NO125020B - - Google Patents

Description

Device for arc extinguishing, in particular

electrical switches.

"The invention relates to a device

for arc extinguishing, especially electric switches, where the arc extinguishing electrodes or such parts consist of metallic and non-metallic substances, which mitigate the impact of the arc's heat and emit electro-negative or reaction-slow gases.

There are already known devices for arc extinguishing, in particular electric switches, where the electrodes or similar parts, over which the arc burns, consist of a composition of metallic and non-metallic elements such as fluorine, sulfur and other suitable chemical compounds, so that due to of

the heat of the interruption arc from the electrodes is given off reaction products in the gas phase or plasma phase, as through reaction

the products are formed arc extinguishing compounds such as SFg etc.

Bite the electrodes hair on one side,

due to the metallic elements, a very good electrical conductivity, on the other hand, it is achieved due to the non-metallic parts present, that a certain quantity of reactants is emitted through the arc bases burning at the metallic elements sion's product is , which forms arc extinguishing compounds, such as SFg, in the plasma phase or the gas phase.

These arc extinguishing connections produced through the arc base points are located directly in the arc axis and. at the same time also surrounds the arc column.

Due to this direct effect of the arc extinguishing compounds, the arc electrons are already captured at the electrodes and brought together with neutral molecules. The resulting negative ions have the same speed as the positive ions and are therefore very easily recombined with them to form neutral molecules.

Because of this recombination between the electrically charged particles that make up the current flow, the current-carrying capacity of the arc is reduced, while at the same time the speed of building up a voltage resistance between the electrodes after the arc is extinguished is increased.

The operation of these electrodes fulfills in every respect the conditions for arc extinguishing.

It has now been shown that the current carrying capacity of the arc during the extinguishing process, and thus the current to be interrupted, can be lowered even more if the electrodes . consists of a composition of metallic substances and a non-metallic substance, such as e.g. silicon dioxide (SiO^), so that with certain constructive devices and electrical conditions, an arc extinguishment follows.

The gases produced due to the arc at these electrodes have the same properties as air and are therefore not favorable for an extinguishing agent flow for arc extinguishing. The speed of building up a voltage resistance between the electrodes is therefore very small after the arc is extinguished, so that flashback ignitions can easily occur.

In order to improve the operation of the electrodes for producing electronegative gases by lowering the current during the extinguishing process, the invention proposes a device where the arc-extinguishing electrodes or such parts consist of metallic and non-metallic substances, which under the influence of the arc heat emit electronegative or slow-reacting gases, which device according to the invention is characterized by the fact that, in addition to the substances that emit electronegative or reaction-slow gases, further non-metallic and inorganic substances with a high melting point are added, such as e.g. silicon dioxide (S102), which itself does not emit any volatile arc extinguishing gases.

It is appropriate that an electrode consisting of metallic parts and silicon dioxide is arranged in the electrode consisting of -metallic and non-metallic parts. You can also use two opposite electrodes to let one electrode serve to generate reaction products and form arc extinguishing compounds (SFg etc.), while the other electrode consists of metallic parts and silicon dioxide. In the case of an extinguishing chamber with two consecutively connected interruption points, the electrode pair of one interruption point advantageously serves to produce reaction products, with the help of which the arc-extinguishing compounds (SFg etc.) are formed, while the other electrode pair consists of a composition of metallic substances and e.g. . silicon dioxide. A binder such as e.g. epoxy resin.

The drawing shows three examples of the implementation of the invention.

Fig. 1 shows an extinguishing chamber with electrodes consisting of a composition of metallic and non-metallic substances, where arc-extinguishing compounds are formed by means of the reaction products, the composition having been added to a further non-metallic substance, such as e.g. silicon dioxide.

In fig. 2, only the electrodes with a connecting pin are produced, as both in the electrodes which consist of metallic and non-metallic parts, the reaction products of which form arc-extinguishing compounds, which are also inserted in the connecting pin, side electrodes made of a composition of metallic substances and e.g. silicon dioxide.

Fig. 3 shows an extinguishing chamber with two successive disconnection points, consisting of an electrode pair for producing arc-extinguishing compounds and an electrode pair, which consists of a composition of metallic elements and silicon dioxide or the like.

In fig. 1, in an extinguishing chamber 1, the disconnecting point is formed by means of the fixed contacts 2, 3 and the connecting pin 4 - Parallel to this disconnecting point, the fixed electrodes 5 and 6 are arranged, which are electrically connected to the connecting parts 8, 9 and 10. The hollow electrode 5 serves as an outflow opening. The coupling pin 4 has an electrode tip 11, by means of which the extracted arc is led over to the electrodes 5°g 6.

The electrodes 5>6 and the connecting dust tip 11 consist of a composition of metallic and non-metallic substances for the formation of arc extinguishing compounds and silicon dioxide or a similarly acting substance, which serves for current reduction and arc extinguishing.

The quantity proportion of these three elements - metallic and non-metallic substances for producing arc extinguishing compounds and silicon dioxide or the like - is determined for the composition of a solid electrode so that a good electrical conductivity is achieved (specific resistance less than 0.15 /~Ohm ~'~ J) and that during the extinguishing process with the help of the arc-extinguishing points, on the one hand, a sufficiently large amount of arc-extinguishing compounds is secreted, while on the other hand, however, the current flowing through is reduced due to the action of the silicon dioxide .

These three substances are advantageously mixed in powder form and combined into a fixed electrode by compression or molding.

In order to achieve the correct electrode conditions, it is necessary to combine the three elements with a specific grain size into a cohesive mass, so that the conditions for electrical conductivity and for the quenching process can be met.

The way the arc extinguishing works is as follows: When the switch is opened, an arc is drawn by means of the switch pin 4 between the tip of the connecting pin 11 and the electrode 5* As these electrodes 5°g H consist of a composition of the substances described above, arc extinguishing compounds are produced, and the current flowing through is reduced due to the silicon dioxide present in the electrodes.

At a certain length and produced pressure increase, the arc jumps over to the electrode 6, in order there under the same conditions to produce arc extinguishing compounds, respectively electronegative gases, whereby due to the effect of the silicon dioxide, the current reduction is maintained.

Due to the extinguishing agent flowing out under pressure, or the electronegative gas, whereby the arc burns at the electrode 5) and due to the achieved current reduction due to the effect of the silicon dioxide, the arc extinguishing takes place under very favorable conditions.

An outflow of the extinguishing agent, or the electronegative gas, can take place in a special room, so that the extinguishing chamber is completely closed and the produced electronegative gas is available for further arc extinguishing.

Instead of silicon dioxide, you can also use another substance, such as e.g. aluminum oxide, with the same properties for arc extinguishing..

In Fig. 2, the electrodes are designed in two stages, with special side electrodes 15, 16 and 17 arranged in the electrode bodies 12, 13 and 14.

The electrode bodies 12, 13 and. 14 serves

for producing the arc extinguishing compounds, respectively the electronegative gases, qg consists of a composition of metallic and non-metallic parts, so that due to the arc heat is given off reaction products, which form the arc extinguishing compounds. The side electrodes 15, 16 and 17 serve during the extinguishing process for current reduction and consist of a composition of metallic parts and silicon dioxide or the like..'

Appropriately becomes. the side electrodes 15 and 16 and 17, which consist of metallic parts and silicon dioxide and a binder, such as e.g. epoxy resin, produced by a special process, by compression or molding by a be-

set temperature. These finished side electrodes are then pressed together into an electrode by means of compression with the powdered mixture of metallic and non-metallic substances for the formation of arc extinguishing compounds, as can be seen from fig. 2.

It is an advantage if the electrical conductivity of the side electrodes 15, 16 and 17 is greater than that of the electrodes 12, 13 and 14 which emit the arc-quenching compositions or the electronegative gases. It is thereby achieved that the arc foot point burns on the side electrodes 15, 16 and 17, as these are, however, surrounded by electrodes 12, 13 and 14 with a greater proportion. of non-metallic parts for emitting arc-extinguishing compounds or electronegative gas, then a large quantity of these extinguishing agents is produced.

One can also, instead of the side electrodes 15, 16 and 17, place the electrode 12 without side electrode 15 above the counter electrode 16. In this case, the electrode 12 serves to produce arc extinguishing connections, or electronegative gas and the electrode 16 to reduce the current.

In fig. 3, in the extinguishing chamber 20 there are arranged two interruption points lying in series, which are formed by the fixed contacts 21, 22 and the connection pins 23, 24 - Parallel to these two interruption points are arranged the fixed electrodes 25, 26 and.27, 28, which is in electrical connection with the coupling pins 23, 24 by means of the towing contacts 29, JO.

The hollow electrodes 25, 27, which are in electrical connection with the supply lines 31, 32, also serve as an outflow opening. The coupling pin tips 33»34 consist of the same material as the electrodes 25126 and 27", 28 respectively.

The two disconnection points arranged in the extinguishing chamber 20 are spatially separated by means of the wall 35, so that each disconnection point is independent of the other.

The electrodes 27, 28 and 33 consist of a composition of metallic and non-metallic substances, so that at this point of interruption due to the arc, only arc extinguishing compounds, respectively electronegative gases, are produced. The electrodes 25, 26 and 34 consist of a composition of metallic substances and silicon dioxide or the like, and serve mainly for current reduction, as the gases produced mainly have the same properties as air and therefore only under certain circumstances serve for arc extinguishing.

The operation of the switch is as follows.

Due to the division of the two disconnection points, arcs are drawn with the help of the two connecting pins 23, 24 and the fixed contacts 21, 22, the base points of which burn on the connecting pin tips 33, 34 and the electrodes 25, 27-

Each of these two arcs produces a pressure rise in its chamber.

With the help of the arc that burns over the electrodes 34, 25, a current reduction is carried out, as these electrodes consist of a composition of metallic elements and

silicon dioxide. With the help of the arc between the electrodes 33, 27, arc-extinguishing compounds, respectively electronegative gases, are produced, as these electrodes consist of a composition of metallic and non-metallic substances, whereby the desired arc-extinguishing compounds are emitted.

During the continuation over the coupling pins 23, 24, the arc base points are led to the electrodes 26, 28, so that the arcs now continue to burn between the electrodes 27% 28 and 25, 26 under the same operating conditions.

Due to the outflow of the pressurized arc extinguishing compounds, respectively the electro-negative gases, the arc extinguishing is achieved very easily, as under certain circumstances the gas flow produced by the arc at the electrodes 24, 25 also contributes.

Without changing anything about the invention, the described electrodes or contacts can be used for all devices and appliances (fuses, surge arresters, etc.)" where an electric arc is to be extinguished.

One can also, for devices for extinguishing electric arcs, use electrodes or other parts for drawing electric arcs, which consist of a composition of metallic substances and silicon dioxide or a similar product.

The electrodes or the arcing parts can also be used in coupling devices where no extinguishing agent flow is used, so that the extinguishing of the arc only takes place by burning the arc base point in the mass of the electrode, respectively the arcing parts.

The metallic parts and the non-metallic parts of the new electrodes can be united with each other by compression under higher pressure. Preferably, however, a hardenable synthetic resin is used as a binder, e.g. a phenolic resin, urea resin, melamine resin or especially an epoxy resin. As epoxy resin, the known types come into play, such as e.g. poly-glyoidyl ether of the polyphenol, such as bisphenol A. For the curing of epoxy resins, the usual curing classes, such as polycarbonic anhydrides or preferably aromatic, aliphatic or cycloaliphatic polymers, serve.

Examples of electrode manufacturing:

30 parts by weight of quartz flour, 44.0 parts by weight of nickel powder, 10 parts by weight of a mixture of 6 parts by weight of polytetrafluoroethylene powder ("TEFLON") and 1 part by weight of sulfur powder are well mixed with an impregnation resin mixture, consisting of 14.5 weight-

parts of a mixture of 85 parts by weight of a by condensation of epi-chlorohydrin..with bis(p-hydroxyphenyl)dimethylmethane in the presence of alkali prepared, at room temperature liquid epoxy resin with an epoxide-

content of 5>0 - 5j5 epoxide equivalents/kg and 15 parts by weight of 1,4-butanediol diglycidyl ether, 50 parts by weight of triethylenetetramine, 50 parts by weight of

parts of 2,2-bis(4<*->amino-cyclohexyl)propane and 10 parts by weight of bis(p-hydroxylphenyl)dimethylmethane, the moist mass thus obtained pressed into an electrode mold, the binder appeared hardened within 15 minutes at" 140°C, and then after cooling removed from the mold.

This manufacturing example can be

varied as follows::

- Quartz flour (silicon dioxide) is replaced with aluminum oxide or pumice stone

- Polytetrafluoroethylene powder is replaced with calcium fluoride

- Sulfur is replaced with preferably twice the amount of ferric ammonium

sulfate

- Polytetrafluoroethylene powder and sulfur are replaced with calcium fluoride and preferably twice the amount of iron ammonium sulfate

- Quartz flour, polytetrafluoroethylene powder and sulfur are replaced with

step by step the double amount of calcium fluoride and ferric ammonium sulphate

- Quartz flour is replaced with aluminum oxide and sulfur and polytetrafluoroethylene powder with calcium fluoride

- Quartz flour and sulfur are replaced with barium sulphate and iron ammonium sulphate

- Quartz flour is replaced with dolomite powder ("MIKRODOL") and sulfur is

replaced with ferric ammonium sulphate

- The nickel proportion is increased to 60 to 65 parts by weight and quartz flour, polytetrafluoroethylene powder and sulfur are replaced with calcium fluoride.

The particulate substances must have

an average grain size of approx. 2 to 5/u*

Claims (5)

1. Device for arc extinguishing, in particular electric switches, where the arc-extinguishing electrodes or such parts consist of metallic and non-metallic substances, which under the influence of the arc heat emit electronegative or reaction-slow gases, characterized in that, in addition to the substances that emit electronegative or reaction-slow gases moreover, additional non-metallic and inorganic substances with a high melting point are added, such as e.g. silicon dioxide (SiO^ ), which itself does not emit any volatile arc extinguishing gases. 2. Device according to claim 1, characterized in that the metallic and non-metallic substances are united into a solid electrode body by means of a hardened plastic material, such as e.g. epoxy resin. 3. Device according to claims 1 and 2, characterized in that an electrode consisting of metallic substances and silicon dioxide is arranged in the electrode which consists of metallic substances and non-metallic substances emitting electronegative or reaction-slow gases. ill. Device according to claim 1, characterized in that with two electrodes facing each other, one electrode serves to emit electronegative or slow-reacting gases, while the other electrode consists of metallic substances and silicon dioxide (SiO2). 5. Device according to claim 1, characterized in that in the case of two disconnection points connected one after the other, the electrodes at one disconnection point serve to emit electronegative or slow-reacting gases, while the other disconnection point's electrodes, which consist of metallic substances and silicon dioxide (SiO2 ) , serves to reduce the conducted current.