DE4400618A1 - Reduction of galloping in overhead HV lines - Google Patents

Abstract

A h.v. overhead line comprising bundle conductors has damper devices between different individual conductors to reduce galloping oscillations. The dampers are attached to the conductors by elastic linkages. They are arranged in a zigzag line down the length of the line, to simulate a sinusoidal distribution. Alternatively, they can be replaced by a continuous single plastic or rubber covered damper cable. The cable extends over only part of the distance between towers. There may be one or several damper cables for each span.

Description

The invention relates to a high-voltage overhead line with the features of The preamble of claim 1.

Such an overhead line for the transport of electrical energy contains meh rere bundle ladder. Each bundle conductor corresponds to a phase conductor, e.g. B. for a 3-phase system.

Each bundle conductor in turn consists of several sub-conductors of the same electrical potential. The conductor ropes are caused by ice build-up, by wind or also sporadically u. a. to long-wave mechanical vibrations excited. These very low frequency (less than 1 Hz) mechanical vibrations are called "dancing" or "galloping". These are before all vertical vibrations. The vibration amplitudes can be so become large that - in addition to mechanical damage to individual Partial conductor - the partial conductors of different phases touch and thereby trigger an earth or phase short circuit. This leads to significant Malfunctions of the overhead line and in the power plants. The overhead line can be so damaged by the short circuit that an expensive and expensive playful repair is required. This in turn leads to an undesirable one Interruption of energy transport with significant business Consequences.

To avoid such short circuits, the distances between the individual Phases of the overhead line are enlarged. However, this will help build the Pylons too complex and too expensive. EP 0 033223 A2 Damping devices for damping mechanical vibrations Conductor cables of a bundle conductor disclosed. The damping device has two Fastening ends and is with one fastening end on each Partial conductor attached. The damping device thereby connects two with ge  opposite vertical spacing of a sub-conductor of a well delleiters with each other. The two partial conductors coupled in this way form one part head pair. The fastening points on the partial conductors for the dampers tion device are always in the same vertical plane, the vertical plane perpendicular to the longitudinal direction of the conductor is ordered. Such an arrangement of the damping device enables however, only a very limited damping effect with certain off steering directions of the partial conductors. The specially designed for long-wave damping The proposed damping device is only for a pair of partial conductors with a horizontal distance and accordingly only for the dampers suitable for horizontally aligned vibrations. Besides, they are damping devices proposed in EP 0 033 223 A2 are very complicated built up.

Based on the disadvantages described, the object of the invention based on the damping of mechanical vibrations of the conductor cables further improve. This task is achieved through the combination of features of the claim ches 1 solved.

According to the fastening points on the two are vertically spaced stood partial conductors of the partial conductor pair offset in the longitudinal direction of the cable orderly. This allows the phase opposition, in the most diverse Directions of relative movements of the two partial conductors of a part use pair of conductors to dampen vibrations. So z. Belly the occurring mutual displacements of the partial conductors along the line Use direction for damping. Such a coupling of two partial conductors is independent of a specific design of the damping device especially for damping long-wave vibrations of the parts suitable.

Depending on the expediency, the offset of the attachment points at the the two partial conductors in the longitudinal direction of the line may be of different sizes. Important is only that the damping device two with mutual vertical the sub-conductors arranged to each other mechanically connected to each other.

Due to the offset of the fastening points in the longitudinal direction of the line Do the damping device a larger damping work. This will the efficiency of the damping device is improved. You can also  also damping devices are used, which due to their construct tive dimensions for alignment in the direction of the vertical distance two partial conductors are not suitable.

The fastening points on the different vertical levels Partial conductors for the damping device increase the internal damping of the Bundle ladder. He is also stiffened. The deviations from the ge desired target position of the individual sub-leaders and also of the entire bundle ters are reduced. In the inventive arrangement of the Befe Stigungsstellen for the damping device are also the transverse movements damped against the bundle conductor and thereby also reduce the occurrence vibration amplitudes of the individual bundle conductors.

The arrangement of the attachment points according to the invention is independent of the design of the damping device. The only important thing is a front direction with spring and damping effect.

The arrangement of a damping device according to the invention can also Support the operation of a field spacer or replace it.

Claim 2 proposes a conventional Schwin as a damping device damper with two fastening ends. The vibration damper usually extends along the line connecting the two bees ends. Vibration damper in the field of high voltage free There are a large number of cables with different designs tion available. It can therefore, depending on the desired offset of the fastener supply points on the two partial conductors of the partial conductor pair accordingly constructively designed vibration damper easily selected the. The vibration damper can hydraulic damper or me be a Chinese damper. Vibration dampers can also be turned off entirely their areas of application, e.g. B. from the automotive industry or washing machine drums are used.

According to claim 3 is a relative mobility between the end regions of the vibration damper and the sub-conductors connected to it accomplishes. In this way, any mechanical damage to the Partial conductor in the area of the attachment point reduced over the course of the operating time.  

An elastic joint according to claim 4 can be an additional depending on the material cause damping effect. This is the internal damping of the Bundle conductor further improved.

Claim 5 proposes as a damping device in the longitudinal direction of the line wavy damper rope. In the area of his waves The damper cable is plitual by means of suitable fastening means on the feet Stigungsstellen of the two conductor cables fixed, for. B. clamped.

It is also possible that the damper cable between all sub-conductors Bundle ladder - e.g. B. between three partial conductors - in the longitudinal direction of the cable runs helically and with suitable fasteners on the the helix tangent fastening points of the conductor cables are fixed.

The individual wires stranded together can be metallic or also made of Plastic. On the one hand, they enable good mechanical properties Stability of the damper rope and on the other hand due to the friction of the individual wires lying opposite each other have a sufficient damping effect of the Damper rope. The inherent stability of the damper rope supports this Damping effect over a long period of operation.

Claim 6 improves the bundling of the individual wires of the damper cable. The individual sub-conductors of a bundle conductor become even more reliable together quantity and act as a system unit. Between the individual wires greater friction forces arise which further increase the damping effect.

Claims 7 and 8 propose different materials for the outer jacket of the damper rope. Depending on the required damping effect, an ent select speaking material. These materials can also be used high coefficient of friction of the outer jacket are taken into account. A high one Friction coefficient supports the bundling effect of the outer jacket and increases the internal friction forces of the damper cable.

Claim 9 allows adaptation of the damper cable to different Span lengths of the bundle conductor. By simply disconnecting the damper ropes to a certain length or by stringing several Ren damper cables in the longitudinal direction of the line is the required damping effect can be easily achieved for the entire span length.  

According to claim 10 is on each pair of conductors and thus also on each part head attached at least one damping device. Not even with each other Partial conductors connected directly via a damping device are therefore out visually coupled with each other the damping effect. The inner damping the bundle conductor is thereby further improved.

Claim 11 takes large span lengths of a bundle conductor into account which a single damping device for the required damping wir is not sufficient. Depending on the expediency can be used for attachment of the damping devices in different areas of the bundle conductor Longitudinal direction can be selected. In addition, several guarantee Damping devices that dampen the mechanical vibration conditions continue to occur even if a damping device is defective or fails.

There can also be vibration dampers and damper cables in a bundle ladder can be used in combination. It is also possible to do this damping directions for bridging a horizontal distance between two partial conductors clog.

The subject of the invention is based on the Aus shown in the figures examples of management explained in more detail. Show it:

Fig. 1 is a schematic representation of a clamped between two pylons conductor bundle with a plurality of vibration dampers,

Fig. 2a shows the representation of a 2-beam according to the direction of the arrow II-II in Fig. 1,

FIG. 2b shows the diagram of a 3-beam according to the direction of the arrow II-II in Fig. 1,

Fig. 2c, the representation of a 4-beam according to the direction of the arrow II-II in Fig. 1,

Fig. 3, the 4-bundle according to FIG. 2c with a damping device on each conductor pair,

Fig. 4 is a schematic representation of a bundle conductor with a Dämp ferseil,

Fig. 5 shows the cross section of a damper rope according to the arrow Rich tung VV in Fig. 4.

In Fig. 1, a bundle conductor 1 is clamped between two clamping ends 2 . The two clamping ends 2 are the schematic representation of two line masts, the distance of which speaks the span length of the bundle conductor 1 ent. The span length extends in the longitudinal direction 3 of the cable, i.e. along the longitudinal extent of the bundle conductor 1 . The bundle conductor 1 is composed of several partial conductors 4 . The individual partial conductors 4 of a bundle conductor 1 run parallel to the longitudinal direction 3 of the line. This representation of the partial conductors 4 is idealized schematically. Usually, the partial conductors 4 are bent in a vertical direction 5 arranged at right angles to the longitudinal direction 3 of the line in the direction of the earth's surface.

Between the two partial conductors 4 shown in FIG. 1 there is a vertical distance a _v running in the vertical direction 5 . The vertical distance a _v is bridged by egg nem vibration damper 6 . The vibration damper 6 is attached with its two schematically illustrated fastening ends 7 to each egg nem conductor 4 . The two fastening points 8 occupied by the fastening ends 7 on the two partial conductors 4 are arranged offset in the line longitudinal direction 3 . Due to the offset arrangement of the attachment points 8 , the relative longitudinal displacements taking place in the longitudinal direction 3 of the two partial conductors 4 coupled via a vibration damper 6 are used for the vibration damping. Also relative movements of the two partial conductors 4 in other spatial directions can be better utilized by the inventive arrangement of the fastening points 8 . As a result, the internal damping of the bundle conductor 1 is considerably improved.

It must only be noted that the connecting line of the two fastening points occupied by the fastening ends 7 of a vibration damper 6 and supply lines 8 and the longitudinal direction 3 together form an angle w. The following applies: 0 ° <w <90 °. The exact amount of the acute angle w depends on the required damping effect, the vertical distance a _v or also on the structural conditions of the vibration damper 6 . Depending on the span length, several vibration dampers 6 must be hen vorgese. In Fig. 1, the two sub-conductors 4 along the line longitudinal direction 3 are coupled via a total of three vibration dampers 6 . Two vibration damper 6 are directly lined up. In further exemplary embodiments, not shown here, such a stringing together is also conceivable with a larger number of vibration dampers 6 . The next vibration damper 6 would then be mounted with its one attachment end 7 at the attachment point 8 not occupied in FIG. 1. In Fig. 1, all three vibration dampers 6 amount approximately the same Win angle w with the longitudinal direction of line 3 .

Referring to Fig. 2a to FIG. 2c, it is seen that the bundle conductors shown in FIG. 1 1 of two, three or four sub-conductors can be made. 4 In FIG. 1 due to the congruent arrangement of several conductor elements 4 are only two sub-conductors 4 are visible. Two partial conductors 4 arranged with the vertical spacing a _{v from} one another form a partial conductor pair 10 . In principle, bundle conductors 1 with more than four partial conductors 4 are also conceivable.

In FIG. 3, all four partial conductor pairs 10 of the bundle conductor 1 according to FIG. 2 c are provided with a vibration damper 6 . In further exemplary embodiments, further vibration dampers 6 can be mounted on each pair of partial conductors 10 along the longitudinal line direction 3 . It is also conceivable not to provide all pairs of Teillei 10 of the bundle conductor 1 with vibration dampers 6 .

In FIG. 4, a wavy line extending in the line longitudinal direction 3 damper wire 11 is visible. Like the vibration damper 6, it bridges the vertical distance a _{v of} two partial conductors 4 . The damper cable 11 is fi fixed in its wave amplitudes by means of conventional clamping means 12 on the partial conductors 4 . The attachment points 8 of the partial conductor 4 for the clamping means 12 are in turn arranged in the longitudinal direction 3 Lei offset.

From Fig. 5 it can be seen that the damper wire 11 is stranded with each other from a plurality of individual wires 13 and the individual wires 13 surrounding outer jacket 14. In a further embodiment, not shown, for example, the damper cable 11 does not have an outer jacket 14 .

Reference list

1 bundle ladder
2 clamping ends
3 Longitudinal line
4 partial conductors
5 vertical direction
6 vibration dampers
7 fastening ends
8 attachment point
10 pair of partial conductors
11 damper cable
12 clamping means
13 single wire
14 outer jacket
a _v Vertical distance
w angle

Claims (11)

1. High-voltage overhead line with several from each individual sub-conductors ( 4 ) existing bundle conductors ( 1 ), in which the same bundle conductor ( 1 ) associated sub-conductor ( 4 ) at least partially a vertical Ab (a _v ) have each other, the is bridged by a damping device for damping mechanical vibrations of the partial conductors ( 4 ), characterized in that the fastening points ( 8 ) of two partial conductors ( 10 ) forming part conductors ( 4 ) for the damping device are arranged offset in the longitudinal direction of the line ( 3 ) . 2. overhead line according to claim 1, characterized in

• - That the damping device is a vibration damper ( 6 ) with two loading ends ( 7 ) and
• - That the vibration damper ( 6 ) with one attachment end ( 7 ) is attached to one of the two partial conductors ( 4 ).

3. Overhead line according to claim 2, characterized in that the fastening end ( 7 ) is a joint. 4. overhead line according to claim 3, marked by an elastic joint. 5. Overhead line according to claim 1, characterized in that the damping device in a longitudinal line direction ( 3 ) wienli nieniform between the partial conductors ( 4 ), consisting of several individual wires ( 13 ) existing damper cable ( 11 ). 6. Overhead line according to claim 5, characterized in that the damper cable ( 11 ) is surrounded by an outer jacket ( 14 ). 7. Overhead line according to claim 5 or 6, characterized in that the outer jacket ( 14 ) consists of plastic. 8. Overhead line according to claim 5 or 6, characterized in that the outer jacket ( 14 ) consists of rubber. 9. Overhead line according to one of claims 5 to 8, with a span length defined by the distance between two masts for fastening the bundle conductor ( 1 ), characterized in that the damper cable ( 11 ) extends in the longitudinal direction of the line ( 3 ) at least over a portion of the span length . 10. Overhead line according to one or more of the preceding claims, characterized in that a damping device [= vibration damper ( 6 ), damper cable ( 11 )] is attached to each pair of partial conductors ( 10 ) of the bundle conductor ( 1 ). 11. Overhead line according to one or more of the preceding claims, characterized in that on the pair of conductors ( 10 ) in the longitudinal line direction ( 3 ) a plurality of damping devices [= vibration damper ( 6 ), damper cable ( 11 )] be fastened.