DE1463006B2 - Trip device for a current-limiting switchgear - Google Patents

Description

The invention relates to a triggering device for an externally controlled current-limiting switching device, which is to be triggered when at least two electrical quantities to be monitored (measured variables) exceed the instantaneous value according to predetermined limit values (setting values), at least one measured variable being the steepness of the current. The device is primarily intended to trigger an explosive separator, i.e. a switching device in which a tubular conductor section is blown open by means of an explosive charge to be ignited from the outside and the current is commutated and extinguished on a fusible conductor connected in parallel. With such a switching device, due to its speed, it is possible to limit and switch off a short-circuit current before its peak value, which is otherwise possible, occurs. However, it is customary to measure not the instantaneous value of the current itself, but that of its steepness and to make the tripping dependent on it. It is necessary to measure the current steepness only in a certain range from a lower limit i _min to an upper limit i _max , so that on the one hand higher-frequency equalizing currents of low amplitude do not lead to false tripping, on the other hand the switching device does not lead to an excessively high instantaneous current value is triggered and thereby fails.

A release device that meets these requirements is described in German patent specification 1140 268. It contains a current converter with an easily saturable core, which is constantly premagnetized and terminated with an inductive load. The pre-magnetization results in the smallest current i _min and the voltage-time area of the transformer core the largest current i _max , between which tripping may take place. A voltage proportional to the rate of rise of the current is taken from an auxiliary winding of the inductive load. Although this release device is very robust and reliable, it has the disadvantage of little freedom of movement with regard to the dimensioning and selection of the response values and difficult dimensioning, combined with an accuracy that depends heavily on the properties of the saturable iron. In addition, the triggering of the device only depends on the level of the voltage occurring at the inductive load and not on its polarity. This can lead to a trip if, for example, the measuring range is run through with positive current instantaneous values at a negative current rate of increase.

The object of the invention is to provide a way of triggering the presence to make several different measured variables dependent, possibly on the most varied An electrical system to be monitored may occur, with less monitoring expensive and the triggering should nevertheless be made more precise.

To solve this, the invention provides in the above-mentioned device that the measured variables in analog voltages are converted that these voltages are separated for positive and negative polarity the measured variables are determined and each fed to an AND gate made up of diodes, their outputs with the input of an electronic flip-flop with a defined response voltage are connected.

Currents, voltages and sums of currents or voltages can be recorded as measured variables.

The analog voltages shown for the measured quantities can be referred to as image voltages.

The fact that the instantaneous value of a measured variable exceeds or exceeds the associated response value. has fallen below, is referred to below as the triggering criterion. Will be more than two measurands monitors and should not only trigger triggering in the event of a single constellation of trigger criteria can take place after the instantaneous values of the measured variables are mapped in the manner described have been, at least two different constellations each of some of the depicted Instantaneous values are linked with one another in the manner of a logical "and" link. That can e.g. B. be necessary if not only the steepness of a single stream, but also that a sum of currents should lead to tripping as soon as they exceed certain values and as long as the instantaneous value of the

tendency stream is currently in a certain area, or if in this way two different ones Sums of currents are to be monitored.

The precisely defined response voltage of an electronic device, such as e.g. B. a Schmitt trigger. The switching device should sometimes not be triggered if one of the measured variables exceeds a certain value, for example if the current flowing through the switching device has such a high instantaneous value that the switching device would fail when triggered and would be destroyed as a result. In order to prevent this, a blocking potential is switched to the input of the electronic device, in such a way that the image voltage of said measured variable is formed with the opposite polarity to the reference point as the other image voltages and via a Zener diode of greater Zener voltage than the response voltage of the electronic device is given directly to its input. As a result, the input is blocked when the image voltage of the measured variable in question exceeds the difference between the Zener voltage and the response voltage of the electronic device.

The switching device with the triggering device according to the invention is mainly used for monitoring used by alternating current networks because the positive and negative half-waves of the measured variables are separated mapped and the image sizes of the positive and negative half-waves of several measured quantities, respectively linked separately. The reason for this is as follows: In general, the triggering criteria are Instantaneous values and steepnesses of currents. Should the triggering take place, for example, if a current has a certain instantaneous value and a certain steepness at the same time, then the image tensions of the individual half-waves of such polarity become "and" linked with one another linked that tripping occurs only in the rising part of the current half-wave; in the descending part The polarity of the instantaneous values of the current wave is then the same, but that of the slope is reversed, so that no suitable "and" links are possible and the triggering does not occur. A current transformer with a limited overcurrent figure can now be used to measure the current, i. H. one whose core goes into saturation after passing through a certain stress-time area. Because the decisive starting area of the rising branch of each current half-wave is cleaned by the converter transmitted, and saturation does not occur until the current instantaneous value for a trip has become unacceptably high anyway. After saturation has occurred, the secondary current of the converter follows no longer the primary current, but goes in any one that depends on the time constant of the burden History back again. This undefined behavior of the saturated under certain circumstances, very harmful Current transformer is made harmless by the feature of the invention just mentioned, there as a result, tripping can only take place in the rising branch of the current half-wave. One can on this way to current transformers with extremely high overcurrent figures, as would otherwise be required would do without.

In the drawing, the circuit diagram of a release device according to the invention is shown. The structure and the operation are described below.

The secondary current of a current transformer, which is located in a feed of an alternating current switchgear, is conducted via the terminals α and b. An explosive separator is arranged in this feed. In the other feeds the switchgear current transformers are disposed, the secondary currents (including the via from flowing) in

ίο added up in a suitable manner and routed across terminals c and d ; For example, the secondary current of a summation current transformer can be routed via cd.

The separator is triggered when a negative voltage of 12 volts against the grounded reference point m occurs at the measuring input e of the electronic flip-flop 1, for example a Schmitt trigger. The flip-flop should be equipped with pnp transistors; when using npn transistors

ao or vacuum tubes would require a positive voltage at point e and therefore a polarity reversal of all diodes. The battery 2 supplies the negative supply voltage for the flip-flop 1 and · for the logic circuit to be discussed below.

The triggering of the separator should essentially be made dependent on the presence of a certain steepness of the current flowing through ab or cd , because such a steepness allows conclusions to be drawn about the expected short-circuit power as soon as a short circuit occurs. A certain short-circuit power fed into the switchgear via the separator means a certain steepness of the current flowing through from and thus a certain voltage on the auxiliary windings 4 and 5 of the choke 3. Correspondingly, a total short-circuit power fed into the switchgear means a certain steepness of the flowing through cd Total current and thus a certain voltage at the auxiliary windings 7 and 8 of the choke 6. The voltages at the chokes 3 and 6 are adjusted with the adjustable voltage dividers 9, 10, 11 and 12 in such a way to the response voltage at point e that the triggering of the separator takes place at the desired short-circuit power.

The current via the explosive separator itself is used for further triggering criteria. For this purpose, the current is conducted via α and b via the adjustable ohmic resistors 13, 14, 15 and 16. It can be seen that two of the resistors 9 to 16 always belong to a trigger criterion, one for the positive and one for the negative half-wave. The half-waves are separated by the rectifiers 17 to 24. The rectifiers 17 to 22 also have the effect that all image voltages occurring at the resistors 9 to 14 are negative with respect to the grounded reference potential m .

The following constellations of trigger criteria should lead to the triggering of the explosive separator:

1. Tripping should take place when the sum of the short-circuit power fed in is 400 MVA if, in addition, the short-circuit power flowing through the separator itself 100 MVA and if at the same time the instantaneous value of the explosive separator flowing current exceeds 3 kA.

5 6

2. Triggering should take place when the short-circuit power flowing to the separator via points / and g, via diodes 35 and 36, exceeds the aforementioned diodes in reverse transmission-400 MVA and when the direction is switched at the same time, the momentary value fed to the flip-flop be about the explosive separator. A difference to the real so-called flowing current exceeds 3 kA. 5 logic circuits is that there is simple

Signal voltages, i.e. yes-no decisions

3. The triggering should in any case be prevented, while according to the invention Bildwenn the instantaneous value of the explosive voltage, d. H. splitter analog values with each other flowing current exceeds 5 kA. be tied.

ίο The second trigger condition becomes accordingly

Compliance with these trigger conditions is met. The lower wiper of the voltage divider 9

achieved with the help of diode gates. There will be the and the upper of the voltage divider 10 on

that current half-wave is considered at which the current 400 MVA is set. The "and" links

flows from b to α or from d to c . For the first, diodes 31 and 32 or 33 and 34 follow.

The trigger condition is set with the grinder on the chip

voltage divider 11 a total short-circuit power of diodes 37 and 38 and the resistors 41 and 42

400 MVA, with the upper wiper on the voltage simply by expanding the diodes already 35

divider 9 made a single short-circuit power of 100 MVA and 36 containing diode gate

and a current value of 3 kA with the resistor 13, so that a complete gate with the

set, d. That is, with these values, the 20 diodes should result in 35 to 38.

associated image voltage is 12 volts. The three image voltages are achieved on the diodes 25, 26 and 27 as follows: The resistors 15 and 16 are given. Via the high resistance 39 and are set in such a way that 12 volts are applied to each of the diode 35, the battery 2 tries to kick the tilt when a current from element 1 is triggered via the disconnector. But that succeeds 25 5 kA flows. The image tensioning Not occurring at them as long as even one of the three in question image are calculations as opposed to all the other positive voltages m compared to the resistor 39 to ground. This positive image voltages are werniederohmig, required at the point e arrival to with the diodes 43 and 44 has not yet reached a corresponding value in relation to one another. Flows z. B. via couples and via the Zener diode 45 directly to the explosive separator only a current of 1.5 kA, so 30 measuring input e of the flip-flop 1 is given. The zener occurs at resistor 13 only 6 volts, and it flows diode 45 has a zener voltage of 24 volts. You a current through the diode 27 and the resistor 39, causes the positive potential of the point k, which holds the voltage of the point / to ground m from the negative potential of the point e, i.e. the incidence to about -6 volts, so that the toggle gear of the toggle element 1, at most 24 volts away, element 1 cannot yet respond. Only when all can be 35, since otherwise it becomes permeable and every three image voltages have reached at least the value of the higher voltage between the points mentioned 12VoIt, also takes the point / which is limited to 24 volts. If, for example, the explosive voltage - 12VoIt flows to ground and the isolator lets 6.25 kA, then the resistor 15 or 16 trigger element 1 will respond. (depending on the direction of the current) a positive voltage of

If the current half-wave flows in reverse direction 40 15 volts against ground, the voltage of point e

taxig, ie the secondary currents flowing from α to b will therefore be at most - 9 volts against ground

or from c to d, the rectifiers 17 block, limited, which leads to the response of the flip-flop 1

19 and 21, and there are now tensions that are no longer sufficient. The resistors 15 and

Voltage dividers 10 and 12 and the resistor 14 16 are of course low resistance to the resistors

on that linked to diodes 28, 29 and 30 45 39 to 42.

and whose smallest is the stress of the punk. Is the zener stress due to specimen

tes g determined against mass. The point / has no dispersion, for example only 23 volts, so must be attached to the

Voltage to ground, but nevertheless resistors 15 and 16 occur each 11 volts,

Triggered by resistor 40 and the diode when 5 IcA current flows through the separator,

36, if the smallest of the three of interest now 50 d. that is, the image voltage must be at the value of the measurement

Image voltages and thus the point g 12VoIt, from which the release is blocked,

enough. The diode 35 blocks the voltage equal to the difference in the Zener voltage of the Zener

Point / from the input e of the flip-flop 1. diode 45 and the response voltage at point e

It can be seen with the diodes 25, 26 and 27. In this and in all other cases or 28, 29 and 30 each have a type of "and" 55 the diodes were connected as an ideal rectifier, while the results of these two assume, that is, without a voltage drop in the forward "And" links, namely the tensions of direction.

1 sheet of drawings

Claims (5)

Patent claims: 1. Triggering device for an externally controlled current-limiting switching device, which is then triggered should be if at least two electrical quantities to be monitored (measured quantities) dem Exceed the instantaneous value after predetermined limit values (setting values), whereby at least a measured variable is the steepness of the current, characterized in that the measured variables in analog voltages are converted that these voltages are separated for positive and negative The polarity of the measured variables is determined and an AND gate made up of diodes in each case are supplied, the outputs of which with the input of an electronic flip-flop with defined Response voltage are connected. 2. Tripping device according to claim 1, characterized in that the measured variables Currents, voltages and sums of currents or voltages are recorded. 3. Tripping device according to claim 1 or 2, characterized in that from the measured variables obtained analog voltages are tapped at adjustable resistors, so that depending on the position of the resistor tap, the full voltage or only a partial voltage is fed to the downstream gate. 4. Trip device according to claim 1, characterized in that the instantaneous current value and current rate of increase as measured variables be used. 5. Release device according to claim 1 or one of the following, characterized in that that the triggering is then blocked with the help of a Zener diode when a measured variable a exceeds the specified value.