RU2595600C2 - Method of switching in assembly of power switches and arrangement of plurality of power switches - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: group of inventions relates to switching devices. For this purpose, a method of switching in assembly of power switches, in which switching units are controlled by data processing devices, including following steps: controlling switching unit of first power switch for switching state change by means of data processing device of first power switch, determining whether switching state change has occurred, and if not, sending a signal by data processing device of first power switch on data processing device of second power switch switching unit, control of second power switch for switching state change by means of data processing device of second power switch.

EFFECT: creation of switching devices, which provide separate branches of equipment energy distribution reliably connected or disconnected.

7 cl, 1 dwg

Description

The invention relates to a switching method in the arrangement of power switches, and under this arrangement in this case should be understood that the power switches are connected in series and / or parallel to each other. The property of the power switches should be that the switching units themselves are controlled by a data processing device, and the data processing device is typically configured as a microcontroller. Using such a microcontroller, a power switch can handle logic tasks. In particular, self-diagnosis functionality may be provided.

In devices of the above type, there must be high reliability in that the power switch that should be turned on is really turned on and that the power switch that should be turned off is also really turned off. Until now, such reliable switching on and off in energy distribution equipment has been carried out by means of a superior system. This system consists of many measuring sensors that measure the flowing current in many parts of the equipment. From part of the power switches that are capable of communication, switching data and switching values may be requested. A control system created in such a way as a superior system is usually controlled by a control room in which either automatically or by a technician manually, in the event of a malfunction, that is, when the envisaged switching action cannot be performed, countermeasures are introduced.

The use of such a control system is fraught with high costs. Automation of the implementation of countermeasures is difficult, but manual implementation of countermeasures is also associated with risk, due to the possibility of failure caused by the human factor.

Thus, it is an object of the present invention to provide a switching method in an arrangement of power switches of the above type in which it is ensured to an increased extent that individual branches of power distribution equipment are reliably connected or disconnected.

This problem is solved in one aspect by a method with features according to paragraph 1 of the claims and, in another aspect, by arrangement with features according to paragraph 6 of the claims.

Corresponding to the invention, the method includes, therefore, the following steps:

- controlling the switching unit of the first power switch to change its switching state by means of a data processing device of the first power switch,

- determining whether a change in the switching state has occurred (via the data processing device), and if this occurs, the method can be completed. In this case, of interest is the case when a change in the switching state has not occurred, since then the method continues by performing the following steps:

- sending a signal through the data processing device of the first power switch to the data processing device of the second power switch,

- controlling the switching unit of the second power switch to change its switching state by the data processing device of the second power switch.

The present invention, on the one hand, proceeds from the fact that the power switch can fail so that it can no longer turn itself on and off reliably and that another power switch must be turned on to replace the provided switching process. The peculiarity now is that the power switches themselves communicate with each other, so that a workaround through the control room is no longer required: one power switch itself recognizes that it will not be able, as provided, to change the switching state of its switching unit, reports using a signal to another power switch, and then it switches instead. In this way, reliable connection and disconnection of the branches of the energy distribution equipment is ensured.

In an alternative embodiment of the invention, the switching blocks are controlled in order to turn off, that is, the switching contacts must also open so that the current can no longer flow through them and thereby through the power switch. In this case, the signal is sent to such a second power switch, which is connected in series with the first power switch. Alternatively to the choice of this second power switch by means of targeted sending, the signal can be transmitted to all power switches, and the second power switch can recognize by the type of signal, for example, the address contained in it, or possibly also by the sender’s identifier (first power switch) that he himself for the signal-sending first power switch should function as a second power switch. The fact that the second power switch is connected in series with the first power switch is important when turning off, because after switching off, no more current should flow in the entire branch.

On the contrary, it is true that if the control of the power switches is carried out in order to turn on the current, then such a second power switch is selected or independently activated that is connected in parallel to the first power switch, since in case of parallel connection the current flows for redundancy.

The method according to the invention can be performed when a change in the switching state is to be initiated externally, that is, after the corresponding signal is received from the first power switch externally, by which a change in the switching state of the switching unit of the first power switch is requested. The method is equally applicable when the data processing device of the first power switch recognizes the existence of a (predetermined) condition, which, according to a predetermined criterion, requires a change in the switching state, in which case the power switch operates independently, that is, changes its switching state if he is workable.

In the arrangement according to the invention, from a plurality of series and / or parallel connected power switches that are at least partially connected to each other via a data network, at least the first power switch has the functionality to send such a signal with respect to which at least one second the power switch has the ability to change its switching state based on the reception of this signal. In other words, at least one pair of the first and second power switches has the ability to communicate through a data network so that one power switch can cause a change in switching state in another power switch.

Preferably, the at least one first power switch has a self-diagnosis functionality. In the framework of self-diagnosis, it is determined whether a change in the switching state of the switching unit on the basis of the control command occurs, and if this does not occur despite the control command, it is the first power switch with the functional ability of self-diagnosis that can send the signal, which is interpreted by at least one second power switch so that the second power switch must change its own switching state.

The following describes a preferred embodiment of the invention with reference to FIG. 1, where an arrangement according to the invention is shown in series and parallel to one another of switched on power switches, in which the method according to the invention can be implemented.

In power distribution equipment, which, for example, is connected to a public power supply network, a plurality of power switches S1, S2, S2 ', S2 ”, S3, S3', S3” are interconnected, namely in a hierarchical form in this case at three levels . The electrical connection is shown here by solid lines. At the same time, the power switches are interconnected via a data network, which is illustrated by dashed lines.

From the power supply network NW, current can flow to the first consumer branch VZ1 through a series connection of the first level power switch S1, the second level power switch S2 and the third level power switch S3. At the second level, another additional power switch S2 'is connected in parallel with the power switch S2. Thus, there is also a connection of the power switches S1, S2 'and S3 with the consumer branch VZ1.

The consumer branch VZ2 is connected to the network NW through the first level power switch S1, both the second level power switches S2 and S2 'are parallel to each other and the third level power switch S3'.

Finally, the consumer branch VZ3 is connected to the network NW via a first level power switch S1, another second level power switch S2 ”and another third level power switch S3”.

Each power switch has, as in this case is indicated only for the power switch S3 ”, its own switching unit SE, that is, a unit of two connected contact elements that are detachable from each other to open the switch. When the contacts are separated, the switching unit turns off; when the contacts are brought into contact, it turns on. In this case, the power switch must be controlled by a microcontroller µС. In the symbols of FIG. 1 μC microcontroller can be indirectly associated with the communication channel, which is symbolically indicated by dashed lines, and the switching unit SE, with the current path, which is symbolically indicated by solid lines.

First, the case should be discussed when, with the switch S1 closed and the switches S3 and S3 'closed, the consumer branches VZ1 and VZ2 must be connected due to the fact that the second level closes.

The switch S2 receives, for example, an appropriate control command from outside, and the data processing device of the power switch S2 controls the associated switching unit so that it closes. The power switch S2 is equipped with a self-diagnostic functionality and can determine whether the intended change in the switching state has occurred, i.e., closing or switching on of the switching unit. If this is the case, then, as desired, a connection is created between the NW network and the consumer branches VZ1 and VZ2. If, on the contrary, the switch S2 is faulty and therefore the last one is not turned on, the power switch S2 sends, as the first power switch of the second level, a corresponding signal to the second power switch S2 'of the same level, which is connected in parallel to it. The data processing device (microcontroller) of the second power switch S2 'receives this signal and causes, by controlling the switching unit of the second power switch S2', that it is now closed or turned on.

Thus, by arranging the first and second power switches S2 and S2 'in parallel with each other, redundancy is provided, and this redundancy is used by communication via a data network, namely, the first power switch sends the corresponding signal according to arrow P1 to the second power switch S2'.

On the contrary, it is possible that first the power switch S2 'should be closed as the first power switch, and if it does not, then it sends the corresponding signal P2 to the power switch S2 as now the second power switch, after which at least the last one closes.

More than only two power switches S2, S2 'can also be connected in parallel to each other so as to provide redundancy to an even higher degree, and also the failure of more than one power switch can be overcome.

The following describes the shutdown situation.

For example, the consumer branch VZ3 should be disconnected from the NW network, for which reason the S3 ”power switch located closest to it would have to be turned off.

It may take place that in this case the external initiation is also carried out, but it can also be that the power switch S3 ”, due to the registration of the fault current or overcurrent, would like to carry out its own shutdown. Thus, the microcontroller µC (data processing device) of the third-level power switch S3 ”also controls the corresponding switching unit SE. Now suppose also that this power switch S3 ”as the first power switch can perform a self-test. If the shutdown is carried out as desired, then the consumer branch VZ3 is successfully disconnected from the NW network. If the shutdown is not carried out and therefore the power switch S3 "is not fully operational, then it sends a signal P3 to the power switch S2", with which it is connected in series. The latter now functions as a second power switch, which receives the signal and then, through its microcontroller, issues a control command to its own switching unit.

Now also the second power switch S2 ”is configured for self-diagnosis and can determine whether the shutdown has been successfully completed. If the power switch S2 ”of the second level is turned off, then now, in a successful manner, during the second attempt, the connection between the network NW and the consumer branch VZ3 is interrupted.

If this is not the case, then the power switch S2 ”sends on its side again as the first power switch the signal P4 to the power switch S1 of the first level and causes the latter to now be triggered.

Therefore, by connecting the three power switches S1, S2 ”and S3” in series, double redundancy is ensured if the consumer branch VZ3 is to be disconnected from the NW network.

If a consumer branch VZ1 or VZ2 is to be turned off, this will first be done through a third-level power switch S3 or S3 '. Here, now, one of the second level power switches S2 or S2 'must be turned off, which has been turned on so far. If both are on, then both power switches S2 and S2 'must be turned off.

If now the second level power switch S2 is turned on and the power switch S2 'is still not there, then the signal P5 or P5' causes the power switch S2 to turn off its switching unit via its microcontroller. If this is not the case, then the signal P6 is sent to the next highest level, the power switch S1 of the first level, to turn off at least it.

Alternative to a workaround through the second level power switches S2 and S2 ', if the consumer branch VZ1 or VZ2 is connected to the network via such a connection that contains two parallel switches S2, S2', this method also allows parallel switching. In this case, not shown in FIG. 1, a signal is directly sent from one of the third level power switches S3, S3 'to the first level power switch S1.

Claims (7)

1. A switching method in the arrangement of power switches (S1, S2, S2 ′, S2 ″, S3, S3 ′, S3 ″), in which the switching units are controlled by data processing devices, which includes the following steps:
- control of the switching unit (S2; S3 ″) of the first power switch to change its switching state by the data processing device of the first power switch,
- determining whether a change in switching state has occurred, and if not,
- sending a signal (P1, P2, P3, P4, P5, P5 ′, P6) through the data processing device of the first power switch (S2; S3 ″) to the data processing device of the second power switch (S2 ′; S2 ″),
- controlling the switching unit of the second power switch (S2 ′; S2 ″) to change its switching state by the data processing device of the second power switch (S2 ′; S2 ″). 2. The method according to p. 1, characterized in that the control of the switching units is carried out in order to turn off and that the second power switch (S2 ″) is connected in series with the first power switch (S3 ″). 3. The method according to p. 1, characterized in that the switching blocks are controlled for inclusion and that the second power switch (S2 ′) is connected in parallel to the first power switch (S2). 4. The method according to any one of paragraphs. 1-3, which is executed after a signal is received from the outside by means of the first power switch, by which a change in the switching state of the switching unit of the first power switch is requested. 5. The method according to any one of paragraphs. 1-3, which is performed when the data processing device of the first power switch recognizes the existence of a condition that, according to a predetermined criterion, requires a change in switching state. 6. An arrangement of a plurality of power switches in series and / or parallel connected (S1, S2, S2 ′, S2 ″, S3, S3 ′, S3 ″), which are at least partially connected to each other via a data network, of which at least at least the first power switch (S2; S3 ″) has the functionality to send such a signal (P1; P3), in relation to which at least one second power switch (S2 ′; S2 ″) has the ability to change its signal own switching state. 7. The arrangement according to p. 6, characterized in that at least one first power switch (S2; S3 ″) has the ability to self-test.

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