NO117137B - - Google Patents

Description

Device for extinguishing electric arcs,

especially in electrical switches.

For interrupting electric arcs with great effect

the arrangement of the extinguishing chamber and the extinguishing agent used are of the greatest importance. •«

Here, it is irrelevant whether the arc is extinguished by means of magnetic blowing, an externally supplied pressurized gas or by means of an extinguishing agent flow produced by the arc itself, and air is used as extinguishing agent,

gas in any form, carbonated ice or a liquid.

An electronegative gas, e.g. sulfur hexafluoride (SF,,) , selenium hexafluoride (SeF6) or trifluoromethylsulphur pentafluoride (CF-jSF,.) , then extinguishing the arc can be made much easier with a very simple extinguishing chamber.

When using an electronegative gas as an extinguishing agent, however, it is necessary to close or seal the extinguishing chamber completely pressure-proof, so that the previously or previously introduced electronegative gas does not escape and therefore has to be kept in stock continuously.

Such an extinguishing chamber requires a very solid and

expensive construction and continuous monitoring of the electronegative gas contained in the extinguishing chamber and kept in storage"

Here, a device must be described which entails

that it is not necessary to keep the electronegative gas continuously stored in a completely closed or sealed extinguishing chamber, but the electronegative gas is first released

made by the arc itself during the extinguishing process, to then serve to extinguish the arc"

A more detailed description of such a device to which the invention is directed and the new and distinctive features of this device can be found in the patent claims.

The drawing shows two embodiments of the invention. Fig»1 shows a simple extinguishing chamber by which the movable contact pin leaves the extinguishing chamber. Fig. 2 shows a completely closed extinguishing chamber, with the arrangement of a special extinguishing point formed by electrodes.

In fig. 1, a fixed contact 2 and a movable contact 3 are arranged in the extinguishing chamber 1. The extinguishing chamber is divided into rooms 4 and 5 by means of the transverse wall 6. The fixed contact 2

is electrically connected to a tubular electrode 7 which expands in the downward direction. This electrode 7 consists of a compound or combination of metallic elements and non-metallic elements containing electronegative gases, which non-metallic elements e.g. can be fluorine, sulphur, selenium, etc., which serve to form the electronegative sulfur fluorides, such as sulfur hexafluoride, sulfur pentafluoride, selenium hexafluoride, etc.

In the connection or combination of the metallic and non-metallic elements, a metallic material is preferably used which is resistant to the effects of the electric arc. The tip 8 of the switch pin 3 also consists of such a connection or combination of metallic and non-metallic elements in order to achieve the release of the electronegative gases immediately upon separation of the contacts. In the transverse wall 6, in the opening between the rooms 4 and 5, a ring electrode 9 is arranged which is also made of a compound of metallic and non-metallic elements.

The current flows through the connection piece 10

over the fixed contact 2 to the switch pin 3.

The way the arc extinguishing works is as follows Ved

opening of the switch, the switch pin 3 is moved downwards and an arc is drawn between the contact pin 8 and the electrode 7, which

a pressure rise in the extinguishing chamber works. As both the contact tip 8 and the electrode 7 are made of metallic elements and non-metal"

ical elements that contain electronegative gases, the electronegative gases are split off or released due to the heat of the arc and mix with the extinguishing agent already present in the room 4„ With the continued movement of the switch pin 3, the arc is carried along with its end point on the electrode 7, whereby

the arc is drawn further through the extended tubular electric

trode 7 and the pressure increase in room 4 as well as the development of the electronegative gases continue. The switch pin now comes with its tip 8 into the opening in the cross wall 6 and thus into the ring electrode 9, so that at this stage the arc burns between the electrode 7, the ring electrode 9 and the switch pin tip 8. During the arc's burning time, the electronegative gases are released as well from the switch pin—the tip 8 as from the electrodes 7 and 9, so that the room 4 which is exposed to a pressure rise has been completely filled with electronegative gases, respectively these gases have been mixed with the extinguishing agent already present.

When the switch pin 3 steps out of the chamber 4, the pressurized electronegative gases flow into the chamber 5, and the light

arc burning in the ring electrode 9 is exposed to an effective flow of the electronegative gases and is extinguished.

The switch pin 3 can now completely leave the extinguishing

chamber 1, so that room 5 is also opened and all the electro-negative gas under pressure in extinguishing chamber 1 flows out. If the extinguishing of the arc does not occur within rooms 4 and 5, then

the arc is under the influence of the current in the two openings i

. the cross wall 6 and in the extinguishing chamber wall. By means of this double pressure extinguishing agent flow with electronegative gases occurs

it an absolutbg forced extinguishment.

However, it is appropriate to let the switch pin remain in the extinguishing chamber 1, as the developed electronegative gas is thereby not lost and is available for further arc extinguishing. The volume of the room 5 is chosen so large that, during the extinguishing process, an effective flow is produced by pressure equalization between the rooms 4 and 5 through the opening arranged in the transverse wall 6. In the room 5, devices can be inserted to remove or eliminate the components of the electronegative gases that have been split or decomposed due to the arc—the heat. In order to always have pure sulfur fluoride stored in the extinguishing chamber, this can be filled before it is put into operation or taken into use, whereby, however, the unconditional requirement for a tight and pressure-fixed extinguishing chamber is not fulfilled, as the electronegative gases are produced each time anew during the extinguishing process. For utilization of the available electrode surfaces for producing the electronegative gases, devices can be used by means of which the end point of the arc runs through the entire surface and does not remain at one point. For example can in the present embodiment example according to fig. 1 is provided for one. such influence of the light*-» arc that burns between the switch pin tip 8 and the electrode 7 by means of magnetic fields, that the end point of the burning arc which is on the electrode 7, runs around radially.

Without changing anything about the invention, the contacts, electrodes, etc., which emit electronegative gases, can be used in all devices and appliances, which serve to extinguish electric arcs. Connection or combination of the metal with other elements that emit gas can also be carried out, when these elements are favorable for the arc extinguishing.

In fig. 2, the extinguishing chamber 11 is divided into rooms 13 and 14 by means of the transverse wall 12. In room 13, in addition to the

fixed contact 15 and the switch pin 16, arranged a special disconnection point parallel to these, which consists of the hollow electrode 17 and the pin electrode 18. The pin electrode 18 is electrically connected to the tubular electrode 19 which expands in the downward direction, and to the fixed contact 15. The electrode 19 has such a shape that the arc drawn by the switch pin tip 20 is drawn first along the left surface of this electrode 19, and then is transferred to the pin electrode 18. In the transverse wall 12, an opening is arranged which accommodates the hollow electrode 21 and in which the switch pin 16 is displaced. Above the hollow electrode 17, there is a room 22 which is in open connection with the room 13 through the hollow electrode 17. The rooms 13 and 22 are dimensioned in such a way that a pressure

leveling during the extinguishing process and consequently an effective extinguishing agent—current.

Electrodes 17, 18, 19 and 21 as well as the tip of the switch pin

20 consists of a compound or combination of metallic elements - and non-metallic elements that emit electronegative gases.

The action of the arc extinguishing in this case is

as follows: When the switch pin 16 is moved, an arc is drawn between the switch pin tip 20 and the electrode 19, which causes a pressure increase in the space 13. Due to the shape of the electrode 19, the end point of the arc follows the switch pin 16 on the left side of the electrode 19, and becomes thus extended. As both the switch pin tip and the electrode 19 consist of a material that emits electronegative gases, these gases are released due to the heat of the arc and mix with the extinguishing agent that is already in the extinguishing chamber during a simultaneous increase in pressure. When the switch pin tip 20 comes close to the pin electrode 18, the arc jumps onto the electrodes 17 and 18 and continues to burn between the electrodes 17 and 18 as well as the switch pin tip 20. Due to the produced pressure rise due to the electronegative gases and the outflow through the hollow electrode 17, the arc is located soon in an effective extinguishing agent flow and can be extinguished after a short time. If the extinguishing of the arc is not completed, then the arc burns with the continued movement of the switch pin with a further increase in pressure and the production of electronegative gases, on the electrode 21. When the switch pin 16 steps out of the chamber 13, a pressure equalization now also takes place between the chambers 13 and 14 , so that the arc is extinguished by means of the double extinguishing agent flow. The switch pin 16 can then continue to keep the extinguishing chamber closed in its end position.

With the help of the described device, it is achieved

that the burning arc on the electrodes, contacts and other parts, during its burning time without interruption splits off electronegative gases from these parts, which gases on the one hand mix with and complete the gas volume that surrounds the arc, and on

the other side is directly used for pressurized extinguishing agent flow and for extinguishing the arc.

The connection, respectively the alloy between the metallic elements and the non-metallic elements which give off electro-negative gases can take place by means of fusion and casting, by sintering of powder mixtures, cleavage of compounds, etc. This connection or combination can also be produced by layer-by-layer placement and composition of the metallic elements and the non-metallic elements that emit electronegative gases.

In figures 3 - 7, for example, the electrodes in figures 1 and 2 - by which the metallic elements and the non-metallic elements that emit electronegative gases are combined or composed in one body - by layered arrangement and composition, of the metallic and the non-metallic elements emitting electronegative gases, united or combined in a body in two parts.

In Figures 3 and 4, the electrodes are 8, respectively 20,

for placing the non-metallic elements emitting electro-negative gases formed with the slot 23 and the bore 24 which is filled with the non-metallic elements 25 for emitting the electro-negative gases. *

In fig. 5, the electrode 7 in fig. 1 presented as a body consisting of two types of parts or substances. For this purpose, the electrode 7 is composed of metallic discs 26 and of non-metallic elements 27 which are held together by means of pins 28 and 29. The discs can also be held together by means of an adhesive.

In fig. 6 is the electrode 9, respectively 21 in the figures

1 and 2 made as a body consisting of two types of parts or substances. For this purpose, the slits 30 are filled with non-metallic elements 31 which emit the electro-negative gases.

In fig. 7, the electrode 18 in fig. 2 shown as a body consisting of two types of parts or substances. In this regard, be-

stands the electrode of the plates 32 and 33 which are held together by means of staples or an adhesive. While the plates 32 consist of metallic elements, the plates 33 are made of non-metallic elements* which emit electronegative gases.

The operation of these electrodes in which the metallic and the non-metallic elements emitting electronegative gases are combined by a layered assembly and composition is the same as in such electrodes in which the metallic and non-metallic elements are combined by casting together etc. The base of the arc also burns here immediately between the composite metallic<p>and non-metallic elements so that the electronegative gases produced directly affect the arc column and cause the arc to be extinguished.

Without changing anything about the invention, one can also in such devices where e.g. an arc occurs when a wire is melted, use the described arrangement of metallic elements and non-metallic elements to extinguish the arc. The melting wire then also consists of a compound of metallic elements and non-metallic elements that emit electronegative gases, where melting of the metallic conductor due to an overcurrent or the like, an arc appears, so that due to the heat of the arc, electronegative gases are released which then act as an extinguishing agent for the arc. Such a fusible wire can also be surrounded by a layer of non-metallic elements that emit electronegative gases.

Claims (7)

1. Device for extinguishing electric arcs, especially in electric switches in whose extinguishing chamber non-metallic substances are arranged which, due to the heat of the arc, give off electro-negative gases, e.g. sulfur hexafluoride, selenium hexafluoride or trifluoromethylsulfur pentafluoride, characterized in that the non-metallic substances are enclosed or embedded in the metallic substances in the electrodes which serve as the base for the arc. 2. Device according to claim 1, characterized in that the non-metallic substances, in addition to fluorine, also contain sulfur or selenium. 3. Device according to claim 1, characterized in that metallic substances with large cohesive forces are used, especially tungsten and molybdenum. 4. Device according to claim 1, characterized in that the electrodes are designed in a manner known per se so that the base points of the arc travel over large surfaces. 5. Device according to claim 1, characterized in that the combination or union of metallic and non-metallic substances in the electrode is achieved by fusion, compression or by sintering of powder mixtures" , 6. Device according to claim 1, characterized in that the combination or union of the metallic and non-metallic substances is achieved by layered construction or packing. 7. Device according to claim 1 used as fusible link, characterized in that the fusible wire consists of metallic substances and non-metallic substances which form electro-negative gases.