DE102014215007A1 - Protection switching device and magnetic yoke - Google Patents

Abstract

The protective switching device (1) according to the invention, which is designed in particular as a circuit breaker, has an input terminal (3-1) and an output terminal (3-2), which are designed for contacting the protective switching device (1) with an electrical line. Furthermore, the protective switching device (1) on a switching contact, which in turn has a stationary fixed contact (4) and a relatively movable moving contact (5), which are designed such that when opening the current-carrying switching contact an arc (7) between the Moving contact (5) and the fixed contact (4) is formed. Furthermore, the protective switching device (1) on a short-circuit release system, which in turn has a coil (8) and a relative thereto movably mounted release means (9) and is adapted to act on triggering the moving contact (5) to open the switch contact cause. In this case, the short-circuit release system to a magnetic yoke (15), which is integrally formed and has a coupling region (20). Furthermore, the fixed contact (5) by a fixed contact region (30) of the magnetic yoke (15) is formed, which is integrally connected at its first end (31) with the coupling region (20), and the second end (32) is formed as a free end , Furthermore, the magnetic yoke (15) has a quenching chamber region (40), which is integrally connected to the coupling region (20) and forms a bypass current path which occurs when an arc (7) occurs due to an opening of the switching contact after a commutation of the arc (7). from the fixed contact region (30) to the quenching chamber region (40) is energized.

Description

The invention relates to a protective switching device, in particular a circuit breaker, which has an input terminal and an output terminal, which are designed for contacting with an electrical line. In this case, the protective switching device has a switching contact, which has a stationary fixed contact and a movably arranged movable contact, which are designed such that forms an arc between the moving contact and the fixed contact when opening the current-carrying switching contact. Furthermore, the protective switching device has a short-circuit release system with a coil and a relative thereto movably mounted release means, which is designed to act in the case of triggering on the moving contact to cause an opening of the switching contact. The invention further relates to a magnetic yoke, which is arranged adjacent to the coil of the short-circuit release system and serves to reinforce the magnetic effect of the coil on the triggering means in the event of triggering.

Various protective switching devices are known from the prior art: Circuit breakers are designed especially for high currents. A circuit breaker (so-called LS switch) is an overcurrent protection device used in electrical installations 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 electrical equipment from overload, for example, from damage to the cables due to excessive heating due to excessive electrical current. Circuit breakers and circuit breakers are used in particular as switching and safety elements in electrical energy supply networks and serve to monitor and secure an electrical circuit.

For this purpose, the protective switching device is electrically connected via two terminals with an electrical line of the circuit to be monitored in order to interrupt the electrical current in the respective line when needed. The protective switching device in this case has a switching contact with a stationary fixed contact and a movable relative to moving contact. The moving contact is actuated via a switching mechanism of the protective switching device, so that the switching contact can be opened and closed. In this way, when a predefined state, for example a short circuit or an electrical overload, occurs, the switching contact is opened in order to disconnect the monitored circuit from the electrical line network. Such protective switching devices are known in the field of low-voltage technology as DIN rail mounted devices.

In order to achieve a better electrical contact behavior, a so-called fixed contact piece is arranged on the fixed contact in an electrically conductive manner, which cooperates with a moving contact piece arranged in an electrically conductive manner on the moving contact. If the switching contact is opened at a time when an electric current flows via the switching contact, then an arc is formed when the switching contact between the fixed contact piece and the moving contact piece is removed therefrom. To extinguish the arc, conventional protective switching devices have a so-called quenching chamber with a multiplicity of splitter plates arranged next to one another and spaced apart from one another. If the arc is driven into the quenching chamber, it divides when hitting the quenching plates into several partial arcs, which then burn in series between the individual quenching plates. The multiple, partially sequentially connected in series, partial arcs lead to an overall higher arc voltage, which leads to a faster extinction of the arc as a result.

A standing between the fixed contact piece and the Bewegkontaktstück arc leads to a so-called contact erosion, i. for a removal of material on the fixed contact piece as well as on the moving contact piece. In the case of a closed, current-carrying switching contact, such contact erosion leads to increased electrical resistance. Furthermore, the contact erosion leads to contamination of the contact pieces with microparticles, which in turn leads to a higher tendency to weld of fixed contact piece and moving contact piece. Overall, a contact erosion leads to damage of the protective switching device and is therefore to be avoided as much as possible. Therefore, the arc should be driven as quickly as possible away from the lying between the fixed contact and moving contact contact area in the quenching chamber and deleted.

In addition, during a shutdown by the protective switching device even after a commutation of the arc to another current-carrying element still flowing electrical current causes the contact area is heated further. This promotes a re-ignition of the arc in the contact area, which can lead to a burn through of individual, arranged in this area components and therefore must be avoided.

Furthermore, when using a protective switching device with a so-called snap-action mechanism, it should be noted that when closing the Switching contact, which occurs abruptly due to the used jump gear, the contact is not immediately closed. When closing the switch contact, the moving contact is rather rebounded up to a few times on the rigid, stationary fixed contact. This results in small arcs, which melt the contact pieces and thus prejudice.

It is therefore the object of the present invention to provide a protective switching device and a magnetic yoke for a protective switching device, which are inexpensive to manufacture, characterized by an improved switching behavior and at least some of the above problems fix or at least partially improve.

This object is achieved by the protective switching device and the magnetic yoke according to the independent claims. Advantageous embodiments are the subject of the dependent claims.

The protective switching device according to the invention, which is designed in particular as a circuit breaker, has an input terminal and an output terminal, which are designed for contacting the protective switching device with an electrical line. Furthermore, the protective switching device has a switching contact, which in turn has a stationary fixed contact and a movable relative to movable contact, which are designed such that forms an arc between the moving contact and the fixed contact when opening the current-carrying switching contact. Furthermore, the protective switching device on a short-circuit release system, which in turn has a coil and a relative thereto movably mounted release means and is adapted to act in the event of triggering on the moving contact to cause an opening of the switch contact. In this case, the short-circuit release system on a magnetic yoke, which is integrally formed and has a coupling region. Furthermore, the fixed contact is formed by a fixed contact region of the magnetic yoke, which is integrally connected at its first end to the coupling region, and the second end is formed as a free end. Further, the magnetic yoke on a quenching chamber region, which is integrally connected to the coupling region and forms a bypass current path, which is energized when an arc occurs due to an opening of the switch contact after commutation of the arc from the fixed contact region to the quenching chamber region.

The protective switching device according to the invention has a switching contact, consisting of a fixed contact and a movable relative to movable contact on. To improve the electrical contact, a separate fixed contact piece may be electrically conductively attached to the fixed contact, which cooperates with a moving contact arranged on the moving contact moving contact piece. While the moving contact can be actuated via a switching mechanism of the protective switching device, the fixed contact is formed as part of the magnetic yoke of the short-circuit release system of the protective switching device, the so-called fixed contact region of the magnetic yoke. The resulting merger of functions on existing components of the protection switching device leads to a reduction in the number of parts and thus to a reduction of the assembly costs and the manufacturing cost of the protective device. The action of the triggering means on the moving contact can be effected directly, but also indirectly - for example, by an action of the triggering means on the switching mechanism, which then in turn causes actuation of the moving contact and thus opening of the switching contact. Both possibilities, both indirect and direct action on the moving contact, can be combined.

Furthermore, the design of the second end of the fixed contact area as a free end causes the fixed contact, although stationary, but not rigidly arranged in the housing of the protective device. This results in the advantage that the sudden closure of the switch contact by means of a snap-action mechanism, the free end can spring something, whereby the rebounding of the moving contact is significantly attenuated. The damage to the contacts by small micro-arcs, as they occur when using a rigid fixed contact, thereby significantly reduced. In addition, the design of the second end of the fixed contact region as a free end means that in the case of a short circuit, the direct current flow is interrupted after the commutation of the arc to the quenching chamber region. The load duration acting on the fixed contact region due to the high short-circuit current can thereby be significantly reduced, so that damage due to high temperatures due to the short-circuit current is avoided. Furthermore, the magnetic yoke is integrally formed and therefore - compared to multi-part designs - relatively inexpensive to produce.

The coupling region serves, for example, the coupling of the magnetic yoke to the coil of the short-circuit release system. This coupling can be both electrical, but also magnetic nature. Furthermore, with the aid of the coupling region, a mechanical coupling with a housing of the protective switching device can be realized.

In an advantageous development of the protective switching device, the coupling region has an opening for the implementation of the triggering means. There the magnetic yoke - and in particular the coupling region - is at least partially arranged between the short-circuit release system and the moving contact, the opening formed in the coupling region of the magnetic yoke is a simple, space-saving and cost-effective means to act on the moving contact with the aid of the triggering means to open to effect the switching contact.

In a further advantageous embodiment of the protective switching device, the coupling region is shaped such that a magnetic core is formed, which is at least partially received in the coil in the mounted state. The magnetic core serves to significantly enhance the magnetic effect of the trip coil. This effect can be improved, i. be increased when the magnetic core is at least partially immersed in the coil. In this case, the coupling region of the magnetic coupling of the magnetic yoke is used with the coil of Kurschlussauslösesystems. By the magnetic core formed by the coupling region and thus also integrally formed on the magnetic yoke, the number of parts - and thus the assembly costs and the production costs - can be significantly reduced.

In a further advantageous development of the protective switching device, the coupling region is designed for fastening a magnetic core, which is accommodated in the assembled state at least partially in the coil. As an alternative to the one-piece design, the magnetic core can also be mounted as a separate component on the coupling region of the magnetic yoke. This has the advantage that the magnetic core can be made more massive, which increases its magnetic effect. On the other hand, a suitable material can be selected for this purpose without the design of the magnetic yoke having to be taken into account. This leads to significantly higher degrees of freedom with regard to the structural design of the protective switching device, which is particularly advantageous in high-end devices.

In a further advantageous development of the protective switching device, the magnetic core can be connected to the coupling region by means of welding or riveting. Welding or riveting represent simple and cost-effective method for producing a connection of the magnetic core with the coupling region of the magnetic yoke.

In a further advantageous development of the protective switching device, the free second end of the fixed contact region is designed as a contact horn. With the help of the contact horn, which is oriented towards the quenching chamber area at the free end, the arc produced during the opening of the energized switching contact is pulled away from the switching contact in the direction of the quenching chamber or the prechamber region arranged in front of the quenching chamber. On its way towards the free second end, the arc commutes from the fixed contact region to the quenching chamber region of the magnetic yoke. From this point on, the electric current thus no longer flows through the fixed contact area, but via the bypass current path which is now energized. In this way, a re-ignition of the arc in the contact area as well as excessive heating - and thus a possible damage to the fixed contact area - effectively avoided.

In a further advantageous development of the protective switching device, an electrical connection region is formed by a connection region of the coupling region with the extinguishing chamber region for contacting the coil.

In a further advantageous embodiment of the protective switching device, an electrical connection region for contacting the coil is formed on the coupling region, which is arranged opposite a connection region of the coupling region with the quenching chamber region.

These arrangements of the electrical connection region of the coil at a connection region of the coupling region with the quenching chamber region, or opposite this connection region, represent possible alternatives for electrically contacting the coil with the magnetic yoke. The advantage of the respective alternative is the arrangement of the remaining components of the protective switching device , Especially in confined spaces, as well as the requirements for the most ergonomic mountability of the protection device dependent.

In a further advantageous embodiment of the protective switching device, the magnetic yoke is produced as a sheet metal bent part. The design as a bent sheet metal part represents an extremely cost-effective way of producing the magnetic yoke.

The magnetic yoke according to the invention for a short-circuit release system of a protective switching device, in particular a circuit breaker, is integrally formed and has a coupling region. Furthermore, the magnetic yoke on a fixed contact region, which forms a stationary part of a switching contact of the protective switching device, is integrally connected at its first end to the coupling region, and the second end is formed as a free end. Further, the magnetic yoke on a quenching chamber region, which is integrally connected to the coupling region and forms a bypass current path, which occurs when an arc occurs due to an opening of the Switching contact is energized after a commutation of the arc from the fixed contact region to the quenching chamber region.

The magnetic yoke according to the invention has several advantages. On the one hand, due to its one-piece design, the magnetic yoke can be produced relatively inexpensively compared to multi-part embodiments. Furthermore, in the magnetic yoke according to the invention several - originally designed as individual components - integrated: By merging the original magnetic yoke with the original fixed contact area to a single component, the number of parts is significantly reduced, which has an advantageous effect on the manufacturing and assembly costs of the protection device.

In addition, the design of the second end of the fixed contact area allows as a free end that the fixed contact while stationary, but not rigidly disposed in the housing of the protective device. This results in the advantage that the sudden closing of the switch contact, for example by means of a snap-action mechanism, the free end can spring something, whereby the rebounding of the Bewegkontakts is significantly attenuated. The damage to the contact elements by small micro-arcs, as they occur when using a rigid fixed contact, thereby significantly reduced.

Furthermore, the design of the second end of the fixed contact region as a free end means that in the case of a short circuit, the direct current flow is interrupted via the fixed contact region after commutation of the arc to the quenching chamber region. The energy input acting on the fixed contact area due to the high short-circuit current can thereby be significantly reduced since the fixed contact area is not permanently, i. is energized until the final extinction of the arc in the quenching chamber, but only until the commutation of the arc from the fixed contact area to the quenching chamber area. In this way damage to the fixed contact region is effectively prevented by the high temperature development associated with the short-circuit current.

The coupling region serves, for example, the coupling of the magnetic yoke to the coil of the short-circuit release system. This coupling can be both electrical, but also magnetic nature. Furthermore, with the aid of the coupling region, a mechanical coupling with a housing of the protective switching device can be realized.

In an advantageous development of the magnetic yoke, the coupling region has an opening for the passage of the triggering means. Since the magnetic yoke - and in particular the coupling region - is at least partially arranged between the short-circuit release system and the moving contact, the opening formed in the coupling region of the magnetic yoke represents a simple, space-saving and cost-effective means for acting on the moving contact with the aid of the triggering means Opening the switch contact to effect.

In a further advantageous embodiment of the magnetic yoke of the coupling region is shaped such that a magnetic core is formed, which is at least partially received in the coil in the assembled state. The magnetic core serves to significantly enhance the magnetic effect of the trip coil.

This effect can be improved, i. be increased when the magnetic core is at least partially immersed in the coil, i. at least partially received in the coil. In this case, the coupling region of the magnetic coupling of the magnetic yoke is used with the coil of Kurschlussauslösesystems. By the magnetic core formed by the coupling region and thus also integrally formed on the yoke, the number of parts - and thus the cost of mounting the protection device - and the manufacturing costs are further reduced.

In a further advantageous development of the magnetic yoke, the free second end of the fixed contact region is designed as a contact horn. With the help of the contact horn, which is oriented towards the quenching chamber area at the free end, the arc produced during the opening of the energized switching contact is drawn away from the switching contact in the direction of a quenching chamber of the protective switching device or an antechamber region arranged in front of the quenching chamber. On its way towards the free second end of the fixed contact region, the arc commutates from the fixed contact region to the quenching chamber region of the magnetic yoke. From this time of the commutation of the arc, the electric current thus no longer flows through the fixed contact region, but via the now energized bypass current path, which is formed by the quenching chamber region of the magnetic yoke. In this way, a re-ignition of the arc in the contact area and excessive heating - and thus a possible damage - the fixed contact area effectively avoided.

In a further advantageous development of the magnetic yoke, an electrical connection region is formed by a connection region of the coupling region with the extinguishing chamber region for contacting the coil.

In a further advantageous development of the magnetic yoke, an electrical connection region for contacting the coil is formed on the coupling region, which is arranged opposite a connection region of the coupling region with the extinguishing chamber region.

These arrangements of the electrical connection region for contacting the coil at a connection region of the coupling region with the extinguishing chamber region, or opposite this connection region, represent possible alternatives for electrically contacting the coil with the magnetic yoke. The advantage of the respective alternative is the arrangement of the other components the protective switching device, especially in confined spaces, and the requirements for the most ergonomic mountability of the protective device dependent.

In a further advantageous development, the magnetic yoke can be produced as a sheet metal bent part. The design as a bent sheet metal part represents an extremely cost-effective way of producing the magnetic yoke.

Various exemplary embodiments of the protective switching device according to the invention and of the magnetic yoke according to the invention will be explained in more detail below with reference to the accompanying figures. In the figures are:

characters

1A and 1B a schematic representations of a known protective switching device;

characters

2A to 2E schematic representations of various embodiments of the magnetic yoke according to the invention;

3 a schematic representation of an equivalent circuit diagram of the protection switching device according to the invention.

In the various figures of the drawing, like parts are always provided with the same reference numerals. The description applies to all drawing figures in which the corresponding part can also be recognized.

The 1A and 1B shows the schematic structure of a protective switching device 1 as known in the art. In 1A is a side view of the protective device 1 shown schematically; 1B shows the associated equivalent circuit diagram. The protective switching device 1 has an input port 3-1 and an output port 3-2 on which in a housing 2 of the protective switching device 1 are recorded and held. The input connection 3-1 and the output terminal 3-2 are for contacting the protective switching device 1 formed with an electrical line (not shown) and each have a clamping screw 3-3 for clamping the electrical conductors. The input connection 3-1 is over an electrical coil 8th with one in the case 2 Fixedly arranged fixed contact 4 electrically connected. The fixed contact 4 forms together with a relative thereto movably mounted moving contact 5 a switch contact, which can be opened and closed to control the flow of current between the input terminal 3-1 and the output terminal 3-2 to interrupt or allow. This is the moving contact 5 on a rotatably mounted Bewegkontaktträger 6 attached. The moving contact carrier 6 turn over a strand 14 electrically conductive with the output terminal 3-2 connected.

In the event of a short circuit, a short-circuit release system of the protective switching device is used 1 to open the switch contact. For this purpose, the moving contact 5 with the help of Bewegkontaktträgers 6 from the fixed contact 4 moved away. For this purpose, the short-circuit release system has a coil 8th with a releasably mounted therein trigger means 9 , which in the present case is designed as an armature-tappet unit, on. In principle, the trigger means 9 an anchor and an appended thereto extension - which may be formed, for example, as a plunger - on. Will the armature at one end of the coil into the coil 8th drawn in, so the armature opposite formed extension at the other end of the coil from the coil 8th pushed out. This movement is used when a short circuit occurs to open the switch contact.

When a short circuit occurs, the coil becomes 8th flowed through by the high short-circuit current. The resulting magnetic field causes the armature of the armature plunger unit in the coil 8th is pulled. The ram mechanically fixed to the anchor 9 is thereby abruptly in the direction of Bewegkontaktträgers 6 emotional. Upon impact of the ram 9 on the moving contact carrier 6 this is set in motion about its pivot point D, whereby the moving contact 5 from the fixed contact 4 is moved away. This is called direct or direct action of the triggering agent 9 designated.

As a rule, the protection device has 1 in addition, a switching mechanism (not shown), which upon action of the plunger 9 on the switching mechanism via a mechanical action chain causes a sudden opening of the switch contact. For manual actuation of the protective switching device 1 is at the front of an actuator 2 arranged, which - for example via the switching mechanism - with the Bewegkontaktträger 6 is in active connection. In this way, the switching contact by means of the actuating element 2 be opened and closed manually. This action of the triggering agent 9 on the moving contact carrier 6 via the switching mechanism of the protective device 1 is referred to as indirect or indirect action.

When opening the current-carrying switching contact creates an arc 7 , which first between the fixed contact 4 and the moving contact 5 burning. Removes the moving contact 5 from the fixed contact 4 so the leads with increasing length of the arc 7 rising arc voltage causes the arc 7 on a guardrail 11 , which is located below the opening switch contact, commutes. The first end of the guardrail 11 is at a lower end of an arc quenching chamber 10 , the second end of the guardrail 11 with the output connector 3-2 electrically connected. An upper end of the arc quenching chamber 10 is with the fixed contact 4 electrically connected. The electro-magnetic forces occurring due to the short-circuit current interact with the arc 7 such that it is moved away from the opening switching contact. This force on the arc 7 acts first in the direction of the so-called pre-chamber area 13 located below the switch contact in front of the arc quenching chamber 10 located. In the further course of the arc 7 then me the arc quenching chamber 10 crowded. The arc extinguishing chamber 10 has a variety of quenching plates. Meets the arc 7 on the quenching plates, it is divided into a corresponding plurality of electrically connected in series. Due to the resulting higher arc voltage, the arc eventually breaks off and goes out.

In the 2A to 2E are different embodiments of the magnetic yoke according to the invention 15 shown schematically. A magnetic yoke generally serves to remove the magnetic field from the coil 8th is generated to bundle so that the force on the armature plunger unit is amplified. The in the 2A to 2E illustrated embodiments of the magnetic yoke 15 all have a coupling area 20 , a fixed contact area 30 and a quenching chamber area 40 on.

The coupling area 20 serves the mechanical coupling of the magnetic yoke 15 with a housing of the protective switching device 1 , In the present case, the coupling area is used 20 furthermore the electrical and / or magnetic coupling of the magnetic yoke 15 with the coil 8th of the short-circuit release system of the protective switching device 1 , In this case, the coupling region 20 an opening 21 have, through which the plunger 9 (please refer 1 ) is passed to the moving contact 5 or on the Bewegkontaktträger 6 act. One at the coupling area 20 trained connection area 24 is used for electrical contacting of the coil 8th For example, by welding or brazing.

The fixed contact area 30 is at its first end 31 integral with the coupling region 20 connected and forms the fixed contact 4 (please refer 1 ) of the protective switching device 1 , For this purpose, a contact element 34 at the fixed contact area 30 attached, which with another, at the moving contact 5 (please refer 1 ) formed contact element and the switching contact of the protective switching device 1 forms. The use of separate contact elements allows - with regard to the materials used - a more flexible design of the individual components, in which the components are adaptable with respect to their material properties to the respective function of the component. The second end 32 of the fixed contact area 30 is designed as a free end. This results in the advantage that the fixed contact area 30 is less rigid and can spring to a limited extent. As a result, when the switching contact is suddenly closed, as occurs, for example, when using a snap-action switching mechanism, the moving contact bounces back 5 prevented or at least reduced. In the transition region to the contact element 34 is the free second end 32 as a contact horn 33 educated. In this way, the high electromagnetic forces that occur in the event of a short circuit can specifically affect the arc 7 be used to this as quickly as possible from the area of the switch contact in the direction of the pre-chamber area 13 and continue towards the extinguishing chamber 10 to drive.

The extinguishing chamber area 40 is over a connection area 41 also in one piece with the coupling area 20 connected and forms the upper end of the arc-quenching chamber 10 (please refer 1 ) of the protective switching device 1 , The extinguishing chamber area 40 serves as a bypass current path 42 (please refer 6 ), which in case of a short circuit only after a commutation of the arc 7 from the fixed contact area 30 on the quenching chamber area 40 is energized. This effect is achieved by having the second end 32 of the fixed contact area 30 is designed as a free end. This necessarily means that the free second end 32 not directly with the quenching chamber area 40 is electrically connected. In this way, the fixed contact area 30 only during the period of the formation of the arc 7 up to its commutation on the quenching chamber area 40 thermally stressed, but not during the period from commutation to final extinction of the arc 7 in the arc quenching chamber 10 , During the latter period, the electrical (short-circuit) current flows from the input terminal 3-1 over the coil 8th as well as the extinguishing chamber area 40 and the arc 7 to the output terminal 3-2 , The fixed contact area 30 is no longer energized.

2A shows in a first embodiment, a basic shape of the magnetic yoke 15 in which the coupling area 20 only for mounting with the coil 8th is designed. In contrast, this shows in 2 B illustrated second embodiment of a magnetic yoke 15 with a coupling area 20 to which an additional magnetic core 23 is attached. With the help of this magnetic core 23 that will be from the energized coil 8th generated magnetic field, whereby the force acting on the armature plunger unit of the short-circuit release magnetic force is amplified. Also in 2C such as 2D Illustrated embodiments show a magnetic yoke 15 with a magnetic core 24 for amplifying the magnetic force acting on the armature plunger unit. In contrast to the representation in 2A is the magnetic core 24 but not as an independent component on the coupling area 20 attached, but in one piece with the actual coupling area 20 connected. By this one-piece design of the magnetic yoke 15 As a sheet metal part, the assembly costs and the production costs of the magnetic yoke can be 15 significantly reduce.

This in 2E illustrated embodiment shows a magnetic yoke 15 , whose coupling area 20 reduced is formed and no opening 21 for the implementation of the ram 9 having. Rather, this area is the area of the opening 21 , completely omitted, leaving the pestle 9 above the coupling area 20 to magnetic yoke 15 passed by. This embodiment is particularly interesting for short-circuit release systems, which operate without an additional magnetic core, as a result of the assembly of the magnetic yoke 15 is significantly simplified.

Furthermore, the differ in the 2D and 2E illustrated embodiments of the rest, in the 2A to 2C illustrated embodiments in that the connection area 24 for electrical contact with the coil 8th the connection area 41 opposite to the coupling area 20 is formed while the connection area 24 in the in the 2A to 2C illustrated embodiments by the connection area 41 of the coupling area 20 with the quenching chamber area 40 is formed.

3 shows a schematic representation of an equivalent circuit diagram of the protection switching device according to the invention 1 when using the magnetic yoke according to the invention 15 , As a rule, the electric current flows from the input terminal 3-1 Coming over the coil 8th of the short-circuit release as well as the closed switching contact to the output connection 3-2 (upper rung). When a short circuit occurs, the switching contact is opened, ie the moving contact 5 is over the rotatably mounted in the point D Bewegkontaktträger 6 from the fixed contact 4 moved away. It creates an arc 7 , which first between the fixed contact 4 and the moving contact 5 burning. In the further course of the arc from the switching contact area out in the direction of the quenching chamber 10 driven. The arc commutes from the fixed contact area 30 on the quenching chamber area 40 of the magnetic yoke 15 , This extinguishing chamber area 40 now acts as a bypass flow path 42 , ie during the period of the commutation of the arc 7 until its extinction, the electric (short-circuit) current flows from the input terminal 3-1 over the coil 8th and the as a bypass current path 42 acting extinguishing chamber area 40 (lower rung), and further over in or before the arc quenching chamber 10 standing arc 7 to the output terminal 3-2 ,

In this way, the fixed contact area 30 of the magnetic yoke 15 from the time the arc hit 7 on the quenching chamber area 40 Commutated, no longer energized. The thermal load of the fixed contact area 30 This can be significantly reduced.

LIST OF REFERENCE NUMBERS

1

Protection device

2

casing

3-1

 input port

3-2

 output port

3-3

 clamping screw

4

fixed contact

5

moving contact

6

Bewegkontaktträger

7

Electric arc

8th

Kitchen sink

9

Release means / plunger

10

extinguishing chamber

11

Guardrail

12

actuator

13

antechamber

15

yoke

20

coupling region

21

opening

22

magnetic core

23

magnetic core

24

terminal area

30

Hard contact area

31

first end

32

second end

33

Contact Horn

34

contact element

40

Extinguishing chamber area

41

connecting area

42

Bypass current path

D

pivot point

Claims (16)

Protection switching device ( 1 ), in particular circuit breaker, - with an input terminal ( 3-1 ) and an output terminal ( 3-2 ), which for contacting the protective switching device ( 1 ) are formed with an electrical line, - with a switching contact, which has a stationary fixed contact ( 4 ) as well as a relatively movable moving contact ( 5 ), which are designed such that when opening the current-carrying switching contact an arc ( 7 ) between the moving contact and the fixed contact is formed, - with a short-circuit release system, which is a coil ( 8th ) as well as a triggering device movably mounted relative thereto ( 9 ) and is designed, in the case of triggering on the moving contact ( 5 ) to effect opening of the switch contact, - in which the short-circuit release system a magnetic yoke ( 15 ), which is formed in one piece, - in which the magnetic yoke ( 15 ) a coupling area ( 20 ), in which the fixed contact ( 5 ) through a fixed contact area ( 30 ) of the magnetic yoke ( 15 ) formed at its first end ( 31 ) in one piece with the coupling region ( 20 ) and the second end ( 32 ) is designed as a free end, - in which the magnetic yoke ( 15 ) a quenching chamber area ( 40 ), which with the coupling region ( 20 ) is integrally connected, - wherein the extinguishing chamber area ( 40 ) forms a bypass current path which, when an arc occurs ( 7 ) due to an opening of the switching contact after a commutation of the arc ( 7 ) from the fixed contact area ( 30 ) to the quenching chamber area ( 40 ) is energized. Protection switching device ( 1 ) according to claim 1, wherein the coupling region ( 20 ) an opening ( 21 ) for carrying out the triggering means ( 9 ) having. Protection switching device ( 1 ) according to one of claims 1 to 2, wherein the coupling region ( 20 ) is shaped such that a magnetic core ( 22 ) is formed, which in the assembled state at least partially in the coil ( 8th ) is recorded. Protection switching device ( 1 ) according to one of claims 1 to 2, wherein the coupling region ( 20 ) for fixing a magnetic core ( 23 ) is formed, which in the assembled state at least partially in the coil ( 8th ) is recorded. Protection switching device ( 1 ) according to claim 4, wherein the magnetic core ( 23 ) by means of welding or riveting to the coupling region ( 20 ) is connectable. Protection switching device ( 1 ) according to one of the preceding claims, in which the free second end ( 32 ) of the fixed contact area ( 30 ) as a contact horn ( 33 ) is trained. Protection switching device ( 1 ) according to one of the preceding claims, in which for contacting the coil ( 8th ) an electrical connection area ( 24 ) through a connection area ( 41 ) of the coupling area ( 20 ) with the quenching chamber area ( 40 ) is formed. Protection switching device ( 1 ) according to one of claims 1 to 6, in which for contacting the coil ( 8th ) at the coupling area ( 20 ) an electrical connection area ( 24 ) which forms a connection area ( 41 ) of the coupling area ( 20 ) with the quenching chamber area ( 40 ) is arranged opposite one another. Protection switching device ( 1 ) according to one of the preceding claims, wherein the magnetic yoke ( 15 ) is produced as a sheet metal part. Magnetic yoke ( 15 ) for a short-circuit release system of a protective switching device ( 1 ), in particular a circuit breaker, which is integrally formed and a coupling region ( 20 ), - with a fixed contact region ( 30 ), which a stationary part of a switching contact of the protective switching device ( 1 ), at its first end ( 31 ) in one piece with the coupling region ( 20 ) and the second end ( 32 ) is formed as a free end, and - with a quenching chamber area ( 40 ), which integral with the coupling region ( 20 ) and forms a bypass current path which, when an arc occurs ( 7 ) due to an opening of the switching contact after a commutation of the arc ( 7 ) from the fixed contact area ( 30 ) to the quenching chamber area ( 40 ) is energized. Magnetic yoke ( 15 ) according to claim 10, wherein the coupling region ( 20 ) an opening ( 21 ) for performing one with the coil ( 8th ) cooperating triggering means ( 9 ) of the short-circuit release system. Magnetic yoke ( 15 ) according to one of the preceding claims, wherein the coupling region ( 20 ) is shaped such that a magnetic core ( 22 ) is formed, which in the assembled state at least partially in the coil ( 8th ) is recorded. Magnetic yoke ( 15 ) according to one of the preceding claims, in which the free second end ( 32 ) of the fixed contact area ( 30 ) as a contact horn ( 33 ) is trained. Magnetic yoke ( 15 ) according to one of the preceding claims, in which for contacting the coil ( 8th ) an electrical connection area ( 24 ) through a connection area ( 41 ) of the coupling area ( 20 ) with the quenching chamber area ( 40 ) is formed. Magnetic yoke ( 15 ) according to any one of claims 10 to 13, wherein at the coupling region ( 20 ) an electrical connection area ( 24 ) for contacting the coil ( 8th ) which forms a connection area ( 41 ) of the coupling area ( 20 ) with the quenching chamber area ( 40 ) is arranged opposite one another. Magnetic yoke ( 15 ) according to one of the preceding claims, wherein the magnetic yoke ( 15 ) is produced as a sheet metal part.

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