DE1463595C - Direction relay - Google Patents

Description

seen the short-circuit point is. So there must be 15 position with the one from the current in the one to be monitored.

Directional decisions are made. Such the network derived stream J 2 matches. Direction decisions are made by relay arrangements
met, which are generally used as a direction relay

be drawn.

The quality of a direction relay is primarily what leads to this.

The additional current / 3 generated in the circuit of the other input of the ring modulator is supplied to the primary winding w2.

In addition to the circuit means 5 already mentioned, the voltage divider consisting of the two resistors R 2 and R3 of equal size is arranged in the circuit of the other input of the ring modulator,

determined by whether for near its installation location short-circuits that occur, correct directional determination is still being carried out. The Directional relay according to the invention, which is a good

Directional selectivity or one in the reverse direction on which the from the current in the to be monitored. has an adjustable trigger zone, the network derived current / 2 is characterized by the voltage U 1 being generated by the circuit means in the circle of the. .The resistor R 4 connected to the secondary winding wS of the input of the ring modulator of the current transformer St dimensioned in such a way that, if one occurs in relation to the current, it can also be replaced by a transformer, in the network to be monitored anti-phase 30 is used to obtain the Current in the voltage U 2 , which is proportional to the voltage U 2 that is to be overvoltage in the network to be monitored of the monitoring network

Desired response sensitivity in the reverse direction wl of the transformer Tr and to the circuit between the certain amplitude due to the additional current grain resistors R2 and A3 is pensed and that when a point with respect to 35 the polarized relay N is connected, the current in the network to be monitored Normally closed contact to decide the direction uses in-phase voltage on which is to be monitored. To accelerate the directional decision network, the additional current triggers the polar- it is advantageous not to cause any mechanical relays to contact the contact even when the bias voltage is released. If there were a mecha voltage on the network to be monitored, then this conducted current would be very small or zero. a slight deflection of the actuation

It is known to equip a distance relay with a directional organ of the polarized relay N , equipment-sensitive organ that consists of non- The opening of the contact would then be canceled by the linear impedance elements in the modulator circuit, in the case of the (ring modulator) and a polarized one Relay 45 would not yet open is delayed. One forms is that at the output side of the modulator it therefore prefers the setting of the actuation circuit is connected. One input of the organ of the polarized relay N is provided with a ring modulator from the voltage on the men that when there is no current in the polarized network to be monitored, and an additional voltage derived from the monitored network current without mechanical biasing is closed.

current, the other input of the ring modulator on

current derived from the monitored mains current and the closing of an overcurrent relay belonging to a connected to contacts a1 and a2 derived from the monitored voltage are supplied to the network set current to be monitored. One unit is connected, then the additional current supplied from the ring modulator's voltage to the network to be monitored is derived with the other input of the ring modulator current / 1 together with the additional current / 3 the supplied, monitored by Mains current derived- fed to an input of the ring modulator. Identical through ten stream. However, such a relay has the circuit of the other input of the ring modulator - driven. According to the known effective resistance from the coordinate center point out of the ring modulator, the current / through is shifted. In addition, it does not indicate every short circuit in the polarized relay N in terms of magnitude and direction of release, but speaks of the phase position of the currents / 1 and / 2 to one only in cases in which the impedance of the 65 depends on the other.

short-circuited line section lies within the circle describing the tripping area.
In Fig. 1 is a circuit diagram of a direction

If there is a short circuit in the tripping direction, then
is derived from the voltage on the network
Current 71 through the in-phase additional current / 3

amplified, and a current / flows through the polarized relay JV, which is the normally closed contact of the relay in closes securely in the shortest possible time and thereby triggers it. With the help of the in the circle of other input of the ring modulator lying circuit means 5 generated additional current / 3 is It is therefore possible to trigger the polarized relay even if the relay is out of the Voltage on the network to be monitored derived current 71 is very small or zero.

If a short circuit occurs in the reverse direction, the phase position of the current flowing in the network to be monitored changes by 180 ° and thus also the phase position of the voltage 171 and the additional current / 3 at the other input of the ring modulator. The currents occurring in the windings w 2 and w 3 of the transformer Tr are consequently out of phase with one another and partially compensate for one another. If the flow predominates in the winding w3, then a current I arises which opens the normally closed contact of the polarized relay //. Since the amplitude of the additional current / 3 can be set within wide limits by means of appropriately dimensioned circuit means S , it is possible to define a triggering area of the desired extent in the blocking direction. If, for example, the direction relay is in the vicinity of a busbar in the course of a branch line, then it is often desirable to use the direction relay to monitor part of the busbars that are actually arranged in the reverse direction.

In Fig. 2 shows an exemplary embodiment of the directional relay according to the invention, in which the circuit means form a current branch, in the two branches 7 and 8 of which the current-independent resistors RS and R 6 are located.

The voltage U 2 that drops across the resistor R 4 and is proportional to the current in the network to be monitored causes the current 72, which is divided into a current 7 3 flowing through the branch 7 and a current 74 flowing through the branch 8. Both currents grow proportionally with the voltage £ 72 and, since this voltage is proportional to the current flowing in the network, they are also proportional to the current in the network to be monitored.

If a short circuit occurs, the voltage on the network to be monitored collapses, and the current 71 derived from this voltage becomes very small. The voltage U 2 , which is proportional to the current in the network to be monitored, increases, and the current 72 flowing through the circuit of the other input of the ring modulator also increases, which corresponds to the size of the resistors R 5 in the current branches 7 and 8 and R 6 splits into streams 73 and 74.

If a short circuit occurs in the tripping direction, the circuit should be designed so that the current 71 and the additional current 73 are in phase. A current Jx then flows in the secondary winding wl of the transformer Tr which, together with the current 72, causes a current 7 through the polarized relay N , which reliably closes the normally closed contact. This is also the case when the current 71 is zero and only the current 73 is effective.

If a short circuit occurs in the reverse direction, the current 71 changes its phase position by 180 °. If the flux generated in the primary winding w3 of the transformer Tr by the current 71 is less than or equal to the flux generated by the additional current 73 in the primary winding vv2, the current Jx retains its original phase position with respect to the current 72, and the current / continues to close the normally closed contact of the polarized relay N. If the flow in the primary winding w 3 outweighs the flow in the primary winding w2, then the phase position of Jx changes by 180 ° and the current / opens the normally closed contact.

Since the additional current 73 is proportional to the current in the network to be monitored and the The current 71 derived from the voltage on the network to be monitored is proportional to the If the voltage on the network to be monitored increases, the direction relay blocks regardless of the size of the current flowing in the network to be monitored, always with the same impedance. The direction relay has a tripping zone in the reverse direction, the extent of which is the size of the is almost independent of the current flowing in the network to be monitored.

In many cases a directional relay is required that has very good directional selectivity, i.e. H. one Has the smallest possible trigger zone in the blocking direction. A directional relay according to the invention that this Claims met is shown in FIG. 3 shown.

The circuit means in turn form a current branch, in whose branch 9 the current-dependent resistors, for example consisting of anti-parallel-connected rectifiers G 5 and G 6, and in whose branch 10 the current-independent resistor R 7 is in series with the primary winding w2 of the transformer Tr. In this way a directional relay is obtained which, as the following explanations will show, has an extremely small tripping zone in the reverse direction in the case of high short-circuit currents flowing in the reverse direction and therefore has a high directional sensitivity.

The current 72 flowing in the circuit of the other input of the ring modulator is divided into a current 75 flowing through the current branch 9 and a current 73 flowing through the current branch 10. The voltage i / 3 generated by Strom75 at the anti-parallel connected rectifiers is limited in its amplitude by the threshold voltage of the rectifier used. As a result, only the current 73 can flow through the branch 10, which is driven by the voltage U 3 through the primary winding w 2 of the transformer Tr and the resistor R 7 in series with this winding. If the voltage U 2 at the resistor R 4 rises as a result of the increasing current in the network to be monitored, then the additional current 73 cannot exceed a maximum value because of the limiting effect of the anti-parallel rectifiers G 5 and G 6.

The additional current generated in the circuit means is sufficient for short circuits occurring in the tripping direction 73 has the same function as in the preceding exemplary embodiments. It should be at this point therefore only reference is made to the corresponding sections of the description.

If a short circuit occurs in the reverse direction, then the flow generated by the additional current 73 in the primary winding w 2 increases with increasing current in the network to be monitored only up to

at a constant value. The current 71 derived from the voltage on the network to be monitored therefore only needs to generate a correspondingly limited flow in the primary winding w 3 to compensate for the flow in the primary winding W 2. Therefore, with increasing current in the network to be monitored, the tripping impedance in the reverse direction decreases.

In some cases, for example if the direction relay is part of a branch line, however, is arranged in the vicinity of a busbar, and a monitoring of a part of the reverse direction lying busbar is to be made, it is advantageous to use a direction relay use whose impedance in the reverse direction does not depend so much on the one to be monitored Network has flowing current, as that in the F i g. 3 direction relay described. A Embodiment of a directional relay according to the invention, in which the impedance in which still a tripping in the blocking direction has just occurred, or the tripping zone in the blocking direction as a function of the size of the current flowing in the reverse direction in the network to be monitored in the event of a short circuit by appropriate dimensioning of the circuit means in a wide range of the circumstances can be adapted at the installation site, FIG. 4 shows.

The circuit means in turn form a current branch consisting of branches 11 and 12. In the current branch 11, current-dependent resistors, which here consist of two anti-parallel-connected rectifiers G 7 and G 8, are arranged in series with the current-independent resistor R 8. The other branch 12 is formed by the series connection of the primary winding w 2 of the transformer Tr and the current-independent resistor R 9. At the circuit point 13 located between the anti-parallel connected rectifiers G 7 and G 8 and the current-independent resistor R 8 and between the primary winding w2 and the current-independent resistor /? 9 of the circuit point 14 lying on the current branch 12, the current-independent resistor RIO is connected.

As the F i g. 4 shows, this directional relay is a combination of those shown in FIGS. 2 and 3 direction relay described.

If the direction relay is connected to the network to be monitored in the event of a short circuit occurring in the network to be monitored after actuation of the contacts al and <z2, then the current 72 flows in the circuit of the other input of the ring modulator, which is proportional to the current flowing in the network to be monitored . The additional current 73 flowing through the branch 12 is not only dependent on the threshold voltage of the rectifiers G 7 and G 8 connected in anti-parallel, but is also influenced by the resistors R 8, R 9 and R 10.

For a short circuit occurring in the triggering direction, the circuit means fulfill the repeated described function. For short circuits occurring in the reverse direction, appropriate Dimensioning of the current-dependent and current-independent resistances of each course of the Achieve tripping impedance depending on the short-circuit current that lies between the limit curves, by the circuit arrangements according to FIGS. 2 and F i g. 3 are given. So you win on this Way a direction relay, in which the tripping zone in reverse direction depending on the size of the in the event of a short circuit in the network to be monitored, current flowing according to the conditions can be set at the installation point of the direction relay.

Claims (7)

Patent claims: 1. Directional relay equipped with a ring modulator and a polarized relay, in which one input of the ring modulator has both a current derived from the voltage on the network to be monitored and an additional current generated by switching means in the circuit of the other input of the ring modulator and the other input of the ring modulator a is supplied from the current in the derivative to be monitored network flow, characterized in that the formwork ₁ processing means (Fig. 1; S) measured in the circuits of the other input (5, 6) of the ring modulator (Gl to G 4) in such a way are that when a voltage in phase opposition to the current in the network to be monitored occurs on the network to be monitored, the current (71) derived therefrom is compensated for by the additional current (73) up to an amplitude determined by the desired response sensitivity in the reverse direction, and that in the event of a current in the network to be monitored For in-phase voltage on the network to be monitored, the additional current (7 3) triggers the polarized relay (N) even if the current (71) derived from the voltage on the network to be monitored is very small or zero. 2. Directional relay according to claim 1, characterized in that the currents are fed to the inputs (3, 4 and 5, 6) of the ring modulator (Gl to G 4) via voltage dividers (R2, R3 and Tr, wl). 3. Directional relay according to claim 2, characterized in that the polarized relay (N) is connected to the center taps (1, 2) of the voltage divider (R 2, R 3 and Tr, w 1). 4. Directional relay according to claim 1, characterized in that the circuit means a Current branching for the one in the circuit of the other input (5, 6) of the ring modulator (Gl to G 4) Form flowing stream (72). 5. Directional relay according to claim 4, characterized in that the current branches (Fig. 2; 7, 8) contain current-independent resistors (R5, R6) . 6. Directional relay according to claim 4, characterized in that one branch (Fig. 3; 9) current-dependent resistors (Fig. 3; G5, G6), such as rectifiers, varistors, etc., and the other branch (Fig. 3 ; 10) current-independent resistors (F i g. 3; R 7). 7. Directional relay according to claims 5 and 6, characterized in that the one branch (F i g. 4; 11) is a series connection of current-independent resistors (Fig. 4; R 8) and current-dependent resistors (F i g. 4; Eq, GS), e.g. rectifiers, varistors, etc., and the other branch (Fig. 4; 12) has current-independent resistors (Fig. 4; R 9), and that another current-independent resistors (Fig. 4; RIO) containing current branch is present, the one between the current- independent (Fig. 4; RS) and the current-dependent (Fig. 4; Gl, GS) resistors lying circuit point (Fig. 4; 13) of the one branch (Fig. 4; 11) with that in the other branch (Fig. 4; 12) lying circuit point (Fig. 4; 14) connects. For this purpose 2 sheets of drawings 009 545/113