EP0303965B1 - Electric switchgear - Google Patents

Abstract

Electrical switchgear for fitment to installation circuit breakers. Known switchgears have one or more contact points on which a switch mechanism acts, the switch mechanism interacting with an adjacent circuit breaker. Differential operation of the contact points is thus not possible. To operate the switch poles 35, 45, a switch mechanism 36, 46 is provided in each case, which switch mechanisms are independent of one another and in each case have a coupling element which engages with the adjacent circuit breaker. In this case, each switch mechanism 36, 46 operates a switch pole 35, 45 which in each case is designed as a two-way switch. The arrangement permits the optional connection of the switch poles as opening or closing contacts and allows them to be operated differentially.

Description

The invention relates to an electrical switchgear for mounting on automatic circuit breakers, in particular circuit breakers, with contact points for at least two potential-free switch poles, which are acted upon by an actuating device which cooperates with one or more coupling members which cover the flat sides of the housing of the switchgear and which have a narrow construction if necessary, reach through an adjacent circuit breaker, where they can transmit its switch position to the switch poles via the actuating device.

In electrical low-voltage switchgear, the circuits of which are protected by miniature circuit breakers and, if applicable, by residual current circuit breakers, there is often a need to trigger the safety circuit breakers and the circuit breaker by tripping as a result of overcurrent or short-circuit current or fault current associated interruption of the main circuits to switch so-called auxiliary circuits, ie to switch them on or off.

Auxiliary switches are provided for this purpose, which are arranged in addition to the self-switches installed in meter stations to protect the main circuits. It is advisable to attach the auxiliary switch to a permanently installed self-switch and to couple it mechanically to its release, so that in the event of a trip both the self-switch and the auxiliary switch attached to it are operated simultaneously.

Such an auxiliary switch attachment for circuit breakers has become known from German utility model DE-GM 74 26 189, which has auxiliary contacts in a space separated from the circuit breaker, which are acted upon by an actuating device which engages with the adjacent circuit breaker. The auxiliary switch attachment has a plurality of contact points arranged one above the other, which are formed by fixed contact pieces lying next to one another, each of which can be connected by means of a contact bridge.

The contact bridges are fastened to a contact bridge carrier designed as a slide, which can be displaced by an actuating element of the adjacent circuit breaker via a swivel lever. When changing the switch position of the circuit breaker, the position of the contact bridge support and thus the switch position in the auxiliary switch add-on part also change via this actuator.

By converting the contact bridge on the contact bridge support, it is possible to use the contact point of the auxiliary switch as an opener or a closer as required.

Based on this prior art, it is an object of the invention to improve a switching device of the type mentioned in terms of its handling, functional reliability and range of use. The switch should be compact and easy to use.

This object is achieved in that the actuating device is formed from two mutually independent switching mechanisms, each having a coupling member, which may be in engagement with the adjacent self-switch, that each switching mechanism acts on at least one switch pole, that each switch pole is designed as a changeover switch and that the actuating device has a first control handle and a second control handle.

In a preferred embodiment of the invention it can be provided that a first switch pole as a signal switch for indicating the switch-on position or the result of a malfunction, ie. H. Short-circuit or overcurrent, caused switch-off position of the self-switch is used, while the at least second switch pole is used to switch other auxiliary circuits on and off.

An advantageous embodiment of the invention provides for the switching mechanism of the first switch pole, which is used as a signal pole, to be equipped with a test device Check that the rear derailleur is working properly.

In particular, however, this test device can also be used to control a signal circuit connected with this switch pole. It is also contemplated that if the adjacent circuit breaker is triggered, the signal provided in this case will not appear due to an error in the signal circuit. The test facility is also provided in order to be able to locate such sources of error without interrupting the main circuit.

This test device is formed from a spring-loaded, longitudinally displaceable test button with a key surface on the end face and a sliding surface formed obliquely on its opposite end face, which cooperates with a release lever of the switching mechanism for the signal switch.

When the test device is actuated, ie when the test button is depressed, its sliding surface acts on a slide plate with a release lug, which in turn moves the release lever of the rear derailleur from its rest position and thus leads to the release of the rear derailleur, whereupon the associated switch pole comes into the off position. Simultaneously with the movement of the slide plate, an attached or integrally formed driver pin acts on a driver provided on the associated control handle, provided with a detent and moves it so that the control handle comes to the "off" position.

As already mentioned, it is provided according to the invention that the switching mechanisms for the switch poles are acted upon independently of one another by the adjacent self-switch.

The signal switch, which is used in particular to indicate error states in the main circuit of the circuit breaker - short circuit or overcurrent - is connected to a triggering element of the circuit breaker via the coupling element assigned to its switching mechanism. This release element in turn works with both the magnetic and the thermal release of the circuit breaker and thus transmits its movement directly to the coupling member, which actuates the switching mechanism of the signal switch.

The switching mechanism of the at least second switch pole, which is preferably used as an auxiliary switch for switching on and off other auxiliary circuits, is in engagement with the movable contact piece of the circuit breaker via the coupling member assigned to it.

In the known automatic switches to which the invention relates, the movable contact piece is mechanically coupled to the manual operating element of the automatic switch and can therefore be operated manually by the latter. Accordingly, with each manual actuation of the manual control element of the automatic switch, which is transferred to the movable contact piece, the at least second switch pole of the attached electrical switch, which is provided as an auxiliary switch, is simultaneously actuated.

According to the invention, the electrical switch also has a switching actuating element which is led out on the front side of the housing and is connected in a form-fitting manner to the self-switching manual actuating element for manually switching on the attached auxiliary and signal switch.

The switching mechanism of the first switch pole, which serves as a signal switch, is advantageously designed in such a way that the signal pole can be switched on, but cannot be brought into the switched-off position by manual actuation of the manual control element of the self-switch.

The result of this is that the signal switch, after being switched on, only comes into the switched-off position by pressing the test button or by a short-circuit or overcurrent that actually occurs, regardless of whether the adjacent self-switch was brought into the switched-off position manually, but the signal contact is switched off by means of the test facility not transferred to the adjacent self-switch.

According to a further special embodiment of the invention, the electrical switch is provided with a manual actuating element which serves as a visual switch position indicator.

Here, the actuating member is formed from two control handles which are arranged pivotably about a common axis of rotation. The first control handle, which has a different color than the second control handle to distinguish it, is connected to the switching mechanism of the signal pole. The second of the two control handles is for prepared form-fitting intervention in the manual control element of the adjacent self-switch and serves to switch on the switching devices at the same time. In addition, it has a driver that serves to bring the signal pole switch mechanism into the ON position.

As already mentioned above, the switching mechanism of the signal switch can be switched on manually together with the adjacent self-switch or alone; however, manual deactivation of the signal pole is not possible. This is also not possible with the control handle that is directly engaged with the switching mechanism of the signal pole, since the latch provided in the switching mechanism can only be triggered by actuating the test button or by activating the thermal or magnetic release of the circuit breaker. Both lead to a change in position of the coupling member and thus to a triggering of the switching mechanism of the signal switch.

In a preferred embodiment of the invention, the electrical add-on switch is accommodated in a double-shell housing which consists of half-shells formed in mirror image. The division level of the switch housing, the thickness of which corresponds to half the module width of the usual self-switches, runs at half the thickness parallel to the flat side of the switch housing and divides it into two halves of equal thickness, which accommodate the individual parts of the switch including the connecting terminals.

In this way, it is possible to use the connecting terminals, which are usually provided with clamping screws and are inserted into pre-formed recesses in the housing shells, torsion-proof even against high torques when clamping the electrical connection conductors without further measures, e.g. B. Glue to install.

Another advantage of the invention can be seen in the fact that the contact points for the switch poles, signal switches and auxiliary switches are each designed as changeover switches, so that an optional use as NO or NC contact is ensured without additional effort.

The pin assignment for the contact points is provided in a known manner on the upper and lower end faces facing the switch poles, with each connecting terminal recessed with its clamping screws being accessible only with tools.

To connect the housing shells, alternately molded hooks and corresponding recesses are provided, which interlock.

The electrical switch can be attached to a circuit breaker at any time, i. H. also possible retrospectively by the customer, provided that the provided automatic switches are prepared for this.

According to a special embodiment of the invention, the switching device is fastened to the self-switch by means of clamps which each encompass the narrow sides of the two housings and engage in a form-fitting manner in recesses on the flat sides.

According to another embodiment, pin-shaped connecting elements, for. B. screws or rivets, provided for attachment, which penetrate the housing.

These and further advantageous refinements of the invention are specified in the subclaims.

The invention, advantageous refinements and further advantages of the invention are to be explained and described in more detail with reference to the drawing, which represents an exemplary embodiment of the invention.

Figur 1

Eine Anordnung von elektrischen Selbstschaltern und dem erfindungsgemäßen Schaltgerät auf einer Tragschiene in Schrägansicht

Figur 2

das erfindungsgemäße Schaltgerät in Schrägansicht

Figur 3

das Schaltgerät gemäß Figur 2 im Längsschnitt in Schaltstellung "Aus"

Figur 4

das Schaltgerät gemäß Figur 2 im Längsschnitt in Schaltstellung "Ein"

Figur 5

das Schaltgerät gemäß Figur 2 im Längsschnitt in Schaltstellung "Freiauslösung"

Figur 6

das Schaltwerk des Signalschalterpols

Figur 7

eine Ansicht eines Schaltgriffs

Figur 8

einen Längsschnitt durch den Schaltgriff gemäß Figur 7 (entlang der Linie VII-VII)

Show it:

Figure 1

An arrangement of electrical circuit breakers and the switching device according to the invention on a mounting rail in an oblique view

Figure 2

the switching device according to the invention in an oblique view

Figure 3

the switching device according to Figure 2 in longitudinal section in the switching position "off"

Figure 4

2 in longitudinal section in the switching position "on"

Figure 5

the switching device according to Figure 2 in longitudinal section in the switching position "free trip"

Figure 6

the switch mechanism of the signal switch pole

Figure 7

a view of a control handle

Figure 8

a longitudinal section through the shift handle according to Figure 7 (along the line VII-VII)

FIG. 1 shows an arrangement of electrical circuit breakers 10 and an electrical switching device 12 according to the invention, which are fastened on a mounting rail 14.

The electrical self-switches 10 are provided in a known manner with triggering elements (thermal and magnetic triggers), which are not shown in detail, for the automatic triggering of the previously switched on self-switches 10. The switching device 12 according to the invention arranged between two electrical self-switches 10 has, as will be explained in detail below, no self-trigger , but is coupled to one of the adjacent self-switches 10 with the aid of coupling members 16 which cannot be seen in this illustration.

As can also be seen from this illustration, the contour of the housing of the switching device 12 according to the invention follows the shape of the self-switches 10, i. that is, the switching device 12 forms a uniform switch block with the self-switches 10 lined up next to it.

It is also shown in FIG. 1 that the switching device 12 has an actuating member formed from two switching handles 20, 21, which is aligned with the switching knobs 22 of the adjacent automatic switches 10, 11.

Furthermore, the switching device 12 has on both sides of the actuator 20, 21 three juxtaposed clamping screws 24, which belong to screw terminals 25, not shown in this illustration, which are connected to the Narrow end faces of the switching device 12 access openings 26 arranged one above the other can be reached.

In contrast, in the case of the automatic switches 10, only one electrical connection 28 is provided on each of the two narrow end faces, which can be reached via access openings 29. The self-switches 10 are provided in a known manner with a groove 30 which has a firmly formed locking lug and a movable locking slide with which the self-switches 10 are snapped onto the mounting rail 14 which is designed as a top-hat rail.

In Figure 2, the switching device 12 is shown individually in an oblique view, in particular the previously unrecognizable coupling members 16, 18 are shown, as well as the groove 31 formed on the rear of the switch, which receives the mounting rail 14.

In contrast to the self-switches 10, the groove 31 has neither a firmly formed locking lug nor a movable locking slide, since only the attachment to the adjacent self-switch 11 is provided in holding openings 34.

The coupling members 16, 18, which penetrate a flat side 32 of the switching device 12 at a distance from one another, are guided in curved columns 17, 19 - similar to a switching link - in the side wall 32 of the switching device 12.

For fastening to the self-switch 11, as shown in FIG. 1, the holding openings 34, which serve to hold holding elements (not shown in more detail), which are non-positively and / or positively connected to the automatic switch 11.

Figure 3 shows the longitudinal section through the switching device 12. In this illustration it can be seen that the switching device 12 has two switch poles 35, 45, each of which is acted upon by an associated switching mechanism 36, 46. Each of the switch poles is designed as a changeover switch and has three connection terminals 25 for connecting the electrical supply and output lines. The terminals 25 closest to the rear with the groove 31 serve as access terminals 37, 47, while the terminals 25 above are provided as outgoing terminals 38, 39, 48, 49.

The access terminals 37, 47 are each connected to a movable contact 52, 53 via a flexible conductor piece 50, 51.

Each of the movable contacts 52, 53 is composed of a rotary lever 54, 55 and a contact arm 56, 57 formed thereon with a contact piece.

The contact arms 56, 57 pivot due to the action of the switching mechanisms 36, 46 from a fixed contact piece 60, 61 to an opposite fixed contact piece 62, 63.

Actuating arms 58, 59, which engage the rotary levers 54, 55, are used for the connection to the switching mechanisms 36, 46. An intermediate wall 42 is provided as electrical insulation between the movable contacts 52, 53 and is formed above the groove 31 on the rear wall of the switch housing 40.

The switch pole 35 arranged in FIG. 3 to the right of the intermediate wall 42 is provided according to the invention as a signal switch and is actuated by the adjacent self-switch 11 when the thermal or magnetic trigger is activated, via the coupling member 18, which is coupled to the switching mechanism 36 Has.

According to the invention, manual actuation of the movable contact of the signal switch pole 35 is only possible by actuating a test device 44. The test device 44 is formed from a spring-loaded button with a tactile surface, which is arranged next to the actuating member 20, 21 and, as can be seen in FIG. 3, has an obliquely positioned sliding surface 64 which acts on a release pin 66, the change in position thereof for actuating the movable contact 52 leads through the switching mechanism 36.

The switch position shown in FIG. 3 is defined with regard to the position of the actuating member 21 as the switch-off position, since in this position of the manual control knob 22 the self-switch 10, 11 whose contacts are open.

The switch pole 45 arranged to the left of the intermediate wall 42 serves as an auxiliary switch for switching on or off auxiliary circuits in the event of the circuit breaker being triggered by overcurrent or short-circuit current.

The rear derailleur 46 consists of two lever arms 72, 74 which are rigidly connected to one another at a certain angle and pivot about a pivot point 70 when the coupling member 16, which is in engagement with the movable contact of the adjacent circuit breaker 11, is moved. Here, the double lever 72, 74 executes a pivoting movement, by means of which the contact arm 57 of the movable contact 53 is pivoted to the other fixed contact 63.

The terminals 25 are through tunnel-like recesses 24 for actuating tools, for. B. screwdriver, accessible and through feed openings 26 for connecting electrical lines.

It is further provided according to the invention that the two-part actuator serves simultaneously as a switch position indicator for the signal switch pole 35. It is provided that the first switching handle 20, which is covered by the second switching handle 21 in FIG. 3 and is connected directly to the switching mechanism 36 of the signal switch pole, indicates the respective switching position of the movable contact 52 of the signal switch pole 35. This enables the signal switch pole 35 to be switched on again manually after it has been switched off.

An actuating pin 67 provided on the switching mechanism 36 cooperates with a driver, not shown, arranged on the second switching handle 21. It is thus possible, when the switching mechanism 36 is triggered, to return it to its switched-on position.

FIG. 4 shows the switching device 12 shown in FIG. 2 and explained above in the switching position "on" in a longitudinal section.

With regard to the details of the switching device 12, which can be seen in the figure, reference is made to the explanations relating to FIG. 3, since they correspond to the details explained there and differ only in the switching position. The different switching position is initially easy to see in comparison with FIG. 3.

The contact arms 56, 57 of the movable contacts 52, 53 are each pivoted to the other fixed contact 62, 63. Furthermore, the other switch position is also shown by the position of the second switch handle 21, which is pivoted to the right in relation to the switch-off position shown in FIG. 3.

Figure 5 shows the switching device 12 according to Figure 2 in the switching position "free trip" in longitudinal section.

With regard to the position of the contact arms 56, 57 of the movable contacts 52, 53, there is no difference in this switching position from the switching position “off”, which is shown in FIG. 3. However, it can be seen from Figure 5 that the second control handle 21 is in the position which corresponds to the switch-on position. This is made possible by the fact that a pawl lever 76, which is normally supported in a latching point 77 on a spring-loaded release lever 78, is triggered by moving an S-shaped slide plate 80 and thereby brings the contact arm 56 into the switched-off position.

This displacement of the slide plate 80, which leads to the triggering of the pawl lever 76, is caused by the coupling member 18 from the adjacent automatic switch 11 to the Transmitter 36 transmitted. In the same way, the coupling member 16 transmits the contact movement from the self-switch 11 to the switching mechanism 46. Free tripping is to be understood here to mean that the switch-on should take place even though there is an overcurrent or short-circuit current at the time of switching on, due to which the thermal or magnetic release responds.

FIG. 7 shows the side view of the second control handle 21, which has a body 90 made of insulating material, on which a projection 92 is formed for the positive connection with the control handle 22 of the adjacent automatic switch 11. An elongated cavity 91 is provided inside the second control handle 21, which serves as a guide for the already mentioned driver 94. The driver 94 is a sheet metal stamped part, which is preferably made of sheet steel, but possibly also of copper or aluminum alloy, because of the low cost, and has a longitudinal section in the form of a circular disc with a molded handle. The stem serves as a guide in the cavity 91, while the circular disk fulfills several functions. First, the circular disk is provided with a central recess 99 for receiving the pivot axis 96 for the second control handle 21. The recess 99 has an oval shape and thus allows eccentric displacements of the circular disk. This enables the driver 94 to slide back into the cavity 91, which also receives a compression spring 98 for loading the driver. A molded on the outer circumference of the circular disk of the driver 94 catch 95 takes the axis of rotation 81 of the actuating lever 75 with a pivoting movement of the control handle in the direction of the switch position and thus brings the switching mechanism 36 and the associated switch handle 20 of the signal switch pole 35 into the switch-on position.

FIG. 8 shows a longitudinal section through the second control handle 21 according to FIG. 7 along the section line VII-VII, it being evident that the driver 94 is held in the housing body 90 of the control handle 21 by means of two bent tabs 97. The arrangement of the compression spring 98 is also shown, which the driver in the longitudinal direction of the cavity 91, i. H. acted radially to the pivot axis 96 of the second control handle 21. For the longitudinal mobility of the driver 94, two longitudinal gaps 93 are also provided, which serve to receive the tabs 97.

The structure and mode of operation of the two switching mechanisms 36, 46 will be explained below.

The switching mechanism 46 for the auxiliary switch pole 45 has the coupling member 16, the swivel arm 72, which receives the coupling member 16 at one end, and the transmission lever 74, which is pivotally mounted on the other end of the swivel arm 72, which is pivotably mounted here on a housing pin 70, under one Angle rigidly connects.

The pivoting movement of the coupling member 16, which it carries out when interacting with the adjacent automatic switch 11 when it is triggered, is correspondingly transmitted to the transmission lever 74, the change in position of its free end, to which the connecting rod 59 is articulated, which is connected to the movable contact 53 is, leads to a switching position change of the auxiliary switch pole 53.

The structure and mode of operation of the switching mechanism 36 is more extensive than that of the switching mechanism 46. Therefore, the principle sketch shown in FIG. 6 will be used to explain this in more detail.

The central switching mechanism element of the switching mechanism 36 is the slide plate 80 already mentioned, which is displaceably guided on a circular path around the pivot point of the second control handle 21 through an elongated hole 82 and a guide pin 84 formed on the opposite side of the slide plate 80 and concealed in this view and therefore drawn in dashed lines is. The elongated hole 82 surrounds a housing pin 71, while the guide pin 84 is guided in a housing gap, not shown here, which is formed, for example, by two parallel housing webs.

Another guide pin 86, which carries the coupling member 18, slides in an arcuate recess in the housing cover and thus prevents the slide plate 80 from tilting, the S-shaped outer contour of which roughly corresponds to the curved displacement path.

Apart from the switch position "free release", the latching point 77 simultaneously forms a fulcrum for the latch lever 76, which is connected to the second switching handle 21 via an adjusting lever 75. The switch position shown in FIG. 6 corresponds to the switch-on position.

With the exception of the free release, the pawl lever 76 pivots about the latching point 77 due to the action of the actuating lever 75.

When the shift handle 21 is in the switched-off position, its articulation point 81 for the actuating lever 75 is at a greater distance from the latch lever 76 than in the switched-on position. Due to the rigid coupling by the actuating lever 75, the pawl lever 76 is correspondingly retracted and pivots about the latching point 77. The movable signal contact 52, not shown here, whose pivoting lever 54, as shown in FIG at the auxiliary contact 53 is mounted around a housing pin 41, operated.

When the test device 44 is actuated, in which the oblique edge 64 acts on the release pin 66, the slide plate 80 is correspondingly shifted to the right and presses with its release lug 83 against the release lever 78, as a result of which the latching point 77 releases the latch lever 76. Here, the articulation point 79 on the pawl lever 76 serves as a floating bearing for the actuating lever 75, about which the support arm 76 pivots clockwise and also actuates the signal contact 52 via the transmission lever 58.

Simultaneously with the displacement of the slide plate 80, the driver 94 arranged in the second control handle 21 is acted on by means of a driver pin 67 formed thereon. The driver pin 67 presses against the driver 94, whereby this slides back into the cavity 91 provided as a longitudinal guide in the second control handle, so that the locking lug 95 formed on the driver 94 does not come into engagement and the second control handle 21 after the unlatching process into the switched-off position goes back.

The same process takes place in the so-called free release, the coupling member 18 providing for the lateral displacement of the sliding plate 80.

The axis of rotation of the articulation point 79 is in this case guided in an arc-shaped groove in the lower housing part and thereby defines the sequence of movements for the pawl lever 76 and the adjoining transmission lever 58.

Claims (17)

1. Electric switching device (12) for fitting on an installation automatic circuit-breaker (10, 11), especially a power circuit-breaker, having contact points (60, 61, 62, 63) for at least two potential-free breaker poles (35, 45) which are acted on by an operating device (36, 46) which interacts with one or more coupling elements (16, 18) which penetrate the flat sides (32) of the housings, constructed to a compact design, of the switching device (12) and, if necessary, of an adjoining automatic circuit-breaker (11), it being the case that they transfer the switch position of the latter to the breaker poles (35, 45) via the operating device (36, 46), characterised in that the operating device is formed from two mutually independent switch mechanisms (34, 46) which in each case have a coupling element (16, 18) which optionally engages with the adjoining automatic circuit-breaker (11), in that each switch mechanism (36, 46) acts on at least one breaker pole (35, 45), in that each breaker pole (35, 45) is constructed as a two-way switch, and in that the operating device has a first operating handle (20) and a second operating handle (21).
2. Electric switching device according to Claim 1, characterised in that the operating device has a test device (44) which serves for functional testing of the first switch mechanism (36) and of the assigned breaker pole (35).
3. Electric switching device according to Claim 2, characterised in that the test device (44) serves for controlling a signal circuit connected to the assigned breaker pole (35).
4. Electric switching device according to Claim 2 or 3, characterised in that the test device (44) is configured as a longitudinally displaceable test key having a probe surface on the end face and a sliding surface (64) integrally formed obliquely on its opposite end face for acting on a triggering pin (66) of the first switch mechanism (36).
5. Electric switching device according to one of the preceding claims, characterised in that two breaker poles (35, 45) are provided, of which the first breaker pole (35) serves as signalling breaker and the second breaker pole (45) serves as auxiliary switch.
6. Electric switching device according to one of the preceding claims, characterised in that the first breaker pole (35), which is provided as signalling pole, is acted on by the first switch mechanism (36), which is provided with the test device (44).
7. Electric switching device according to one of the preceding claims, characterised in that the coupling element (18) of the switch mechanism (36) for the first breaker pole (35) engages in a triggering lever of the adjoining automatic circuit-breaker (11), and transfers the switching movement thereof, which is caused by a thermal or magnetic trigger in the event of response, to the first breaker pole (35) via the first switch mechanism (36).
8. Electric switching device according to one of the preceding claims, characterised in that the coupling element (16) of the second switch mechanism (46) for the second breaker pole (45) can engage with a moving contact of an adjoining automatic circuit-breaker (11), and transfers the switching movement thereof to the second breaker pole (45) via the second switch mechanism (46).
9. Electric switching device according to Claim 2, characterised in that the triggering pin (66) is integrally formed on a slider plate (80) which interacts with a triggering lever (78).
10. Electric switching device according to Claim 8, characterised in that the slider plate (80) has a triggering nose (83) which upon operation of the test device (44) acts on the triggering lever (78) and thereby releases the latching lever (76).
11. Electric switching device according to one of the preceding claims, characterised in that the first operating handle (20) is connected to the first switch mechanism (36) of the signalling breaker pole (35) and serves the manual connection thereof.
12. Electric switching device according to one of the preceding claims, characterised in that the first operating handle (20) serves for indicating the switch position of the signalling breaker pole (35).
13. Electric switching device according to Claim 10, characterised in that the second operating handle (21) can be connected to the manual operating element (22) of an adjoining automatic circuit-breaker (11) and serves for simultaneous connection of the switching devices (11, 12).
14. Electric switching device according to one of the preceding claims, characterised in that the second operating handle (21) has a driver (94) which is longitudinally guided in the handle (90) and grips by means of a latching nose (95) the axis (81) of rotation of the connecting lever (75), which axis penetrates the second operating handle (21), and thus drives into the connected position the first operating handle (20) and the first switch mechanism (36), coupled thereto, of the signalling breaker pole (35).
15. Electric switching device according to Claim 13, characterised in that the longitudinally displaceable driver (94), which is guided in the second operating handle (21), is acted on radially relative to the pivoting axis (96) of the second operating handle (21) by a compression spring (98).
16. Electric switching device according to one of the preceding claims, characterised in that a driver pin (67) integrally formed on the slider plate (80) displaces the latching nose (95), which is integrally formed on the driver (94), and thereby releases the axis (81) of rotation of the connecting lever (75).
17. Electric switching device according to one of the preceding claims, characterised in that the driver (94) is a bent punched part made from sheet metal.

Images