DE3123552A1 - "Zinc oxide varistor with an insulating coating" - Google Patents

Description

description

The invention relates to zinc oxide varistors, in particular those for use in surge arresters ^ those in yasi-insulated Substations are used.

In U.S. Patents 2,936,703, 3,767,973 and 3,842,318, the Use of surge arresters in gas-insulated substations described, wherein the surge arresters are surrounded by a grounded metal housing.

The surge arrester housing is in some substations in connection with the lines of the substation, so that the insulating SFg gas in direct Contact with the zinc oxide varistors inside the surge arrester housing got.

As stated in JA-PS 957 072, one influences non-oxidizing environment, such as SFg gas or transformer mineral oil, the thermal stability of zinc oxide varistors disadvantageous. According to this JA-PS, chemical effects on the surface of the zinc oxide edge are supposed to be oxygen from the edge and so a decrease in resistance cause which leads to an increase in the varistor current flowing to earth. It will be in this YES- ' PS proposed an oxygen-containing gas in one Amount of 10 to 30% by volume of the surge arrester to add.

It has since been found that the non-oxidizing ends isolating environments used in substation surge arresters diffuse through the porous ceramic coating that is on the edge of the zinc oxide varistors is applied to prevent electrical flashover. The used iso-

Lying liquids and gases quickly diffuse through the porous ceramic coating and cause the chemical Reaction described in the aforementioned JA-PS.

Varistor disks with an insulating ceramic coating, in which the low stability has occurred, as evidenced by high watt losses under more stringent test conditions showed were removed from the test and treated in the following manner:

The ceramic coatings were carefully removed from the periphery of the disks _; and several layers of zinc oxide material were further removed from the edge of each varistor. Then the varistors were provided with a new layer of ceramic material on the edge and subjected to the stability tests again. The watt losses occurring in the varistors were as low as for the varistor disks used initially, but increased within less than 100 hours to such an extent that the disks could no longer be used as varistors.

The present invention was based on the object of creating new zinc oxide varistors which, when used in non-oxidizing Atmospheres remain stable.

This object is achieved according to the invention in that on the outer circumference or edge of the varistor disks Zinc oxide impermeable insulating coatings are applied, which protect the edge from deterioration Protect stability that would otherwise occur when the varistor disks are in a non-oxidizing atmosphere to be used. One embodiment of such an insulating The coating comprises a low temperature glass made of several oxides including copper oxide. Another embodiment for the insulating coating comprises relatively high temperature resistant gas impermeable organic coatings on.

In the following the invention with reference to the Drawing explained in more detail. Show in detail:

FIG. 1 is a front view, in partial section, of a surge arrester within a gas-insulated metal container, in which the invention Varistors with the gas-impermeable insulating collar are used,

FIG. 2 shows a perspective top view of a varistor for use in the surge arrester according to Figure 1,

Figure 3 is a graph of the watt loss of a varistor as a function of time (square root from the time in hours) and

FIG. 4 is a side sectional view of the varistor of FIG. 2 within an SF atmosphere.

FIG. 1 shows a surge arrester 10 with a porcelain housing 11 within a metal container 12 which is filled _{with an insulating gas, such as SF g.} The surge arrester 10 has a plurality of gapless zinc oxide varistor disks which are arranged in a stack, each individual varistor being electrically connected in series with the other varistors in the stack. The electrical energy is supplied by means of a line 14 which is arranged within a tube 9 which also contains the SF _fi gas. The porcelain housing 11 is usually in connection with the metal container 12, so that the SF. - 'gas in the porcelain housing 11 is in equilibrium with the SF _g gas in the metal container 12.

In Figure 2, a varistor 13 is shown, which consists of a zinc oxide disc 8, has a metal electrode layer 14 on each of the opposing surfaces and is surrounded on its outer circumference by a collar or coating 15 made of a gas-impermeable material. A suitable one A material with the required impermeability to gas is a glass that melts at a low temperature U.S. Patent 3,959,543. Other possible gas impermeable materials include organic polymers such as alkyd resins, obtained from polyhydric alcohol and phthalic anhydride, e.g. B. under the name "Glyptal" of from the General Electric Company and polyamide-imide-based wire enamel as described in U.S. Patents 3,661,852 and 3,862,092.

The stability of a zinc oxide varistor disk is defined in the following application as the rate of change the watt loss of the varistor as a function of time when a certain voltage is applied to the varistor will. In order to accelerate the increase in watt loss over time, the varistors are generally set at about 115 ° C, as the varistor stability increases with Temperature decreases rapidly. Has a stable varistor disk therefore, even after an operation of several 100 hours at a temperature of 115 ° C, a watt loss that is essentially is equal to the initial watt loss.

Figure 3 shows the relationship between watt loss and that of time for several zinc oxide varistor disks, the two had different insulation coatings and were exposed to two different atmospheres. Varistors with a Ceramic collars tested in an SFg atmosphere are shown at A. For comparison purposes, at B are the Results shown from an equal number of zinc oxide varistors with ceramic coatings, but using an air atmosphere were exposed. The big difference in sta-

bility between these two types of varistors with Ceramic coatings make the adverse effect of the SF,

'O

Atmosphere on the varistor stability.

Varistors according to the present invention with a gas impermeable Collars made of glass are applied at C and you can see their very good stability.

Varistors according to the aforementioned JA-PS, according to which the gas-containing Space 10 to 30% by volume of an oxygen-containing Containing gas should also be stable. While the use of an oxygen-containing gas also increases stable varistors should lead, is the use of an oxygen-containing gas within a substation that is insulated with SFg gas is not entirely feasible, as oxygen affects the insulating properties of the gas can.

Also the use of other non-oxidizing gases, such as Argon and nitrogen cause zinc oxide varistors with a ceramic collar become unstable after a few hours of operation. It was also found that the varistors with ceramic collars become unstable when mineral oil or silicone fluids are used as an isolating agent will. For example, varistors with ceramic collars in mineral oil showed Watt losses that increased in a manner similar to that for the varistors of curve A in Figure 3 in 'SF, -Gas der Case is. On the other hand, varistors with a collar made of polyamideimide wire enamel should be used when testing in mineral oil or SF, have a watt loss increase similar to the varistors with a glass collar that were tested in SF (see curve C in Figure 3), since the polyamide-imide is also impermeable is.

FIG. 4 shows an enlarged cross section of the zinc oxide varistor 13 within an SF, atmosphere, where a

Overlap pad 18 between the upper and lower electrodes is indicated along the collar 15.

Used in some applications where electrical equipment needs to be both cooled and insulated a halogenated, such as chlorinated or fluorinated, hydrocarbon to serve both purposes. Zinc oxide varistors with an insulating ceramic collar should behave in such an atmosphere similar to the varistors in curve A in Figure 3 for an SF atmosphere. It is not currently fully understood why using mineral oil and other non-oxidizing liquids and gases instability occurs. The addition of 10 to 30% by volume of an oxygen-containing gas is not possible with oil or chlorinated and fluorinated hydrocarbons, which are usually liquids, as gas pockets can form and damage the insulated electrical equipment.

Varistors with an insulating collar made of a gas-impermeable Glass, as used for curve C in Figure 3, show very good stability when one a i ei accelerated stability tests in an atmosphere of mineral oil, SF ,, N., or argon. It is believed that these varistors also operate under an atmosphere chlorinated or fluorinated hydrocarbon are stable.

While the reason why zinc oxide varistors operated in a non-oxidizing atmosphere become unstable, is not yet fully understood, it has been found that the instability is near the magnitude of the Varistor disk occurs, which is covered by the collar 15 if this collar is not impermeable to the gas flow is.

Varistor disks that were unstable when tested in SF, such as

they are shown at A in Figure 3 have been taken out of the test

and removed, their ceramic collars and the thick layers of zinc oxide material from the circumference of the panes were removed by sandblasting and the panes again provided with a fresh collar made of ceramic insulation. When the test was resumed in SF ₆ , these disks also again showed the behavior indicated in curve A in FIG. 3, ie the watt loss increased over time in the SF 1 environment

strong too. It is believed that the operation of zinc oxide varistors in a non-oxidizing atmosphere to a reduction of some zinc oxide near the edge of the Varistor leads, with a lower oxidation state arises, which is more conductive.

It is also currently not possible to determine the exact mechanism by which the proposed insulation coating protects the zinc from reacting with the non-oxidizing atmosphere. One possible explanation would be the transport of oxygen ions from the insulating coating to the edge of the varistor disk in order to replenish the zinc oxide or other metal oxides that become unstable due to the loss of oxygen atoms. This would be ¹ gases, such as SF ,, improves the stability of the zinc oxide varistors in accordance with the tehre according to the above JA-PS, followed by the addition of a considerable amount of oxygen or a gas containing oxygen to non-oxidizing · dielectric.

Another possible explanation for the · instability of the Zinc Oxide Varistors That A Non-Oxidizing Atmosphere is a possible chemical reaction between the atmosphere and the zinc oxide surface. A possible chemical reaction would be the partial reduction of the outer zinc oxide material to a more conductive state. The more conductive state increases the wattage

lust of the varistor and caused the instability by thermal runaway. The application of organic insulation material that is stable at high temperatures and impermeable to gas prevents the interaction between the zinc oxide and the non-oxidizing atmosphere. the end Coatings produced by polyamide-imide wire enamel, as described in the two above-mentioned US patents, should also lead to zinc oxide varistor panes with good stability if they are used in non-oxidizing atmospheres, operate. However, it is not known of such organic wire enamels which are stable at high temperature they supply oxygen ions, as is the case with oxide-containing glasses: The coating from the organic Wire enamel therefore only appears to form a barrier between the non-oxidizing atmosphere and the zinc oxide. Other organic materials such as high temperature resistant epoxies and silicones were found to be ineffective in improving the stability of zinc oxide vari-stors, if you used them as an insulating collar and the appropriately insulated varistors in non-oxidizing ones Atmospheres tested. The epoxy material even led to instability when viewed as an insulating collar used in an oxidizing atmosphere.

Except for gas-insulated surge arresters in substations The varistors according to the invention can of course be used wherever a non-oxidizing atmosphere is present.

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L e r s e i t e

Claims (1)

Claims .). Zinc oxide varistor for use in non-oxidizing atmospheres with a sintered body of a plurality of metal oxides, which consist mainly of zinc oxide, each with a metal electrode layer on each of the opposing surfaces and an insulating coating on the periphery of the Sintered body, characterized by 'that the coating is impermeable to gas and consists of an organic polymer or an oxide-containing glass. ■ 2. Varistor according to claim 1, characterized in that that the organic polymer is selected from alkyd resins and polyamide-imides. 3. Varistor according to claim 1, characterized that the glass comprises the oxides of lead, zinc, boron, silicon and copper. .4. Varistor according to Claim 1, 2 or 3, mounted in a surge arrester with a housing made of an insulating Material, the housing containing several varistors, one of which each composed of a disk-shaped sintered body mainly made of zinc oxide, which has a pair of metal electrodes has on the opposite surfaces and an insulating coating on the periphery of the disc, the insulating coating consists of a gas-impermeable layer made of an organic polymer and that Housing a lot of non-oxidizing material. electrically isolating the varistors. 5. Surge arrester according to claim 4, characterized characterized in that the non-oxidizing material is selected from SF, and N-. 6. Surge arrester according to claim 4, characterized characterized in that the non-oxidizing Material is selected from mineral oil, silicone fluid and a halogenated hydrocarbon. 7. Surge arrester according to claim 4, 5 or 6, characterized in that the case is made of porcelain.