EP3073588A1 - Insulation kit for an overhead line - Google Patents

Abstract

The invention relates to an insulator arrangement (1) for an overhead line (2). This has a holding insulator (4) for fastening an overhead line (2) to a mast (3) and a line arrester arrangement (8) arranged electrically parallel to the holding insulator (4). The line arrester arrangement (8) has a surge arrester (9, 10) electrically connected to ground potential and a spark gap (11) connected in series with a first spark electrode (6) connected to the overhead line (2) and one with the surge arrester (9, 10) connected to the second spark electrode (7). According to the invention, the line arrester arrangement (8) has a mounting insulator (5) which can be fastened to the overhead line (2), the first spark electrode (6) being attached to a first fastening device (12) at a first end of the mounting insulator (5) and the second sparking electrode (7 ) is attached to a second attachment device (13) at a second end of the mounting insulator (5).

Description

The invention is in the field of electrical engineering and refers specifically to an insulator arrangement for an overhead line. Such overhead lines are used in power transmission networks for the transport of electrical energy in the high voltage range. Individual rope-like conductors are usually to be fastened to masts by means of holding insulators. In order to protect the overhead lines, line arresters are used in this connection in order to dissipate any overvoltages, for example due to lightning strikes, to the ground potential.

Line arresters are connected in a power transmission network, in particular in high-voltage networks with voltages above 1 kV, in parallel with a line insulator of the overhead line. They contain a dissipation element made of non-linear metal oxide resistors in a porcelain or plastic housing. Line arresters are preferably used where, due to a lack of or insufficient earth-wire protection and / or high resistance to crushing joints (eg in the case of heavily rocky subsoil), rear-side overturning occurs frequently. To subsequently increase the reliability of already existing transmission or distribution lines is often the installation of line arresters on all or even on some masts a cost effective alternative to improve the Erdseilschutzes or the Masterdungsverhältnisse. Line arresters are used both in sparkless technology and in conjunction with an external series spark gap, which isolate the arresters in normal operation, against switching overvoltages or even after an overload of the line used. In the following, only line arresters with external series spark gaps are considered.

A line arrester with external series spark gap (English: externally gapped line arrester or EGLA) has a series connected to the diverter spark gap. One end of the line arrester is earthed at a grounding point of the transmission tower, at the other end there is a spark electrode, which forms a spark gap with a spark horn at the high voltage end of the line insulator. Instead of the sparking horn, the overhead line itself can serve as the high-voltage end of the spark gap.

If an overvoltage occurs, for example as a result of a lightning strike in the overhead line, the spark gap is short-circuited by an arc and the overvoltage controlled by the line arrester is discharged to earth. After the overvoltage subsides, the spark gap extinguishes and isolates the line arrester from the high voltage. Line arresters with external series spark gap are standardized in IEC 60099-8. In the US 2012/0087055 A1 Such a line arrester with external series spark gap is shown.

Frequently, line arresters with external series spark gaps are retrofitted into existing high-voltage grids. There is the problem that the suspension of the line arrester must be adapted to the conditions on site.

The present invention is based on the object to provide an insulator arrangement for an overhead line, which allows easy installation, even in the case of retrofitting.

The object is achieved with the features of the invention according to claim 1. Claims 2 to 9 have advantageous embodiments of the solution according to the invention. Accordingly, the invention relates concretely to an insulator arrangement for an overhead line, comprising a holding insulator for fastening an overhead line to a mast and a line arrester arrangement arranged electrically parallel to the holding insulator with a surge arrester electrically connected to ground potential and a spark gap connected in series with a first spark electrode connected to the overhead line and a second spark electrode connected to the surge arrester.

The object is achieved according to the invention in that the Leitungsableiteranordnung has a mountable to the overhead line mounting insulator, wherein the first spark electrode is attached to a first fastening device at a first end of the mounting insulator and the second spark electrode to a second fastening device at a second end of the mounting insulator ,

The mounting insulator is preferably designed as a rigid long-rod insulator. He offers with the two fastening devices a holder for the surge arrester or the spark electrode. Each spark electrode may either be attached directly to one end of the fixture or the spark electrode is attached to one end of an over-surge arrester which in turn is attached to the fixture at its other end. Over the length of the mounting insulator, the distance between the two spark electrodes and thus the spark gap is determined. The mounting insulator thus forms together with the surge arrester and the spark electrodes a mechanically stable compact unit which can be easily attached via a holding device on the overhead line. The connection to the earth potential can be made via a ground line to the mast. Such a Leitungsableiteranordnung is independent of attaching to the holding insulators fasteners and can be attached in the vicinity or at a certain distance from the holding insulator to the overhead line.

An advantageous embodiment of the invention provides that the mounting insulator is designed as a long-rod insulator. As a result, the mounting insulator can be provided as a prefabricated product that can be produced industrially in large numbers for a low price. Such rod insulators usually consist of a glass fiber reinforced plastic material, which is protected by a coating for weather protection in the form of, for example, a silicone material from the weather.

Advantageously, the mounting insulator may have a lower mechanical stability than the holding insulator. As a result, the overall arrangement can be produced particularly inexpensively.

A further advantageous embodiment of the invention provides that the first and / or second attachment device connects spark electrode or a surge arrester with the mounting insulator angle stiff.

Due to the rigid connection of the spark electrode or the surge arrester with the mounting insulator, the length of the spark gap is fixed and remains unchanged over a longer period of time. The angle-rigid attachment may comprise a pivoting device, which allows an alignment of the spark electrode or the surge arrester during assembly. After alignment, the pivoting device is fixed, for example by clamping screws and again angle stiff.

A further advantageous embodiment of the invention provides that the Leitungsableiteranordnung has at least two surge arresters.

In addition, the invention can advantageously be configured in that the spark gap is arranged between the two surge arresters.

The two surge arresters are separated by the spark gap. By dividing the function of the Overvoltage arresters on two individual surge arresters can be made shorter and thus subject to a lower bending load.

Each of the surge arresters can then, for example, carry a spark electrode of the spark gap. The respective spark electrode is expediently arranged and fastened in each case to an end fitting of the surge arrester.

Preferably, a surge arrester with a first end is attached to each of the fastening devices angle stiff and at a second end of each surge arrester a spark electrode is arranged in each case. The function of the surge arrester is divided into two preferably similar parts. Each part consists of a surge arrester and a spark electrode attached to it. Each of the two parts is attached to one of the fastening devices. The surge arresters are each fixed at one end to the fastening device with an angle. The spark electrodes are respectively arranged at the other end of the surge arrester and together form the spark gap.

An advantageous embodiment of the invention may provide that at least one spark electrode rod-shaped, arranged at the end of a surge arrester and inclined with respect to its longitudinal axis against the longitudinal axis of the surge arrester.

Here, for example, be provided that the two surge arresters are constructed similar.

Due to the optionally pivotable fastening devices, the two surge arresters, for example, in their angles against each other adjustable, whereby the angular ratio of the rigid-shaped spark electrodes is adjustable and the distance between the spark electrodes to each other. In addition, it may also be advantageously provided that the spark electrode is rotatable about the longitudinal axis of the surge arrester.

If the spark electrodes are rotatable with respect to the longitudinal axis of the respective surge arrester to which they are attached, a spacing adjustment of the two spark electrodes to one another can also follow via a rotation of the spark electrodes.

In the following the invention will be shown by means of embodiments in figures of a drawing and explained below.

Figur 1

eine Seitenansicht eines Strommasten mit einem Abschnitt einer Freileitung und einer erfindungsgemäßen Isolatoranordnung,

Figur 2

einen Ausschnitt aus einer Vorrichtung ähnlich wie in Figur 1, wobei die Gestaltung der Isolatoranordnung gegenüber der Figur 1 verschieden ist und

Figur 3

eine detailliertere Darstellung der Isolatoranordnung, wie sie bei den Konstruktionen der Figuren 1 und 2 Anwendung finden kann.

Showing:

FIG. 1

a side view of a power pole with a portion of an overhead line and an insulator arrangement according to the invention,

FIG. 2

a section of a device similar to in FIG. 1 , wherein the design of the insulator arrangement with respect to FIG. 1 is different and

FIG. 3

a more detailed view of the insulator assembly, as in the constructions of FIGS. 1 and 2 Application can be found.

The FIG. 1 shows in detail an overhead pole 3 with a boom 20, which represents a horizontal arm for supporting an overhead line 2. Such overhead lines 2 are designed, for example, as stranded stranded conductors for conducting electrical energy.

It is common practice to support such overhead lines 2 to the arms 20 of masts 3 by means of holding insulators 4. Such holding insulators 4 are usually made of porcelain or other inorganic material or else made of a material such as glass fiber reinforced plastic, and usually have screens to extend the creepage distance. When using plastics, an outer coating, for example consisting of silicone, is usually provided, which forms the shielding.

The holding insulators 4 must on the one hand carry the weight of the overhead line 2, on the other hand absorb the applied by the bracing of the overhead line forces. Because of this, such holding insulators 4 are generally constructed to be mechanically stable. According to the present invention, a Leitungsableiteranordnung 8 is electrically connected in parallel to the holding insulator 4. Both the holding insulator 4 and the Leitungsableiteranordnung 8 are electrically connected between the overhead line 2 and the mast 3 to the ground. The Leitungsableiteranordnung 8 has the function, in case of overvoltages in the overhead line 2, for example, by lightning strikes, derive the overvoltage that has occurred to the earth. The Leitungsableiteranordnung 8 consists of a mounting insulator 5, a surge arrester 9 and two spark electrodes 6, 7. The holding insulator 4 is connected at a first end to the overhead line 2. The opposing second end of the mounting insulator 5 is connected via a ground cable to the mast 3 or a boom 20 and above ground potential. At the first end of the mounting insulator 5, a spark electrode 6 is fixed. At the second end of the mounting insulator 5, a surge arrester 9 is attached to a second spark electrode 7. The space between the spark electrodes 6, 7 forms the spark gap 11. The mounting insulator 5 thus represents on the one hand an attachment for the spark electrode 6 and the surge arrester 9 and at the same time over its length the distance of the spark electrodes 6 and 7 and thus the length of the spark gap eleventh firmly.

The FIG. 2 further shows an alternative embodiment of the invention, with respect to the FIG. 1 the mast is shown only torn. In contrast to FIG. 1 are here at first and at the second end of the mounting insulator 5 surge arrester 9, 10 with spark electrodes 6, 7 attached.

The FIG. 3 shows a more detailed illustration of the Leitungsableiteranordnung 8 of the FIG. 2 , The mounting insulator 5 is shown here as a long-rod insulator. Such a long-rod insulator has a core made of a glass fiber reinforced plastic, whereupon a protective cover, usually made of silicone, is applied. The protective cover usually has screens for Kriechwegverlängerung. At a first end, the mounting insulator 5 has a fastening device 12. About a arranged on the fastening device 12 holding device 23, the Leitungsableiteranordnung 8 is suspended from the overhead line 2. Both the first fastening device 12 and the second fastening device 13 each have a fastening arm 25, 26. On the mounting arms 25, 26 a surge arrester 9, 10 is attached to one end.

The attachment arms 25, 26 may extend from their mounting point on the mounting insulator 5 on both sides of the mounting insulator 5. On one side of the mounting insulator 5 then the surge arrester 9 or as here two surge arresters 9, 10 are attached. At the opposite end then further components of the Leitungsableiteranordnung 8 may be attached. For example, there, as shown here, arc electrodes 17, 18 may be arranged, which, if a surge arrester 9, 10 is defective, lead the occurring in case of overvoltage arc and keep away from the mounting insulator 5. The distance of the arc electrodes 17, 18 is smaller than the length of the mounting insulator 5 and larger than the spark gap eleventh

One or both ends of the attachment arms 25, 26 may be provided with field control elements. Here are at the surge arresters 9, 10 opposite ends of the mounting arms 25, 26 arranged rounded plates, whereby the voltage spikes are prevented.

At its attachment to the fastening arm 25, 26 opposite end of each surge arrester 9, 10 a spark electrode 6, 7 on. The spark electrodes 6, 7 are spaced from each other. This distance forms the spark gap 11. The surge arrester 9, 10 have an electrically insulating protective housing for protection against weather conditions. Inside the protective housing not shown varistors are arranged here. The two surge arresters 9, 10 are separated from one another via the spark gap 11. The surge arresters 9, 10 are arranged on the mounting arms 25, 26 such that their longitudinal axis 21 is arranged at an angle to the longitudinal axis 30 of the mounting insulator. The angle here is about 45 ° and can be between 30 ° and 60 °. The spark electrodes 6, 7 are each arranged at one end of the surge arrester 9, 10. Its longitudinal axis 22 is inclined relative to the longitudinal axis 21 of the surge arrester 9, 10. Preferably, the spark electrodes 6, 7 are arranged on the surge arrester 9, 10 such that they are rotatable about the longitudinal axis 21 of the respective surge arrester 9, 10. As a result, the distance of the spark electrodes 6, 7 and thus the spark gap 11 can be finely adjusted in their length. The mounting arm 25 is made of an electrically conductive material and provides an electrical connection of the surge arrester via the fastening device 12 and the holding device 23 with the overhead line 2 and thus with the high voltage potential. The second end of the mounting insulator 5 via the second fastening device 13 with the mounting arm 26 fortified surge 9 is connected by means of a ground cable 16 to the mast or a boom 20 with the earth.

Claims (10)

Insulator arrangement (1) for an overhead line (2), comprising a holding insulator (4) for fixing an overhead line (2) to a mast (3) and
a line arrester arrangement (8) arranged electrically parallel to the holding insulator (4) having a surge arrester (9, 10) electrically connected to earth potential and a spark gap (11) connected in series thereto with a first spark electrode (6) connected to the overhead line (2) ) and a second spark electrode (7) connected to the surge arrester (9, 10),
characterized in that the Leitungsableiteranordnung (8) has a on the overhead line (2) attachable mounting insulator (5), wherein the first spark electrode (6) on a first fastening device (12) at a first end of the mounting insulator (5) and the second spark electrode (7) is attached to a second attachment device (13) at a second end of the mounting insulator (5). Insulator arrangement (1) according to claim 1,
characterized in that the mounting insulator (5) is designed as a long-rod insulator. Isolator arrangement (1) according to Claim 1 or 2,
characterized in that the mounting insulator (5) has a lower mechanical stability than the holding insulator (4). Insulator arrangement (1) according to one of the preceding claims,
characterized in that the first and / or second fastening device (12, 13) comprises a spark electrode (6, 7) or a surge arrester (9, 10) with the mounting insulator (5) in an angularly rigid links. Insulator arrangement (1) according to one of the preceding claims,
characterized in that the Leitungsableiteranordnung (8) has at least two surge arresters (9, 10). Isolator arrangement (1) according to Claim 5,
characterized in that at each of the fastening devices (12, 13) in each case a surge arrester (9, 10) with a first end is fixed angle stiff and at a second end of each surge arrester (9, 10) each have a spark electrode (6, 7) is arranged , Insulator arrangement (1) according to Claim 5 or 6, characterized
characterized in that the two surge arresters (9, 10) are constructed similarly. Insulator arrangement (1) according to one of the preceding claims,
characterized in that at least one spark electrode (6, 7) rod-shaped, arranged at the end of a surge arrester (9, 10) and inclined with respect to its longitudinal axis against the longitudinal axis (21) of the surge arrester. Insulator arrangement (1) according to claim 8,
characterized in that the spark electrode (6, 7) is rotatable about the longitudinal axis of the surge arrester (21). Insulator arrangement (1) according to one of the preceding claims,
characterized in that the first and second fastening devices (12, 13) each comprise a fastening arm (25, 26) each extending from a mounting point to both sides of the mounting insulator (5), wherein the surge arrester (9, 10) at one end of a mounting arm (25, 26) and in each case an arc electrode (18, 19) arranged at the surge arrester (9, 10) opposite end of the fastening arms (25, 26) is.

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