EP1829067A1

EP1829067A1 - Method and device for securely operating a switching device

Info

Publication number: EP1829067A1
Application number: EP05850482A
Authority: EP
Inventors: Fritz Pohl; Peter Hartinger; Ludwig Niebler; Norbert Zimmermann
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2004-12-23
Filing date: 2005-12-22
Publication date: 2007-09-05
Anticipated expiration: 2025-12-22
Also published as: JP4662564B2; ATE478429T1; WO2006069962A1; JP2008525948A; DE102004062266A1; DE502005010117D1; PL1829067T3; DE112005002950A5; WO2006069956A1; US20080094156A1; CN101080791B; CN101080791A; WO2006069958A1; WO2006069959A1; KR20070086263A; KR100887448B1; DE112005003110A5; US7812696B2; EP1829067B1; BRPI0519350A2

Abstract

A method and a device for secure operation of a switching device including at least two main contacts which can be switched on and off and include contact pieces and a displaceable contact bridge, and a control magnet having a displaceable anchor. The method may include producing an electric control signal to release a contact breaking device when the control magnets are switched on and off. The emitted control signal lies outside the ON state of the switching contact during the regular operation of the switching device and releasing the contact breaking device in defective operation of the switching device if the switching contact remains in the ON state when the control magnets are switched on or off. The switching contact may connect through the control signal to release the contact breaking device.

Description

description

Method and device for safe operation of a switching device

The present invention relates to a method for the safe operation of a switching device according to the preamble of An ^¬ claim 1 and 3 and a corresponding device according to the preamble of claim 8 and 10.

With switching devices, in particular low-voltage switchgear, the current paths between an electrical supply device and consumers and thus their operating currents can be switched. In other words, by opening and closing current paths from the switching device, the connected consumers can be reliably switched on and off.

An electrical low-voltage switching device, such as ^¬ example, a contactor, a circuit breaker or a Kompaktstar ter, has one or more so-called main contacts for switching the current paths, which can be controlled by one or more control magnets. In principle, the main contacts consist of a movable contact bridge and fixed contact pieces, to which the consumer and the supply device are connected. To close and open the main contacts a corresponding on or off signal is given to the control magnets, whereupon they act with their armature so on the movable contact bridges that the contact bridges perform a relative movement with respect to the fixed contacts and either close the current paths to be switched or to open.

For better contact between the contacts and the contact bridges are in places where both consecu- the meeting, see correspondingly formed contact surfaces pre ^¬. These contact surfaces are made of materials, such as silver alloys, which are used at these locations. probably on the contact bridge and the contacts are placed on ^¬ and have a certain thickness.

The materials of the contact surfaces are subject to wear in each of the switching operations. Factors that can influence this wear are:

^■ increasing contact wear or contact abrasion with stei ^¬ gender number of turning on and off,

■ increasing deformations,

■ Increased contact corrosion due to arcing or

^■ environmental influences, such as fumes or Schweb ^¬ materials, etc.

As a result, the operating currents are no longer safely switched, which can lead to power interruptions, contact heating or contact welding.

Thus, in particular with increasing contact erosion, the thickness of the materials applied to the contact surfaces will decrease. Thus, the switching path between the Kontaktflä ^¬ surfaces of the contact ^bridge and the contact pieces longer, which ultimately reduces the contact force when closing. As a result, with increasing number of switching operations, the contacts will not close properly. Due to the resulting power interruptions or else by an increased switch-on bounce, it can then come to a contact heating and thus to an increasing melting of the contact material, which in turn can lead to a welding of the contact surfaces of the main contacts.

If a main contact of the switching device worn or so ^¬ welded even, the switching device can no longer safely turn off the consumer. This is just what happens with a welded th contact despite the switch-off at least the current ^¬ ground with the welded main contact on current- or remain energized, and thus the consumer ^¬ cher not overall separates completely from the supply. Thus, since the consumer remains in a non-safe state, the switching device is a potential Feh ^¬ lerquelle.

As a result, for example, in compact starters according to IEC 60 947-6-2, in which an additional protection mechanism acts on the same main contacts as the control magnet during operational switching, the protective function can be blocked.

For safe operation of switching devices and thus to protect the consumer and the electrical system such sources of error should be avoided.

European Patent Application EP 1 002 325 A1 discloses a relatively complicated method for detecting the residual electrical service life of contacts, in which contact welding is detected by switching off the switching device by existing or additional means. By issuing a message and / or by shutting down the Schaltbe- operation, especially after short circuits, so the risk of serious electrical faults for consumers and electrical systems is eliminated.

From the European patent application EP 0 832 496 A1, a method is known in which the contact welding on the switching device is detected by monitoring the switching device drive. It is a serially connected second switching ^¬ device operated to interrupt the circuit when the switching device drive is not reached in the off-switching in its regular off position. Object of the present invention is to detect such potentiel ^¬ len sources of error and yaw accordingly to rea ^¬.

This object is achieved by the method with the Merkma ^¬ len of claim 1 and 3 and by the device having the features of claim 8 and 10. In claims 15 and 16, a suitable switching device is specified. In the Unteransprü ^¬ chen 2, 4 to 7, 9, 11 to 14 and 17 advantageous developments are further developments of the method and the devices included.

The present invention allows ei ^¬ nen welded contact when switching on and off of the switching device to recognize and then break the welded contact with little effort.

The invention relates to a method and a device for safe operation of a switching device with at least one main contact, which can be switched on and off, which contact pieces and a movable contact bridge. The switching device has at least one control magnet with a movable armature, wherein the armature when switching on and off acts on the contact bridge so that the corresponding main contact can be closed and opened. There is provided a switch contact having an ON and OFF state corresponding to a closing and opening position of the armature.

According to the invention, in a first step, an electrical drive signal for triggering a Kontaktaufbrechmittels when switching on and / or off of the control solenoid is generated, wherein the drive signal is output so that this is outside the ON state of the switch contact during proper operation of the switching device. In a second step, in particular in the case of at least ei ^¬ nes welded main contact of the switching device is in the faulty case, the Kon triggered ^¬ taktaufbrechmittel, when the switching contact at the switching on or off of the control magnet in the ON state comparable remains or has remained, in that the switching contact switches the on ^¬ control signal for triggering the Kontaktaufbrechmittels ^¬ .

Alternatively, according to the invention, in an initial step, an electrical drive pulse for the possible triggering of a contact breaker when switching on and / or off of the control magnet is generated, wherein the respective duration of the on ^¬ control pulse is such that it during normal operation of the switching device temporally within the OFF state of the switch contact. In a second step, the contact break-up means is triggered by the switching contact the drive pulse for triggering the contact ^¬ break-off means turns on when the switching contact when turning on or off of the control magnet remains in the ON state or remains.

The essence of the invention lies in the generation of suitable electrical signals which release the triggering of a contact break-up means.

The particular advantage of the invention is that the switching device can be checked for each switching operation in terms of the presence of at least one welded main contact. In case of failure of the Kontaktaktaufbrechmittels can be broken at least a welded main contact ^¬ by triggering. Additionally or alternatively, corresponding alarms can be generated that drove the non-secure Be ^¬ View of the switching device.

Thus, with the inventive method and the inventive device, the safe operation of a multi-poli ^¬ gen switching device such as a contactor, a circuit breaker or a compact feeder and insbesonde- the safe operation of a re three-pole switching device ge ^¬ ensured. In particular, the electrical drive ^pulse is delayed by a predetermined value when switching off the switching device. This delay can be generated, for example, by means of an OFF-delayed normally-closed contact.

Alternatively, the electrical drive pulse can also be generated by means of an electronic circuit. For this purpose, at least one pulse generator, such as hen may be a monostable multivibrator or a so-called one-shot, and a time delay element vorgese ^¬ for generating the time duration of the electrical drive pulse and possibly the time delay.

In addition, the further operation of the switching device can be interrupted if the contact breaker has been triggered. The closure of the operational shift, by a display by a mechanical display and return ^¬-setting member, indicated by a signaling contact or via a data bus and / or further processed.

Further advantageous embodiments and preferred Weitererbil ^¬ tions of the invention can be found in the dependent claims.

The invention and advantageous embodiments thereof are described in more detail below with reference to the following figures. Show it:

1 shows a simplified flow diagram of the invention ^shown SEN method, FIG 2 shows a first embodiment of the device according to the invention,

3 shows a second embodiment of the device according to the invention,

4 shows a timing diagram which shows the time profile of the generated drive pulse when switching on

Switching device in the proper and in ^{errand ¬} th operation shows and 5 shows a timing diagram which shows the time profile of the generated drive pulse when switching off the switching device in the proper and in ^{errand ¬} th operation.

As shown in FIG 1 are in the inventive

Procedure essentially carried out the following two steps:

Step a) generating an electrical drive signal for

Triggering a contact breaking means when switching on and / or off the control magnet, wherein the drive signal is output so that the ^¬ ses during normal operation of the switching device tes outside the ON state of the Schaltkon ^¬ clock is, and

Step b) triggering the Kontaktaufbrechmittels in errone ^¬ th operation of the switching means, when the switching contact when switching on or off the control solenoid remains in the ON state or remains by the switching contact the drive signal for triggering the ^{Kontaktaufbrechmittels ¬} switches.

In the alternative method according to the invention essentially the following two steps are carried out:

Step a) generating an electrical drive pulse for the possible triggering of a contact breaking means when switching on and / or off of the control magnet, wherein the respective duration of the drive pulse is dimensioned such that it is during the proper operation of the switching device in time within the OFF state of the switching contact, and

Step b) triggering the contact breaking means by the switching contact turns on the drive pulse, when the switch contact remains ON or OFF when the control solenoid is turned ON or OFF.

This ensures that at the end of life of the switching device, that is, when the contact materials of the contact surfaces are removed in particular so far that at least one main contact is welded, this ver ^¬ welded contact can be broken, so that ensures safe operation of the switching device is.

The method according to the invention is used in switching devices whose operational switching is accomplished by controllable drives, such as remotely operated switches, contactors or contactors.

By triggering a force storage device, such as a switch lock, unlocked, whereby the welded contacts are broken. Furthermore, an electrically operated force element can be present in order to break up the contact fusion. In order to switch off the flow of current to the consumer in the case of a solid contact weld which can not be broken open by the switch lock, the switch lock can actuate a further contact opening mechanism which allows the switch contacts to be opened independently of one another. Since ^¬ by the non-welded contacts are opened by the switching mechanism and the current flow is interrupted.

The pulse delay and the drive pulse can be realized in known manner by mechanical, electromechanical or electronic means, and the required electrical energy can be provided by an electrical energy store, such as by a capacitor or a coil. For electrical charging of the energy storage, the control voltage of the contactor can be used. Subsequently, the device of the invention will be described by way ^¬ reference to two embodiments in more detail, for example.

FIG. 2 shows, by way of example, a first embodiment of the device 1 ^{according to the} invention. The device 1 is supplied electrically with a switching voltage Us via two terminals shown in the left-hand part of FIG. The switching voltage Us is usually connected to a control magnet or to an electromagnetic drive of the switching device when the control unit is switched on. By applying the switching voltage, an excitation coil of the control magnet is supplied with current, so that an armature of the control magnet can actuate the main contacts of the switching device for opening and closing. Parallel to the switching voltage Us a capacitance 2 in the form of a capacitor for energy storage is shown. This energy is available in particular when switching off the switching device, ie after removal of the switching voltage Us, to trigger a Kontaktaufbrechmittels 6 available.

In the example of Figure 2, a trip unit 5 is shown, which is in a mechanical operative connection with a switching lock 6 as a contact breaking means for breaking a ver ^¬ welded main contact. The triggering unit 5 requires to trigger the switching mechanism 6, an electric current iA, which must be applied to the trip unit 5 for a certain minimum time. In the example of FIG 2, this is only mög ^¬ exist if the two, in series with the trip unit 5 geschal ^¬ ended switching contacts 3 and 4 are closed. The electrical contact 3 is a normally closed contact; at the electrical contact 4 to a make contact. The normally open contact 4 essentially corresponds in its ON and OFF state to the closing and opening position of the armature. The normally closed contact 3 may be a off delayed relay contact, for example, wherein the coil of the relay contact before ^¬ is preferably connected to the buffered switching voltage Us. When switching on the electromagnetic drive or the control magnet of the switching device, the armature moves in the case of non-welded contacts after increasing the magnetic force on the value of the force difference from spring opening force of the armature and contact load of moving contacts

Closing direction. After a few millimeters of closing, such as 4 mm, meet the mechanical actuators ^¬ coupled to the armature moving contacts on the fixed contacts of the switching device. With the further closing movement of the armature is built on the switching contacts necessary for safe contact force pressure. The total armature travel from the start of the armature movement to the switch-on position can be, for example, 6 mm. When the accelerated closing movement of the armature from the open position to the closed position is a typical for switching devices, such as shooters

Closing time of 10 to 30 milliseconds at a Schließge ^¬ speed between 0.5 and 2 m / s achieved. In this case, the main part of the closing time accounts for the way from the off ^¬ position of the moving contacts to their contact with the fixed contacts. With the movement of the armature, the operation of the electrical contact 4 is linked, which is open in the armature opening position and is closed during the armature closing movement at a certain anchor position. This armature position is determined so that at a Kontaktverschweißung and turned off control this contact 4 is closed with certainty.

According to the invention, an electrical drive signal for triggering the contact break-up means 6 is now output. This is achieved in that with or shortly after the presence of the switch-on, ie with concerns the switching voltage Us, the electrical NC contact 3 is opened before the electrical contact normally 4 when reaching the Schaltposi ^¬ tion of the armature in the contact point in the proper switching operation closes.

When the control magnet is switched off, before the start of the armature opening movement, a reduction of the magnetic field occurs. until the magnetic armature closing force is weaker than the armature opening force. After a few millimeters of opening travel, the armature or the contact slides positively connected to it strike the moving contacts of the switching device in the case of non-welded main contacts and open them. The shutter contact 4 actuated with the armature movement opens its contact at the predetermined position of the armature and remains in the off state during the further armature opening movement. The period from the switch-off of the Schaltergerä- tes to the safe off the normally open contact 4 be ^¬ true the minimum duration for the predetermined delay time of the control signal for controlling the trip unit 5. Upon error-free switching operation is thus before or at the end of the delay period, the drive signal when switching off by the normally open contact 4 and disabled until the next switch command A ^¬ maintained. When switching off the switching device, ie when removing the switching voltage Us, the normally closed contact 3 falls back with the predetermined delay time, such as 100 ms, after the normally open contact 4 has opened again in the proper switching operation. Due to the mutual OFF position of the switching contacts 3 and 4, no current flow iA to the tripping unit 5 for triggering the contact breaking means 6 is possible in the proper switching operation.

According to the invention, the contact opening means 6 is now triggered in the faulty operation of the Schaltmit ^{¬ means} when the switching contact 4 remains on or off when switching on or off of the control magnet in the ON state. This then turns on the drive signal to trigger the Kontaktaufbrechmittels 6 by the trip unit 5 with current iA ver ^¬ ensures. The drive signal can be considered as a release signal, which at power-up and in case ei ^¬ nes already closed normally closed contact 3 in the form of the switching voltage Us and which when switching off and after "Staying" of the normally closed contact 3 in the form of the buffered switching voltage Us on the trip unit 5 is present. Thus, it is reliably detected a contact welding when switching off the switch device and the switching mechanism 6 unlatched by the trip unit 5. By breaking up the con ^¬ taktverschweißung the circuit is overall consumer separates and locks the switching device against further betriebsmä ^¬ FLOWING switching.

A restart of the switch device is possible only after breaking the contact welding or after installing new contacts. A current flow through the switching contacts is therefore no longer possible. With some such to switch on an equal number to ^¬ sätzlicher Aufbrechversuche the welded contact is out ^¬ leads from the switching mechanism through which usually medium-rer contact welding strength can be eliminated.

The make contact 4 switches the exciter circuit of the trip unit ^{¬ on} or off and can also be carried out electronically and sensor-controlled switchable. The normally open contact 4 may be, for example, a reed relay, which is brought to close and open by a permanent magnet attached to the armature. The normally open contact 4 can also be a positively driven mechanical switching element, which is actuated by the armature or by a mechanical component coupled thereto. With a mechanical, an electro-mechanical or an electronic circuit, a time-delayed drive signal from the off ^¬ of the control magnet on command the trip unit 5 derived which is fed by the electrical energy store and which actuates the trip unit 5 in the case of contact welding, and the switching mechanism 6 of the switch unit unlocks. This is described in detail in the following FIG.

3 shows an exemplary second embodiment of the inventive device 1. The function of the switching contact 3 is now carried out by an electronic circuit or by a control electronics 8, which suitable drive pulses PL in a sum signal S at the output of Circuit 8 provides. The sum signal S is generated in the example of FIG. 3 by means of an OR element 13, which combines the two individual signals P and V.

The signal P is generated by a monostable multivibrator 10 and a monostable multivibrator 10 as a pulse generator, either of which nal is responsive to a positive edge-triggered-Eingangssig ^¬. In the present case, the input signal is the switching voltage Us. This means that when switching on the switching device, the monoflop 10 generates a square pulse with a predetermined time period TP, which is then applied as a drive pulse PL in the sum signal S. The time period TP is such that the drive pulse PL is already "over" before clocking in the ordinary switching operation of Schließerkon- 4 closes. On the other hand, has the drive pulse TP applied for a minimum period, so that the downstream Auslö ^¬ seeinheit 5 still can trigger The triggering mechanism can be designed, for example, electromagnetically, pyrotechnically or by motor means, for example, the duration TP is within a range of a few milliseconds.

The signal V is delayed by a time delay TV by a few milliseconds against a signal N by means of a time delay element 12. In this case, the signal N is generated by means of a further monostable flip-flop 11 or a further monoflop 11, which responds to a negative-flan ^¬ kengetriggertes input signal. In the present case, the input signal is again the switching voltage Us. This means that the monoflop generated upon turning off the switching device or in case of failure of the switching voltage Us 11 a rectangular pulse having a predetermined time duration TN that abuts then as drive pulse PL, delayed by the time period TV, the Sum ^¬ mensignal S. The time duration TN is dimensioned such that the drive pulse PL is long enough for the trip unit 5 to still be triggered and delayed by such a time duration TV, so that the normally open contact 4 has closed again in the proper switching operation. The duration TP is thus in the range of a few milliseconds. In the left part of the monitoring device 1, a series connection of a diode 7 and a storage capacitor 2, which is parallel to the terminals, is shown. The diode 7 serves to decouple the voltage applied to the capacitor 2 voltage from the switching voltage Us, so that even when removing the switching voltage Us, the electronic circuit 8 can provide power to generate the drive pulses PL.

FIG. 4 shows a time diagram which shows the time profile of the generated drive pulse PL when the power supply is switched on

Represents switching device. 5 shows the same timing diagram when switching off the switching device. In the respective left part of FIG 4 and FIG 5, the switching behavior of the switching device in the proper operation and in the right part of FIG 4 and FIG 5 in faulty operation, ie in particular at least one welded main contact ^¬ shown.

FIG. 4 shows the activation pulse PL with the pulse width TP generated in each case when the switching device is switched on essentially from the switching voltage Us without delay. As FIG 4 further shows, this drive pulse PL is in proper switching operation in time before the switching edge of the closing switch contact 4. This shows the time ^¬ Liche course of the armature control signal A, which acts on the switching contact 4. In contrast, the right part of FIG 4 shows the case of a weld in which the switching contact 4 has not opened. In this case, with the output of the drive pulse PL, a current flow iA for triggering the trip unit 5 is possible.

FIG. 5 shows the drive pulse PL having the pulse width TN generated by the buffered switching voltage Us when the switching device is switched off by a period TV. As FIG 5 further shows, this drive pulse PL is in the proper switching operation time after the switching edge of the opening switching contact 4. This shows the time course of the armature control signal A, which acts on the Schaltkon ^¬ clock 4. In contrast, the right part of FIG 5 shows the Case of welding, in which the switching contact 4 has not opened. In this case, with output of the drive pulse PL a flow of current iA to trigger off ^¬ solvent unit 5 is possible.

Claims

claims

1. A method for safe operation of a switching device with ^{¬ at} least one on and off main contact having contact pieces and a movable contact bridge, and with at least one control magnet with a movable An ^¬ ker, which on switching on and off so on the Kontaktbrü ^¬ act acts that the corresponding main contact is closed and opened, and wherein a switching contact (4) is provided which has an ON and OFF state corresponding to a closing and opening position of the armature, characterized by the following steps: a) generating an electrical Control signal for triggering a contact breaking means (6) when switching on and / or off of the control magnet, wherein the drive signal is output so that this during normal operation of the switching ^{device is} outside the ON state of the switching ^¬ contact (4), and b ) Triggering the contact breaking means (6) in the faulty operation of the switching means when the switching contact (4) when switching on or off of the control magnet in the ON state remains or remains, by the switching contact (4) the drive signal for triggering the Kontaktaufbrechmit ^{¬ means} (6) through switches.

2. A method according to claim 1, characterized in that the electrical drive signal with ^¬ means of an OFF-delayed break contact (3) is generated.

3. A method for safe operation of a switching device with ^{¬ at} least one on and off main contact having contact pieces and a movable contact bridge, and with at least one control magnet with a movable Anker ker, which acts on the contact bridge when switching on and off in that the corresponding main contact is closed and opened, and wherein a switching contact (4) is provided which has an ON and OFF state corresponding to one Has closing and opening position of the armature, characterized by the following steps: a) generating an electrical drive pulse (PL) for ^{¬ possible} triggering a Kontaktausbrechmittels (6) when switching on and / or off of the control magnet, the jewei ^¬ time period (TP , TN) of the drive pulse (PL) so bemes ^¬ sen is that this is during the proper operation of the switching device in time within the OFF state of the switching contact (4), and b) triggering the contact breaking means (6) by the switch ^¬ contact (4) switches the drive pulse (PL) if the switching contact (4) when turning on or off of the ermagneten STEU ^¬ remains in the oN state or remains.

4. The method according to claim 3, characterized dadurchgekenn ^¬ records that the electrical drive pulse (PL) when switching off the switching device by a predetermined value (TV) is delayed.

5. The method according to any one of the preceding claims, ^{¬ characterized in} that the electrical ^¬ cal drive signal or the electrical drive pulse (PL) by means of an electronic circuit (8) is generated.

6. The method according to claim 5, dadurchgekenn ^¬ records that for this purpose in the electronic circuit (8) at least one monostable flip-flop (10, 11) and a time delay element (12) are provided.

7. The method according to any one of the preceding claims, ^{¬ characterized in} that the further operation of the switching device is interrupted when the Kon ^¬ clock breaking means (6) has been triggered.

8. A device for safe operation of a switching device with at least one on and off main contact, which contact pieces and a movable contact bridge, with at least one control magnet having a movable armature wherein the armature when switching on and off acts on the contact bridge so that the corresponding main contact is closed and apparently, and with a switching contact (4) having an ON and OFF state corresponding to a closing and opening position of the armature characterized in that a) that means for generating an electrical Ansteuersig ^¬ nals for triggering a Kontaktaufbrechmittels (6) when switching on and / or off of the control solenoid are provided, wherein the drive signal is output so that this au during normal operation of the switching ^device is outside of the ON state of the switching contact (4), and b) the means for triggering the contact breaking means (6) are provided in the faulty operation of the switching means when the switching contact (4) remains ON or OFF when the control solenoid is turned on or off or remains, by the switching contact (4), the drive signal for triggering the contact breaking means (6) on.

9. The device according to claim 8, characterized in that the electrical control signal with ^{¬ means of} a decay-delayed NC contact (3) can be generated.

10. A device for the safe operation of a switching device having at least one main contact which can be switched on and off, which has contact pieces and a movable contact bridge, with at least one control magnet having a movable armature, the armature acting on the contact bridge during switching on and off, in that the corresponding main contact is closed and apparent, and having a switching contact (4) which has an ON and OFF state corresponding to a closing and opening position of the armature, characterized in that a) means for generating an electrical control ^pulse ( PL) for the possible triggering of a Kontaktaufbrechmit ^{¬ means} (6) when switching on and / or off of the control magnet are provided, wherein the respective time duration (TP, TN) of the drive pulse (PL) is dimensioned so that the ^¬ ser during proper operation of the switching device is still within the OFF state of the switching contact (4), and b) that means are provided for triggering the Kontaktaufbrechmittels (6) by the switching contact (4) the drive ^¬ pulse (PL) turns on when the switching contact (4) remains ON or OFF when switching on or off of the control magnet.

11. The apparatus of claim 10, dadurchge ^¬ indicates that the electric Ansteuerim ^¬ pulse (PL) for turning off the switching device to a superiors specified value (TV) can be delayed.

12. Device according to one of claims 8 to 11, ^{¬ characterized in} that the electrical ^¬ cal control signal or the electrical drive pulse (PL) by means of an electronic circuit (8) can be generated.

13. The apparatus of claim 12, dadurchge ^¬ indicates that for this purpose in the electronic circuit (8) at least one monostable flip-flop (10, 11) and a time delay element (12) are provided.

14. Device according to one of claims 8 to 13, ^{¬ characterized in} that the further operation of the switching device can be interrupted when the contact breaker means (6) has been triggered.

15. Switching device, which leads to the safe switching of consumer ^¬ chern the method according to one of claims 1 to 7 ^¬ , wherein the switching device is a contactor or a power switch or a compact feeder.

16. Switching device for safe switching of consumers with a device according to one of claims 8 to 15, wherein the switching device is a contactor or a circuit breaker or a compact branch.

17. Switching device according to claim 15 or 16, d a d u r c h e c e n e z e i c h e s that the switching device is a three-pole switching device with three main contacts for switching on and off of three current paths with a control magnet.