EP1301935B1 - Arc extinguisher with an attachment for low voltage switchgear - Google Patents

Description

The invention relates to an arc quenching device for an air-switching low-voltage switching device with a universally usable, variable attachment for adapting the arc extinguishing chamber to increased requirements.

Low-voltage circuit breakers operating in air require an arc extinguishing device to operate to extinguish any arcing faults without affecting the circuit-breaker itself and adjacent equipment or other components, otherwise there is a risk that the hot and hence ionized arc gases will cause electrical flashovers, Injure operators or cause other damage.

In the conventional arc extinguishing devices for low-voltage circuit breaker two fundamentally different designs are known. In the case of large circuit breakers, complete conventional extinguishing chambers, that is to say a sturdy arc-resistant, pressure-resistant and heat-resistant housing with extinguishing plates located therein and a suitable blow-out device, have been conventionally placed on the circuit breaker. As a rule, a quenching chamber per pole is provided. This chamber has a complete housing which has a strength which is adequate to both the mechanical and the electrical forces of the arc to be extinguished therein, in particular with respect to the pressure and the temperature of the switching gases. In this chamber are the quenching plates. The chamber can be designed as a pot-like shaft, in which the sheets are inserted, or as a construction of half shells in which a device is needed to insert the sheets only in a half-shell, then put on the second half-shell and ultimately connect both.

Fire extinguishing chamber inserts are used as the second design, in which only the function of the actual arc quenching in one unit can be achieved. However, these structures are unable to withstand the pressure associated with the arc. Therefore, these inserts are inserted into a slot provided in or on the switch housing. This design has been mainly used in small molded case circuit breakers, but is increasingly used in larger circuit breakers application, where the housing these rooms, ie the control room and the extinguishing room, clothe.

In these modern low-voltage circuit breakers, the arc extinguishing chambers are integrated into the housing of the switch. The extinguishing chambers thus do not form an object protruding beyond the contour of the switch. Although they are still separate objects for large circuit-breakers, they are included in the overall design in such a way that they are flush with the housing contours and only the outlet openings are visible. The parts are accessible and can be taken out, for example, to inspect the contacts underneath. Optionally, the entire extinguishing chamber can also be replaced.

For certain designs, even larger low-voltage circuit breakers, which are under the American name ICCB (insulated case circuit breaker) are known, such a construction has already been selected in which prefabricated splitter plate packages are inserted into the switch housing. However, this results in a secondary problem. With the insertion of the splitter stack, the arc quenching device as a whole is not complete, because ultimately the switching gases must leave the switch and exit into the open, without causing damage.

In the classic circuit breakers are provided in the housing outlet openings that are part of the housing, for example, a perforated wall in the housing or inserted into a receiving opening of the housing wire grid. This is necessary because the switching gases have not yet cooled enough after passing through the splitter stack to let them escape to the outside. The gas is hot and ionized, which can lead to flashovers to grounded parts or between busbars. Also, the hot switching gases may carry sparks and may endanger or injure operators. Consequently, further cooling is essential. Therefore, further chamber essays have been created. So show the DE-OS 35 41 514 and 44 10 108 , but on

Conventional arc extinguishing chambers, which are completely independent structure with housing bodies and arranged therein quenching plates, placed on the extinguishing chambers damping devices for further cooling of the penetrated through the quenching plates to be hot switching gases, said in the DE-OS 44 10 108 proposed damping device is designed as an insulating patched chamber lid and the DE-OS 35 41 514 shows a solution in which the article contains a number of perforated inserts, which are held by means of a cover member, which is penetrated by fasteners. This essay is constructive and production moderate and affects only partially the properties.

An intended damping insert also requires a certain pressure behavior. The gases must escape unhindered from the splitter plate space and then be collected in a temporary storage space, from which they can finally escape cooled into the open.

There are cases where even this solution is insufficient. In the EP-PS 0437151 B1 a multi-pole low-voltage circuit breaker is shown in an equipped with a double cooling device for the quenching gas insulating housing, which is divided by Isolierstoffteilwände in several internal compartments, each associated with one of the poles. In this case, each switching pole is assigned a splitter stack for deionization of the arc drawn during the separation of the contacts, and an outlet opening for the switching gases which is equipped with a first gas cooling device. These outlet openings then open into a common for all switch poles further

Chamber, which has a second cooling device, after the passage through the switching gases are discharged through gas discharge openings in the surrounding medium. The still very hot and still strongly ionized gases meet in front of the second cooling device to each other, which can lead to disadvantages. All these solutions have no to only a single arc-extinguishing chamber itself belonging to damping and blow-out and thus represent both in terms of material, as well as with respect to the installation amount a relatively high cost. They also do not allow the use uncomplicated material-saving extinguishing chamber constructions, because they do not sufficiently damp and cool the escaping switching gases. In addition, they do not effectively prevent hot, ionized switching gases from entering areas of the switchgear where they can cause damage. In known circuit breakers, therefore, either the voltage range is limited or, as described, additional parts such as chimneys or attachments with deionizing media are used. This can be when an increased short-circuit breaking capacity is required or a higher rated voltage, or a higher short-circuit current, because this usually means that the quenching chamber must receive a larger volume, because these parameters affect the formation of the quenching chamber, for Example on the number of quenching plates, on the length of the distance that the arc can run on the quenching plates, on the type of insulation, damping or deionization at the exit of the quenching chamber and other features.

However, the said chimneys or essays are always designed only for a special case and neither universally usable, expandable, variable or interchangeable.

The object of the invention is therefore to provide an arc quenching device with a universally applicable today according to the kit design, variable essay can be adapted to the increased requirements with the arc extinguishing chambers without corresponding extinguishing chambers must be specially constructed.

This object is achieved according to the present invention by an arc quenching device with a top for low-voltage switchgear, in which the essay as chimney-like arc extinguishing chamber extension is formed to increase the volume of the arc extinguishing chamber and a molding having a lower contour which is exactly equal to the contour of the arc extinguishing chamber normally located on the arc extinguishing chamber cover and whose upper contour is formed identical to the upper contour of the housing for receiving the arc extinguishing chamber cover is. Thus, the arc quenching chamber is used without the standard lid, and instead of the lid, a former is first applied as an extension of the arc quenching chamber to which the arc quenching chamber lid is now placed. One or more further fittings may be previously provided before the arc quenching chamber lid is placed as a conclusion. A fitting causes an increase in the chamber volume by a certain additional volume.

Due to the design of the lower contour of the fitting identical to the contour of the arc extinguishing chamber cover and the formation of the upper contour of the fitting identical to the upper contour of the housing for receiving the arc extinguishing chamber cover stacking any number of fittings is possible and it can thus a technical requirements corresponding increase in volume the arc extinguishing chamber can be achieved by a multiple of the additional volume and by simple stacking of fittings. Thus, an increase in the switching capacity can be effected in a simple manner.

The material of the fitting is suitably identical to the material of the arc quenching chamber cover.

Due to the special contours of housing, attachment and arc extinguishing chamber cover, gas-tight labyrinths are produced, which cause a safe phase separation even in the event of a short circuit.

The essay or the essays are fastened with a correspondingly long screw at the identical attachment point as the arc extinguishing chamber cover and have, as described above, the cover-typical insertion Verrastmechanismus for mechanical coupling between the switch housing and the arc extinguishing chamber cover. Suitably, the essays sentencewise have different heights, so that the enlargement of the arc extinguishing chamber can be gradually adjusted to the requirements.

Die Fig. 1

zeigt einen Niederspannungs-Leistungsschalter, bei dem das Bedienpult und die Antriebsteile weggelassen sind, in perspektivischer Ansicht, von der Vorderseite des Schalters gesehen.

Die Fig. 2

zeigt einen erfindungsgemäßen Aufsatz in perspektivischer Darstellung, von der Seite der Befestigungsschraube gesehen.

Die Fig. 3

zeigt den gleichen Aufsatz in perspektivischer Ansicht von der entgegengesetzten Seite gesehen.

The invention will be explained in the following for better understanding with reference to a preferred, non-limiting scope of the invention embodiment.

Fig. 1

shows a low-voltage circuit breaker in which the control panel and the drive parts are omitted, in perspective view, seen from the front of the switch.

FIG. 2

shows an attachment according to the invention in a perspective view, seen from the side of the fastening screw.

FIG. 3

shows the same essay in perspective view seen from the opposite side.

Fig. 1 shows a low-voltage circuit breaker 1 with foot plates 2, in which the control panel and the drive parts are omitted as essential for a better overview for the description of the invention. It's just the threaded bushings 3 to see the necessary for fixing the same fixing screws and the passage openings 4 for the shift linkage of the three switching poles. In order to make the essence of the invention clear, two extinguishing chambers are shown in the normal state, that is, there are only with the top 5 of the low-voltage circuit breaker 1 flush extinguishing chamber cover 6; 7 to see.

On the third arc extinguishing chamber, an attachment 8 according to the invention with an extinguishing chamber cover 9 is arranged. The attachment is designed as an arc extinguishing chamber extension for increasing the volume of the extinguishing chamber and constitutes a fitting 10 which, with its lower contour 16, fits exactly into the contour of the receptacle of the arc extinguishing chamber cover normally located on the arc extinguishing chamber. The upper contour of the fitting 10 is identical to the upper contour of the housing for receiving the arc quenching chamber cover 6; 7; 9 trained. On the arc extinguishing chamber so instead of the arc quenching chamber cover 6; 7; 9 first placed a fitting 10 as an extension of the arc extinguishing chamber and this now the arc extinguishing chamber cover 6; 7; 9. It may also be provided before yet another fitting 10 or more further fittings, which are then covered with the arc extinguishing chamber cover 9. The attachment 10, or the articles 10, are fastened with a correspondingly long screw at the identical attachment point 11 as the arc quenching chamber cover.

Figs. 2 and 3 show an attachment 8 according to the invention in a perspective view, seen from different sides. The article 8 is as a fitting 10 with a front wall 12, a rear wall 13, a first side wall 14 and a second side wall 15 is formed. He has a lower contour 16, which is exactly equal to the contour of the arc extinguishing chamber normally located on the arc extinguishing chamber cover 6; 7; 9 is and its upper contour 17 identical to the upper contour of the switch housing for normal reception of the arc quenching chamber cover 6; 7; 9 is formed. in the rear wall 13, a recess 18 is provided, through which the fastening screw is guided, whose length is selected according to the number of attachments 8 used.

The article 8 has, as described above, the lid-typical slide-latching mechanism for mechanical coupling between the switch housing and the arc extinguishing chamber cover 6; 7; 9, shown here by a groove 19 on the upper side 20 and an engaging in this groove engaging projection 21 on the underside 22 of the attachment 8.

After applying an attachment 8 on the switch housing or an existing further attachment 8, the arrangement is fixed by a guided through the recess 18 mounting screw and the special contours of housing, essay and arc extinguishing chamber cover gas labyrinths are generated, which also in short circuit a safe Cause phase separation. It can be stacked in this way, the modular design essays 8 in any number.

The invention provides an arc quenching device with a universally usable according to today's kit idea, variable attachment to create, can be adapted to the increased requirements with the arc extinguishing chambers without having to design extra fire extinguishers.

LIST OF REFERENCE NUMBERS

1

1 low-voltage circuit breaker

2

toeboard

3

threaded bushings

4

Port

5

top

6

Quenching chamber cover

7

Quenching chamber cover

8th

attachment

9

Quenching chamber cover

10

fitting

11

attachment point

12

front wall

13

rear wall

14

First sidewall

15

Second side wall

16

Lower contour

17

Upper contour

18

indentation

19

groove

20

top

21

head Start

22

Lower side

Claims (7)

1. Arc quenching device for a low-voltage switching device which switches in air and having a universally usable, variable attachment for matching the arc quenching chamber to more stringent requirements,
   characterized
   in that the attachment (8) is in the form of a chimney-like arc quenching chamber extension in order to increase the volume of the arc quenching chamber, and represents a molding (10) which has a lower contour (16) which is precisely the same as the contour of the arc quenching chamber cover (6; 7; 9) which is normally located on the arc quenching chamber, and whose upper contour (17) is identical to the upper contour of the switch enclosure in order to accommodate the arc quenching chamber cover (6; 7; 9).
2. Arc quenching device according to claim 1,
   characterized
   in that any desired number of moldings (10) can be stacked by virtue of the shape of their lower and upper contours (16; 17).
3. Arc quenching device according to claim 1, characterized
   in that the material of the molding (10) is identical to the material of the arc quenching chamber cover (6; 7; 9).
4. Arc quenching device according to claim 1,
   characterized
   in that the matched contours of the switch enclosure, attachment (8) and arc quenching chamber cover (6; 7; 9) form labyrinths which provide a seal for the switching gases, and provide safe phase isolation in the event of short circuits.
5. Arc quenching device according to claim 1,
   characterized
   in that the upper and lower contours (16; 17) of the attachment (8) are identical to the insertion/matching mechanism, which is typical for such covers, for mechanical coupling between the switch enclosure and the arc quenching chamber cover.
6. Arc quenching device according to claim 1,
   characterized
   in that the attachment (8) or the attachments (8) is or are attached by means of a screw of appropriate length to the identical attachment point (11) as the arc quenching chamber covers (6; 7; 9).
7. Arc quenching device according to claim 1,
   characterized
   in that the attachment (8) can have different heights, for matching to the requirements for enlarging the arc quenching chamber.

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