DE102010004641B4 - Electromagnetic release system and installation switching device with an electromagnetic release system - Google Patents

Abstract

Electromagnetic tripping system (1) for a circuit breaker, with a magnet system (2) with striker (45), with a contact lever (5) rotatably mounted about an axis (4) fixed to the housing, with a control lever (7) mounted so as to be pivotable about a pivot axis (6) ), which has a first coupling point (8) on which a shackle spring (9) engages with its first end (10), the restraining force of the shackle spring acting on the control lever (7) in its rest position, and the control lever (7) under the action of the striker (45) from its rest position against the retaining force of the restraint spring (9) can be pivoted into its release position, with a coupling between the contact lever (5) and the control lever (7) which enables the control lever (7) to pivot transmits a pivoting movement of the contact lever (5), characterized in that the control lever (7) has a second coupling point (11) which is set up to attach an additional spring (12) where when by the additional spring (12) when attached to the second coupling point (11) in the rest position of the control lever (7), the retaining force of the restraint spring (9) is reinforced.

Description

The invention relates to an electromagnetic release system for a circuit breaker, with a magnet system with a striker, with a contact lever rotatably mounted about an axis fixed to the housing, with a control lever pivotably mounted about a pivot axis, which has a first coupling point on which a restraint spring engages with its first end , the restraining force of the restraint spring acts on the control lever towards its rest position, and the control lever can be pivoted from its rest position against the restraint force of the restraint spring into its release position under the action of the striker, whereby there is a coupling between the contact lever and the control lever, which pivoting movement of the control lever is transmitted to a pivoting movement of the contact lever, according to the preamble of claim 1.

The invention further relates to an installation switching device, in particular a line circuit breaker or a main line circuit breaker, with a contact point that is formed between a fixed contact piece and a movable contact piece, comprising an electromagnetic release system with a magnet system with a striker, with a contact lever rotatably mounted about an axis fixed to the housing, which carries the movable contact piece, with a control lever pivotably mounted about a pivot axis, which has a first coupling point on which a shackle spring engages with its first end, the retaining force of the shackle spring acting on the control lever towards its rest position, and the control lever under action of the striker from its rest position against the retaining force of the restraint spring can be pivoted into its release position, with a coupling between the contact lever and the control lever which allows the control lever to pivot in a The pivoting movement of the contact lever is transferred to its open position, in which the fixed and movable contact pieces are separated, according to the preamble of claim 7.

A generic installation switching device is, for example, a selective main line circuit breaker. Main line circuit breakers of this type are mainly used in the lower connection rooms of meter stations, for example in a house installation system. In cooperation with the downstream miniature circuit breakers to which individual consumer circuits are assigned, they protect the electrical installation system from dangerous overcurrents and short-circuit currents by selectively and automatically switching off the downstream circuits when an overcurrent or a short-circuit current occurs.

A generic installation switching device has an electromagnetic release for disconnection in the event of a short circuit. It is switched off within a few milliseconds by an electromagnet through which the current flows. A generic electromagnetic release is for example from DE 10 2008 021 768 known. It comprises a magnetic core and a magnetic circuit with a movable magnet armature, also known as a swing armature, further a coil arrangement comprising a coil tube with a core yoke plate to which the magnetic core is attached and with a yoke armature plate, as well as the yoke connecting the core yoke plate and the yoke armature plate -Side parts. Together with the core yoke plate and the yoke armature plate, these form a housing for the coil arrangement with the armature and form a path for the magnetic flux. The striker is located in a through hole in the magnetic core. A control lever is pivotably mounted on the core yoke plate. A restraint spring engages the control lever and the contact lever of the contact point. The restoring force of the restraint spring acts on the control lever in the direction of its rest position and the contact lever in the direction of its closed position, in which the fixed and movable contact pieces are in contact with each other and the main contact point is thereby closed. The restraint spring causes the contact pressure force and the restraint force for the control lever at the same time.

When a short-circuit current occurs, the armature moves very quickly towards the magnetic core and acts on the striker, so that it hits the control lever through the yoke armature plate. He moves it against the restoring force of the restraint spring from its rest position in the direction of its release position. A coupling between the control lever and the contact lever causes the control lever to pivot the contact lever into its open position. In the open position of the contact lever, the main contact point is open until the circuit breaker has switched off via its disconnection mechanism.

The force with which the armature strikes against the striker and the striker against the control lever depends on the level of the short-circuit current. The so-called tripping characteristic of a miniature circuit breaker indicates at which multiple of the rated current the rapid short-circuit triggering begins; it therefore indicates the response threshold of the miniature circuit breaker. For example, selective miniature circuit breakers are manufactured according to the so-called E characteristic, in which the short-circuit current release can trip at 5 - 6.25 times the rated current for alternating current, but has to trip at 6.25 times the rated current for alternating current.

In the case of currents below the tripping threshold defined by the characteristic (i.e. 5 times the rated current), the electromagnetic release should not trip. The restraint mechanism, the mechanical system including the control lever and the restraint spring, is therefore designed in such a way that the force of the armature is only sufficient to control the control lever from a short-circuit current that corresponds to the lower response threshold of the respective trigger characteristic, which can be referred to as the threshold force, for example to pivot towards its release position. In particular, the lever ratios are selected in coordination with the rigidity of the restraint spring so that after the threshold force has been exceeded, the further course of the force when the contact lever is pivoted is as low and uniform as possible.

For certain applications, e.g. in the industrial sector, devices with a higher short-time delayed release behavior are required, i.e. with a higher response threshold. In order to achieve this, the restraint mechanism has to be completely redesigned and manufactured based on previously known devices, which is complex.

From the DE 30 21 867 C2 a circuit breaker is known, known for a selective protection device with an overcurrent and a short-circuit current release, with two main contact points, which are formed by two movable contact pieces attached to a movably mounted contact lever, an additional armature system with a magnet coil, a magnet core, a magnet armature and a Striking pin that hits the movable contact lever directly and without delay in the event of short-circuit currents and thus lifts the movable contact pieces off the stationary contact pieces quickly and briefly.

From the DE 10 2006 037 225 A1 a switching unit for the selective shutdown of at least one consumer is known, which has at least one contact point with a movably mounted contact arm, an actuatable impact armature ( 7th ) to open the contact point by moving the contact arm and a switch lock with a movably mounted pawl and a movably mounted release lever associated with the pawl.

In the U.S. 4,808,952 A describes a magnetic release for a selectively operating switch with a plunger armature, the plunger armature being actuated by a solenoid coil at a current corresponding to the tripping current for opening the contacts of the switch and its plunger acting on the movable contact of the switch.

Starting from the solutions known in the prior art, it is therefore desirable to create an electromagnetic release system that is designed for one release threshold and can be modified in a simple manner for use with at least one other release threshold. It is also an object of the present invention to provide an improved service switching device which is designed for one trip threshold and can be modified in a simple manner for use with at least one other trip threshold.

The object of creating an improved electromagnetic release system is achieved by an electromagnetic release system with the features of claim 1. With regard to the service switching device, the object is achieved by an service switching device according to claim 7. Further developments of the aforementioned subjects are set out in the subclaims.

According to the invention, the control lever has a second coupling point, which is designed to attach an additional spring, the retaining force of the restraint spring being increased by the additional spring when the control lever is attached to the second coupling point in the rest position of the control lever.

The advantage of the invention is that the existing magnetic release system of a generic installation switching device is modified in such a way that an additional restraint spring can be installed in addition to the already existing restraint spring between the control lever and the contact lever, which is also a contact force spring is, also attacks the control lever. This increases the restraint force of the control lever on the armature without changing the force acting on the contact lever. Only the response current of the electromagnetic release system is increased; the force curve when the movable contact is opened remains unchanged.

According to an advantageous embodiment, the magnet system has a third coupling point, the additional spring being attached to the second and third coupling point. For this purpose, the other spring end of the additional spring can be fastened to the core yoke plate via a fastening bracket. Thus, the existing core yoke plate can be used both for the E characteristic, namely, as is known, without an additional spring, but also for a characteristic with an increased release threshold, then with an additional spring inserted.

According to a further advantageous embodiment, the restraint spring engages the contact lever with its second end.

According to a further advantageous embodiment, in the rest position of the control lever, the line of action of the force exerted by the auxiliary spring on the control lever with respect to the pivot axis is on the same side as the line of action of the restoring force of the restraint spring, and when the control lever is turned out of the rest position, the line of action intersects the the force exerted by the auxiliary spring on the control lever, The additional spring is arranged in such a way that the spring action line is quickly shifted into the axis of rotation of the control lever after the magnet system has responded by turning the control lever, so that the force effect during the contact opening movement becomes zero.

According to a further advantageous embodiment, the magnet system comprises a housing with a cover plate, and the cover plate carries a fastening web, at the free end of which the third coupling point is located. The cover plate corresponds, for example, to the core yoke plate in known electromagnetic release systems. The fastening web can be welded to the core yoke plate in the form of a fastening bracket. Thus, the existing core yoke plate can be used both for the E characteristic, but also for a characteristic with an increased trigger threshold, in which case the fastening bracket for the additional spring is welded on.

According to a further advantageous embodiment, a spring holding part is coupled to the axis fixed to the housing, the third coupling point being located on the spring holding part. In this embodiment, a basic device that does not contain the additional spring can also be used with an additional spring, almost unchanged. For upgrading with the additional spring, a spring holding part only needs to be coupled to the axis fixed to the housing, which then forms the third coupling point for the additional spring.

According to a further advantageous further development of the last-mentioned embodiment, the spring holding part has a holding leg and a support leg, the third coupling point being located on the holding leg.

According to a further advantageous development, the retaining leg has a recess for receiving the axis fixed to the housing.

According to a further advantageous development, the support leg is coupled to a stop in order to prevent the spring-holding part from rotating on the axis fixed to the housing.

According to a further advantageous development, the magnet system comprises a housing with a cover plate, and the stop is attached to the cover plate.

According to a further advantageous embodiment, the contact lever comprises a contact arm, which carries the movable contact piece, and a control arm, with which the coupling to the control lever exists, which are fastened on both sides of an axis of rotation aligned with the axis fixed to the housing, and a shackle bar is fastened to the contact lever , at the free end of which engages the second end of the restraint spring.

In an installation switching device according to the invention, the control lever has a second coupling point which is set up to attach an additional spring, the retaining force of the restraint spring being reinforced by the additional spring when the control lever is attached to the second coupling point in the rest position of the control lever.

According to an advantageous embodiment of the invention, in the rest position of the control lever, the line of action of the force exerted by the auxiliary spring on the control lever with respect to the pivot axis lies on the same side as the line of action of the restoring force of the restraint spring, and when the control lever is turned out of the rest position, the line of action intersects the the force exerted by the auxiliary spring on the control lever controls the pivot axis.

Figures and description serve to better understand the subject. Objects or parts of objects that are essentially the same or similar can be provided with the same reference symbols. The figures are only a schematic representation of an embodiment of the invention.

• 1 eine Ausführungsform eines erfindungsgemäßen elektromagnetischen Auslösesystems,
• 2 eine Detailansicht der Deckplatte des Magnetsystems gemäß der Ausführungsform nach 1, mit dem Steuerhebel und der Zusatzfeder,
• 3 schematisch ein erfindungsgemäßes Installationsschaltgerät mit einem elektromagnetischen Auslösesystem, sowie
• 4 eine weitere Ausführungsform eines erfindungsgemäßen elektromagnetischen Auslösesystems..

Show:

• 1 an embodiment of an electromagnetic release system according to the invention,
• 2 a detailed view of the cover plate of the magnet system according to the embodiment 1 , with the control lever and the additional spring,
• 3 schematically a service switching device according to the invention with an electromagnetic release system, and
• 4th another embodiment of an electromagnetic release system according to the invention ..

First there will be the 3 in connection with the 1 considered. 3 shows a service switching device in a schematic cross section 30th , with an insulating housing 31 . The Service switchgear 30th here is an example of a selective main line circuit breaker. Between an access clamp 32 and an output terminal 33 runs a main current path, which at a contact point 34 can be interrupted. The contact point 34 is formed between a fixed contact piece 35 , which with the output terminal 33 is in conductive connection, and a movable contact piece 36 . The moving contact piece 36 is located at the free end of a contact arm 20th . The contact arm 20th is with a control arm 21st to a double arm lever, the contact lever 5 , composed. At the junction between the contact arm 20th and the control arm 21st is the contact lever 5 pivotally mounted in an axis, the axis of rotation fixed to the housing and mounted in the housing 4th flees.

The housing parts, i.e. side parts, base plate - also called yoke anchor plate, based on those in the DE 10 2008 021 768 A1 terminology used - and the cover plate - also called core yoke plate - of the housing 17th of the magnet system 2 are at least partially made of metal. The current path is from the access terminal 32 starting over a ladder strip 38 who have favourited solenoid 46 , another conductor strip, the contact lever 5 and the contact point 34 to the output terminal 33 .

The magnet system 2 is in the interior of the device housing 31 fixed.

At the contact lever 5 remote side is on the cover plate 18th of the magnet system 2 a holding bar 39 appropriate. At its free end is a pivot axis 6th stored around the one control lever 7th is pivoted.

The control lever 7th is essentially like a double arm lever with a trigger arm 40 and a fetlock arm 41 built, with between the two partial arms, the trigger arm 40 and the fetlock arm 41 , there is a slightly obtuse angle of slightly more than 90 °. In the 1 is the control lever 7th in its rest position, the trigger arm 40 lies approximately parallel to the cover plate 18th . The free end of the control arm 21st and the free end of the trip arm 40 partially overlap and rest against one another in the overlap zone. This creates a coupling between the control lever 7th and the contact lever 5 produced. When the joystick 7th from the in the 3 or. 1 would rotate clockwise out of rest position shown, the contact lever would due to this coupling 5 Twisted counterclockwise, eliminating the contact point 34 would open.

At the free end of the fetlock arm 41 there is a first coupling point 8th for a shackle spring 9 . On the contact lever 5 , near the axis 4th , is a bondage bridge 22nd attached, approximately perpendicular to the contact or control arm 20th , 21st stands out. At its free end there is another coupling point for the restraint spring 9 . The coupling points are hooks into which the terminal eyelets of a cylinder spring can be hung.

The fetter 9 pulls in the in the 1 or. 3 position shown on the contact lever clockwise and on the control lever 7th in the counterclockwise direction. This causes the cuff spring 9 that at the point of contact 34 between the fixed and movable contact piece 35 , 36 a contact pressure force of the desired magnitude acts.

Between the axis 4th and the holding bar 39 is on the cover plate 18th another fastening bar 19th appropriate. At its free end there is a third coupling point 13 in the form of a hook. On the ankle 41 of the control lever 7th is located near the first coupling point 8th a second coupling point 11 , also in the form of a hook. Between the second and third coupling point 11 , 13 an additional spring can be used. In the example of the 1 and 3 is such an additional spring 12 used, also a cylinder spring with eyelets at its ends, with which it is hooked into the hooks of the second and third coupling point. When the additional spring 12 is attached, it causes an additional restraint force in the counterclockwise direction on the control lever 7th .

The magnet system 2 further comprises one of a drop anchor 3 driven striker 45 who is here in the 3 easily from the cover plate 18th is outstandingly represented. If a short-circuit current of sufficient strength occurs, the striker would 45 further from the cover plate 18th driven out upwards onto the free end of the trip arm 40 hit and thereby pivot the control lever clockwise out of its rest position into its release position, against the restoring force of the restraint spring 9 and, if installed, the additional spring 12 . The impact anchor acts on the striker 45, which in turn acts as a coupling link between the impact anchor and control lever, and on the free end of the release arm 40 presses or hits. The striker is located in the through hole of the magnetic core.

Other parts and assemblies of the service switching device, such as, for example, a thermal release, an arc extinguishing device, a switching mechanism or an auxiliary contact point, are shown in the schematic illustration according to 3 Not shown. They correspond to those known in the prior art.

The 1 shows a specifically executed embodiment of an electromagnetic release system according to the invention 1 as it is in 3 is shown schematically. The same reference symbols denote the same elements, parts or assemblies.

The 2 shows the cover plate in a detailed view 18th an electromagnetic release system according to the invention 1 . The same reference symbols denote the same elements, parts or assemblies. You can see the recess 44 , through which the striker, actuated by the strike anchor 3 (please refer 3 ), can push through to get onto the release arm 40 of the control lever 7th hold true. The fetlock arm 41 of the control lever 7th is designed in the form of a plate and transversely to the longitudinal direction of the release arm designed as an elongated strip 40 attached to this. On its free longitudinal edge it has an approximately rectangular recess, on the side walls of which the two hooks of the first and second coupling point 8th , 11 are formed by punching and bending. On the narrow sides of the fetlock arm 41 carries this in the direction parallel to the release arm 40 extending ear-shaped projections, ears for short, 42, at their free ends eyelets 43 to accommodate the swivel axis 6th are formed. How 1 shows, carries the retaining bar 39 also those ears with expressed stub axles which serve as bearings, so that the control lever 7th , can be pivotably connected.

Near the recess 44 is on the cover plate 18th a fastening bar 19th welded on in the form of a bracket. This carries a hook at its free end, which is the third coupling point for the additional spring 12 forms.

The attachment of the ear-shaped appendages 42 for receiving the pivot axis has something to do with the mechanical design already described above. The ear-shaped extensions ensure that the line of action of the force, which the auxiliary spring 12 on the joystick 7th exerts, even with a very small pivoting from the rest position clockwise into the axis of rotation of the pivot axis 6th is shifted and thus no longer exerts an effective restoring force on the control lever when the control lever is turned further. On the contrary, the additional spring can even after overcoming the dead center, which is formed by the fact that the line of action of the force of the additional spring 12 in the swivel axis 6th apply an additional torque and thus a twisting of the control lever 7th support in its clockwise release position. The additional spring 12 Due to this construction, it only counteracts clockwise rotation of the control part at the first moment. It only increases the restraint force on the control lever at the beginning of the release process 12 , in the further course of the contact opening process it no longer has any influence on the contact opening force.

Without attached additional spring 12 the electromagnetic release system would have the release characteristics caused by the restraint spring 9 is given alone, for example an E characteristic. By attaching the additional spring 12 a tripping characteristic with a higher response threshold can easily be made from the E characteristic. Nothing else needs to be changed in the electromagnetic release system, and the properties of the electromagnetic release system do not otherwise change either. The fastening bar 19th can either basically be welded to all cover plates, and then remains unused for devices with E characteristics. However, the fastening web can also only be welded to the cover plates of those electromagnetic release systems that are intended for use with an additional spring 12 are provided. Overall, an electromagnetic release system according to the invention can thus be configured in a very variable manner with minimal change intervention.

It will now be the 4th considered. This shows a further embodiment of an electromagnetic release system according to the invention. Components, assemblies or systems which are the same or have the same effect have the same reference numbers as in the previous figures. In the 4th is the cover plate 18th of the trip system shown with the contact lever 5 and the axis fixed to the housing 4th , as well as the control lever 7th . The restraint spring, the pivot axis for the control lever and the retaining bar are in the 4th not shown for the sake of clarity.

The embodiment according to 4th differs from the one as used in the 1 and 2 and 3 is shown, in that the third coupling point 13 is located on a spring holding part 47. The spring retainer 47 has a retaining leg 48 in the form of a rectangular plate, on one narrow side of which a support leg protruding perpendicular thereto 49 is molded. The third coupling point 13 is in the form of an eyelet-like recess on an overhead narrow side of the retaining leg 48 formed into which the end of the auxiliary spring 12 is hooked. The retaining leg 48 carries a central recess 50 , here a hole with which it is attached to an end piece of the axis fixed to the housing 4th is postponed. This is a basic device without the additional spring 12 can be easily upgraded to a release system with an additional spring. All that needs to be done is the spring holding part 47 pushed onto the axis fixed to the housing and the additional spring attached.

The additional spring exerts a torque on the spring holding part 47 without countermeasures this would therefore be on the axis fixed to the housing 4th twist and the line of force action of the additional spring would no longer be fixed, but different depending on the rotational position of the spring-holding part, which is undesirable. Therefore, the retaining leg carries 48 of the spring retainer 47 laterally one perpendicular to the axis fixed to the housing 4th towards the cover plate 18th pointing support leg 49 . This is dimensioned so that it comes up to a stop 51 which is at the top of the cover plate 18th is attached, is enough and rests against this when the additional spring 12 the spring retainer 47 applied clockwise. Through this coupling of the support leg 49 with the stop 51 when acted upon by the additional spring, the spring holding part is twisted 47 prevented.

The spring retainer 47 can advantageously be produced as a stamped and bent part in which the hole 50 and the support leg 49 are incorporated or attached in one operation. The attack 51 can be used in the manufacture of the cover plate 18th also punched out or from the cover plate 18th be stamped out, or it is then glued, welded, soldered or screwed to the cover plate as a small block, or fastened in another, in principle known, way. However, the variant according to which the stop is preferred is preferred 51 from the cover plate 18th is embossed, so as part of the cover plate 18th is executed.

List of reference symbols

1

Electromagnetic release system

2

Magnet system

3

Drop anchor

4th

housing-fixed axis for contact lever

5

Contact lever

6

Swivel axis for control lever

7th

Control lever

8th

first coupling point

9

Shackle spring

10

first end of the shackle spring

11

second coupling point for additional spring

12th

Additional spring

13

third coupling point for additional spring

14th

second end of cuff spring

17th

Yoke housing

18th

Cover plate of the yoke

19th

Fixing web of the yoke

20th

Contact arm of the contact lever

21st

Control arm of the contact lever

22nd

Shackle bar of the contact lever

30th

Service switchgear

31

Insulated housing

32

Access clamp

33

Output terminal

34

Main contact point

35

fixed contact piece

36

movable contact piece

38

Ladder strips

39

Retaining bar of the yoke

40

Trigger arm of the control lever

41

Control lever shackle arm

42

Ears of the control stick

43

Control lever eyelets

44

Recess in the cover plate of the yoke

45

Striker

46

Solenoid

47

Spring retainer

48

Retaining leg

49

Support leg

50

Recess

51

attack

Claims (13)

Electromagnetic tripping system (1) for a circuit breaker, with a magnet system (2) with striker (45), with a contact lever (5) rotatably mounted about an axis (4) fixed to the housing, with a control lever (7) mounted so as to be pivotable about a pivot axis (6) ), which has a first coupling point (8) on which a shackle spring (9) engages with its first end (10), the restraining force of the shackle spring acting on the control lever (7) in its rest position, and the control lever (7) under the action of the striker (45) from its rest position against the retaining force of the restraint spring (9) can be pivoted into its release position, with a coupling between the contact lever (5) and the control lever (7) which enables the control lever (7) to pivot transmits a pivoting movement of the contact lever (5), characterized in that the control lever (7) has a second coupling point (11) which is set up to attach an additional spring (12), w obei by the additional spring (12) when attached to the second coupling point (11) in the rest position of the Control lever (7) the retaining force of the restraint spring (9) is increased. Electromagnetic release system (1) according to Claim 1 , characterized in that the magnet system (2) has a third coupling point (13), the additional spring (12) being attached to the second and third coupling point (11, 13). Electromagnetic release system (1) according to Claim 1 , characterized in that the restraint spring (9) engages with its second end (14) on the contact lever (5). Electromagnetic release system (1) according to Claim 2 , characterized in that in the rest position of the control lever (7) the line of action of the force exerted by the additional spring (12) on the control lever (7) with respect to the pivot axis (6) lies on the same side as the line of action of the restoring force of the restraint spring (9) ), and that when the control lever (7) is unscrewed from the rest position, the line of action of the force exerted by the additional spring (12) on the control lever (7) intersects the pivot axis (6). Electromagnetic release system (1) according to Claim 2 , characterized in that the magnet system (2) comprises a housing (17) with a cover plate (18), and that the cover plate (18) has a fastening web (19), at the free end of which the third coupling point (13) is located. Electromagnetic release system (1) according to Claim 2 , characterized in that a spring holding part (47) is coupled to the axis (4) fixed to the housing, the third coupling point (13) being located on the spring holding part (47). Electromagnetic release system (1) according to Claim 6 , characterized in that the spring holding part (47) has a holding leg (48) and a supporting leg (49), the third coupling point (13) being located on the holding leg (48). Electromagnetic release system (1) according to Claim 7 , characterized in that the retaining leg (48) has a recess (50) for receiving the axis (4) fixed to the housing. Electromagnetic release system (1) according to Claim 7 , characterized in that the support leg (49) is coupled to a stop (51) in order to prevent rotation of the spring holding part (47) on the axis (4) fixed to the housing. Electromagnetic release system (1) according to Claim 9 , characterized in that the magnet system (2) comprises a housing (17) with a cover plate (18), and that the stop (51) is designed as part of the cover plate (18) or is attached to the cover plate (18). Electromagnetic release system (1) according to Claim 3 , characterized in that the contact lever (5) comprises a contact arm (20) which carries the movable contact piece (36), and a control arm (21) with which there is the coupling to the control lever (7), which on both sides one with the axis of rotation fixed to the housing (4) are fixed in alignment, and that a shackle web (22) is attached to the contact lever (5), at the free end of which the second end (14) of the shackle spring (9) engages. Installation switching device, in particular line circuit breaker, with a contact point which is formed between a fixed contact piece (35) and a movable contact piece (36), comprising an electromagnetic release system with a magnet system (2) with striker pin (45), with an axis (45) fixed to the housing. 4) rotatably mounted contact lever (5) which carries the movable contact piece (16), with a control lever (7) mounted so as to be pivotable about a pivot axis (6) and which has a first coupling point (8) on which a restraint spring (9) is connected its first end (10) engages, the restraint force of the restraint spring acting on the control lever (7) in its rest position, and the control lever (7) being pivotable from its rest position against the restraint force of the restraint spring (9) into its release position under the action of the impact anchor is, wherein between the contact lever (5) and the control lever (7) there is a coupling that a pivoting movement of the control lever (7) in a different transfers the pivoting movement of the contact lever (5) in its open position, in which the fixed and movable contact pieces (35, 36) are separated, characterized in that the control lever (7) has a second coupling point (11) which is used to attach an additional spring ( 12) is set up, the restraining force of the restraint spring (9) being increased by the additional spring (12) when it is attached to the second coupling point (13) in the rest position of the control lever (7). Installation switching device according to Claim 7 , characterized in that in the rest position of the control lever (7) the line of action of the force exerted by the additional spring (12) on the control lever (7) with respect to the pivot axis (6) lies on the same side as the line of action of the restoring force of the restraint spring (9) ), and that when the control lever (7) is unscrewed from the rest position, the line of action of the force exerted by the additional spring (12) on the control lever (7) intersects the pivot axis (6).

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