DE691082C - - Google Patents

Description

Protection device for electrical networks The invention relates to on reverse power relays, which on the one hand have the task of tripping of the switch, `nenn a reverse power of sufficient magnitude occurs, and on the other hand to automatically close the open switch again, provided that the prerequisites for this are given.

In particular, the invention is directed to the fact that the reverse current sensitivity the reverse power relay when the switch is switched on by one of a phase earth voltage energized winding is reduced, which interacts wattmetrically with a second coil, which is excited by the corresponding phase earth voltage as soon as the concurrent symmetrical component of the mains voltage exceeds a certain size. It can for this purpose, for example, a relay can be provided that is dependent on responds from the symmetrical component of the mains voltage running along. When the Switches excited by the differential voltage relay windings can also, if the switch is closed and the symmetrical position in the mesh network is none has sufficient height to be closed in itself and then in this case to Increase the relay sensitivity. To carry out the invention furthermore, for example, a voltage rotating field separator is provided over which those windings of the relay are excited which cause an additional torque, which counteracts the triggering movement of the relay. The reduced reverse current sensitivity is expediently canceled again as soon as the reverse power relay receives the switch-on pulse has given. This has the advantage that the relay does not have to be completed after Switch closure assumes the reduced reverse current sensitivity, so that the Relay does not cause the switch to trip again immediately, d. H. the switch turns on and triggers alternately.

Further details of the invention are given on the basis of exemplary embodiments described. However, the invention is not restricted to the exemplary embodiments.

In Fig. I, a multi-phase energy direction relay i is shown. This has two induction discs z and 3, which are rotatable on a common Shaft 4 are attached. Two drive magnets 5 and 6 exercise on the Ferrari disk 3 torques and a third drive magnet 7 equally drives the Ferrari disk z. A pair of brake magnets 8 acts on the Ferrari disc 2 and delayed the speed of rotation of the shaft 4. Each of the drive magnets 5, 6 and 7 has one Voltage winding 9a, gb and 9 ″ furthermore differential voltage windings ioQ, iob and io, and current windings IIQ, Iib and ii ,.

A shorting ring 12 is on each pole piece of a voltage magnet 9, e.g. B. 9d, attached so that the voltage flows through the windings 9a, .9b and 9, respectively, lag behind in the phase.

The shaft 4 carries a gear train 13 which acts on a movable contact member 14. The movable contact member 14 is normally pressed by a return spring 15 against an adjustable closing contact 16, but it can be moved towards the tripping contact 17 with a corresponding rotation of the shaft 4.

Each of the drive magnets 5, 6 and 7 has an overvoltage device, of which only the adjusting screw i8o can be seen in FIG.

In Fig. 2, this adjustment mechanism for the voltage pole 9d of the Drive magnet 9 shown. The adjustment screw is what's out of the illustration though not shown, arranged so that the spindle 8 can be rotated. On the Spindle sits a tab igb of a sheet metal body made, for example, of copper, which carries the short-circuit ring iga. This short-circuit ring ig "is in front of the end face of the magnet 9d and is parallel to the Ferrari disk within the air gap of the magnets movable. If you move the short-circuit ring i9 "out of the center position of the pole 9d adjusted, only part of the power flow of this magnet is through the short-circuit ring delayed in phase, as a result of which the tension magnet then calls for itself a torque emerges.

In Fig. 3 a part of a mesh network is shown with a Protection device according to the invention. One of the feeding transformers is represented by the transformer 2o. It lies between the high voltage network 22 on the one hand and the power switch 23 on the other hand. The circuit of the transformer 2o is not essential to the invention.

The switch 23 is provided with a release device which receives their energy from the network, for example, and also with a switch-on motor or a switch-on coil 23b, which through the contact member 16 of the reverse power relay is controlled: The current windings iiQ, IIb and ii, of the Zückleistungsrelais i are connected to a Stromx andlersatz 24 and -on phase currents are excited. The phase windings ioQ, iob and io, of the relay i are via lines 25u, 25b and 25, on the one hand to the secondary terminal of the transformer 2o and on the other hand to terminals 26Q, 26b and 26. The circuits of these windings ioQ, praise and io, divide at points 26Q, 26b and 26 such that one part is closed over Auxiliary contacts 27 of the switch 23 and suitable resistance elements, for example are shown as phase lamps 28, to the corresponding phase conductors 21a, give and 2I. The other part of these circuits runs over when closed Line switch also closed auxiliary contacts 29 and adjustable resistors 3o and the contacts of a voltage relay 3I to a grounded star point.

The voltage relay 31 is via a rotating field separator (for example according to Austrian patent 13d.928) connected to the power lines in such a way that the Relay energized only by the positive component of the mesh network voltage will.

The voltage relay 3 i is set so that it has its contacts closes when the concurrent component of the line voltages exceeds a certain limit value exceeds, for example, the amount of 95% of the mains voltage. The relay leaves drop its anchor when the rotating component falls below the value of 85 or go ° / o of the normal mains voltage drops.

The current transformers 24 can be created so that they are due to iron saturation Do not allow the secondary currents to rise above a certain limit. For the same Basically, the lamps 28 already mentioned can also contain tungsten filaments, which have a high positive temperature coefficient of resistance. Through the Saturation of the current transformers, the current windings IiQ, IIb, and ii, are protected, through the tungsten lamps 28, the windings ioQ, i ob and io ,.

The voltage windings 9Q, 9b and 9 of the relay i are connected to the voltage between phase conductors 21, give and 21, and earth, d. H. at the star voltage of the network. Fuses 34 are provided on lines 2I ", 24 and? Ic to To protect the transformer 2o from overload currents in normal and reverse directions in the case; that the voltage drops so sharply that the direction relay i does not able to work more.

The three groups of current and voltage windings 9Q, IIQ, 9b, IIp and 9c, IIc are traversed by the current in such a direction that, when the line flows into the network 21, the torque of each of the three magnets 5, 6 and 7 (Fig i) acts in the sense of closing the switch-on contact 16. However, if the energy flows from the network to the transformer 2o, the torque reverses each of the three .Triebmagnete, so that consequently all act in the sense of closing the trip contact 17th

The differential voltage windings ioa, lob and io are connected with respect to the direction of the force flow of the voltage windings 9a, 9b and g, that when the switch 23 is open and the line network 21 receives voltage from the other side, in each drive magnet 5, 6 and 7 a torque arises in the direction of closing the switch-on contact 16, provided that the secondary voltage of the transformer is in the correct phase position to the mains voltage and exceeds the mains voltage by a certain minimum, for example by a fraction of a volt. If, however, the transformer voltage is less than the mains voltage, the contact 17 is closed, even if the phase position of the voltages of the transformer 2o corresponds to that of the mains.

It is now assumed that initially both the feed line 22 as also the mesh network 21 in Fig. 3 are dead and the various movable Parts in Fig. 3 are all shown in this state. If first the feed line 22 receives voltage, a voltage is generated on the secondary side of the transformer 2o, but no power yet because switch 23 is still open. It flows as a result so no current through the windings i i ", I Ib, i i, of the relay i. The windings ioa, iob, io, are then connected in series, with corresponding voltage windings 9a, 9b> 9, and the ballast lamps 28 between each corresponding terminal of the Transformer 2o and earth. So there is a current in these windings. the Currents in the coils ioa, lob and io, and the voltage windings 9a, 9b, 9, are then identical. In the Ferraris relay, these two currents do not call any torque apart from the low torque generated by the short-circuit coil iga is evoked; but is negligible as long as the magnetic flux of the voltage pole remains very small. As a result, the spring 15 holds the movable Contact member 15 firmly on the mating contact 16.

When a connection is established between the power supply unit to the left of switch 23 and the power supply unit 2i, which is not fed from any other side, there is a shunt to the associated voltage windings 9a, 9b, 9,. A phase shift then arises between the fluxes of the current drive core and the voltage drive core, as a result of which a torque is triggered in relay i. Under this condition, a torque arises in the sense of closing the switch-on circuit (contact 16) of the line switch 23. When it is switched on, the switch 23 connects the voltage coils 9a, gb and 9c of the relay i to the phase conductors of the network 2i and also causes the Drelifeldscheider 32 gets tension. If the circulating symmetrical component of the mains voltage is greater than 95 % of the normal mains voltage, the relay 31 responds and closes the windings ioa, iob and io of the relay i in series with the resistors 3o to the voltages between phase conductor and earth.

The windings ioa, iob and io now generate together with the voltage windings 9a, 9b and g, torques of such direction and magnitude that the relay passes through the curve D assumes the property described. By setting the resistors 3o one can adjust the size of this torque accordingly in the respective application. The relay is then set insensitive. The insensitive setting of the Relay allows a significant reverse current, which z. B. in switching operations the synchronization or restart of generators connected to the grid, but in which a switch triggering should not take place, can arise.

If a fault occurs in the mesh network 21, all parallel Switched transformers supply power to the point of failure.

If, on the other hand, a fault occurs in the high-voltage network 22, it is reversed It is true that the direction of energy also changes, and one or more phase voltages break together to a considerable extent. According to the decrease in tension increases also the moving component of the voltage drops sharply, and the voltage drop relay 31 drops its anchor and thereby opens the plias test windings ioa, praise and io, In this state the relay works with its full sensitivity without retraction force. If there is a strong reverse current, the torque in the relay i reverses around, and the movable contact 14 immediately flies over to the other mating contact 17, whereby the switch 23 is turned off.

The line switch 23 closes the auxiliary contacts 27 in its open position and thereby switches the windings ioa, iob and io, of the relay i in series with the ballasts 28 to the main contacts of the switch 23, which is then open. As soon as the fault on the high-voltage line 22 has been eliminated and the feed line has normal voltage again, relay i closes the switch 23, provided that the secondary voltage of the transformer 2o is at least slightly higher than the voltage of the network 21. The measure by how much the The secondary voltage of the transformer must be higher, depends on the setting of the adjusting screw 18. In addition, the reclosing of the switch 23 depends on the fact that the correct phase position between the transformer voltage and the mains voltage exists at the same time. With the arrangement described, the normally set insensitive relay is automatically made sensitive in the event of a line fault (voltage imbalance). In individual cases, on the other hand, it may be more advantageous to work with a sensitive relay arrangement from the outset in order to ensure that the switch is already opened when a reverse current of the magnitude of the magnetizing current of the transformer 2o occurs. In order to obtain a relay that is more sensitive under all circumstances, it is sufficient to open the detachable connection meshes 33 and to disconnect the conductors 25a, 25b and 25 from the connection points 26a, 26b and 26 and instead to the connections 27 ″, 27b and 27 In this circuit, the windings ioa,, Ob and io, are closed via the ballast lamps 28 when the line switch is switched on, and the relay i has the greatest sensitivity.

Fig. 4 shows the use of three voltage drop relays 34, 34 and 31, instead of just one relay 31 with rotating field separator 32 in Fig. 3. The voltage relays 3ra, 3ib and 31 are expediently excited by the star voltages of the mesh network and adjusted so that they close their contacts when these voltages are more than 95 % of the normal voltage and their contacts open when these voltages below 9o or 85 % the normal value decrease.

Fig. 5 shows another embodiment of the invention than Fig. 3, which is mainly to be used when transformers connected in V-connection serve to feed the mesh network. In Fig. 5, the transformer has a 20 "V circuit and grounded center tap of the single-phase winding. Otherwise this arrangement is correct with the arrangement in Figure 3 with the exception; that the relays 31 are not the resistors 30 to earth and that the voltage windings 9a, 9b and 9 of the relay i are different are connected. The voltage windings are in place of being connected in star are each switched on in a circuit which has a resistor 35a or 35b and 35, respectively, and they are influenced by stresses which are opposite by 90 ° the corresponding phase currents are shifted. The resistors 35a, 35b and 35, have such resistance values that the voltage applied to each voltage winding 9a, 9b and 9, is pressed, by 6o to 70 ° compared to the one exciting the circuit Voltage leads.

This is useful; to achieve the correct behavior of the relay in the event of a fault. In devices with transformers connected in V, as shown in FIG. 5, the lamp circuits of the loads are generally fed by two different phase conductors each, in order to achieve an even distribution of the load. The single-phase load transformers are distributed to the three-phase phases and are connected to the voltages of the phase conductors A and B, B and C or A and C. The current transformers 24 therefore carry linked currents; a star connection of the voltage windings of the relay would not be suitable for this.

The following describes the processes involved in the Play embodiment of the invention shown in Figure 6.

If the high-voltage network 22 is initially excited, the network: 2 but de-energized and the switch 23 is open, then, apart from a small current, which flows through a voltage rotating field separator i6, no current through the current transformer flow on the secondary side of the transformer 20. The lines are on the other hand under full voltage, and it is over the phase test coils io, which with the ballast lamps 28 are in series, a current will flow. When the line switch 23, as assumed, is open and the network 21 is de-energized, the current is in the phase test windings io in phase agreement with the current in the associated Voltage windings 9. Since the relay has a Ferrari system, results from these two currents no torque: but as soon as the switch 23 is closed, im but the rest of the network 21 is not fed from any other side, the coils 9 short-circuited, so that no significant torque is generated in this case either can.

The circuit for the closing coil 23b is made by an auxiliary relay 6 closed when the counter contact 16 is closed on the reverse power relay.

The relay 6 closes when it is energized on the one hand the excitation circuit for the closing coil 236 and on the other hand the excitation circuit for the voltage relay 31 by connecting this relay to the Drelifeldscheider 16.

When the voltage relay 31 closes its contacts, "-grounds" as a result voltage applied to the windings.

If a fault then arises in the feed line 2a, the rivet-running line drops symmetrical voltage component so far that the relay 31 drops its contacts, whereby the coils io are closed by the ballast lamps 28. In this circuit then has the relay the increased sensitivity, so that it responds immediately as a result of the reverse current occurring and closes contact 17, which triggers the switch 23.

An arrangement that prevents the reverse power relay from pumping, Fig. i shows. Except for your reverse power relay i and the one in a voltage rotating field separator 16 connected voltage relay 31 and the auxiliary contactor 6 contains the arrangement an additional differential voltage relay 18 with a voltage winding 18 ", a resistor 136 and a winding 18 ,. The voltage coil 18 ″ is in series with resistor 186 at the star voltage of the mesh network. The contact links this relay 18 are in series with the switch-on contact 16 of the reverse power relay i. The windings 18 of this relay are in series with an associated resistor ig at the main contacts of the oil switch 23. A resistor 4.o is connected to a The help of the resistor ig formed voltage divider circuit when the relay 3 i its contact closes and then causes an additional torque in your relay 18. As soon as the voltage relay 31 closes its contacts, i. H. already during the switch-on movement of the oil switch 23, arises both in your reverse power relay i and in your additional Relay is an additional force in the sense of improving the contact pressure. The trigger of the line switch is done independently from relay 18.

In a somewhat simplified arrangement. in which the relay 6; the resistor 30 and a set of contacts on the voltage relay 31 are no longer available, control the switch-on contact of the power relay i and the contact element of the additional Relay 18, the switch-on coils of the oil switch 23 and at the same time the voltage connection for the rotary field separator 16.

Furthermore, the excitation coil of the switch-on contactor 6 can be in a circuit be switched on, which contains the closing contact of the reverse power relay, as well as in series with it the contact of a phase test relay. Another auxiliary relay In addition to contacts for closing the closing coil of the circuit breaker also contacts through which it closes a holding circuit for itself, the is independent of the contacts of the phase test relay. The relay 6 switches on Voltage rotating field separator on.

A voltage relay that controls power connections for the additional Rotation of the direction relay is also connected to the voltage rotating field separator connected. This voltage relay corresponds to relay 31 in FIG. 3.

The phase test relay contains differential voltage windings and a Voltage winding with series resistors. Otherwise it corresponds to the direction relay in Figs. i and 2.

Claims (7)

PATENT CLAIMS: i. Protection device for electrical networks with reverse power relay for the automatic restart of the power switch, characterized in that that the reverse current sensitivity of the reverse power relay when the switch is switched on (23) by a winding (io) excited by a phase earth voltage, which is connected to a second coil (g) interacts wattmetrically, that of the corresponding phase earth voltage is excited, is reduced as soon as the, for example, a relay (31) exciting, concurrent symmetrical component of the line voltage exceeds a certain value (Feg. 3). 2. Protection device for electrical networks with reverse power relay for automatic restart of the power switch, in particular- according to claim i, characterized in that the relay windings excited by the differential voltage when the switch is open (1o11; 'ob, 1o,) when the switch is closed and when the symmetrical Component of the mains voltage does not have a sufficiently specific size, each is self-contained and thereby increases the relay sensitivity. 3. Protection device according to claim i, characterized in that over a voltage rotating field separator (3a11, 3a6, 32,) such windings (io ", lob, io,) of the reverse power relay (i), which generate an additional torque, which the direction of movement of the moving system required to trip the switch (14) counteracts. . 4 .. Protective device according to claim i, thereby characterized in that the reduced reverse current sensitivity of the reverse power relay is canceled again as soon as the return relay activates. switch-on command has given (Fig.7). 5. Protection device according to claim i or the following, characterized characterized that the voltage rotating field separator only when closing or when Conclusion of the closing command of the line switch to the voltage of the transformer (2o) is connected. 6. Protection device according to claim i and 5; characterized, that via the switch-on contact (i6) of the reverse power relay (i) an auxiliary relay (6) is controlled, which is the sensitivity of the reverse power relay to reverse current makes dependent on the symmetry of the mains voltages by the auxiliary relay (6) a Voltage rotating field separator (1i6) connected to a relay (3i), which is the Winding (io) of relay (i) applies voltage which, when excited, reduces reverse current sensitivity lowers (Fig. 6). 7. Protection device according to claim i and 5, characterized in that that the voltage rotating field separator via the switch-on contact of the reverse power relay voltage is applied. B. Protection device according to claim i or the following, characterized characterized that the rotary field separator via the switch-on contact of the RückinistungsreIais and the contact of one in series with it, the phase shift between the Voltages at the open switch and the plia earth voltage monitoring relay voltage is applied. G. Protective device according to claims i and 8, characterized in that that the closing of the line switch only takes place; if besides the phase shift the voltages prevailing at the open switch contacts compared to the phase earth voltage testing relays also check the presence of a sufficient symmetrical voltage locking relay has closed its contacts. ok Protective device according to Claims i and 9, characterized in that the voltage rotating field separator of the voltages on either side of the open or closed circuit breaker is excited.