DE1254229B - Surge arrester for maximum voltage - Google Patents

Description

Surge arrester for extra high voltage The invention relates to on a surge arrester for extra high voltage, in which the same elements become one Columns are stacked, each element being one of two equal parts Has composite housing, the spark gaps and / or voltage-dependent Contains resistors.

Most known surge arresters consist of a spark gap, which is in series with a so-called "non-linear" resistor, its value the greater the voltage on its terminals, the smaller it becomes. Such surge conductors are generally in the form of a column of a stack of blocks of variable Resistance across which a certain number of spark gaps connected in series formed spark gap block lies. The number of resistor blocks and the parameters the spark gap depend on the operating voltage. If this is very high (e.g. B. 300 kV between line and earth), the surge arrester cannot be used in a single column, as this is an apparatus with a ratio to its diameter too great height would arise, what it besides the manufacturing difficulties sensitive and bulky.

Surge arresters are already available to avoid this disadvantage known, in which the resistances and the spark gaps are partly ring-shaped and are partly cylindrical. The cylindrical members are inside of the annular members arranged, and the circuit runs alternately across the cylindrical and the annular members. This can reduce the overall height but there is the disadvantage that two different forms of resistors and spark gaps must be used. Furthermore, the links must be inserted the corresponding insulating parts and connecting conductors individually nested on top of one another will. The production is therefore relatively expensive.

The use of variously shaped links is known in others Surge arresters avoided in which the resistors and the spark gaps are housed in insulating housings, which are composed of two identical parts are. Each part consists of two adjacent cylindrical cavities, one of which is twice the height of the other. When assembled, the two lower cavities of two parts joined together, so that three cavities arise that lie on the corners of an equilateral triangle. Every cavity contains a column of stacked spark gaps and resistors. Even However, the assembly of these surge arresters is relatively complicated, and when stacking several insulating housings, the correct mutual Location must be carefully observed.

In contrast, the aim of the invention is a surge arrester which the two-part housing can be assembled easily and quickly and the arrangements formed in this way without observing special regulations simply in any number can be stacked on top of each other.

According to the invention this is achieved in that each housing consists of two flat shells, each of which has an opening that each a metal disk is inserted between two consecutive housings and that in each housing side by side an odd number of blocks, at least a block made of a material with voltage-dependent resistance and at least one Spark gap block arranged and below and above the shell openings with the two adjacent metal plates are connected in series.

In the surge arrester designed according to the invention not whole stacks of spark gaps and resistors in the insulating housing used, but the stacking takes place in that there is always a metal plate, a shell with the corresponding odd number (for example three) blocks another Bowl and again one: metal plate can be stacked on top of each other in any number.

Another major advantage of the executed according to the invention surge arrester is the very even distribution of voltage along the Stacks from the elements. It is therefore particularly suitable for extremely high voltages. The even voltage distribution is based on the fact that the insulating housing of the individual Elements have a very low overall height and that between two such housings each has a metal plate. This creates an axially symmetric distribution of the electric field along the column.

The invention is described below by way of example with reference to the drawing explained. In it, F i g. 1 is a view of an element of the invention Surge arrester in the disassembled state, F i g. 2 the element of FIG. 1 in assembled state and F i g. 3 a sectional view of a surge arrester, which consists of elements according to FIG. 1 and 2 is composed.

The in Fig. 1 element of a surge arrester according to the invention contains two shells 1 and 2 made of insulating material, a metal plate 3 with a thickening 4 and three holes 5 arranged on its periphery, two cylindrical blocks 6 and 7 made of a material whose resistance depends on the two of them voltage applied to parallel sides is variable, a spark gap block 8, the z. B. is formed from embedded in an insulating, series-connected elements, two contact members 9 and 10 and springs 11, 12 and 13. These different parts are assembled as indicated by the dash-dotted lines.

The spark gap block 8 can have any known design. It is provided with electrodes 14 at each end. The contact member 10 has small tabs 15 for fastening the springs 12 and 13.

The shell 1 contains an opening 16 for receiving the spark gap block 8 and two recesses 17 and 18 for receiving the resistor blocks 6 and 7, respectively.

At the bottom of these depressions, pins 19 and 20 are provided, onto which the springs 12 and 13, respectively, are pushed, which were previously attached to the contact member 10 electrically connecting the blocks 6 and 7.

The shell 2 is provided with an opening 21 for receiving the block 6, which lies on the thickening 4 of the plate 3, whereby an electrical contact is made between this plate and the block. The shell 2 also has two recesses 22 and 23 for receiving the spark gap block 8 and the resistor block 7, respectively. At the base of the recess 22 , a pin 24 holds the spring 11, while the part 26 of the contact member 9, which is designed in the form of a hollow cover, engages via an elevation 25 provided on the base of the recess 23. The electrical circuit of the surge arrester element described above runs as follows: The plate 3 is in contact with the underside of the resistor block 6 through its thickening 4. The member 10 electrically connects the upper surfaces of the resistor blocks 6 and 7. Further, the lower electrode of the resistor block 7 and the lower electrode of the spark gap block 8 are connected through the member 9, and the upper electrode of the block 8 protrudes from the shell 1 . The springs 11, 12 and 13 produce the required contact pressure.

The shells 1 and 2 have semi-cylindrical grooves 27 on their circumference for assembly by means of the means shown in FIG. 2 visible insulating rods 28 which go through the holes 5 in the plate 3. The electrical terminals of the surge arrester element formed in this way are formed by the plate 3 and the electrode 14 of the spark gap block 8 . If an identical element is placed on this element, its base plate corresponding to the plate 3 lies against the electrode 14, whereby contact is established with the latter. To form the entire surge arrester, it is sufficient to stack the number of elements corresponding to the operating voltage on top of one another. F i g. 3 shows a longitudinal section of such a surge arrester, only the top and bottom elements being shown.

The surge arrester is contained in a cylindrical hollow insulator 29, at the ends of which cylindrical sleeves 31 and 32 are fastened by means of a cementing material 30. The sleeve 32 is soldered to another sleeve 33 which is attached to a base plate 34 supporting the apparatus. The insulator 29 is closed at its ends by end plates 35 and 36 with an elastic seal 37 interposed.

The upper end plate 35 is soldered to the socket 31 , while the lower end plate 36 is attached to the socket 32 by bolts 38.

The individual elements of the surge arrester, which are made up of the elements shown in FIG. 1, there are parts arranged between the shells 1 and 2, are pushed onto the three rods 28 made of insulating material. Each of these rods is provided at its ends with threaded parts 39 and 40 , which are cemented into the insulating material and serve to fasten the plates 41 and 42 , between which the stack of elements of the surge arrester is clamped.

The lower end plate 36 contains three cylindrical cups 43, the inner wall of which is covered with a ring 44 made of elastic material. This ring surrounds a sleeve 45 in which a cylindrical part 46 can slide, which is screwed to the part 40 and serves to fasten the plate 42 to the rods 28.

The entire surge arrester rests on the sleeves 45 via a stack of plate springs 47. The upper end plate 35 carries a cup 48 which is lined with an elastic material 49 on the inside. This surrounds a sleeve 50 in which a cylindrical part 51 attached to the plate 41 slides. The bottom of the sleeve 50 is also covered with an elastic material 52.

One which is supported on the end plate 35 and surrounds the cup 48 Spring 53 pushes the entire surge arrester across the plate 41 together. This spring is bridged by flexible foils 54, the one Short-circuit the spring forming the choke coil.

The fasteners described above take any impacts on which on the surge arrester during its transport and its installation can act.

The terminals of the surge arrester are through the end plates 34 and 35 formed. The interior of the sealed by the training described Isolator 29 is filled with nitrogen.

Claims (2)

Claims: 1. Surge arrester for extra high voltage, in which the same elements are stacked to form a column, each element having a housing composed of two identical parts containing spark gaps and / or voltage-dependent resistors, characterized in that each housing consists of two flat Shells (1, 2), each of which has an opening (16, 21) , that a metal disk (3) is inserted between two consecutive housings and that an odd number of blocks, namely at least one block, is placed next to each other in each housing made of a material with a voltage-dependent resistor (6, 7) and at least one spark gap block (8), arranged and connected in series with the two adjacent metal plates (3) below and via the shell openings (16, 21). 2. Surge arrester according to claim 1, characterized in that the openings (16,21) of the two shells forming the housing (1, 2) are arranged at two corners of an equilateral triangle and that the housing contains three blocks, the third block on the third corner of the equilateral triangle is arranged. 3. Surge arrester according to claim 2, characterized in that the first block (6) is a resistance block and is in contact with the lower metal plate (3) via the opening (21) provided in the lower shell (2) of the housing, that the The top of this resistor block (6) is electrically connected to the top of a second resistor block (7) (at 10), that the bottom of the second resistor block (7 ) is electrically connected to the bottom of a spark gap block (8) (at 9) and that the The upper electrode (14) of the spark gap block (8) is in contact with the upper metal plate via the opening (16) made in the upper insulating shell (1). Considered publications: German patent specifications No. 931 539, 935 619: Swiss patent specification No. 315 021.