DE3426054A1 - Overvoltage suppressor - Google Patents

Abstract

A gas at high pressure, which is produced by means of a plasma in the event of any disturbance of an overvoltage suppressor, is intended to be commutated in such a manner that any risk of accident is considerably reduced and damage to the overvoltage suppressor itself or to shock-sensitive electrical apparatuses which are located in the vicinity of the overvoltage suppressor is prevented or kept to a minimum. In a first variant, the gas is commutated directly into free space at the location of origin, in that the insulating housing (1, 3), which is a composite body having two materials, is locally perforated. In a second variant, the gas is commutated via a pressure relief channel (15) into a pressure relief container (2) which is arranged in the lower part of the overvoltage suppressor. <IMAGE>

Description

OVERVOLTAGE ARRESTER

The invention is based on an electrical surge arrester according to the preamble of claims 1 and 2.

With this generic term, this invention takes on a prior art Reference as described in U.S. Patent 4,100,588.

There varistors are stacked on top of one another inside a hollow porcelain insulator and at least partially embedded in a thermally conductive plastic material, which in turn is in direct thermally conductive contact with the inner wall of the porcelain insulator. The varistor column is shown in the individual embodiments eccentrically arranged in the cavity of the porcelain insulator. This creates the possibility created to arrange a pressure relief channel in the event of a malfunction in the surge arrester the gas pressure created by the plasma without causing damage to the surge arrester from inside the porcelain insulator to be able to commute.

This eccentric arrangement of the varistor column in the cavity of the porcelain insulator but has the consequence that the varistors are only in partial thermally conductive contact stand with the porcelain insulator, and the heat in part via the neighboring, poorly heat-conducting air envelope has to be released to the porcelain insulator.

This ensures the heat transfer from the varistors to the porcelain insulator degraded. Since the heat transfer from the varistors to the insulating housing, both in the stationary operating state of the surge arrester and in its non-stationary operating condition - with overvoltages - mainly in radial Direction occurs, there is a distorted temperature profile in the varistors, which the power loss and the energy absorption capacity in a disadvantageous manner influenced.

In the known surge arrester according to US Pat. No. 4,100,588 the gas pressure at the top and / or due to a possibly forming plasma the lower end of the porcelain insulator commutates to the outside. But this has the disadvantage that, depending on the strength of the plasma, the gas pressure discharge causes damage in the Electrical shock-sensitive apparatus located near the surge arrester can cause.

The invention as defined in claims 1 and 2 solves the problem of specifying an electrical surge arrester with which im Damage occurring in the event of a malfunction can be prevented or reduced.

An advantage of the invention is that the entire active part of the surge arrester, regardless of the nominal voltage in a one-piece Insulating housing can be accommodated. This will help even with a lot stronger Pollution. commutation of leakage currents on the outer surface of the insulating housing prevented to the varistors and thus a voltage maldistribution connected avoided with partial overloading of the surge arrester.

By arranging the varistors centrally within the cavity The insulating housing is used to dissipate heat from the varistors to the insulating housing take place more evenly in the radial direction, which in turn is beneficial whose power loss affects.

In the event of a plasma build-up in the event of a fault within the surge arrester The resulting gas is at the place of the creation of the plasma by a on this place Limited breaking open of the resiliently stable insulating housing commutates into the open.

Another advantage of the invention is to be seen in the fact that the a possibly occurring plasma evoked gas under controlled conditions is commutated from the pressure relief duct into a pressure relief vessel. In order to a risk of accident and damage from in the vicinity of the surge arrester is excluded avoid any shock-sensitive electrical systems.

The advantage according to claim 3 is that a possibly occurring Plasma in the end areas of the surge arrester and the resulting Gas can be fed into the pressure relief vessel under controlled conditions can.

The solution according to claim 4 has the advantage that with the used Materials for the composite body of the insulating housing have a relatively high dimensional stability coupled with high elasticity properties at the same time can be achieved.

The arrangement of a rupture disc between the pressure relief duct prevented in the insulating housing and the pressure relief container according to claim 5 an overflow of any insulating gas from the duct into the container and at the same time enables a pressure equalization between duct and, which can be determined in advance Container due to the pane bursting after a critical pressure has been exceeded.

The arrangement of the pressure relief vessel is essentially below the insulating housing according to claim 6 ensures a relatively high mechanical Stability of the surge arrester by using the container as a foundation can serve for the surge arrester.

The volume of the pressure relief container, which according to claim 7 at least is chosen to be the same size as the internal volume of the insulating housing, ensures that even relatively large amounts of gas can be discharged into the container.

The advantage of claims 8 and 9 is that several varistor columns embedded in the heat-conducting layer within the cavity of the insulating housing are and that in order to save the material forming the heat-conducting layer, cavities arise, which can also serve as pressure relief ducts.

The invention is explained in more detail below with the aid of exemplary embodiments explained: FIG. 1 shows a view of a surge arrester according to the invention in a first embodiment, FIG. 2 shows an enlarged, partial vertical section according to Fig. 1, 3 shows a partial vertical section of an inventive Surge arrester in a second embodiment, and FIG. 4 shows a horizontal section according to Fig. 3.

Fig. 1 shows an overall view of a one-piece according to the invention trained surge arrester. With 1 is the outer part of the insulating housing and designated with 1 'screens on the insulating housing 1. The surge arrester 1, 1 'is arranged on a pressure relief container 2, which is on a foundation 16 supports.

Fig. 2 shows an enlarged, partial vertical section according to Fig. 1. The insulating housing 1, 3 consists in this embodiment of a Composite body made up of two materials, namely a glass fiber reinforced one Plastic pipe 3, which forms the inner part of the insulating housing 1, 3 and from a silicone elastomer 1, 1 ', which covers the outer part of the insulating housing 1, 3 forms. The outer part 1, 1 'of the insulating housing 1, 3 is also tubular formed and has screens 1 'to enlarge the heat radiating surface on. The plastic tube 3 is dimensionally stable, while the silicone elastomer 1, 1 'is elastic and is electrically insulating. As in FIG. 1 and in particular in FIG. 2 on an enlarged scale As can be seen in the illustration, the surge arrester is in a metal flange 7 held, which by means of a screw 8 and nut 9 on the end plate 2 'of the pressure relief container 2 is attached. The varistors 5 are stacked on top of one another and electrically connected to one another by contact disks 6. In the lower part of the Arrester a helical spring 12 is arranged, which extends over a holding plate 13 on a bursting disc 11 supports. The coil spring 12 presses the varistors 5 against each other, so that in every operating state a perfect electrical contacting of the varistors 5 is guaranteed.

In the embodiment according to FIGS. 1 and 2, there is no concern about the total axial height of the surge arrester extending pressure relief duct present between the outer surface of the varistors 5 and the insulating housing 1, 3, since the varistors 5 including the heat-conducting layer 4 cover the entire cross-section of the cavity of the insulating housing 1, 3 fill and embedded in the heat conducting layer 4 rest closely against the inner wall of the insulating housing 1, 3. That in case of a possible plasma formation in the event of a fault within the surge arrester, gas is released at the location of the Creation of the plasma by breaking up the elastically stable one limited to this location Insulating housing commutated to the outside by the gas discharge pressure. The pressure relief vessel 2 is in the embodiment according to FIG.

2 is only intended for the case when there is a plasma in the area of the flange 7 should form. The associated gas pressure becomes the rupture disc 11 break through and the gas will pass through the opening 10 of the end plate 2 'discharged into the pressure relief vessel 2.

3 likewise shows an enlarged, partial vertical section as shown and described in FIG.

The only difference between Fig. 3 and Fig. 2 is that that in the embodiment of the surge arrester according to FIG. 3, the surge arrester is hermetically sealed at its lower end by an end plate 11 ' and that the surge arrester is supported on the foundation 16. On his upper At the end of the surge arrester is also hermetic through a closing plate locked.

However, this upper end plate is not shown in FIG. 3.

In the embodiment according to FIGS. 4 and 5, there are two varistor columns 5A, 5B within the cavity of the insulating housing 1, 3 in the heat-conducting layer 4 embedded.

In order to save the material forming the heat-conducting layer 4 a cavity is created which serves as a pressure relief channel 15. In the event of a malfunction of the surge arrester, the gas formed by a plasma can flow through the Pressure relief channel 15 after breaking through the rupture disc 11 in the pressure relief container 2 are commutated. The pressure relief vessel is only partially shown in FIG. However, its volume is dimensioned in such a way that it also absorbs large amounts of gas be, d. H. it is chosen to be at least the same size as the internal volume of the insulating housing 1, 3.

With the embodiments of the invention shown in FIGS Overvoltage arrester, no gas is commutated in its immediate vicinity, so that a risk of accident as well as destruction or damage to the immediate vicinity of the surge arrester located in shock-sensitive electrical apparatus is definitely excluded.

There can also be more than two varistor columns 5A, 5B within the cavity of the insulating housing 1, 3 be arranged.

Instead of an elastic, dimensionally stable insulating housing, the The embodiment according to FIGS. 4 and 5, of course, also includes a porcelain housing be used. It is then advantageous to use the inner wall of the porcelain housing to cover completely with the heat-conducting layer 4, since then namely in the event of a fault through the Plasma formation locally generated heat not directly can act on the porcelain housing. The heat conducting layer 4 then fulfills the Function of a heat protection shield.

Claims (10)

PATENT CLAIMS Electrical surge arrester with at least a disk-shaped varistor (5), which inside a hollow Insulating housing (1, 3) over its two end faces with end connections is in electrical connection and with a heat conducting layer (4) made of an elastic, thermally conductive material, which at least in sections between the varistor (5) and the inner wall of the insulating housing (1, 3) is arranged, characterized in that that the insulating housing (1, 3) is a composite body, which at least two materials having, an inner part (3) of the insulating housing (1, 3) made of an elastic and dimensionally stable material and an outer part (1) made of an elastic and electrical insulating material that the varistor (5) together with the heat conducting layer (4) the entire cavity of the insulating housing (1, 3) fills that the insulating housing (1, 3) is hermetically sealed at both of its end faces and that the insulating housing (1, 3) is designed in one piece and has several screens 1 'on its outside having. 2. Electrical surge arrester with at least one disc-shaped formed varistor (5), which within a hollow insulating housing (1, 3) Electrical connection via its two end faces with terminals at the ends stands, with a heat-conducting layer (4) made of an elastic, heat-conducting material between the varistor (5) and the inner wall of the insulating housing (1, 3) and with a pressure relief duct (15) which is connected between the at least one varistor (5) and the insulating housing (1, 3) is provided and which is different from a The end of the varistor (5) extends to its other end, characterized in that that the pressure relief channel (15) at at least one end of the insulating housing (1, 3) opens into a pressure relief container (2) and that the insulating housing (1, 3) is formed in one piece and has several screens on its outside. 3. Surge arrester according to claim 1, characterized in that that at least one end of the insulating housing (1, 3) has a pressure relief container (2) is connected. 4. Surge arrester according to claim 1, characterized in that that the inner part (3) of the insulating housing (1, 3) made of a plastic tube, in particular from a glass fiber reinforced plastic tube, and that the outer part (1) of the Insulating housing (1, 3) made of an elastic plastic coating, in particular made of a silicone elastomer. 5. Surge arrester according to claim 2, characterized in that that between the pressure relief channel (15) of the insulating housing (1, 3) and the Pressure relief container (2) at least one bursting disc (11) is arranged. 6. Surge arrester according to claim 2, characterized in that that the pressure relief vessel (2) is essentially below the insulating housing (1, 3) is arranged. 7. Surge arrester according to one of claims 2 to 4, characterized characterized in that the volume of the pressure relief container (2) is at least equal is chosen as large as the internal volume of the insulating housing (1, 3). 8. Surge arrester according to claim 1, characterized in that that within the insulating housing (1, 3) at least two varistor columns (5A, 5B) are arranged. 9. Surge arrester according to claim 2 to 7, characterized in that that within the insulating housing (1, 3) at least two varistor columns (5A, 5B) are arranged and that the pressure relief duct (15) extends in sections from the varistor jacket surface extends to the heat-conducting layer (4). 10. surge arrester, characterized in that the insulating housing made of porcelain and on the inner wall completely with the heat conducting layer (4) is covered.