. In the prototype, the loads are fixed at the ends of the elastic rod so that their longitudinal axis is directed along the elastic rod, coincide with its longitudinal axis or parallel to it.

The disadvantage of the prototype is the possibility of the occurrence of a "wire with a damper" in the system under certain wind influences of stable resonant vibrations, the amplitude of which exceeds the value allowed for a given vibration frequency.

This disadvantage of the prototype and other known designs of the damper due to the following.

The wire is characterized by a frequency range Δf depending on its diameter, in which aeolian vibration may occur at different wind speeds. The absorber is characterized by many natural frequencies f _p , which are determined by the design parameters of the absorber and are arranged in pairs on the frequency axis. If, when a damper is placed on a shielded wire, the damping eigenfrequencies f _r fall into the frequency range Δf characteristic of the shielded wire, it is possible (under adverse wind conditions) the appearance of resonant vibrations of the wire with an unacceptable oscillation amplitude, which leads to a sharp increase in the probability of fatigue damage to the wire and, therefore , to reduce the reliability of overhead lines in general. Practical danger is getting into the characteristic frequency range of the wire at least one frequency of the first two (lower in frequency) pairs of natural frequencies of the damper.

The objective of the invention is to remedy this drawback.

Disclosure of the invention

The technical result of the invention is to increase the reliability of protection of wires and lightning cables of overhead lines from aeolian vibration.

The subject of the invention is a vibration damper of wires of an overhead power transmission line, comprising an elastic rod, a clamp for fastening an elastic rod parallel to a wire with a diameter of d meters, and two weights, each of which is elongated along its longitudinal axis and secured with a middle part across the elastic rod on one of its Finally, each natural frequency f _p Hertz of the absorber satisfies one of the conditions:

f _p <0.18 / d or f _p > 1.4 / d.

This allows you to get the specified technical result.

The invention has clarifying developments characterizing particular cases of its implementation.

The first development is that each load can be made in the form of a piece of steel pipe filled with heavy metal, such as lead.

Another development is that in the absorber designed to protect the wire with a diameter of 15.2-17.5 mm, the elastic rod is made of a piece of a single-strand steel rope (type TK according to GOST3063-80) with a diameter of 11.0 mm, the total length of the damper with a clamp width of 60 mm is 400 mm, and the moment of inertia of each load relative to its longitudinal axis does not exceed 4-10 ^-4 kgm ² . Moreover, each load can be made, for example, in the form of a steel cylinder with a diameter of 40 mm and a mass of 1.6 kg (the moment of inertia of such a load is 3.2 · 10 ^-4 kgm).

A brief description of the figures.

Figure 1 presents the damper according to the claimed invention, figure 2 is an explanatory frequency diagram.

The implementation of the invention in view of its development.

The damper located on the wire 1 contains an elastic rod 2, a clip 3 for attaching the damper to the wire 1 and loads 4.

The clamp 3 is fixed in the middle of the rod 2 and is mounted on the wire 1 so that the rod 2 and its longitudinal axis 5 are parallel to the wire 1. In this case, the wire 1, the rod 2 and the clamp 3 are placed in the vertical plane, and the axis 6 and the axis 5 in the horizontal .

Each load 4 is elongated along its longitudinal axis 6 and can be made, for example, in the form of a cylinder or a square bar.

Each load 4 of this form is fixed with its middle part at the end of the rod 2 across the axis 5, while the axis 6 can be, for example, orthogonal to the axis 5.

The position on the frequency axis (see figure 2) of the pairs of natural frequencies f _{p of the} absorber depends on the bending stiffness of the two working parts of the rod 2, cantilevered in the clamp 3, the mass of each load 4 and its moment of inertia relative to axis 6.

These parameters are selected (by calculation or experimentally) so that any natural frequency f _p (in hertz) of the absorber satisfies one of the conditions:

f _p <0.18 / d or f _p > 1.4 / d,

where d is the diameter (in meters) of the wire or lightning protection cable of the overhead power line for which the vibration damper is intended.

In particular, the first condition is satisfied by the upper frequency of the first (from the beginning of the frequency axis) pair of natural frequencies of the absorber, and the second is the lower frequency of the second (from the beginning of the frequency axis) pairs of natural frequencies of the damper.

Lower and upper limits range Δf located at frequencies f _n = 0,18 / d and f _in = 1,4 / d, respectively [Standard IEC 61897-1998. Overhead lines. Stockbridge Aeolic Vibration Absorber Requirements and Testing]. Therefore, if the absorber is made according to the claimed invention, the range Δf of the wire 1 is located between adjacent pairs of natural frequencies f _p , and within itself does not have the natural frequencies of the damper.

The removal of the natural frequencies f _p outside the range Δf improves the reliability of wire protection from aeolian vibration in the case of application of the proposed damper design.

We now compare the possibility of obtaining such a result by appropriate selection of parameters in the known and proposed damper design.

The natural frequencies of the absorber can be calculated according to its structural data using specialized programs and measured experimentally [S. Trofimov. Analysis of the results of calculations of the effectiveness of the vibration dampers of the PTG on a wire sample AC 120-19. // Electro. Electrical engineering, electric power industry, electrical industry. 2011, No. 2].

A calculation and experimental study of the influence of the design parameters of the damper on the position of the two lower pairs of natural frequencies f _p relative to the lower and upper boundaries of the range Δf showed the following.

Suppose that, for any practical reasons, the material and design parameters of the damper’s elastic rod 2 and the width of the clamp 3, which rigidly fixes the middle part of the rod 2, are selected, and, therefore, the flexural rigidity of each of its working parts (considered as a console rigidly fixed in the clamp) is selected. If this parameter is selected and fixed in the calculations, then for the output of the first lower pair of natural frequencies f _p beyond the lower limit of the range Δf, an increase (up to the value determined by the diameter of the protected wire) of the mass of the damper is required, and for outputting the second lower pair of natural frequencies f _p for the upper limit of the Δf range requires a decrease (to a value determined by the diameter of the protected wire) of the moment of inertia of the load relative to the axis of rotation, directed perpendicular to the axis of the flexible rod.

For the design scheme of the prototype (and other well-known absorbers), these two requirements are contradictory and (as calculations performed with respect to vibration protection of widespread aluminum-steel wires with a diameter of 15.2-17.5 mm) showed their simultaneous implementation, since in the known design of the damper an increase in the mass of a load is inevitably accompanied by an increase in its moment of inertia.

In contrast to the prototype, the fulfillment of the above requirements for the parameters of the damper elements is easily ensured in the design of the proposed device. In this design, the moment of inertia of the cargo 4 relative to the axis 6 can be reduced (by reducing the radius of the cylinder or reducing the cross section of the cargo of a different shape) without reducing the mass of the cargo, with its corresponding extension along the axis 6, since this extension does not affect the moment of inertia of the cargo 4 axis 6.

To obtain a sufficient mass of the load 4 with a small moment of inertia about the axis 6, each load 4 can be made in the form of a piece of steel pipe filled with heavy metal, such as lead.

For a practically important special case of the proposed damper (wire with a diameter of 15.2-17.5 mm, the elastic core is made of a piece of steel rope of a single strand like TK according to GOST3063-80 with a diameter of 11.0 mm, the total length of the damper is 400 mm, the clamp width is 60 mm) as a result of the calculations, it was determined that the maximum allowable moment of inertia of the load 4 relative to the longitudinal axis 6 is 4.0 · 10 ^-4 kgm ² .

The last requirement is met, for example, by load 4 in the form of a steel cylinder with a diameter of 40 mm and a mass of 1.6 kg. Calculated according to these parameters, the moment of inertia of the load 4 relative to axis 6 is 3.2 · 10 ^-4 kgm ² .

Claims (4)

1. The vibration damper of the wires of an overhead power transmission line, comprising an elastic rod, a clamp for fastening an elastic rod parallel to a wire with a diameter of d meters, and two weights, each of which is elongated along its longitudinal axis and secured with a middle part across the elastic rod at one of its ends , each natural frequency f _p hertz absorber satisfies one of the conditions:
f _p <0.18 / d or f _p > 1.4 / d. 2. The damper according to claim 1, in which each load is made in the form of a piece of steel pipe filled with heavy metal, such as lead. 3. The damper according to claim 1, designed to protect the wire with a diameter of 15.2-17.5 mm, in which the elastic rod is made of a piece of steel rope single lay with a diameter of 11.0 mm, the total length of the damper with a clamp width of 60 mm is 400 mm , and the moment of inertia of each cargo relative to its longitudinal axis does not exceed 4 · 10 ^-4 kgm ² . 4. The damper according to claim 3, in which each load is made in the form of a steel cylinder with a diameter of 40 mm and a mass of 1.6 kg.

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