WO2008068020A2 - Installation switchgear comprising a double break - Google Patents

Abstract

The invention relates to an installation switchgear (1) with at least one pole current path (2), said switchgear comprising two fixed contact pieces (5, 6) and two mobile contact pieces (8, 9) arranged on a mobile contact bridge (7), forming a pole switch with two contacts and a double break. The contact bridge (7) is acted upon by a pusher (12) in the opening direction (O) and by a contact pressure spring (11) in the closing direction. The two contacts are closed in the connected state, and in the event of a short circuit, the contact bridge is pushed in the opening direction thereof and the pusher is moved into its trigger position in which it acts on the contact bridge in order to open same. Said switchgear is also provided with an electromagnetic tripping device (13), the armature of which releases the latching position of a switch latch (15) in the event of a short-circuit, such that the switch latch maintains the pusher (12) in the trigger position thereof by means of an actuating lever (17) which lags in relation to the pusher (12) and moves from the idle position into the disconnected position thereof. The contact bridge (7) is thereby permanently held open against the force of the contact pressure spring (11). The installation switchgear (1) comprises a control slide (30) mounted in such a way that it can be displaced between a release position and a locking position and, in its locking position, maintains the pusher in the trigger position thereof. The movement of the actuating lever from its idle position into its disconnected position causes the control slide to move from its locking position into its release position such that the pusher (12) is released from the trigger position thereof.

Description

 Installation switching device with a double break

description

The invention relates to an installation switching device with a double break according to the preamble of claim 1. Generic installation switching devices, such as motor protection switch, have at least one Polstrompfad, comprising two fixed contacts and two arranged on a movable contact bridge, movable contact pieces through which a pole switch with two contacts and double interruption is formed. The contact bridge can be acted upon by a pusher in the opening direction and by a contact pressure spring in the closing direction. When switched on, the two contacts are closed. In the event of a short circuit, the contact bridge is pushed into its opening direction and the pusher is moved into its release position, in which this acts on the contact bridge opening. Furthermore, generic installation switching devices include an electromagnetic release whose armature unlocks the Verklinkungsstelle a switching mechanism when a short-circuit current in the Polstrompfad so that this trailing the trigger from its rest position to its off position and thereby moving from its rest position to its off position effective lever the pusher holds in its release position and thus the contact bridge is permanently opened against the contact pressure spring.

Immediately after opening the contact bridge and thus interrupting the 'short-circuit current in the Polstrompfad breaks the electrodynamic recoil of the electromagnetic release together and the contact bridge is hit by the force of the contact pressure spring back in the closing direction to its closed position.

Due to the greater inertia of the mechanical system formed by the switch lock and the active lever, compared with the lower inertia of the armature and the pusher comprehensive mechanical system, the active lever hurries for permanent keeping open of the contacts through the switch lock the pusher movement after. Because after unlatching the switching mechanism, it takes a certain time until the active lever is acted upon by the switching mechanism in the opening direction, and then again passes a certain amount of time until the active lever has traveled the designated as tripping distance between its rest position and its point of attack on the pusher , For design reasons, a certain trip path of the action lever is unavoidable, since the pusher and the active lever at rest require a certain amount of play. Under unfavorable conditions, it may happen that the contacts have already been closed again by the contact pressure spring before the switch lock can cause a permanent opening via the active lever and the pusher. One then speaks of the occurrence of a contact bounce, which is undesirable.

It is therefore the object of the present invention to provide a generic instal onsschaltgerät with improved dynamic behavior in the short-circuit current interruption while avoiding contact bounce.

The object is achieved by a generic service switching device me the characterizing features of claim 1.

According to the invention the installation switching device comprises a displaceably mounted between a release position and a locking position spool, which holds the pusher in its release position in its locking position, wherein the movement of the action lever from its rest position in its off position a shift of the spool from its locked position to its release position causes, so that then the movement of the pusher is released from its release position.

It is thus effectively prevented premature contact closure by the spool of the invention. The service switching device requires only an additional component or an additional module, namely the spool, so that an easy to install and cost-effective solution is achieved. According to an advantageous embodiment of the active lever is mounted in a fixed axis of rotation, acting as a reversing lever toggle lever with a first and a second lever arm.

According to a further advantageous embodiment, in the switch-off position of the active lever, the second lever arm of the action lever is coupled to the pusher so that it can hold it in its release position.

According to a further advantageous embodiment, the control slide is held by the pusher in its release position in the on state, and in the case of short circuit, the displacement of the spool is released into its locking position as a result of the movement of the pusher in its release position.

According to a further advantageous embodiment of the spool can be designed as a diaphragm with an opening, wherein in the locking position, the aperture blocks the movement of the pusher from the triggering out, and in the release position, the opening releases the displacement of the pusher from the triggering out position. In this case, in a further very advantageous embodiment, the spool or the diaphragm can be coupled to the active lever via a spring, so that the displacement of the control panel between the release and the locking position is controlled by the spring coupling with the active lever. In a further advantageous embodiment of the invention, the control lever is hinged to the control lever in the rest position of the active lever in the direction of its locking position acting spring. In a very advantageous embodiment of the invention, the spring may be a bent leaf spring.

The control of the displacement of the spool between its release position and its locking position thus happens according to the invention by the interaction between the mechanical coupling of the spool with the active lever and the inhibition of movement of the spool by the pusher.

If the spool of the invention is designed as a shutter and is in the release position, the shutter is penetrated by the pusher in its opening, whereby a sliding movement of the shutter is blocked by the pusher. At the same time the shutter is in its release position when the active lever is in his Resting position is applied by mechanical coupling towards their locking position with a force.

As soon as the pusher is beaten into its release position by an electromagnetic release by the armature of the electromagnetic release or by an electrodynamic repulsion between the fixed and the movable contact pieces, it leaves the area of action of the aperture of the aperture and releases it. Under the influence of the mechanical coupling with the active lever, the diaphragm can now move into its locking position.

Now, if the armature force has collapsed after the interruption of the short-circuit current and the contact bridge and the pusher are pressed back into the on position by the restoring force of the contact pressure spring, then this closing movement of the pusher is inhibited by the aperture now in its locked position ,

Only when the active lever has been used by the switching mechanism in such a switch-off, in which he can now inhibit the closing movement of the pusher permanently, the aperture is returned to its release position due to the mechanical coupling between the diaphragm and the active lever.

And after the switch lock has been latched and reset by intervention of an operator, and thereby the active lever was returned to its rest position, the pusher is released and can now go through the opening in the aperture back into its on position.

According to an advantageous embodiment of the invention, the spring, which produces the coupling between the active lever and the control panel, a bent leaf spring.

The active lever can be in a very advantageous embodiment of the invention in a fixed rotational axis mounted toggle lever with a first and a second lever arm, which acts as a lever. The first lever arm is acted upon by the switching mechanism, the second lever arm can hold the pusher on a shoulder in its trigger position. The direction in which the force pulse is transmitted from the Lock acts, forms an angle with the direction of movement of the pusher. The reversing lever thus deflects the direction of action of the switching mechanism in the direction of movement of the pusher.

Reference to the drawings, in which an embodiment of the invention is shown, the invention and further advantageous refinements and improvements of the invention will be explained and described in detail.

Show it:

1 shows a functional diagram of an installation switching device according to the invention according to a first embodiment with a diaphragm in its release position,

FIG. 2 shows a functional diagram of the service switching device according to FIG. 1 shortly after the occurrence of a short-circuit current,

3 shows a functional diagram of the service switching device according to FIG. 1 while inhibiting the return movement of the pusher, through the panel in its locking position, FIG.

4 shows a functional diagram of the service switching device according to FIG. 1 with permanent opening through the switch lock via the active lever, FIG.

5 shows a schematic representation of a second embodiment with a control slide, which is guided on the underside of the second lever arm of the active lever, in its release position, FIG.

FIG. 6 shows a representation of the embodiment according to FIG. 5, with the return movement of the pusher being inhibited by the control slide in its locking position,

FIG. 7: a representation of the embodiment according to FIG. 5, with permanent opening through the switch lock via the active lever, 8 shows a schematic representation of a third embodiment with a control slide, which is guided on the underside of the second lever arm of the active lever, in its release position,

FIG. 9 shows an illustration of the embodiment according to FIG. 8, while inhibiting the return movement of the pusher, by the control slide in its

Locking position,

FIG. 10: a representation of the embodiment according to FIG. 8, with permanent opening through the switch lock via the active lever,

FIG. 11 shows a schematic illustration of a fourth embodiment with a control module which comprises a control slide, in its release position,

FIG. 12 shows an illustration of the embodiment according to FIG. 11, with the return movement of the pusher being inhibited by the control slide in its locking position,

FIG. 13 shows an illustration of the embodiment according to FIG. 11, with permanent opening through the switch lock via the active lever, as well as

FIG. 14 shows a schematic illustration of the control module of the embodiment according to FIG. 11.

In the figures, the same or equivalent elements or assemblies are each denoted by the same reference numerals.

First, the embodiment according to FIGS. 1 to 4 will be considered.

1 shows an inventive installation switching device 1 with a Polstrompfad 2 between an input terminal 3 and an output terminal 4. It could for example be a Polstrompfad a three-pole motor protection switch, the other two Polstrompfade are constructed accordingly.

The Polstrompfad 2 comprises two fixed contact pieces 5.6 and two arranged on a movable contact bridge 7 movable contacts 8.9, through which a contact point 10 is formed with double interruption. The contact bridge 7 is acted upon by a contact pressure spring 11 in the closing direction, see directional arrow S. By means of a pusher 12, which acts on the side of the contact bridge 7 opposite the contact pressure spring 11 and carries an extension on its narrow side opposite the contact pressure spring 11, which forms a striking pin 20, it can be acted upon in the opening direction, see directional arrow O.

The Polstrompfad 2 still includes a thermal release 113 and an electromagnetic release 13 with an armature that hits the contact bridge 7 in the opening direction in the event of a short circuit current occurring in the Polstrompfad 2 due to an electrodynamic recoil over the pusher 12, indicated by the action line 14. At the same time acts the armature of the electromagnetic release 13 in the event of a short circuit on a switching mechanism 15 and unlatched Verklinkungsstelle, indicated by the action line 16, so that the switching mechanism 15 in the unlatched state via an active lever 17, indicated by the action line 18, the pusher 12 permanently in the opening direction the contact bridge 7 acted upon.

The function of the thermal release 113, which also acts on the switching mechanism 15 in the case of an overcurrent, indicated by the action line 114, is known in principle.

The mechanical system comprising the switching mechanism 15 and the active lever 17 may, for example, be a toggle lever system with a two-stage lock.

The active lever 17 is designed as a double-arm lever, the first, acted upon by the switching mechanism 15 lever arm 171 and the second, cooperating with the pusher 12 lever arm 172 form an obtuse angle with each other and rotatably supported in a stationary axis of rotation 173, whereby the active lever 17th acts as a lever.

The mechanical system just described has a certain mechanical inertia, whereby a certain amount of time, for example 2 ms, would pass after the unlatching of the switching mechanism before the active lever 17 strikes the pusher 12 with the free end of its second arm 172 permanently in the opening direction apply. In contrast, the time to direct strike of the contact bridge 7 by the armature of the electromagnetic release 13 is much shorter, it is for example only 1 ms. As a result, if no further measures are taken, it could happen that the contact bridge 7 is already pressed back into its starting position in the closed position by the restoring force of the contact pressure spring 11 and the contact point 10 is thereby closed again, before the effective lever 17 also engages the free end of its second arm 172, the pusher and thus the contact bridge 7 can act permanently in the open position.

The measures according to the invention, which are taken to prevent this are described below.

The pusher 12 is a total of an elongate member having approximately a cylindrical basic shape. He could also have a roughly cuboid basic shape. It comprises a main body and a striking pin 20 firmly molded thereto.

In a slot-like opening 21 in the pusher 12, which can be closed down to the narrow side of the pusher 12 through a web 25, the contact bridge 7 is guided.

In the opening 21 of the pusher 12, an upper stop 23 is formed for the contact bridge 7.

At the point of attachment of the striker pin 20, the pusher 12 has a shoulder 24 forming a lower stop for the free end 174 of the second lever arm 172 of the action lever 17.

The slide can be made in one piece with the striker 20 or the aforementioned slot as an injection molded part. However, it could also consist of two parts, in the simplest case of a lower part and a head screw screwed into this lower part, which then acts as a striking pin with guide shoulder.

In the vicinity of the shoulder 24, a control slide in the form of a diaphragm 30 is mounted, which has an opening 32 which, in the closed position of the pusher 12, see Figure 1, the striker 20 of the pusher 12 includes. The diaphragm 30 is mounted longitudinally displaceable in approximately perpendicular to the longitudinal direction of the pusher 12. In the closed position of the pusher 12 shown in FIG. ne possible sliding movement of the aperture 30 blocked by the striker 20 of the pusher.

About a bent approximately U-shaped leaf spring 34 which is hinged at one end to a narrow side of the panel 30, and at the other end to the second lever arm 172 of the action lever 17 in the vicinity of its axis of rotation 173, the diaphragm 30 is mechanical coupled with the active lever 17.

In this case, the leaf spring 34 is mounted between the second lever arm 172 of the active lever 17 and the diaphragm 30 in such a way that in the rest position of the active lever 17, as shown in FIG. 1, the diaphragm 30 is actuated in the direction of the active lever 17. suggests, indicated by the directional arrow P.

The effect of this arrangement according to the invention is the following. If a short circuit occurs in the pole current path 21, see FIG. 2, the armature of the electromagnetic release 13 strikes the striking pin 20, indicated by the force arrow I in conjunction with the action line 14. This force push causes the trigger 12 to open in its opening direction O beaten, where it takes over the stop 23, the contact bridge 7, so that thereby the fixed contact pieces are 5.6 separated from the movable contact pieces 8.9 and the pad 10 is opened altogether. The contact bridge 7 presses in its downward movement, the contact pressure spring 11 together. As a result of the displacement of the pusher 12 in the opening direction, the striking pin 20 finally comes out of the area of action of the opening 32 in the control slide 30. Now, the blocking of the spool 30 is released, and he can follow the force of the spring 34 acting on him and move to the locking position shown in Figure 3. After opening the contact point 10, the electrodynamic recoil breaks down in the electromagnetic actuator 13 and the force impulse on the trigger 12 disappears. Due to the inertia of the pusher 12, this initially continues its movement in the opening direction O. After the contact bridge 7 has reached its maximum deflection in the opening direction, it is pressed by the restoring force of the contact pressure spring 11 again in the closing direction S. However, the closing movement of the pusher 12 is now blocked by the spool 30, and the contact point 10th stays open. During this entire time, the active lever 17 remains in its rest position due to the mechanical inertia of the pawl mechanism of the switching mechanism 15 and the active lever 17 comprehensive mechanical system.

After expiry of the inertia-related delay time, the latch mechanism, after releasing its latching mechanism, exerts a force K on the first lever arm 171 of the action lever 17 via a mechanical device known per se, see FIG. 4, whereby it is rotated clockwise relative to its starting position.

The second lever arm 172 of the action lever 17 strikes with its free end on the shoulder 24 of the pusher 12. Now, the active lever 17 takes over the permanent hold down of the pusher 12 in its trigger position.

At the same time, the pivoting of the action lever 17 causes the leaf spring 34 to push the aperture 30 back into its release position. The striking pin 20 is now below the opening 32. If the switch lock 15 is reset by an operator by hand back to the closed position, the force K would be lifted to the first lever arm 171 of the active lever 17 and the pusher 12 by the restoring force of the contact pressure spring 11 is pressed back again in its closed position according to FIG. He would also pivot the active lever 17 via the shoulder 24 again counterclockwise in the Ruhr position.

All implementation possibilities which are familiar to the person skilled in the art after disclosure of the inventive function described here are, of course, to be covered by the invention. In particular, the mechanical coupling between the diaphragm 30 and the active lever 17 could also be realized so that in the rest position of the active lever 17, the diaphragm 30 is acted upon in a direction away from the active lever 17 direction. Furthermore, the timing in the interaction between the aperture 30, the pusher 12 and the active lever 17 could also be designed so that the striking pin 20 penetrates a small distance into the opening 32 before the active lever 17 has been pivoted clockwise so far that its second Lever arm holds the pusher 12 permanently in its trigger position.

At high short-circuit currents it can also lead to an electrodynamic repulsion of the movable of the fixed contact pieces. As a result, the contact bridge 7 is then pushed down in the opening direction without the electromag- netic triggers would have acted on the striker 20 via the action line 14. The contact bridge 7 takes in its downward movement the pusher 12 with down. As a result, the striking pin 20 finally comes out of the area of action of the slot 32 just as if it had been knocked out by the electromagnetic trigger. The inhibition of the counter-upward movement of the pusher 12 by the spool 30 is the same as described above. Although the electromagnetic release reverts to the electrodynamic repulsion, it unlatches the latching point of the switching mechanism 15 via the line of action 16 even in this operating state. The embodiment according to FIGS. 5 to 7 will now be considered. This embodiment differs from that of Figures 1 to 4, characterized in that a spring-loaded slide 1030 is used as a control slide instead of a control panel on the underside of the second lever arm 172 of the action lever 17, which causes the locking of the pusher. To the bottom of the second lever arm 172 are grooves (not shown in the figures), in which the slider body 1030 can move. The slider body 1030 is also connected by means of a compression spring 42 with the active lever 17.

The compression spring 42 pushes the slider body 1030 toward the free end of the second lever arm 172 of the action lever 17 back. At its free end facing away from the compression spring 42, the slider body 1030 carries a slide nose 1032, as well as a laterally projecting pin 40 on both sides, that is, in the illustration according to FIGS. 5 to 7, protruding out of the plane of the drawing.

This results in an assembly comprising the active lever 17, the compression spring 42 and the slider body 1030. This assembly can be pre-assembled and used as a subunit in the service switching device 101.

The pusher body 12 has at the contact pressure spring 11 opposite narrow side a first shoulder 24, here also referred to as the first paragraph 24, and about a second shoulder 48, here also referred to as the second paragraph 48, on. At the second paragraph 48, the striker 20 connects. In the vicinity of the slide nose 1032 in the service switching device 101, a guide member 44 is mounted, which has a control surface 46 in the form of a slope, which, starting approximately from the slide nose 1032, extends obliquely in the direction of the contact point 10 and the axis of rotation 173. The guide member may be attached to an inserted into the service switching device and held therein adapter or as Anformung on the housing inner wall. In the closed position shown in Figure 5, the active lever 17 is in its rest position, and the slider body 1030 is connected to the slide nose 1032 by the bias of the compression spring 42 to the pusher body 12 at. The contact point is located below the first paragraph 24. The movement of the pusher 12 from the closed position in its release position is not hindered by the slider body 1030. The slider body 1030 is in Fig. 5 in its release position.

When mounting the module in the service switching device this is fixed by using a mounting fork in the desired position. The mounting fork pushes the slider body 1030 in its release position. After insertion of the assembly, the mounting fork is removed and the slider body abuts against the pusher body 12 due to the compressive force of the compression spring 42. After inserting the assembly, the mounting fork is then removed.

In the event of a short circuit, the contact bridge in the opening direction, in the illustration of FIGS. 5 to 7 down, moved and the pusher 12 is in its release position, e- downwards, moves. Through the second shoulder 48, a clearance is created between the slide nose 1032 and the striking pin 20, into which the pressure spring 42 presses the slider body 1030 with the slide nose 1032. The slide nose 1032 is thus above the second shoulder 48 on the striker 20 at. He is then in his locked position. The active lever 17 initially remains in its rest position due to the mechanical inertia already described above.

When the contact bridge is pressed again in the direction of the closed position due to the restoring force of the contact pressure spring 11, the spool 1030 with the slide nose 1032 on the second shoulder 48 blocks the return movement of the spool 12. The upper stop 23 then also causes the movement Contact bridge held in its open position. This position is shown in FIG. 6. In the embodiment described here, the opening travel of the contacts, ie the distance between the fixed and the movable contact piece with the contact point open, is determined by the position of the second shoulder 48 on the pusher 12. The closer the second shoulder 48 is set to the upper end face at the free end of the striker pin 20, the greater the opening path of the contact point.

In a further embodiment, which is not shown here figuratively, the second shoulder 48 coincides with the upper end face at the free end of the striker pin 20. In this case, the pusher could also no longer have a second shoulder 48. The blocking of the pusher 20 by the spool 1030 then takes place at the upper end face at the free end of the striker pin 20. The opening travel of the contacts is then maximally large.

After the mechanical delay time and unlatching of the Verklinkungsstelle in the switch lock the active lever 17 is rotated about the axis of rotation 173 in a clockwise direction relative to its starting position in its off position. The second lifting arm 172 of the action lever strikes with its free end on the first shoulder 24 of the pusher 12. Now, the active lever 17 takes over the permanent hold down of the pusher 12 in its trigger position and thus the holding open the contact point 10th

Upon pivoting of the action lever 17 clockwise reach the pins 40 on the slider body 1030 in contact with the control surface 46 of the guide member 44, it creates a sort of movable coupling between the spool 1030 and the control surface 46. By the inclination of the control slope 46 and the movable coupling causes the spool 1030 upon further pivoting of the action lever. 17 is pressed clockwise back into its release position and held there, against the force of the compression spring 42. This position is shown in FIG.

During the subsequent resetting of the service switching device, the active lever 17 is again rotated counterclockwise back to its rest position. The plunger 12 follows the active lever while up, and the contact bridge is pressed by the contact pressure spring 11 back into its closed position. The spool 1030 is then back to the pusher 12 below the first shoulder 24, so that the position shown in FIG 5 is reached again. The figures 8 to 10 will now be considered. Also in the embodiment shown there, a spring-biased slide 1030 is inserted on the underside of the second lever arm 172 of the action lever 17, which causes the locking of the pusher. To the bottom of the second lever arm 172 are grooves (not shown in the figures), in which the slider body 1030 can move. The slider body 1030 is also connected by means of a compression spring 42 with the active lever 17. In this respect, the functional effect of this embodiment largely corresponds to that described in FIGS. 5 to 7.

The difference from the embodiment according to the figures 5 to 7 is that the movable coupling between the spool 1030 and the control surface 46 of the guide member 44 via a guide ramp 50 on the underside of the spool 1030, see FIGS. 9 and 10. The spool 1030th carries no laterally projecting pins more. This 1030 place won laterally of the spool.

The figures 11 to 13 will now be considered. In the embodiment shown there, the service switching device 101 comprises a separate control assembly 1040, which is inserted between the active lever 17 and the pusher 12 in the device. The control assembly 1040 includes a frame 54, which serves as a support member for a longitudinally displaceably mounted in the frame spool 1030. The direction of displacement of the spool 1030 runs approximately parallel to the contact bridge and approximately perpendicular to the pusher 12. The spool is connected to a compression spring 42 with the frame 54, so that the compression spring 42 pushes the slider body 1030 in the direction of the pusher 12 back. At its free end facing away from the compression spring 42, the slider body 1030 carries a slide nose 1032, which passes through the frame 54 in the direction of the pusher 12 through a lateral opening. The spool 1030 carries on its side facing the active lever 17 side a guide ramp 50. This forms a sloping towards the slide nose 1032 inclined plane. The second lever arm 172 of the action lever 17 carries on its side facing the spool 1030 a bulge 52, which may also be referred to as a cam or control extension. The bulge 52 is mounted so that it can enter into a movable coupling with the guide ramp 50 of the spool 1030 upon pivoting of the action lever 17 in a clockwise direction. The pusher body 12 has, on the narrow side opposite the contact pressure spring 11, a first shoulder 24 and above a second shoulder 48. At the second paragraph 48, the striker 20 connects.

In the closed position shown in FIG. 11, the active lever 17 is in its rest position, wherein in this position it is inclined slightly upwards relative to the direction of displacement of the spool 1030. The slider body 1030 abuts the pusher body 12 with the slider nose 1032 by the bias of the compression spring 42. The contact point is located below the first paragraph 24. The movement of the pusher 12 from the closed position in its release position is not hindered by the slider body 1030. The slider body 1030 is in Fig. 11 in its release position.

In the event of a short circuit, the contact bridge in the opening direction, in the illustration of FIGS. 11 to 13 down, moved and the pusher 12 is moved to its release position, also down. The movement of the contact bridge can be done either due to electrodynamic repulsion of the fixed and movable contact points or due to the action of the impact armature of the electromagnetic release on the striker 12. Through the second shoulder 48, a clearance is created between the slide nose 1032 and the striking pin 20, into which the pressure spring 42 presses the slider body 1030 with the slide nose 1032. The sliding nose 1032 is therefore in contact with the striking pin 20 above the second shoulder 48. He is then in his locked position. The active lever 17 initially remains in its rest position due to the mechanical inertia already described above.

If the contact bridge is pressed back toward the closed position due to the restoring force of the contact pressure spring 11, then blocked the spool 1030 with the slide nose 1032 on the second paragraph 48, the return movement of the slider 12. About the upper stop 23 is then the contact bridge in held open position. This situation is shown in FIG. 12.

After the mechanical delay time and unlatching of the Verklinkungsstelle in the switch lock the active lever 17 is rotated about the axis of rotation 173 in a clockwise direction relative to its starting position in its off position. The second lever arm 172 of the action lever meets with its free end on the first shoulder 24 of the Pusher 12. Now takes over the active lever 17, the permanent hold down the pusher 12 in its trigger position and thus the holding open the contact point 10th

Upon pivoting of the action lever 17 in a clockwise direction, the bulge 52 on the second lever arm 172 of the action lever 17 comes into contact with the guide ramp 50 of the spool 1030, it creates a sort of movable coupling between the spool 1030 and the bulge or the control extension 52. By inclination the guide ramp 50 and the movable coupling causes the spool 1030 is pressed on further pivoting of the action lever 17 in a clockwise direction in its release position and held there, against the force of the compression spring 42. This position is shown in FIG.

During the subsequent resetting of the service switching device, the active lever 17 is again rotated counterclockwise back to its rest position. The plunger 12 follows the active lever while up, and the contact bridge is pressed by the contact pressure spring 11 back into its closed position. The spool 1030 is then back to the pusher 12 below the first shoulder 24, so that the position of FIG 11 is reached again.

The embodiment shown in Figures 11 to 13 with the tilted in the rest position relative to the direction of displacement of the spool 1030 active lever 17 is not the only possible. All functionally identical embodiments, in which the second lever arm of the action lever can also run parallel to the contact bridge or at another angle, should be included in the invention in the context of equivalence. Details of the concrete design of the active lever is not discussed in the context of the present invention. All concrete design variations that cause a movable coupling according to the invention between the active lever and the spool should therefore be included within the scope of equivalence in the invention.

FIG. 14 shows a possible embodiment of a control module 1040. The approximately rectangular frame 54, in which three mutually parallel recesses 1042, 1043, 1044 are introduced, can be seen. Each of the recesses 1042, 1043, 1044 is used for slidably receiving a control slide, wherein in FIG. 14 only in the recess 1042 a spool 1030 and in the recess 1044, a spool 1031 are shown. The three control slides are correspondingly assigned to a Polstrompfad in the service switching device. It should be noted at this point that all that has been described in the description of the present invention with reference to a contact point in a Polstrompfad, of course, also applies to installation equipment and has validity in which a plurality Polstrompfade are arranged parallel to each other. The described arrangements and functional relationships of contact bridge, pusher, active lever, spool, etc. are then multiple according to the number of Polstrompfaden. The active lever 17 can be configured as a single active lever which carries a common first lever arm 171 and a number of second lever arms 172 corresponding to the number of Polstrompfaden.

The spool 1030 is slidably held in side guide grooves 1046 in the recess 1042. The compression spring is not shown, it is to be inserted into the free space between the rear wall 1048 and the spool 1030 in the recess 1042.

At an end opening 1050 of the spool 1030 passes through with its slide nose 1032 the frame 54. The slide nose 1032 carries a semicircular recess 1033 so that it has approximately a bifurcated shape. The semicircular recess 1033 is adapted to the diameter of the striker pin 20 of the pusher 12, so that it can be better kept in the locking position shown in FIG 12.

LIST OF REFERENCE NUMBERS

1, 101 Installation switchgear

2 Polstompfad

3 input terminal

4 output terminal

5, 6 Fixed contact pieces

7 movable contact bridge

8.9 movable contact pieces

10 contact point

11 Contact pressure spring

12 pushers

13 Electromagnetic release

14 effective line

15 switch lock

16 action line

17 active lever

18 action line

20 striker

21 opening

23 Upper stop

25 footbridge

24 First shoulder

30, 1030 spool

32 opening

34 leaf spring

40 cones

42 compression spring

44 guide part, intermediate piece

46 control surface, slope

48 Second shoulder

50 guide ramp

52 bulge, cam

54 frame

113 Thermal release

114 effective line

171 First lever arm

172 Second lever arm

173 axis of rotation

1032 slide nose

1040 control module

1042, 1043, 1044 recess

1033 recess

1046 guide groove

1048 back wall

1050 Front opening

O opening direction

S closing direction

I power surge

K force

Claims

claims

1. Installation switching device (1) having at least one Polstrompfad (2), comprising two fixed contact pieces (5,6) and two on a movable contact bridge (7) arranged movable contact pieces (8,9), through which a pole switch with two contacts and double interruption is formed, wherein the contact bridge (7) by a pusher (12) in the opening direction (O) and by a contact pressure spring (11) in the closing direction (S) can be acted upon, in the on state, the two contacts are closed and wherein in the short circuit case the contact bridge is pushed in its opening direction and the pusher is moved into its release position, in which this acts on the contact bridge opening, with an electromagnetic release (13), the anchor unlatched the Verklinkungsstelle a switching lock (15) in the event of a short circuit, so that this via a the pusher (12) trailing and thereby moving from its rest position to its off position Active lever (17) holds the pusher (12) in its release position, and thus the contact bridge (7) permanently against the force of the contact pressure spring (11) is acted upon opening, characterized in that the service switching device (1) between a release position and a lock - Position displaceably mounted spool (30, 1030), which holds the pusher (12) in its release position in its locking position, wherein the movement of the action lever (17) from its rest position in its off position towards a displacement of the spool (30, 1030) causes its locking position in its release position, so that then the movement of the pusher (12) is released from its release position out.

2. Installation switching device (1) according to claim 1, wherein the active lever (17) mounted in a fixed axis of rotation (173), acting as a reversing lever toggle lever with a first and a second lever arm (171, 172).

3. Installation switching device (1) according to claim 2, wherein in the off position of the action lever (17) whose second lever arm (172) with the pusher (12) is coupled so that it can hold this in its release position.

4. Installation switching device according to claim 3, wherein in the on state of the spool (30, 1030) is held by the pusher in its release position, and in the short circuit, the displacement of the spool (30, 1030) in its locking position as a result of the movement of the pusher (12). released in its trigger position.

5. Installation switching device (1) according to claim 4, characterized in that the control slide (30) is designed as a diaphragm with an opening (32), wherein in the locked position, the aperture blocks the movement of the trigger from the triggering position out, and in the release position the opening (32) releases the displacement of the pusher (12) from its release position out.

6. Installation switching device (1) according to claim 5, characterized in that the control slide (30) with the active lever (17) is coupled via a spring, so that the displacement of the control panel (30) between the release - and the Verriegeiungs- position by the spring coupling with the active lever (17) is controlled.

7. Installation switching device (1) according to claim 6, characterized in that on the active lever (17) a control panel (30) in the rest position of the action lever (17) in the direction of their Verriegeiungs- position acting spring (34) is hinged.

8. Installation switching device (1) according to claim 7, wherein the spring (34) is a bent leaf spring.

9. Installation switching device (1) according to claim 4, characterized in that the control slide (1030) on the second lever arm (172) is guided longitudinally displaceable.

10. Installation switching device (1) according to claim 9, wherein the spool (1030) by means of a compression spring (42) with the second lever arm (172) is connected, and wherein the restoring force of the compression spring (42) the spool (1030) in its locking position acted upon.

11. Installation switching device (1) according to claim 10, which comprises a guide part (44) with a control surface (46), wherein the guide part (44) with respect to the active lever (17) is arranged so that upon pivoting of the action lever (17). From its rest position in its off position, a movable coupling between the spool (1030) and the control surface (46) is formed, by which the spool (1030) is pushed back into its release position.

12. Installation switching device (1) according to claim 4, characterized in that the control slide (1030) in a separate control assembly (1040) guided longitudinally displaceable and by means of a compression spring (42) to the control assembly (1040) is connected, and wherein the resetting Force of the compression spring (42) the spool (1040) acted on the locking position out.

13. Installation switching device (1) according to claim 12, wherein the second lever arm (172) of the active lever (17) has a control extension (52) and the control slide

(1030) comprises a control surface (50), wherein upon pivoting of the action lever (17) from its rest position in the off position, a movable coupling between the control extension (52) and the control surface (50) is formed by the spool (1030) in his Release position is pushed back.