EP1829065A1

EP1829065A1 - Method and device for the secure operation of a switching device

Info

Publication number: EP1829065A1
Application number: EP05825230A
Authority: EP
Inventors: Robert Adunka; Peter Hartinger; Bardo Koppmann; Norbert Mitlmeier; Ludwig Niebler; Fritz Pohl; Alf Wabner; 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
Also published as: CN101088133B; US20080036562A1; US7872552B2; KR101012524B1; CN101088133A; JP2008525949A; WO2006069963A1; KR20070089879A; DE102004062267A1

Abstract

The invention relates to a method and to a device for the secure operation of a switching device comprising at least one main contact which can be switched on and off and which comprises contact pieces and a displaceable contact bridge, and also at least one control magnet which comprises a displaceable anchor. The anchor acts upon the contact bridge when it is switched on or off such that the corresponding main contact is opened and closed. The method comprises the following steps: a) the displaceable contact bridge of the at least one main contact recognises when an opening point has been exceeded after being switched off, b) the additional operation of the switching device is interrupted, according to a predetermined duration of time, when the opening point is not exceeded.

Description

description

Method and device for safe operation of a switching device

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

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 safely 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 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 affect this wear are: increasing contact erosion or contact wear, increasing deformations, increasing contact corrosion due to arcing or environmental influences, such as vapors or suspended solids, etc., as a result of increasing number of on and off cycles. As a result, the operating currents no longer safe ^¬ switched, which can lead to power interruptions, Kontaktaufheizungen or Kontaktverschweißungen.

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. So just at a verschweiß ^¬ th contact despite the switch-off will be at least the current ^¬ ground with the welded main contact on current- or remain energized and so that the consumer is not completely disconnected from the supply. Since the consumer thus remains in a non-safe state, the switching device represents a potential source of error. 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.

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, as well as by the device with the features of claim 8.

The present invention thus makes it possible, with little effort, to detect a contact weld when switching off and thus to prevent the switching device from being operated in a safe manner and to respond accordingly.

According to the invention a switching device is detected when turning, whether the movable contact bridge to ^¬ least one main contact has an opening point above cry ^¬ tet, and further operation of the switching device is chen unterbro ^¬ if it is not exceeded after a predetermined time duration of the opening point. Thereto during operation

The predetermined opening point corresponds to a previously determined opening travel of the contact bridge, wherein this ge ^¬ rade is still in connection with the contact pieces. Then, after switching off, that is, after the intended Öff- NEN of the at least one main contact, a contact gap he ^¬ averages is less than or is at least less than or equal than this predetermined opening point, then it can be assumed be that a welding and thus an unsafe operation of the switching device is present.

Movable contact bridges in switching devices are often designed as a bracket at its two opposite ends in each case a contact surface is applied. When the switching ^{device is} switched on, a contact bridge is then moved so that its contact surfaces strike the corresponding contact surfaces of the two associated stationary contact pieces and thus connect the load to the electrical supply device. When turning off the contact link on the other hand is moved so that the corresponding con ^¬ tact surfaces separated, thus opening the main contact and is separated tung with the consumers of the electric Versorgungseinrich- as ^¬. In order to ensure in particular when switching on ^¬ meet both contact surfaces on the corresponding contact surfaces of the fixed contact pieces safely, contact bridges are not rigid, but have a certain allowable flexibility. If it comes to welding or to a type of bonding at least one of the contact surfaces of the contact bridge with the contact surfaces of the corresponding stationary contact pieces, then the contact bridge will turn when turned off due to their flexibility first and then remain in a position that no safe operation of the switching device in the open state represents.

If the occurrence of such a non-safe operating case is monitored and detected during operation, further operation of the switching device can be prevented in good time.

Thus, with the method and the device according to the invention, the safe operation of a Schaltge ^¬ device, such as a contactor, a circuit breaker or a compact feeder, and in particular ensures the safe operation of a three-pole switching device. 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

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 third embodiment of the device according to the invention.

As shown in FIG 1, are in the inventive

Method after a turn-off signal substantially the two following steps:

Step a) detecting whether the movable contact bridge of a Öff- voltage has exceeded point to ^¬ least one main contact after turning off,

Step b) interruption of the further operation of the Schaltge ^¬ advises, if after a predetermined period of time the opening point is not exceeded.

Thus, after the operational switch-off, that is to say in particular after a switch-off signal for opening the three main contacts of a three-pole switching device, it is checked whether all the main contacts of the switching device have been opened.

A main contact consists of two contact pieces which are interconnected via a movable contact bridge. That is the main contact can be switched on or switched OFF ^¬ and thus a consumer with a Versor- be connected device or disconnected from this. Usually, the movable contact bridges in switching ^¬ devices are constructed so that they have the shape of a bracket at its two opposite ends in each case a contact surface is attached. When switching the switching device, these contact bridges are then moved so that their contact surfaces meet the corresponding contact surfaces of the contacts and thus connect the consumer to the electrical supply device. When switching off the contact pieces, however, are moved so that the corre sponding ^¬ contact pieces separated and thus the consumer is disconnected from the electrical supply device. In order to ensure the impact of both contact surfaces on the corresponding contact surfaces of the stationary contact pieces, especially when switching on, these contact bridges are not rigid, but have a certain allowable flexibility. This flexibility is achieved, for example, by the choice of a suitable material or by the shape of the contact clip.

Thus, each movable and flexible contact bridge on a pair of contact surfaces and thus two switching points. Welding these contact surfaces with the corresponding contact surfaces of the associated contact clip, so open due to the welding, the switching points and it comes to malfunction of the switching device. In this case, a possible error case of the switching device can be given if only one contact surface welded on one side of the contact clip. In this case, when opening, the contact bridge will only move on one side away from the contact pieces. Due to the bonding on the other side, however, the contact bridge will only be able to move within the given flexibility, and then remain in a position which does not correspond to a safe state of the switching device in the opened state. In another further possible error case, both contact surfaces of the contact bridge are welded to the corresponding contact surfaces of the contact pieces. In this case, due to the bilateral Welding again bend the contact bridge only within the given flexibility, but then remain in a position that represents no safe operating state of the switching device in the open state.

According to the invention it is therefore checked whether the movable contact bridges have covered a certain opening when opening, which is greater than a predetermined in advance and thus predetermined opening point. If the recognized opening path of one of the contact bridges is still below this opening point even after the expiry of a time period which has just been determined after opening, then a contact welding can be assumed, so that the further operation of the switching device must be interrupted.

If such an error occurs, the interruption of the further operation can take place, for example, by opening a redundant further device-internal switching element, which is connected in series with the main contacts. The switching element then disconnects the load from the supply device regardless of whether the main contacts are open or closed. Due to the fact that the switching element can not be easily closed more, further operation of the switching device is reliably prevented. As an alternative to opening this additional switching element, the control of the control magnet can be interrupted in the event of an error to a reset and thus blocked. In addition, a correspondingly strong energy storage device can be triggered internally, which acts on the or the welded main contacts so that they are broken open again and thus opened.

FIG 2 shows schematically a first embodiment of a switching device 110 with the device according to the invention. The input and Ausschaltsteuersignale on and off the main contacts 10 are applied via terminals Al and A2 and a STEU ^¬ ereinrichtung 16 to the control magnet 12th When switching off, the control solenoid, called the electromagnetic Drive 12 is used for the main contacts, de-energized via the Steuerein ^¬ direction 16. Via the connection 18 acts on the contact bridges a force against the contact load spring 17. The main contacts 10 are opened and thus the consumer M of the supply device, here by the three lines L1-L3, characterized, separated.

After de-energizing the control magnet 12 is also checked by an evaluation device 15 by means of the electrodes 11 and 11 ', if the contact ^bridge have exceeded the predetermined opening ^¬ point. To measure a voltage drop across the main contacts 10 are in the present embodiment ^¬ example for each current path two electrodes 11 and 11 ^Λ , once before the main contact 10 and once after the main contact, provided. According to the invention the main contacts 11 and 11 is then ^Λ 10 made by the evaluation unit 15 via the electrodes, a voltage test of the main contacts 10 after switching off. If the Spannungsab ^¬ falling on one of the main contacts 10 is too low, this is an indication that this is not open far enough. That is, the Retired turning off of the contact bridge ^¬ put opening stroke has not exceeded the predetermined value ^¬ th, and there is a high probability of Ver ^¬ welding before.

If, after a predetermined period of time, for example 100 ms, after a switch-off signal has been triggered, the opening travel is still too short, it must be ensured that further operation of the switchgear is interrupted. In the present embodiment example, the evaluation means 15 ^¬ is connected via an unspecified communication with the control device 16 that. If such an error is detected by the evaluation device 15, it is forwarded to the control device 16, whereupon it interrupts at least one of the control lines.

In addition, in the present exemplary embodiment, an off ^¬ releasing mechanism 14 is activated, with a spring energy storage 13th is unlatched. Such spring energy storage can be, for example, already known of circuit breakers or compact starters switching locks. Such a switching mechanism then proposes mechanically with great force to the non-open main contacts 10 of the switching points of the switching device to the ver ^¬ welded main contacts break. In order to achieve a Aufbre ^¬ chung, the force of the spring accumulator 13 must be dimensioned ent ^¬ large. The spring accumulator 13 then either remains in the unlatched position and can not be reset, or the spring accumulator 13 has a mechanism by means of which the spring tensioned again and the trigger mechanism 14 can be latched again. Since the resetting of the mechanism 13 and 14 can only be done manually, a user is made aware of the accident and must accordingly, for example by a ^¬ exchange the switching device to respond to it.

The illustrated in Figure 2 embodiment of the present invention, in which thus also the inventive method is used, is particularly suitable if each of the

Main contacts 10 is to be monitored separately, but especially so with single-phase switching devices with only one main contact. If both contact surfaces of a contact bridge are bonded, then, for example, by means of an electrode pair 11 and 11 'applied to the main contact 10

Auxiliary voltage of this no longer safe state of the main contact 10 can be detected. In this case, after opening, the auxiliary voltage will continue to be present across the bonded main contact. By the evaluation device 15, this auxiliary voltage or even the current that results from the equivalent resistance of the main contact monitors, it can be seen that the contact bridge of this Hauptkontak ^¬ tes 10 has not exceeded the opening point due to the weld. The evaluation device will then forward this detected error case to the control device 16 and thus interrupt the further operation of the switching device due to the occurrence of a fault. Alternatively to the method described before to ^¬ with auxiliary voltage are also WEI Other versions conceivable. Thus, for example, the difference in the voltages between the load side on the electrode 11, and the network side on the electrode 11 'can be evaluated via the evaluation device. Or it is simply checked the concerns of the mains voltage on the load-side electrode 11.

In another embodiment, not shown, only one current sensor per flow path can be provided. This applies in particular to two- or multi-phase switching devices application. Then it is detected by the current measurement in each of the current paths, whether the opening point has been exceeded after switching off. If, on the basis of the current measurement, it is recognized that an exceeding of the opening point has not occurred, further operation of the switching device is interrupted.

3 schematically shows a further embodiment of the device according to the invention, in which the opening path of the contact bridges of the switching point 20 to be detected is queried directly by the evaluation device 25. This can be done for example by means of corresponding, but not shown in FIG 3, means 21. Thus, for example, switching monitoring means may be provided which are transferred to a first state when the main ^{contacts are} closed when switching on, and which remain in this first state even after switching off when at least one of the main contacts is welded.

It is assumed that the detected opening path has fallen below the predetermined value, if these means remain after switching off in this first state, which does not correspond to the predetermined state after opening.

The illustrated in FIG 3 embodiment of the present invention

Invention, in which thus also the inventive method is used, is particularly suitable, even if the welding or bonding a contact surface to only one side of the contact bridge is to be detected. Especially in such an error case, the main contact 20 while switching ^{¬ off} the consumer while open, but the contact bridge will cover only one way that ensures no safe state of the switching device. Rather, it is to be computationally ^¬ NEN, that in such a case of error due to the increasing burnup soon the second contact surface on the ge ^¬ opposite side of the contact bridge is also welded. Detects when switching off the evaluation device 25 via the means 21 that the contact bridge of the main contact 20 on ^¬ basis of one-sided welding travels only one way that corresponds below the opening point for the safe open state, the further operation of the Schaltgerä ^¬ tes can be interrupted.

Advantageously, this could exporting ^¬ shown in FIG 3 approximate shape also be combined with those described in connection with FIG 2 measures. Thus, for example, with the means 21, the one-sided welding can be detected, which triggers a first indication that a failure of the

Switching device due to a no longer opening Hauptkon ^¬ clock imminent. However, the actual interruption of the further operation of the switching device could only take place if it is recognized in further operation via an auxiliary voltage to additional electrodes, such as the electrodes 11 and 11 ', that due to the double-sided bonding now the main contact no longer opens.

As a further example of the recognition of the Öff- the main contacts voltage path would also be a Induktivitätsmes ^¬ solution directly on the coil of the control magnet conceivable. The control magnet has a different inductance in the regular on-state than in the off state. If this inductance to the off state after a power switch is not reached, it is assumed is that the opening ^¬ point not exceeded and the switching device is switched abge ^¬. 4 shows a further embodiment of the inventive device ^¬ fiction. Here, for interrupting the continued operation, a further switching element is in the fault case, see 39 ^Λ ^¬ provided, which is arranged in the individual current paths in series with the egg sionally switching main contacts 30th In the case of the welding of one of the main contacts 30, the evaluation device 35 recognizes by means of the electrodes 31 and 31 ^Λ too low a voltage drop across this main contact. As a result, the evaluation device 35 causes a trigger mechanism 34 is activated and thus a spring force accumulator 33 is unlatched. This spring energy storage 33 acts on the active connection 39 on the switching element 39 ^Λ and opens it. As a result, the current paths are safe, and regardless of whether the main contacts are open or still closed, interrupted and the further operation of the switching device ^¬ connected.

Claims

claims

1. A method for safe operation of a switching device with minimum to ^¬ a mono- and having disconnectable main contact of the contact pieces and a moving contact link, and having at least one control magnet which has a moving armature,

wherein the armature acts on the contact bridge during switching on and off in such a way that the corresponding main contact is closed and opened, with the steps of: a) detecting whether the movable contact bridge of the at least one main contact has exceeded an opening point after being switched off, b) Interruption of the further operation of the switching device, if after a predetermined period of time the opening point is not exceeded.

2. The method according to claim 1, characterized in that the exceeding of the opening point is detected by a measurement of a current in a current path to be switched by the main contact, wherein the opening point is not exceeded when the measured current is greater than a provided after switching off current is.

3. The method of claim 1, wherein the exceeding of the opening point is detected by measuring a voltage drop across a main contact, wherein the opening point is not exceeded when the voltage drop is smaller than a voltage drop provided after switching off.

4. The method according to claim 1, characterized in that the exceeding of the opening point is detected by a measurement of an inductance of the control magnet, wherein the opening point is not exceeded if the inductance after switching off has a value which does not correspond to the predetermined value after opening.

5. The method according to claim 1, characterized in that the opening point is detected by a state of, with the contact bridge in operative connection, means, wherein the detected opening point is not exceeded, if these means remain after switching off in this state, not one predetermined state after opening corresponds.

6. The method according to any one of claims 1 to 5, characterized in that the further operation is interrupted by a arranged in series with the main contact in the current path switching ^¬ element is opened.

7. The method according to any one of claims 1 to 5, characterized in that the further operation is interrupted by at least ei ^¬ ne control line for controlling the control magnet is interrupted.

8. Device for safe operation of a switching device, where ^¬ in the switching device at least one on and ausschaltba ^¬ Ren main contact, the contact pieces and a movable contact bridge, and at least one control Magent th having a movable armature comprises, and wherein the Anchor when switching on and off acts on the contact bridge that the corresponding main contact is closable and obvious, characterized in that - first means for detecting whether an opening point of the con ^¬ tact bridge the at least one main contact was exceeded ^¬ th, are provided, - and further funds are provided to cover the further operation of the switching device interrupt when the means after switching off recognize that the opening point is not exceeded after a predetermined period of time.

9. The apparatus of claim 8, wherein the first means comprises a current sensor measuring the current in a current path to be switched by the main contact.

10. The device according to claim 8, characterized in that the first means comprise two electrodes, wherein the ers ^¬ te and the second electrode are arranged so that a voltage drop across the main contact can be derived.

11. The device according to claim 8, wherein the first means comprise a means for detecting an inductance, which measures the inductance of the control magnet.

12. The device according to claim 8, characterized in that the first means comprise an opening mechanism which is in operative connection with the contact bridge and can take a ers ^¬ th and second state.

13. Device according to one of claims 8 to 12, characterized in that the further means comprise an evaluation device which opens to interrupt the further operation a arranged in series with the main contact in the current path Schaltele ^¬ ment.

14. Device according to one of claims 8 to 12, characterized in that the further means comprise a control device for controlling the Control magnets include, which interrupts the control line to the control solenoid to interrupt the further operation.

15. Switching device for safe switching of consumers performs the method according to one of claims 1 to 7, wherein the switching device is a contactor or a power ^{scarf ¬} ter or a compact feeder.

16. Switching device for safe switching of consumers with a device according to one of claims 8 to 14, 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 c i n e s, e e s 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.