EP0037364A1 - Surge arrester with a column of surge elements and screening bodies - Google Patents

Abstract

A surge arrester (1) comprises an active part (3) which consists of a number of shielding bodies (6) and arrester elements (10) attached to them. The shielding bodies (6) have a fastening device on their inner circumference, e.g. a circumferential recess (7) for electrical and mechanical connection to the arrester elements. The shielding bodies (6) are also connected to one another by insulating support bodies or conductive support bodies (13). In the case of a star or cross-shaped arrangement of the arrester elements, conductive or insulating connecting bodies can also be provided in the center. The arrangement is particularly suitable for the construction of surge arresters for gas-insulated, metal-enclosed high-voltage switchgear in conjunction with voltage-dependent resistors based on zinc oxide. In addition, the active part can be installed outdoors without a housing. In addition to zinc oxide resistors, resistors based on other non-linear materials can also be used.

Description

• a) einer in dem Gehäuse angeordneten, aus einer Vielzahl von Ableiterelementen gebildeten Säule und
• b) mehreren die Säule umschließenden Abschirmkörpern.

The invention relates to a surge arrester

• a) a column arranged in the housing and formed from a plurality of conductor elements and
• b) several shielding bodies surrounding the column.

A surge arrester with these features has become known, for example, from DE-AS 20 37 921. The shielding bodies have the task of ensuring a uniform distribution of the voltage over the arrester elements connected in series. The desired operation of the surge arrester can be ensured in this way even if the surge arrester has a grounded metal housing, as is used in connection with pressurized gas-insulated, metal-enclosed switchgear.

The arrangement of the arrester elements mentioned, which in particular includes voltage-dependent resistors and spark gaps, in a column has been tried and tested in surge arresters for a long time because it enables the desired series connection without additional switching or connecting elements. However, this arrangement leads to an extraordinary height of the surge arrester, if this for very high operating voltages, for. B. 500 kV or more to be executed. To reduce the overall height, it is already known to distribute the arrester elements over several parallel columns and for this purpose scaffolding or tier-like constructions apply (CH-PS 304 299 and 303 429 and US-PS ₂₉ 46 920). However, these arrangements are not suitable for metal-encapsulated surge arresters, because the effort for the equalization of the voltage distribution becomes too great and the gain in space is partly consumed by the means for the voltage distribution. In any case, simple shielding bodies such as the one-column arrangement cannot be used.

The invention has for its object to provide a surge arrester for high and very high operating voltages that is equally suitable for installation in metal encapsulations or for outdoor use, which, with a low overall height, manages with simple means for controlling the voltage distribution and has a greater energy absorption capacity.

• c) die Abschirmkörper untereinander durch Stützkörper verbunden sind und daß
• d) die Abschirmkörper eine Einrichtung zur Befestigung von Ableiterelementen besitzen.

According to the invention, this object is achieved in a surge arrester of the type mentioned in that

• c) the shielding bodies are interconnected by supporting bodies and that
• d) the shielding body has a device for fastening arrester elements.

The basic idea of the invention is therefore to use a number of shielding bodies as carriers for arrester elements instead of using a column of arrester elements as carriers for shielding bodies.

The space utilization can be increased further by arranging several arrester elements in series and / or parallel connection in the space enclosed by each shielding body. A mechanically stable arrangement can be achieved so that the shield have a circumferential recess on their inner circumference, in which clamping pieces can be anchored. For example, sliding nuts can be used as clamping pieces, into which the arrester elements are screwed with a threaded bolt.

A parallel connection of arrester elements can also extend over several levels. In particular, at least two adjacent shielding bodies can be conductively connected to one another and the arrester elements attached to them can thereby be connected in parallel. Thus, using uniform parts, surge arresters can be manufactured with the desired values for the leakage current and the quenching voltage with increased energy absorption capacity.

Several arrester elements can be accommodated in the space enclosed by a shielding body, in particular in a cruciform or star-shaped arrangement; it is advisable to provide a connecting body in the center of this arrangement, which can be connected to the connecting bodies of adjacent groups of arrester elements. The connecting bodies can be conductive or insulating, depending on the way in which the leakage current is to flow through the overall arrangement.

A column formed of similar shielding bodies and arrester elements arranged in the interior thereof can be provided with shielding bodies of larger diameter at both ends. These improve the field pattern at the ends of the arrester arrangement and can at the same time be used for fastening within an enclosing housing or as a ground-side base or voltage connection for installation without a housing.

The invention is explained in more detail below with reference to the exemplary embodiments shown in the figure. Fig. 1 shows a metal-encapsulated surge arrester in section.

2 and 3, two embodiments of surge arresters for outdoor installation without a housing are shown in view.

The surge arrester 1 comprises a metal housing 2, which can be closed gas-tight and an insulating gas, for. B. SF ₆ contains. The active part of the arrester, designated as a whole by 3, is connected by means of a bushing 4 to the live parts of the system to be protected. An earth connection 5 is located at the opposite end of the cylindrical housing 2.

The active part 3 comprises a number of annular shielding bodies 6 which have a groove-like depression 7 on their inner circumference. It can also be a slot if the shielding bodies 6 are made of sheet metal as hollow bodies. The groove 7 creates the possibility of attaching conductor elements 1-0 at any point on the inner circumference of the shielding body 6 by means of suitable clamping pieces, slide nuts or similar parts. In the example shown, four arrester elements 10 are provided in a cross-shaped arrangement in the space enclosed by each shielding body 6. These four arrester elements are electrically connected in parallel with a conductive connection to the shielding bodies 6 and to a common central connecting body 11. Each individual arrester element 10 can be a voltage-dependent resistor, a spark gap, a series connection of such elements or an element used to control the voltage distribution. Which elements are selected or combined depends on which voltages and currents the surge arrester should be able to handle. With regard to a compact design of the Über Voltage arresters for high and very high operating voltages, it is advisable to use those based on zinc oxide as voltage-dependent resistors. Of course, resistors based on silicon carbide or other non-linear materials can also be used.

As shown in FIG. 1, at each connection point of a conductor element 10 with a shielding body 6, an insulating support body 12 is arranged on one side and a conductive support body 13 on the other side. The next group of arrester elements 10 with their associated shielding body 6 rests on these. If one selects conductive and insulating supporting bodies alternately from level to level, and in alternating succession, conductive connections are made between each two middle connecting bodies 11, one obtains one alternately from the outside current path running inwards and outwards through the entire surge arrester. As can easily be seen, a smaller or larger number of arrester elements than four can also be accommodated per level.

At the lower end of the arrangement shown there is a further shielding body 14 with a larger diameter in order to homogenize the edge field. A similar larger shielding body 14 is located at the upper end of the active part 3. The entire active part, as shown in FIG. 1, is fastened and centered in the metal housing 2 by the bushing 4 and the insulating supports 15. Instead of a metal housing, an insulating material housing can also be used if the arrester is intended for outdoor installation.

As is known per se in surge arresters in an encapsulated version, the housing or the Encapsulation should be provided with a crushing membrane which prevents the housing or the encapsulation from being subjected to excessive pressure when the active part of the surge arrester is overloaded. In this case, the interior spaces of the shielding bodies, if these are designed as hollow bodies, can be used as collecting or buffer spaces for the gases that occur in the event of an overload if the connection with the arrester elements is suitable. These then do not directly stress the housing or the encapsulation and can be derived from them at a desired location.

The surge arrester 20 according to FIG. 2 is designed without a housing. Its structure corresponds to the structure of the active part explained with reference to FIG. 1. A number of ring-shaped shielding bodies 21 are thus provided, to which a larger shielding body 23 is connected in the direction of the voltage connection 22 and also a larger shielding body 25 in the direction of the earth connection 24. Between the lower final shielding body 25 and the ground connection 24, a monitoring device 26, for. B. a response counter inserted.

Two of the shielding bodies 21 are shown partially in section in FIG. 2 in order to make the arrester elements visible. As can be seen, each shielding body 21 has a similar arrangement as in FIG. 1, arrester elements 27. Likewise, by alternately inserting conductive and insulating support bodies 30 and 31 and conductive and insulating connecting bodies 32 and 33 for a flow direction that changes from level to level Electricity is taken care of, as indicated by the arrows.

The surge arrester 35 according to FIG. 3 differs from the surge arrester 20 in 2 in that in each case two adjacent shielding bodies 36 are directly adjacent to one another and are therefore arranged in a conductive connection or are combined to form a shielding body. In this way, the arrester elements 37 enclosed by them are connected in parallel. With a total of six shielding bodies 36, this results in three groups of arrester elements connected in parallel, which are then connected in series in the same way as was explained above. This arrangement with partial parallel connection is advantageous if higher leakage currents or energy values are to be mastered.

The number of shielding bodies shown in the figures is selected only for the purpose of clear presentation. In their actual design, the surge arresters can therefore have a smaller or larger number of shielding bodies. Furthermore, the circular ring shape of the shielding body is chosen only as an expedient example. Therefore, if it turns out to be favorable for the accommodation of the arrester elements, other shapes, e.g. B. rectangular or square shielding body with rounded shape can be selected.

Claims (6)

1. Surge arrester with a) a column arranged in the housing and formed from a plurality of conductor elements and b) several shielding bodies surrounding the column, characterized in that c) the shielding bodies (6) are connected to one another by supporting bodies (12, 13) and that d) the shielding body (6) has a device (7) for fastening arrester elements (10). 2. Surge arrester according to claim 1, characterized in that a plurality of arrester elements (10) are arranged in series and / or parallel connection in the space enclosed by each shielding body (6). 3. Surge arrester according to claim 2, characterized in that at least two adjacent shielding rings (36) are conductively connected to one another and thereby the arrester elements attached to them are connected in parallel. 4. Surge arrester according to claim 1, characterized in that the shielding bodies have a circumferential recess (7) on their inner circumference, in which clamping pieces or the like can be anchored. 5. Surge arrester according to claim 1, characterized in that with a cross or star-shaped arrangement of a group of arrester elements (10) in the center, a connecting body (11) is arranged which can be connected to the connecting bodies (11) of adjacent groups of arrester elements (10) . 6. Surge arrester according to claim 1, characterized in that a column formed of the same type of shielding bodies (6) and in the interior arranged arrester elements (10) column is provided at both ends with shielding bodies (14) of larger diameter.

Images