DE102010019432A1 - Double-breaking circuit breaker for monitoring a circuit - Google Patents

Abstract

The invention relates to a double-interrupting protective switching device (1) for monitoring a circuit, comprising a coil (2) for beaar, comprising a first fixed switching contact (3) and a first movable switching contact (4), a second pair of switching contacts, comprising a second fixed switching contact (12) and a second movable switch contact (13), the movable switch contacts (4, 13) being actuated by the trigger, a first arcing chamber (5) with a first guide rail (6) and a first contact horn (7) which is connected to the first fixed switching contact (3) is electrically conductively connected, a second arcing chamber (14) with a second guide rail (15) and a second contact horn (16) which is electrically conductively connected to the second fixed switching contact (12), in which the first switch contact pair (3, 4) rotated by 170 ° to 190 ° to the second switch contact pair (12, 13) next to the second switch contact pair (1 2, 13) and in which a flexible electrical conductor (30) is provided between the first movable switch contact (4) and the second movable switch contact (13), which connects the first movable switch contact (4) with the second movable switch contact (13 ) connects in an electrically conductive manner.

Description

The present invention relates to a double-breaking circuit breaker for monitoring a circuit, comprising a coil for actuating a trigger, comprising a first switching contact pair, a first fixed switching contact and a first movable switching contact, a second switching contact pair comprising a second fixed switching contact and a second movable switching contact, wherein the movable switching contacts are actuated by the trigger, a first quenching chamber having a first guide rail and a first contact horn, which is electrically connected to the first fixed switching contact, a second quenching chamber with a second guide rail and a second contact horn, with the second fixed Switching contact is electrically connected.

Such double-breaking protective switching devices, such as circuit breakers and circuit breakers, work in particular as switching and safety elements in electrical energy supply networks. Circuit breakers are specially designed for high currents. A circuit breaker is an overcurrent protection device in the electrical installation and is used in particular in the field of low-voltage networks. Circuit breakers and miniature circuit breakers guarantee a safe shutdown in the event of a short circuit and protect consumers and systems from overload. For example, they protect cables from damage caused by overheating as a result of excessive current. This means that protective switching devices, such as circuit breakers and circuit breakers, can switch off the circuit automatically in the event of overload.

Double-breaking protective switching devices have two switching contact pairs, each consisting of a fixed switching contact and a movable switching contact. For passing current, the movable switch contacts contact the fixed switch contacts. To separate the flow of current, the moving switch contacts remove from the fixed switch contacts. The interruption of the current flow leads at least briefly to each protective switching device to a voltage flashover between the fixed switching contacts and the movable switching contacts, since the distance during the separation process of the switching contacts for isolation is not sufficient. If there is gas between the switching contacts, it is ionized by the flashover with a correspondingly high voltage difference between the switching contacts, and arcs are formed due to the gas discharge.

Such double-breaker protective switching devices, such as circuit breakers or circuit breakers, are designed so that the resulting arcs when opening the switch contacts deleted and thus the flow of current is interrupted.

Such protective switching devices preferably have a coil, via which the current or part of the current flowing to the switching contacts, is passed. With a rapid increase in current, the coil attracts an armature that releases a trigger, in particular a latch. This release, which is pneumatically or hydraulically pressurized or resiliently biased, triggers the protection device and interrupts the flow of current. Thus, for example, a preloaded spring after the release of the trigger, in particular the pawl, move it and thereby separate the movable switch contacts from the fixed switch contacts.

Such protective switching devices furthermore have special arc extinguishing devices for faster extinguishment of the arcs. The arc extinguishing devices are used to better interrupt or delete the arcs that occur when opening the current-carrying switching contact pairs of the protection device. When the switch contacts are disconnected, the current flows through increasingly small areas of an associated contact zone and heats them up more and more. Shortly before the actual separation of the switching contacts, a molten bridge is formed, which finally breaks off at low currents or evaporates at high currents. The current can therefore continue to flow only via an arc in the form of a conductive plasma column.

The strength of the arcs is influenced by the magnitude and type of the switched current. In the event of a short circuit in a circuit protected by a circuit breaker, for example, short-circuit currents of more than 25,000 A may occur. The arcs generate in the circuit breaker housing during its burning time in response to a supply of direct or alternating current temperatures of up to 20,000 K. However, the high thermal load leads to adverse effects for the protection device. For example, metal and insulating parts can be damaged or destroyed by the arc effects. Consequently, it is necessary to extinguish the arcs as quickly as possible in order to minimize the thermal energy conversion. For this purpose, modern protection switching devices arc extinguishing devices, the extinguishing chambers, guide rails, possibly blowing loops and / or metal sheets that cover an antechamber area, have.

Double-breaker protection devices, that is to say protection devices with two switching contact pairs, have the advantage over simple circuit breakers, that is to say protection switching devices with only one switching contact pair, that two arcs are generated at the same time and thus a higher arc voltage can be built up. As a result, the arcs can extinguish faster and the converted energy in the contact zones or in the protective switching devices are kept low. Particularly in the field of high-performance protection switching devices, double-breaking protective switching devices, ie protective switching devices with two switching contact pairs, are used.

A protective switching device with a double break is for example from the EP1548772 A1 known. The two extinguishing chambers of the local protection device are arranged side by side and limit together one side of the antechambers) of the arc quenching device. The contact horns of each quenching chamber project in the same direction and parallel to each other in the antechamber of the arc quenching device. The disadvantage of this protective switching device is the arrangement of the extinguishing chambers or the contact horns to each other that the two magnetic fields of the moving arcs interfere with each other and hinder the flow of the other arc. That is, the flow of current in the arc quenching device runs EP1548772 A1 from the first fixed contact via the first resulting arc to the first movable contact and a second resulting arc on to the second fixed contact. The resulting magnetic fields are directed opposite and do not support the respective neighboring arc, but hinder even its movement.

This harmful influence is usually accepted in the known double-break protection devices. Sometimes it is attempted to shield the magnetic fields from one another by a steel jacket of the individual prechambers. This solution is complicated and costly. Another approach is to spatially separate the extinguishing systems of the arc quenching device, that is to say the extinguishing chambers and correspondingly the contact horns and the guide rails, so that the magnetic fields are correspondingly attenuated. However, this requires a higher space requirement for the extinguishing systems of the arc quenching device in the protection switching device.

Object of the present invention is to provide a double-breaker protection device for monitoring an electrical circuit, which allows a particularly fast and safe erasure of the resulting when opening the switching contacts of the protective device arcing. In particular, a double-breaker protection device is to be created, which allows the resulting arcs in the antechamber region of the extinguishing chambers of the protective switching device does not damage the protective switching device.

This object is achieved by a double-breaking protection device with the features of the independent claim 1. Further features and details of the invention will become apparent from the dependent claims, the description and the drawings.

According to the invention, the object is achieved by a double-breaking protective switching device for monitoring a circuit, comprising a coil for actuating a trigger, a first switching contact pair, comprising a first fixed switching contact and a first movable switching contact, a second switching contact pair, comprising a second fixed switching contact and a second movable switching contact, wherein the movable switch contacts are actuated by the trigger, a first quenching chamber having a first guide rail and a first contact horn, which is electrically conductively connected to the first fixed switching contact, a second quenching chamber with a second guide rail and a second contact horn, with the second fixed switching contact is electrically connected, in which the first switching contact pair is rotated by 170 ° to 190 ° to the second switching contact pair next to the second switching contact pair and in which between the first movable switching contact and the second movable switching contact, a flexible electrical conductor is provided, which electrically conductively connects the first movable switching contact with the second movable switching contact.

Such a double-breaking protective switching device allows the arcing occurring during the separation of the switching contact pairs to be forced rapidly out of the contact zones through the pre-chamber into the extinguishing chambers.

The arrangement of the first switching contact pair by 170 ° to 190 ° twisted to the second switching contact pair, wherein these are arranged side by side, and the flexible electrical conductor between the first movable switching contact and the second movable switching contact, the first movable switching contact with the second movable switching contact electrically conductive connection, allows a particularly fast driving the resulting arcs in the extinguishing chambers of the protective device.

The reverse arrangement of the switching contact pairs to each other causes the Emerging magnetic fields in the region of each pair of switching contact each disturbing the other pair of switching contact and even amplify and thereby the arcs are significantly accelerated so that they are quickly expelled from the contact zones between each fixed contact and a movable switching contact.

It is particularly advantageous if the first switching contact pair is arranged parallel to and rotated by 180 ° relative to the second switching contact pair. But it is also conceivable that the switching contact pairs extend at an angle of up to 10 ° to each other. The switching contact pairs are next to each other in the protection switching device. Twisted in the sense of the invention means that the first fixed switching contact is located approximately next to the second movable switching contact and the first movable switching contact approximately adjacent to the second fixed switching contact. The reverse alignment of the switching contact pairs and the connection of the movable contacts via the flexible electrical conductor, in particular the stranded wire, enables the magnetic fields generated in the area of the switching contact pairs to support one another when expelling or blowing out the arcs from the contact zones.

The switching contact pairs of the double-breaking protective switching device are arranged such that the current flow can generate a blinding coil driving the arcs. The magnetic field of the individual current paths also helps the other switching contact pair or the respective other contact zone for rapid movement of the arcs.

The current flow proceeds in the case of the double-breaking protective switching device after the separation of the switching contacts via the first stationary switching contact and via a first arc to the first movable switching contact. From the first movable switching contact, the current flows via the flexible electrical conductor, which is designed in particular as a strand, to the second movable switching contact. From the second movable switching contact, the current continues to flow via a second arc to the second stationary switching contact. This current flow creates a blow coil driving the arcs. The amplified magnetic field or blowing field of the blow coil already acts at the smallest opening of the switching contacts and drives the resulting arcs immediately in the direction of the extinguishing chambers of the double-breaking protective switching device.

The flexible electrical conductor, in particular the stranded wire, is designed in such a way that it can follow a relative movement of the movable switching contacts relative to one another and does not break off from the movable switching contacts. The ends of the flexible electrical conductor are fixedly arranged on the two movable switching contacts.

Advantages of such a double-breaking protection switching device is the powerful acceleration of the resulting arcs after the opening of the switch contacts by the resulting strong magnetic field or blow field and the associated rapid driving the arcs in the extinguishing chambers. Due to the rapid driving of the arcs in the quenching chamber, the residence time of the arcs between the switching contact pairs can be reduced. This has the consequence that the arc load between a fixed switch contact and a movable switch contact is reduced, which is why a saving in the contact material of the switch contacts is possible. Such a double-breaking protective switching device has a higher short-circuit breaking capacity than known double-breaking protective switching devices of the same size. Due to the flexible electrical conductor and the blown loop the contact points or contact plates are relieved at the switch contacts.

According to a particularly preferred further development of the invention, it can be provided in the double-breaking protective switching device that the first switching contact pair and the second switching contact pair are in an antechamber formed by the two extinguishing chambers, the prechamber being arranged mirror-inverted between the first extinguishing chamber and the first extinguishing chamber second quenching chamber is located. That is, the extinguishing chambers are not next to each other, but opposite each other. As a result, the antechamber is between the two extinguishing chambers. The two switching contact pairs are at least partially in the antechamber, so that the resulting arcs can be easily driven into the proposed extinguishing chambers. Due to the mirror-inverted arrangement of the extinguishing chambers and the respective guide rails and contact horns of the extinguishing chamber are mirror-inverted and arranged parallel to each other.

Also preferred is a double-breaking protective switching device, in which two metal plates arranged parallel to one another are provided, between which the switching contact pairs and at least a part of the first guide rails and the first contact horns are arranged. The metal plates bound the two free, opposite sides of the antechamber of the quenching chambers. This means that double-breaker protection switching device is designed such that two opposite sides of the antechamber through the two extinguishing chambers and the other two opposite sides of the antechamber through the two Metal plates are limited. The metal plates are connected to a coil of the protective switching device such that the coil can induce a magnetic field between the metal plates. The metal plates in conjunction with the coil of the protective switching device allow a strong magnetic field to form between the metal plates, which influences the arcs in such a way that they are driven once more into the corresponding extinguishing chambers.

The coil axis of the coil of the protective device runs perpendicular or approximately perpendicular to the planes in which the metal plates extend. The metal plates are flat. These may be rectangular, oval, round or L-shaped, for example. Almost perpendicular means in the context of the invention that the coil axis of the coil at an angle between 75 ° and 90 °, in particular at an angle between 85 ° and 90 °, to the planes in which the metal plates extend runs. Preferably, however, the coil axis of the coil is perpendicular to the planes in which the metal plates extend.

According to a particularly preferred further development of the invention, it can be provided in the case of the double-breaking protective switching device that the coil is arranged between the metal plates. That is, the coil of the protective switching device is advantageously arranged between the metal plates such that a magnetic field is created between the metal plates, which is induced by the coil on the metal plates. The magnetic field generated between the metal plates causes the resulting arcs to be influenced in such a way that they are forced out of the contact zones more quickly and in the direction of the quenching chambers. Preferably, at least part of a metal plate covers one side of the spool core of the spool.

According to a further preferred development of the invention may be provided in the protective switching device that the pivot planes, in which the movable switch contacts are movable, and the guide rails and the contact horns of the extinguishing chambers parallel or approximately parallel to the metal plates. As a result, the arcs that arise after the separation of the switching contact pairs can be influenced particularly effectively by the magnetic field that arises between the metal plates, so that they are forced quickly in the direction of the respective extinguishing chambers. That is, the magnetic field generated by the coil of the protective switching device between the metal plates acts in addition to the blowing field, which is generated by the flow of current through the switching contacts and the arcs.

According to a further preferred development of the invention, it can be provided in the double-breaking protective switching device that the first stationary switching contact is arranged as a contact plate on the first contact horn and that the second stationary switching contact is arranged as a contact plate on the second contact horn. Due to the special design of the protective switching device, a material saving on the contact plates is possible because they are less burdened by the rapid driving of the arcs in the quenching chambers, as known protection switching devices.

The double-breaking protective switching device described above is advantageously designed as a circuit breaker or a circuit breaker, in particular as a high-performance protection switching device.

In such a trained double-breaking protective switching device, in particular such a trained double-breaker circuit breaker or a double interrupting circuit breaker designed in this way, the coil axis of the coil or the coil core is preferably aligned perpendicular to the arc running direction. This allows the protective switching device that the arcs are accelerated after the contact opening of the switching contact pairs by the strong magnetic field between the metal plates. A further advantage with such a double-breaking protective switching device is that contact material can be saved at the switching contacts, since the arc load on the switching contacts is shorter and thus relatively low due to the magnetic field between the metal plates and the blowing field generated by the current flow in the switching contacts. Due to the special arrangement of the coil to the metal plates and the switching contact pairs, the double-breaking protective switching device has a higher short-circuit switching capacity in comparison to known double-breaking protective switching devices of the same size. The exploitation of the magnetic fields allows a relief of the contact points in the so-called dynamic contact opening.

In contrast to the previously known protective switching devices, in which the coil is arranged so that the coil axis points in the direction of the arc running direction, whereby the resulting magnetic field of the coil has no or even a negative effect on the arc motion is in the protective device according to the invention preferably the magnetic field the coil, which generates the coil for the magnetic release of the trigger exploited, to force the resulting arcs quickly into the quenching chambers.

The coil of the protective switching device is preferably arranged in such a manner in the double-interrupting protective switching device that the orientation of its magnetic field is perpendicular to the arc running direction. The magnetic field induced by the coil on the metal plates, which arises between the metal plates, acts on the arcs in a positive manner, so that they can be forced again faster in the quenching chambers of the protection device.

The arrangement of the coil, including its coil core, to the two metal plates or steel plates can be in the antechamber, ie in the area between the two extinguishing chambers, a magnetic field caused by the coil is induced on the steel plates, and which ensures that the Arcs between the movable switch contacts and the fixed switch contacts are pressed in the direction of the guide rails so as to jump over to this.

The arrangement of the coil rotated by 90 ° in comparison to the arrangement of the coil in the known protective switching devices allows the magnetic field of the coil can be exploited to extinguish faster the resulting arcs after disconnecting the switch contacts.

The metal plates are preferably connected to the coil in such a way that it can induce a magnetic field between the metal plates. For example, a first metal plate may be disposed at the first end of the coil and the second metal plate may be disposed at the second end of the coil. In particular, the metal plates contact the coil.

Also preferred is a double-breaking protective switching device, in which the respective guide rails are arranged at one end of the respective extinguishing chambers and the respective contact horns at the other end of the respective extinguishing chambers. By such an arrangement of the guide rails and the contact horns, the arcs can be easily forced into the quenching chambers.

The metal plates, in particular designed as iron plates metal plates are preferably designed and arranged in the circuit breaker that they cover the entire pre-chamber or the entire pre-chamber between the extinguishing chambers, so that the resulting arcs by the magnetic field quickly from the contact zones of the switch contacts to the Fire extinguishers can be pressed.

Advantageously, it may be provided in the case of the protective switching device that the first guide rail of the first extinguishing chamber is electrically conductively connected to the second guide rail of the second extinguishing chamber. In particular, it is preferred if the first guide rail of the first extinguishing chambers and the second guide rail of the second extinguishing chambers are monolithic. Monolithically formed means that the guide rails are integrally formed and produced by a common manufacturing process. The guide rails are preferably integrally formed with the bottom sheets of the respective extinguishing chambers. The same applies to the contact horns, which are formed integrally with the uppermost plates of the corresponding extinguishing chambers.

The invention and its developments and advantages thereof are explained in more detail with reference to drawings. Each show schematically:

1 in a side view a section through an embodiment of a double-breaking protective switching device, which is designed according to the inventive design principle,

2 a plan view of the inner region of a double-breaking protective switching device, which is designed according to the inventive design principle,

3 an enlarged view of the switching contacts of the double-breaker protection device according to 1 .

4 in a side view a section through a further embodiment of a double-breaking protective switching device, which is designed according to the inventive design principle.

Elements with the same function and mode of action are in the 1 to 4 each provided with the same reference numerals.

1 shows a side view of a section through an embodiment of a double-breaking protective switching device 1 , which is designed according to the construction principle according to the invention. The double-breaker protection device 1 has a first switching contact pair, comprising a first fixed switching contact 3 and a first movable switch contact 4 , and a second switch contact pair comprising a second fixed switch contact 12 and a second movable switch contact 13 , on. Therefore, the protection device is 1 a so-called double breaker. The protective switching device 1 is designed to monitor a circuit. The protective switching device 1 further comprises a coil, not shown, for actuating a trigger, not shown, which actuates the movable switching contacts, a first extinguishing chamber 5 with a first guardrail 6 and a first contact horn 7 that with the first fixed switching contact 3 electrically connected, and a second quenching chamber 14 with a second guardrail 15 and a second contact horn 16 that with the first fixed switching contact 12 electrically connected, on.

In the 3 is an enlarged view of the switch contacts 3 . 4 such as 12 . 13 of the double-breaking protective switching device 1 according to 1 shown.

The switching contact pairs 3 . 4 such as 12 . 13 are arranged rotated by 180 ° to each other, which are adjacent to each other. Between the first moving switch contact 4 and the second movable switch contact 13 is a flexible electrical conductor 30 , which is designed in particular in the form of a stranded wire provided. The flexible electrical conductor 30 connects the first moving switch contact 4 with the second movable switching contact 13 electrically conductive.

Such a double-breaking protective device 1 allows that at the separation of the switching contact pairs 3 . 4 and 12 . 13 resulting arcs 21 quickly out of the contact zones through the antechamber 17 in the extinguishing chambers 5 . 14 are forced.

The special inverted arrangement of the first switching contact pair 3 . 4 to the second switching contact pair 12 . 13 , which are arranged side by side, and the flexible electrical conductor 30 between the first movable switch contact 4 and the second movable switch contact 13 allow a particularly fast driving in the separation of the switch contacts 3 . 4 and 12 . 13 resulting arcs 21 in the extinguishing chambers 5 . 14 of the protective switching device 1 , The reverse arrangement of the switching contact pairs 3 . 4 and 12 . 13 to each other and the connection via the flexible electrical conductor 30 causes the resulting magnetic field 23 in the area of each switching contact pair 3 . 4 and 12 . 13 the other switching contact pair 3 . 4 and 12 . 13 do not disturb and thereby the arcs 21 be significantly accelerated, so that these quickly from the contact zones between each fixed contact 3 respectively. 12 and a movable switching contact 4 respectively. 13 be driven out. The reverse orientation of the switching contact pairs 3 . 4 and 12 . 13 allows that in the field of switching contact pairs 3 . 4 and 12 . 13 resulting magnetic field 23 when expelling or blowing out the arcs 21 reinforced from the contact zones.

The switching contact pairs 3 . 4 and 12 . 13 of the double-breaking protective switching device 1 are arranged such that the current flow 22 one the arcs 21 driving blow coil produced. The magnetic field 23 the individual current paths also helps the other switching contact pair 3 . 4 and 12 . 13 or the other contact zone for rapid movement of the arcs 21 ,

The current flow 22 runs with the double-breaker protective device 1 after the separation of the switching contacts 3 . 4 and 12 . 13 over the first fixed switching contact 3 over a first arc 21 to the first movable switching contact 4 , From the first moving switch contact 4 the current flows through the flexible electrical conductor 30 , which is in particular designed as a strand, to the second movable switching contact 13 , From the second movable switching contact 13 the current continues to flow through a second arc 21 to the second fixed switch contact 12 , Through this current flow 22 The arcs are created 21 driving blubber. The amplified magnetic field or blowing field 23 the blow coil already acts at the smallest opening of the switch contacts 3 . 4 and 12 . 13 and drives the resulting arcs 21 immediately towards the extinguishing chambers 5 . 14 of the double-breaking protective switching device 1 ,

Advantages of such a double-breaking protective switching device 1 is the powerful acceleration of the resulting arcs 21 after opening the switch contacts 3 . 4 and 12 . 13 by the resulting strong magnetic field or blow field 23 and the associated fast driving in of the arcs 21 in the extinguishing chambers 5 . 14 , By quickly driving in the arcs 21 in the extinguishing chamber 5 . 14 can the residence time of the arcs 21 between the switching contact pairs 3 . 4 and 12 . 13 be reduced. This has the consequence that the arc load between a fixed switching contact 3 . 12 and a movable switching contact 4 . 13 is reduced, which is why a saving in the contact material of the switch contacts 3 . 4 and 12 . 13 is possible. Such a double-breaking protective device 1 thus has a higher short-circuit switching capacity than known double-breaker protection devices of the same size. Through the flexible electrical conductor 30 and the thus enabled electrically conductive connection between the movable switch contacts after opening the switch contacts 3 . 4 and 12 . 13 become the contact points of the switching contacts 3 . 4 and 12 . 13 relieved.

In the 2 is a plan view of the inner region of a double-breaker protection device 1 , which is designed according to the construction principle according to the invention, shown. In this illustration, the twisted by 180 ° arrangement of the switching contact pairs 3 . 4 and 12 . 13 clearly, with the switching contact pairs 3 . 4 and 12 . 13 lie next to each other. Between the first moving switch contact 4 and the second movable switch contact 13 is the flexible electrical conductor 30 arranged. This is followed by the flexible electrical conductor 30 the movements of the movable switching contacts 4 . 13 without making the electrically conductive connection via the flexible electrical conductor 30 get lost.

In the 4 is a side view of a section through an embodiment of a protective switching device 1 that is an arc quenching device 20 has, which is designed according to the construction principle of the invention shown. The guard rails 6 . 15 are each at the bottom 5a the first quenching chamber 5 or at the lower end 14a the second quenching chamber 14 arranged, in particular welded. The first contact horn 7 runs between a first end of the coil 2 and the upper end 5b the first quenching chamber 5 , the second contact horn 16 runs between the first guide rail 6 and the upper end 14b the second quenching chamber 14 , The first contact horn 7 is preferably on the winding of the coil 2 welded. The fixed switch contacts 3 . 12 are on or on the respective contact horns 7 . 16 arranged.

The arrangement of the coil 2 including her spool core 2a and two steel plates 9 , wherein only the steel plate with the reference numeral 9 in 4 is shown leaves in the antechamber 17 or in the antechamber area a strong magnetic field 11 arise, induced by the coil 2 on the metal plates 9 , which ensures that the first arc 21 between the first movable switch contact 4 and the first fixed switch contact 3 in the direction of the first guardrail 6 pressed and the second arc between the second movable switching contact 13 and the second fixed switch contact 12 in the direction of the second guardrail 15 be pressed, so skip to this. The arcs are then between the respective guide rails 6 . 15 and the corresponding contact horns 7 . 16 and are thus by the magnetic field 11 and the resulting blowing fields in the respective extinguishing chambers 5 . 14 pressed where they finally go out.

The strong magnetic field 11 between the metal plates 9 allows acceleration of the arcs and thus a reduction in the load on the switching contacts 3 . 4 . 12 . 13 , This allows contact material to the switch contacts 3 . 4 . 12 . 13 be saved. Such trained protective switching devices 1 have a higher short circuit switching capacity to known protection devices of the same size. The contact points are when disconnecting the switch contact pairs 3 . 4 such as 12 . 13 relieved.

The protective switching device according to the 4 is preferably designed as a circuit breaker or circuit breaker.

Because of the arcs 21 through the resulting magnetic field 11 between the metal plates 9 and the resulting blowing fields 23 quickly into the appropriate extinguishing chambers 5 . 14 can be forced is the circuit breaker 1 very well protected against damage. Especially in current ranges beyond 63 A and with protective switching devices 1 with a switching capacity over 25 kA, ie with high-performance protection switching devices, is the special arrangement of the contact systems and the coil 2 in the protective switching device 1 advantageous. The protective switching device 1 allows the arcs that result from a shutdown to go as fast as possible from the antechamber 17 in the extinguishing chambers 5 . 14 can be forced to in the antechamber the protection device 1 , in particular the switching contacts 3 . 4 and 12 . 13 not to harm.

LIST OF REFERENCE NUMBERS

1

Protection device

2

Kitchen sink

2a

Plunger

3

first fixed switching contact

4

first movable switching contact

5

first extinguishing chamber

5a

lower end of the first quenching chamber

5b

upper end of the first quenching chamber

6

first guardrail

7

first contact horn

9

metal plate

10

coil axis

11

Magnetic field between metal plates

12

second fixed switching contact

13

second movable switching contact

14

second extinguishing chamber

14a

lower end of the second quenching chamber

14b

upper end of the second quenching chamber

15

second guardrail

16

second contact horn

17

antechamber

21

Electric arc

22

current flow

23

Blowout field / magnetic field

30

flexible electrical conductor / wire

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 1548772 A1 [0009, 0009]

Claims (11)

Double-breaking protective device ( 1 ) for monitoring a circuit comprising a coil ( 2 ) for actuating a trigger, a first switching contact pair, comprising a first fixed switching contact ( 3 ) and a first movable switching contact ( 4 ), a second switching contact pair, comprising a second fixed switching contact ( 12 ) and a second movable switching contact ( 13 ), wherein the movable switching contacts ( 4 . 13 ) are actuated by the trigger, a first quenching chamber ( 5 ) with a first guide rail ( 6 ) and a first contact horn ( 7 ) connected to the first stationary switching contact ( 3 ) is electrically conductively connected, a second quenching chamber ( 14 ) with a second guide rail ( 15 ) and a second contact horn ( 16 ) connected to the second stationary switching contact ( 12 ) is electrically conductively connected, characterized in that the first switching contact pair ( 3 . 4 ) rotated by 170 ° to 190 ° to the second switching contact pair ( 12 . 13 ) next to the second switching contact pair ( 12 . 13 ) is arranged and that between the first movable switching contact ( 4 ) and the second movable switching contact ( 13 ) a flexible electrical conductor ( 30 ) is provided, the first movable switching contact ( 4 ) with the second movable switching contact ( 13 ) electrically conductively connects. Double-breaking protective device ( 1 ) according to claim 1, characterized in that the flexible electrical conductor ( 30 ) is a stranded wire. Double-breaking protective device ( 1 ) according to at least one of the preceding claims 1 or 2, characterized in that the first switching contact pair ( 3 . 4 ) parallel and rotated by 180 ° to the second switching contact pair ( 12 . 13 ) is arranged. Double-breaking protective device ( 1 ) according to at least one of the preceding claims 1 to 3, characterized in that the first switching contact pair ( 3 . 4 ) and the second switching contact pair ( 12 . 13 ) in an antechamber ( 17 ), which pass through the two extinguishing chambers ( 5 . 14 ) is formed, the antechamber ( 17 ) between the first quenching chamber ( 5 ) and the first extinguishing chamber ( 5 ) arranged mirror-inverted second extinguishing chamber ( 14 ) lies. Double-breaking protective device ( 1 ) according to at least one of the preceding claims 1 to 4, characterized in that two mutually parallel metal plates ( 9 ) are provided, between which the switching contact pairs ( 3 . 4 . 12 . 13 ) and at least part of the first guardrails ( 6 . 15 ) and the first contact horns ( 7 . 16 ) are arranged. Double-breaking protective device ( 1 ) according to claim 5, characterized in that the coil axis ( 10 ) of the coil ( 2 ) perpendicular or approximately perpendicular to the planes in which the metal plates ( 9 ) run, runs. Double-breaking protective device ( 1 ) according to claim 5 or 6, characterized in that the coil ( 2 ) between the metal plates ( 9 ) is arranged. Double-breaking protective device ( 1 ) according to at least one of the preceding claims 5 to 7, characterized in that the metal plates ( 9 ) so to the coil ( 2 ) are arranged that between the metal plates ( 9 ) a magnetic field ( 11 ), which through the coil ( 2 ) on the metal plates ( 9 ) is inducible. Double-breaking protective device ( 1 ) according to at least one of the preceding claims 5 to 8, characterized in that the pivoting planes in which the movable switching contacts ( 4 . 13 ) are movable, and the guide rails ( 6 . 15 ) as well as the contact horns ( 7 . 16 ) of the extinguishing chambers ( 5 . 14 ) parallel or approximately parallel to the metal plates ( 9 ). Double-breaking protective device ( 1 ) according to at least one of the preceding claims 1 to 9, characterized in that the first fixed switching contact ( 3 ) as contact pads on the first contact horn ( 7 ) is arranged and that the second fixed switching contact ( 12 ) as a contact plate on the second contact horn ( 16 ) is arranged. Double-breaking protective device ( 1 ) according to at least one of the preceding claims 1 to 10, characterized in that the protective switching device ( 1 ) is a circuit breaker or a circuit breaker.

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