EP2244276A2 - Electromagnetic release system and installation device with an electromagnetic release system - Google Patents

Abstract

The system has a contact lever (5) rotatably mounted around a housing-fixed axle (4). A coupling exists between the contact lever and a control lever (7), and transfers pivot movement of the control lever into pivot movement of the contact lever. The control lever includes a coupling point (11) for attachment of an auxiliary spring (12). Retention force of a restraint spring (9) is strengthened by the auxiliary spring during attachment of the auxiliary spring in the coupling point in a rest position of the control lever.

Description

The invention relates to an electromagnetic tripping system for a circuit breaker, comprising a magnet system with a striker, a contact lever rotatably mounted about a housing-fixed axis, with a pivotally mounted about a pivot axis control lever which has a first coupling point on which engages a fetlock spring with its first end , wherein the restraining force of the fetlock spring acts on the control lever on the rest position, and wherein the control lever is under the action of the striker from its rest position against the restraining force of the fetlock in its release position is pivoted, wherein there is a coupling between the contact lever and the control lever, which is a pivoting movement of the control lever transmits 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 circuit breaker or a main line circuit breaker, having a contact point which is formed between a fixed contact piece and a movable contact piece, comprising an electromagnetic release system with a magnetic system with striker, with a rotatably mounted on a housing-fixed axis contact lever, which carries the movable contact piece, with a pivotable about a pivot axis mounted control lever which has a first coupling point on which a fetlock spring engages with its first end, wherein the restraining force of the fetlock spring acts on the control lever on its rest position, and wherein the control lever under the action the striker from its rest position against the restraining force of the fetlock spring in its release position is pivotable, wherein between the contact lever and the control lever is a coupling, which is a pivoting movement of the control lever in a pivoting movement of the contact lever transmits to its open position, in which the fixed and movable contact piece are separated, according to the preamble of claim 7.

A generic installation switching device is for example a selective main circuit breaker. Such main circuit breakers are mainly used in the lower terminal areas of meter locations, for example in a home installation system. They protect in cooperation with the downstream circuit breakers, each associated with individual load circuits, the electrical installation system against dangerous overcurrents and short-circuit currents by selectively and automatically shut off the downstream circuits in the event of overcurrent or short-circuit current.

For shutdown in the event of a short circuit, a generic service switching device has an electromagnetic release. The shutdown takes place within a few milliseconds by a current flowing through the electromagnet. A generic electromagnetic release is for example from the DE 10 2008 021 768 known. It comprises a magnetic core and a magnetic circuit with a movable armature, also referred to as impact armature, a coil assembly comprising a coil tube having a Kernjochplatte to which the magnetic core is fixed, and with a yoke anchor plate, as well as the core yoke plate and the yoke anchor plate connecting yoke -Seitenteile. These together with the core yoke plate and the yoke anchor plate form a housing for the coil arrangement with the armature and form a path for the magnetic flux. In a through hole of the magnetic core is the striker. At the Kernjochplatte a control lever is pivotally mounted. A shackle spring engages the control lever and the contact lever of the contact point. In this case, the restoring force of the fetlock 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 the movable contact piece are in contact with each other and the main contact point is thereby closed. The restraint spring simultaneously causes the contact pressure force and the bondage force for the control lever.

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

The force with which the armature strikes against the striker and this against the control lever depends on the magnitude of the short-circuit current. The so-called tripping characteristic of a miniature circuit breaker indicates at which multiple of the rated current the fast short-circuit tripping occurs, thus indicating the threshold of the circuit breaker. For example, selective miniature circuit breakers are produced according to the so-called E characteristic, in which the short-circuit current release can trigger at 5 to 6.25 times the rated current for alternating current, but must trigger at 6.25 times the rated current for alternating current.

For currents below the triggering threshold defined by the characteristic (ie 5 times the rated current) the electromagnetic release should not trip. The bondage mechanics, the mechanical system comprising the control lever and the fetlock spring, is therefore designed so that the force of the armature only from a short-circuit current corresponding to the lower threshold of the respective tripping characteristic, this can be referred to as a threshold force, for example, sufficient to the control lever to pivot to its trigger position. In particular, the leverage ratios in coordination with the stiffness of the fetlock spring are chosen so that after exceeding the threshold force of the further force curve during the pivoting of the contact lever is as low and uniform.

For certain applications, e.g. In the industrial sector, devices with a higher short-time delayed tripping behavior are required, ie with a higher threshold. To realize this, starting from previously known devices, the bondage mechanics must be completely redesigned and manufactured, which is costly.

Based on the solutions known in the prior art, it is therefore desirable to provide an electromagnetic trip system that is designed for a trip threshold and can be easily modified for use with at least one other trip threshold. It is a further object of the present invention to provide an improved service switching device designed for a tripping threshold and in a simple manner for use can be modified at least one other trigger threshold.

The object of providing an improved electromagnetic tripping system is achieved by an electromagnetic tripping system with the features of claim 1. With respect to the service switching device, the object is achieved by an installation switching device according to claim 7. Further developments of the aforementioned objects are set forth in the subclaims.

Thus, according to the invention, the control lever has a second coupling point, which is set up for fastening an additional spring, wherein the retaining force of the restraint spring is reinforced by the additional spring when attached to the second coupling point in the rest position of the control lever.

The advantage of the invention is that the existing magnetic trip system of a generic service switching device is modified so that the existing Fessel spring between the control lever and the contact lever, which is also the contact force spring, an additional restraining spring can be installed, which then when installed is, in addition to the control lever attacks. As a result, the restraining force of the control lever is increased to the anchor, without the force on the contact lever is changed. It is only increases the operating current of the electromagnetic tripping system, the force profile at the opening of the movable contact remains unchanged.

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

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

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 force with respect to the pivot axis on the same side as the action line of restoring force of the fetlock, and when unscrewing the control lever from the rest position intersects the line of action of the additional spring on the control lever applied force the pivot axis. The additional spring is arranged in total so that the spring action line is quickly shifted by the response of the magnet system via rotation of the control lever in the axis of rotation of the control lever, so that the force in the contact opening movement is 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 Kernjochplatte in the form of a mounting bracket. Thus, the existing core yoke plate can be used for both the E-characteristic, but also for a characteristic with increased triggering threshold, then the mounting angle for the auxiliary spring is welded.

According to a further advantageous embodiment, a spring-holding part is coupled to the housing-fixed axis, wherein the third coupling point is located on the spring-holding part. In this embodiment, a basic unit, which does not contain the auxiliary spring, can be used almost unchanged with additional spring. For the upgrade with the auxiliary spring a spring-holding part must be coupled only with the housing-fixed axis, which then forms the third coupling point for the additional spring.

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

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

According to a further advantageous embodiment of the support leg is coupled with a stop to prevent twisting of the spring-holding part on the housing-fixed axis.

According to a further advantageous embodiment, the magnet system comprises a housing with a cover plate, and the stopper 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, which are fixed on both sides of an axis aligned with the housing-fixed axis of rotation, and to the contact lever a tether is attached , at whose free end the second end of the fetlock spring attacks.

In an installation switching device according to the invention, the control lever has a second coupling point, which is adapted for fastening an additional spring, wherein the retaining force of the fetlock spring is reinforced by the additional spring when attached to the second coupling point in the rest position of the control lever.

According to an advantageous embodiment of the invention lies in the rest position of the control lever, the line of action of the additional spring on the control lever force with respect to the pivot axis on the same side as the line of action of the restoring force of the fetlock, and when unscrewing the control lever from the rest position intersects the line of action of force exerted by the auxiliary spring on the control lever force the pivot axis.

Figures and description serve to better understand the subject. Articles or parts of objects which are substantially the same or similar may be given the same reference numerals. The figures are merely a schematic representation of an embodiment of the invention.

Fig. 1

eine Ausführungsform eines erfindungsgemäßen elektromagnetischen Auslösesystems,

Fig. 2

eine Detailansicht der Deckplatte des Magnetsystems gemäß der Ausfüh- rungsform nach Fig. 1, mit dem Steuerhebel und der Zusatzfeder,

Fig. 3

schematisch ein erfindungsgemäßes Installationsschaltgerät mit einem elektromagnetischen Auslösesystem, sowie

Fig. 4

eine weitere Ausführungsform eines erfindungsgemäßen elektromagneti- schen Auslösesystems..

Showing:

Fig. 1

an embodiment of an electromagnetic tripping system according to the invention,

Fig. 2

a detailed view of the cover plate of the magnet system according to the embodiment according to Fig. 1 , with the control lever and the auxiliary spring,

Fig. 3

schematically an inventive switching device with an electromagnetic tripping system, and

Fig. 4

a further embodiment of an electromagnetic tripping system according to the invention.

It will be the first FIG. 3 in conjunction with the FIG. 1 considered. FIG. 3 shows in schematic cross section an installation switching device 30, with an insulating housing 31. The service switching device 30 is here as an example a selective main line circuit breaker. Between an access terminal 32 and an outlet terminal 33 is a main current path, which can be interrupted at a contact point 34. The contact point 34 is formed between a fixed contact piece 35 which is in conductive connection with the output terminal 33, and a movable contact piece 36. The movable contact piece 36 is located at the free end of a contact arm 20. The contact arm 20 is connected to a control arm 21 to a Double arm, the contact lever 5, composed. At the junction between the contact arm 20 and the control arm 21, the contact lever 5 is pivotally mounted in an axis which is aligned with a housing fixed and mounted in the housing axis of rotation 4.

The housing parts, ie side parts, base plate - also called yoke anchor plate, based on the in the DE 10 2008 021 768 A1 used terminology - and the cover plate - also called Kernjochplatte - the housing 17 of the magnet system 2 are at least partially made of metal. The current path extends from the access terminal 32 via a conductor strip 38, the magnetic coil 46, a further conductor strip, the contact lever 5 and the contact point 34 to the output terminal 33rd

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

At the side facing away from the contact lever 5, a holding web 39 is attached to the cover plate 18 of the magnet system 2. At the free end of a pivot axis 6 is mounted, about which a control lever 7 is pivotally mounted.

The control lever 7 is constructed substantially like a double-armed lever with a release arm 40 and a Fesselarm 41, wherein between the two partial arms, the trigger arm 40 and the Fesselarm 41, a slightly obtuse angle of slightly more than 90 °. In the FIG. 1 the control lever 7 is in its rest position, the trigger arm 40 is approximately parallel to the cover plate 18. The free end of the control arm 21 and the free end of the trigger arm 40 partially overlap and abut each other in the overlapping zone. As a result, a coupling between the control lever 7 and the contact lever 5 is made. When the control lever 7 from the in the Fig. 3 or 1 rest position shown in the clockwise direction, the contact lever 5 would be rotated counterclockwise due to this coupling, whereby the contact point 34 would be opened.

At the free end of the Fesselarms 41 is a first coupling point 8 for a restraining spring 9. At the contact lever 5, in the vicinity of the axis 4, a fetlock web 22 is attached, which protrudes approximately perpendicular to the contact or control arm 20, 21. At the free end there is another coupling point for the restraint spring 9. The coupling points are here hook in which the terminal lugs of a cylinder spring can be hung.

The Fesselfeder 9 pulls in in the FIG. 1 or 3 shown position on the contact lever in a clockwise direction and on the control lever 7 in the counterclockwise direction. As a result, the restraining spring 9 causes a contact pressure force of the desired magnitude to act at the contact point 34 between the fixed and the movable contact piece 35, 36.

Between the axis 4 and the holding web 39, a fastening web 19 is still attached to the cover plate 18. At its free end is a third coupling point 13 in the form of a hook. At the Fesselarm 41 of the control lever 7 is located in the vicinity of the first coupling point 8, 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 FIGS. 1 and 3 Such an additional spring 12 is used, also a cylindrical spring with eyelets at their ends, with which it is hooked into the hooks of the second and third coupling point. When the auxiliary spring 12 is mounted, it causes an additional captive force in the counterclockwise direction on the control lever. 7

The magnet system 2 further comprises a striking pin 3 driven by a striking pin 45, which here in the FIG. 3 is shown slightly protruding from the cover plate 18. Upon the occurrence of a short circuit current of sufficient strength, the striker pin 45 would continue to be driven out of the top plate 18, striking the free end of the trip arm 40 and thereby pivot the joystick clockwise out of its rest position into its trip position, counter to the restoring force of the shackle spring 9 and, if installed, the auxiliary spring 12. The impact armature acts on the striker 45, which in turn acts as a coupling member between the impact armature and control lever and presses or strikes the free end of the trigger arm 40. The striker is located in the through hole of the magnetic core.

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

The FIG. 1 shows a concrete embodiment of an embodiment of the invention electromagnetic release system 1, as it is in Fig. 3 is shown schematically. Like reference numerals designate like elements, parts or assemblies.

The Fig. 2 shows in a detailed view of the cover plate 18 of an electromagnetic tripping system according to the invention Fig. 1 , Like reference numerals designate like elements, parts or assemblies. One sees the recess 44, through which the striker, actuated by the impact armature 3 (see Fig. 3 ), to strike the trigger arm 40 of the control lever 7. The Fesselarm 41 of the control lever 7 is designed in the form of a plate and mounted transversely to the longitudinal direction of the trained as an elongated strip trigger arm 40 thereon. He wears at its free longitudinal edge an approximately rectangular recess, on the side walls, the two hooks of the first and second coupling point 8, 11 are formed by punching and bending. On the narrow sides of the Fesselarms 41 this carries in the direction parallel to the trigger arm 40 extending ear-shaped projections, ears short, 42, at the free ends of eyelets 43 are formed for receiving the pivot axis 6. As Fig. 1 shows, the support web 39 also carries such ears with expressed stub axles which serve as bearings, so that the control lever 7, can be pivotally connected.

In the vicinity of the recess 44, a fastening web 19 is welded to the cover plate 18 in the form of a bracket. This carries at its free end a hook which forms the third coupling point for the auxiliary spring 12.

The attachment of the ear-shaped projections 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 exerted by the additional spring 12 on the control lever 7, is already shifted at a very small pivoting from the rest position clockwise in the axis of rotation of the pivot axis 6 and thus no further rotation of the control lever effective restoring force exerts more on the control lever. On the contrary, the auxiliary spring can even after overcoming the dead center, which is formed by the fact that the line of action of the force of the auxiliary spring 12 is located in the pivot axis 6, apply an additional torque and thus support a rotation of the control lever 7 in its release position in a clockwise direction , The additional spring 12 counteracts due to this construction only in the first moment of the incipient rotation of the control part counterclockwise. Thus, it increases the restraint force on the control lever 12 only at the beginning of the triggering operation, in the further course of the contact opening process, it has no influence on the contact opening force. Without hinged auxiliary spring 12, the electromagnetic tripping system would have the tripping characteristic, which is predetermined by the restraint spring 9 alone, for example, an E-characteristic. By attaching the auxiliary spring 12 can be made in a simple manner from the E-characteristic a tripping characteristic with higher threshold. Nothing else needs to be changed in the electromagnetic tripping system, and otherwise the properties of the electromagnetic tripping system will not change. The attachment web 19 can either be basically welded to all cover plates, and then remains unused in the devices with E-characteristics. But it can also be welded to the mounting plate only on the cover plates of those electromagnetic tripping systems, which are provided for use with additional spring 12. Overall, an inventive electromagnetic trip system is thus highly variable configurable with minimal change intervention.

It will now be the FIG. 4 considered. This shows a further embodiment of an electromagnetic tripping system according to the invention. The same or equivalent components, assemblies or systems bear the same reference numerals as in the preceding figures. In the FIG. 4 the cover plate 18 of the release system is shown, with the contact lever 5 and the housing-fixed axis 4, and the control lever 7. The fetlock spring, the pivot axis for the control lever and the retaining bar are in the FIG. 4 for the sake of clarity not shown.

The embodiment according to Fig. 4 is different from the one in the FIGS. 1 and 2 and 3 is shown, characterized in that the third coupling point 13 is located on a spring-holding part 47. The spring-holding part 47 has a holding leg 48 in the form of a rectangular plate, on whose one narrow side a perpendicular thereto projecting support leg 49 is formed. The third coupling point 13 is formed in the form of an eye-like depression on an upper narrow side of the retaining leg 48, in which the end of the auxiliary spring 12 is hooked. The holding leg 48 carries a central recess 50, here a hole, with which it is pushed onto an end piece of the housing-fixed axis 4. Thus, a basic unit without the additional spring 12 is very easy to upgrade to a release system with additional spring. It only needs the spring-holding member 47 pushed onto the housing-fixed axis and the auxiliary spring are hung.

The additional spring exerts a torque on the spring-holding part 47, without countermeasure, this would therefore rotate on the housing-fixed axis 4 and the line of force of the auxiliary spring would no longer be fixed, but ever after the rotational position of the spring-holding part different, which is undesirable. Therefore, the holding leg 48 of the spring-holding member 47 carries laterally perpendicular to the housing-fixed axis 4 in the direction of the cover plate 18 toward supporting legs 49. This is dimensioned so that it up to a stop 51, which attached to the top of the cover plate 18 is, extends and applies against this when the auxiliary spring 12, the spring-holding member 47 acts clockwise. By this coupling of the support leg 49 with the stop 51 when acted upon by the additional spring twisting of the spring-holding member 47 is prevented.

The spring-holding member 47 may advantageously be made as a stamped and bent part, in which the hole 50 and the support leg 49 in one operation with or are attached. The stop 51 can also be punched or stamped out of the cover plate 18 in the production of the cover plate 18, or it is then glued as a small block on the cover plate, welded, soldered or screwed, or to another, known in principle, Art attached. Preferably, however, is the variant, according to which the stop 51 is embossed from the cover plate 18, so it is designed as part of the cover plate 18.

LIST OF REFERENCE NUMBERS

1

Electromagnetic trip system

2

magnet system

3

impact armature

4

fixed housing axis for contact lever

5

contact lever

6

Swivel axle for control lever

7

control lever

8th

first coupling point

9

restraint spring

10

first end of the bondage spring

11

second coupling point for additional spring

12

additional spring

13

third coupling point for auxiliary spring

14

second end Bondage spring

17

Yoke housing

18

Cover plate of the yoke

19

Fixing web of the yoke

20

Contact arm of the contact lever

21

Control arm of the contact lever

22

Tether of the contact lever

30

Service switching device

31

Insulated

32

access terminal

33

outgoing terminal

34

Main contact point

35

solid contact piece

36

movable contact piece

38

conductor strips

39

Holding bridge of the yoke

40

Trigger arm of the control lever

41

Fetterarm of the control lever

42

Ears of the control lever

43

Grommets of the control lever

44

Recess in the cover plate of the yoke

45

striker

46

solenoid

47

Spring-holding part

48

holding leg

49

support legs

50

recess

51

attack

Claims (13)

Electromagnetic triggering system (1) for a circuit breaker, comprising a magnet system (2) with a striking pin (45), a contact lever (5) rotatably mounted about a housing-fixed axis (4), with a control lever (7) pivotably mounted about a pivot axis (6) ), which has a first coupling point (8) on which a fetlock spring (9) engages with its first end (10), wherein the retaining force of the fetlock spring acts on the control lever (7) in its rest position, and wherein the control lever (7) under the action of the striker pin (45) from its rest position against the restraining force of the restraining spring (9) is pivoted into its release position, wherein between the contact lever (5) and the control lever (7) has a coupling, a pivoting movement of the control lever (7) in transmits a pivoting movement of the contact lever (5),
characterized in that the control lever (7) has a second coupling point (11) which is adapted for attachment of an additional spring (12), wherein by the additional spring (12) when mounted on the second coupling point (11) in the rest position of the control lever ( 7) the restraining force of the shackle spring (9) is reinforced. Electromagnetic triggering system (1) according to claim 1, characterized in that the magnet system (2) has a third coupling point (13), wherein the additional spring (12) at the second and third coupling point (11, 13) is attached. Electromagnetic triggering system (1) according to claim 1, characterized in that the restraining 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 auxiliary spring (12) on the control lever (7) force exerted on the pivot axis (6) on the same side as the Line of action of the restoring force of the restraint spring (9), and that when turning the control lever (7) from the rest position, the action line of the force exerted by the auxiliary spring (12) on the control lever (7), the pivot axis (6) intersects. Electromagnetic triggering 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) carries a fastening web (19), at its free end 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 housing-fixed axis (4), wherein on the spring-holding part (47), the third coupling point (13). Electromagnetic release system (1) according to claim 6, characterized in that the spring-holding part (47) has a retaining leg (48) and a support leg (49), wherein the third coupling point (13) on the retaining legs (48 ) is located. Electromagnetic release system (1) according to claim 7, characterized in that the holding leg (48) has a recess (50) for receiving the housing-fixed axis (4). Electromagnetic trip system (1) according to claim 7, characterized in that the support leg (49) is coupled to a stop (51) to prevent twisting of the spring-holding part (47) on the housing-fixed axis (4). Electromagnetic triggering 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) as part of the cover plate (18) running or on the cover plate (18) is attached. Electromagnetic triggering system (1) according to claim 3, characterized in that the contact lever (5) has a contact arm (20) which carries the movable contact piece (36) and a control arm (21) with which the coupling to the control lever (7). consists, which are fixed on both sides of an axis aligned with the housing fixed axis (4) axis of rotation, and in that on the contact lever (5) a tie bar (22) is fixed, at whose free end the second end (14) of the restraining spring (9) attacks. Service switching device, in particular circuit breaker, having 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 magnetic system (2) with striker (45), with a housing-fixed axis ( 4) rotatably mounted contact lever (5), which carries the movable contact piece (16) with a about a pivot axis (6) pivotally mounted control lever (7) having a first coupling point (8) to which a restraining spring (9) its first end (10) engages, wherein the restraining force of the fetlock spring the control lever (7) acted upon in its rest position, and wherein the control lever (7) under the action of the impact armature from its rest position against the restraining force of the restraint spring (9) pivoted into its release position is, wherein between the contact lever (5) and the control lever (7) has a coupling, a pivoting movement of the control lever (7) in e in pivoting movement of the contact lever (5) transmits in the open position, in which the fixed and movable contact piece (35, 36) are separated,
characterized in that the control lever (7) has a second coupling point (11) which is adapted for attachment of an additional spring (12), wherein by the additional spring (12) when mounted on the second coupling point (13) in the rest position of the control lever ( 7) the restraining force of the shackle spring (9) is reinforced. Service switching device according to claim 7, characterized in that in the rest position of the control lever (7), the line of action of the auxiliary spring (12) on the control lever (7) force exerted on the pivot axis (6) on the same side as the line of action of the restoring force the restraint spring (9), and that when turning the control lever (7) from the rest position, the line of action of the force exerted by the auxiliary spring (12) on the control lever (7) the pivot axis (6) intersects.

Images