DE681453C - Arrangement for the detection of oscillations in electrical energy generators or generator stations coupled to one another several times via lines - Google Patents

Description

Arrangement for the detection of oscillations in the case of multiple lines interconnected electrical energy generators or generator stations Es facilities have been proposed that respond automatically when pendulum-making or voltage drops in a coupling line that connect two power plants connects, occur. These facilities are used in particular in such a Case to interrupt the coupling line. Pendent phenomena and those with a three-phase, igen Short-circuit phenomena are very similar to each other. But while you at. want to switch off a short cut under all circumstances, one looks for this at To limit pendulum phenomena to those cases in which there is no elimination the Pendelurig gives more in other ways. So you wait when there is a pendulum swing if possible from; whether the out of step works and generators again catch.

The invention also relates to an arrangement for detection of pendulums, namely in the case of generators that are coupled to one another several times via lines or producer stations. According to the invention, the existing ones are separated Coupling only when the the same phenomena occur. For example one can disconnect the clutch depends on the matching behavior of the voltage drop relay of the coupling lines do. It is recommended to have fast-acting selective protection devices at every generating station to be provided and also protective devices with delay time. The one with pendulum phenomena appropriate arrangement for interrupting the coupling line is appropriate roughly in the middle of the coupling line and works with a time delay, di, e between the time delays of the two protective devices mentioned above.

The protective devices in the stations should only be used under certain conditions Address error conditions. They become expedient in their responsiveness automatically adapted to the number of generators in operation. To the closer The drawing serves to explain the invention.

In. FIG. I shows a double line system i and 2, for example for supplying a railway system with alternating current of: 25 # Hertz. via transformers q. and switch 1 55 the overhead line g is fed. A 6o-period network ii with the generator stations 9 and io and the frequency converters B. On the second door side of the frequency converters, transformers 7 are provided to feed the 25-periodic system; which switches 2-4 or_25 are in front of them.

If .the two stations L and R get out of step, it is known to fluctuate the voltage roughly halfway between stations L and R between your value Zero and your full value of tension. The frequency of these fluctuations can be very high to be different. Be :: spi@elsweis.-e has a period between i and 5 seconds.

In Fig. I, a station D is assumed in the double line 1, 2, which lies approximately in the middle between the feed points. When a split should be necessary, then the lines z, 2 at station D should be interrupted will. The interruption takes place at points: 2i and 22 in the feed lines i and 2 and at the point 23 in the overhead line 3 of the train.

Fig. 2 shows the protective devices of stations L and D as an explanatory example. All relays are shown in the unexcited state. In the generator station L, the busbar system 5 is connected to the feed lines i and 2 via transformers 7. Through circuit breakers 24 and 25; which are controlled by a fast-acting and a delayed-acting protective device, the energy supply can be interrupted. The instantaneous protective device consists of a differential current relay 26 which is connected to current transformers 27 and 28. This relay 26 closes either a contact 29 or a contact 30, depending on whether the current in the feed line i or that in the feed line: 2 is exceeded. The relay responds in a very short time, for example in 0.07 to 0.7 seconds. The speed of the relay 26 is greater than that of a second protective device operating with a delay. When the differential current relay 26 closes one of its two contacts 29 or 30, the unspecified trigger coil of switch 24 or that of switch 25, which is also unspecified, is excited, whereby feed line i or: d:, e feed line 2 is switched off.

The relay 26 is also dependent on voltage drop relays 32: and 31, of which the first is the voltage of the feed line 2, the second that of the feed line i monitored and the .an capacitor terminals 34 and 33 are connected. These Voltage drop relays have normally open contacts 3: 5, 36, 37 and 38 through which the exciter coils 39 and 40 of the differential current relay 26 short-circuited for so long how the voltage on both lines i and ä is high enough at the same time. The differential current relay 26 can be set very sensitively, even so low residual currents, as they also occur during normal operation of the system . can.

The second protective device operating with delay in station L consists of a pair of delayed overcurrent relays 4i and 4a, which are also fed by converters 27 and 28. The delay device, which is only shown schematically, is denoted by 45. The overflow relays close their contacts 43 and 44 at a certain overcurrent after a delay time that is greater than the largest delay time of the differential current relay 25. When the contacts 43 and 44 are closed, the circuit breakers 24 and z5 are opened. The overcurrent relays 41 and 42 have automatic devices for adjusting their sensitivity. These devices comprise transformers 46 and 47 in economy circuit with several taps and movable contact pieces 49 and 50 which are used to switch over the tapped autotransformers 46 and 47 and which are adjusted by a motor 52 by means of a rod 51. The motor 52 is controlled by a control relay 5.3; controlled.

The device for the automatic adjustment of the sensitivity the overcurrent protection works automatically depending on the connection and disconnection individual generators.

In the illustrated embodiment, there are three frequency converters 8 assume which three generators 54, 55 and 56 have each with a switch 57, 58 and 59-The control relay 53 for controlling the auxiliary motor 52 is a differential relay with two opposing forces caused by the coils 61 and 62 will. The coil 6, i receives constant excitation. The excitation circuit of the Coil 62, however, contains five automatically switched on partial resistors 64 to 68. Each of these partial resistances has half the resistance value of that with the coil 61 _ in series resistor 63. The partial resistors 64 and 65 are connected or switched off when the rod 51, which carries a contact piece 69, moves. the Partial resistors -66, 67 and 68 are switched on or off depending on the position of the circuit breakers 57 to 59 of the generators 54 to 56. The circuit breakers have auxiliary contacts 71 to 73 for this purpose.

When the three generators 54 to 56 are all switched on, the three resistors 66 to 68 are short-circuited by the auxiliary contacts 71 to 73. The two partial resistors 64 and 65, on the other hand, are switched into the circuit of the coil 62 of the relay 53 and have the effect that the coil 62 is excited just as strongly as the coil 61 of this relay. This state is shown in FIG. All turns of the autotransformers 46 and 47 are switched on. In this position of the contact rod 51, the limit contact 74 in the excitation circuit of one field winding of the motor 5-2 is interrupted, so that the motor cannot, for example, continue to rotate counterclockwise.

If now one of the generators, for example generator 56, is switched off, the associated partial resistor 68 is in the excitation circuit of the Coil 62 switched on. The consequence of this is that the force of the coil 61 predominates and that the relay 53 sets the auxiliary motor 52 in clockwise rotation so that the contact rod 51 is moved to the right. After the taps have been switched over for the first time the autotransformers 46 and 47 and the partial resistors 65 and 64 returns the equilibrium of the forces in the relay 53 back so that the motor 52 comes to a standstill. The overcurrent relays 41 and 42 now receive a relatively larger current. If another Generator is switched off, the contact rod 5 i leads a further step to the right and thereby adjusts the setting of the overcurrent relay 41 and 42 as previously described. If the last generator is also switched off, is the current in the coil 62 of the relay 53 by switching on the three partial resistors 66, 67 and 68 weakened even further, so that the relay 53 deflects again to the left, but as a result of the opening of a limit contact 75, the motor 52 can the contact rod Do not pull 51 any further to the right.

The overcurrent relays 41 and 42 can have a starter relay, which has the same setting as the excitation of relay 2,6. In Fig. 2 own. for example, the voltage drop relay 31 and 32 further contacts 76 and 77, through which the excitation coils of the overcurrent relay: s 41 and 42 are short-circuited, as long as the line voltages of lines i and 2 are above a certain limit lie.

At the relay location D there is the facility for call separation of the lines with pendulum phenomena from two arrangements. One contains a pair of voltage relays 81 and 82, which are connected to capacitor terminals 83 and 84, respectively and one of which belongs to line i, the second to line 2. These voltage relays attract or drop their anchor when the line voltage is a certain level Limit value passes. The relays have normally open contacts 85 and normally closed contacts 8: 6. If the number of contacts of the voltage relays is insufficient, you can know how in: the embodiment shown, provide auxiliary relays 9i and 92, the vonden Voltage relays 81 and 82 are controlled. The relays 81 and 82 can then switch can be adjusted more precisely to the desired voltage. The excitation coils of the Auxiliary relays 9i and 92 are short-circuited when the normally closed contacts 86 of the voltage relay 81 and 82 are closed, i.e. i.e., when the line voltage is below that applied to the Relay 81 and 82 set height. But if the voltage relals respond, the rest contacts 86 are opened, and the make contacts 85 are the Excitation circuits of relays 9i, 92 closed. These relays then hold themselves via latching contacts 93. If voltage relays 8i and 82 drop out again, also turn the auxiliary relays 9i and 92 by short-circuiting their field windings de-energized again. The auxiliary relays 91 and 92 have normally closed contacts 94 and 95, the lie in series with one another and are connected to a positive auxiliary line 99 as well as with the excitation winding of a counting relay ioo, which is a counting relay chain controls by which, the periods of the pendulum are counted. The counting relay ioo is only excited if both lines i and lines: 2 below the normal voltage have voltages, and it becomes: de-energized, suddenly also, the voltage only has its normal value on one of the two lines.

If: the counter relay ioo responds to the first voltage breakdown, it closes an excitation circuit via its normally open contact ioi, which leads from the positive auxiliary line 99 to the winding of a resonance relay i o2 with oscillating armature 103 , which carries a weight 104 at one end, causing it after a one-off Impetus stays in vibrations for a while. These natural oscillations last 3 to 5 seconds after the impact. You can set the time within these limits. As long as the oscillating armature oscillates, it alternately closes at the contacts 105 and IO6 circuits which serve to maintain the current from the positive auxiliary line 99 via the time relay 07 and 1 dessenArbentskontakt iog. The timing relay 107 is delayed, which can be achieved, for example, by a copper ring io8. The delay is only noticeable when the armature drops - noticeable because of the extraordinary strength of the excitation field when the magnet is switched on. The normally open contact log of the timing relay 107 is connected in series with the normally closed contact io6 of the resonance relay 102 1n. The timing relay 107 has a normally open contact iio, which is closed when the relay is energized, and an auxiliary line iii, connects to the positive auxiliary line g9: the auxiliary line iii leads to a third auxiliary line 1i2. Lines iii and ii2 are normally connected to one another. Switching on the auxiliary line 112 has the consequence that the first relay 1 1 3 of the counting relay chain is energized and, in the process, its normally open contact 114 closes.

The first time the voltage is reduced on the two lines i and 2, the counter relay ioo has responded. This has excited the resonance relay io.2 with the oscillating armature 103, whereby the contact 1o5 is kept closed and the timing relay io7 is excited. The first time the line voltage returns to its normal value, the resonance relay io2 is de-energized, so that its armature falls back and swings back and forth for a period of 3 to 5 seconds: As a result, the time relay 107 does not drop out during this time because : it receives current surges alternately via contacts 1 05 and i ö6 and its normally open contact io9. Only when the visual oscillation amplitudes of the oscillating armature 10-3 are too small does the timing relay 107 lose its excitation. In order to prevent: the contacts of the timing relay 107 fluttering when the armature of the resonance relay i o2 has just reached the mating contacts 105 and io6, the timing relay 107 (a working contact log. This contact is opened as soon as the falling movement of the Relay armature begins; so that afterwards, if the contacts 105 and io6 are only closed very briefly, an excitation of the timing relay 107 is only possible through the contact closure at: 105, so that the excitation of the timing relay io7 in this position is weakened a noticeable amount in that a closure: of the contact; io6 no longer contributes to the excitation of the timing relay 107. This means that the armature of the timing relay;, 107, once its decay movement has begun, the decay movement also carries out undisturbed .

After: the energization of relay 113 as a result of the first voltage breakdown on the lines i and 2 the counting relay is again de-energized. As soon as it gets the Has lost excitation, it closes a normally closed contact 115, creating a second counting relay 116 responds and holds itself and via its working contact 117 a bridging of the Arbeji.tkontaktes 114 and this normally closed contact 115 produces. That relay 116 remains excited; as long as the auxiliary line dozens of connections with the positive auxiliary line: g 9g owns. The 'counting relay i 16 has a normally closed contact I 18, which is in the excitation circuit of the resonance relay is OK. With: excitation of the relay i 16 leaves the resonance relay io2 drop its anchor, which, as described, swings for a certain time, before he comes to rest. As a result of the opening of the normally closed contact 118 has a closure of the working contact ioi; @d. H. a renewed excitation of the counter relay ioo, initially No effect: This means that the Schwino: around armature 103 of the resonance relay io2 are not disturbed, even if the counting relay ioo again in the meantime appeals to. After the anchor io: 3 has come to rest, the auxiliary lines i i i and 112 switched off by the normally open contacts iio of the timing relay 107.

The counter relay i16 also has a normally open contact 11g; the in Row is with the Anbeitkontakt iäo of the counting relay ioo, so that in the second Voltage decrease of the line i and ä when the counter relay ioo is energized again becomes :, en circuit from auxiliary line 1i2 via contacts i2o and i v9 for another counting relay 12i is closed :. Relay i2i @ closes when responding the mentioned circuit for yourself via one. Normally open contact 122 and closes furthermore a normally open contact 123, which with: a normally closed contact 124 of the counting relay ioo is in series.

If the line voltage is on one or on both lines has reached its nominal value a second time, so that one of the relays 8i and 82 or both respond, the counter relay ioo drops out again and then closes the normally closed contact 124. This completes a circuit emanating from the auxiliary line, which runs via the relay contacts 123 and 124 to a counting relay 125. if .this is energized at the second breakdown of the line voltage, closes it has a holding circuit for itself via its normally open contact 126 and switches: Another interruption point in the excitation circuit of the resonance relay io2. This second interruption consists of an interruption contact 127 from the counting relay 125 is controlled. The counting relay 125 also has a normally open contact 128, the with the normally open contact i29 of the counter relay ioo is in series.

With the third breakdown of the line voltage on both lines i and 2, the counting relay ioo is energized again and creates a circuit here, which leads from the auxiliary line ii over the relay contacts 128 and 129 to the excitation coil of a last counting relay 130, which is delayed by the damper ring 131 Owns anchor waste. This counting relay 13o has a normally open contact 132, when it closes, the line switches 21 and 22 are opened, namely when the third voltage drop. When the counting relay 130 responds, a tripping relay 13.3 is excited via the line 135 by being switched into a circuit that starts from the auxiliary line 99, runs over the winding of a display device 134, which shows the oscillation, and from there is performed via the normally open contact 132 of the counting relay 130. The release relay 133 has two working contacts 136 and 137 in the excitation circuit of the unspecified release coils of switches 21 and 22. The last counting relay 13o of the counting relay chain has a self-holding circuit: is, which is connected from the negative pole via relay 13o, working contact 1318, contact iio, Line 99, contact 167 runs to the positive pole, whereby the relay excitation is independent of the normally open contacts 128 and 129. Furthermore, the counter relay 130 has a normally closed contact 139, through which the auxiliary line 112 is separated from the auxiliary line 111, so that the relays 113, 116 and 121 lose their excitement. The drop in relay 116 has the consequence that the normally closed contact 11 $ of this relay is closed again, but this has no effect on the excitation of the resonance relay Io2 'because (the excitation circuit of this relay is interrupted by the normally closed contact 127 of relay 125 .

The processes described so far can be summarized as follows: When the line voltage first returns after the first voltage reduction, the oscillations of the anchor of the resonance relay 102 start, which last 3 to 5 * seconds depending on the relay setting. Starting with the first voltage decrease, the relays 113, 116, I24, 125 and 130 come into operation one after the other, and that progressively, as often as the normal line voltage returns and disappears again. When the voltage finally drops for the third time, the rushed relay - the counting relay, .dIas counting relay 13o "comes into action and causes the tripping relay 133 to open the line switches 21 and 22. It is always assumed that all these voltage changes follow one another , before the oscillating armature of relay 1o2 has come to rest, otherwise the timing relay 1o7 drops out, opens its normally open contact iio and thus switches the entire device back to the rest position immediately and differentiate between the return of normal tension and the repetitive tension reductions and increases that are a result of the throughput of the stations.

The overhead line also has a line switch at relay location D. 23. It is necessary to open this switch 23 when the switches 21 and 22 are triggered. This can be achieved through the auxiliary contacts 141 and, 142 the switches 21 and 22 by using these auxiliary contacts connected in series the excitation circuit for the unspecified trigger coil of the Sehalters 23 is performed.

The second in addition to the short-term selective protection arrangement Long-term protective device for lines i and 2 contains an overcurrent relay 143, which is excited by the total current of lines i and 2. This overcurrent relay 143 is from the current transformers 144 and 145 in the lines i and 2 in the relay location D excites and has an excitation device. In the embodiment according to FIG This device also includes two relays 146 and 147, the secondary circuit of the Current transformers 144 and 145 normally short through contacts 148, 149. From One of these contacts opens when the voltage is applied to one of the two lines collapses.

The excitation coil of the relay 146 is fed via a normally open contact 151 of the auxiliary relay 91, which monitors the voltage of the line i. The excitation coil of the relay 147 is in a circuit which is routed via a normally open contact 1 52 of the auxiliary relay 92, which monitors the voltage of the line 2. As long as the line voltages are within permissible limits, relays 146 and 147 are energized. At. 2, relay 143 is short-circuited if only one of the two relays 146 or 147 is energized.

The overcurrent relay 143 has a normally open contact 153 which, when it closes, switches on the trip relay 133 for the switches 21 and 22. The overcurrent relay 143 attracts its armature with a slight delay, which is sufficient to initially .the short-term protection, ie the differential current relay 26 to come into effect. Only if this relay does not switch off the error, the overcurrent relay 143 can switch off the lines i and 2 together. On the other hand, it is desirable that the overcurrent relay ais 143 works faster than the protective devices 41 and 4a, which represent the reserve time protection, so that one of the stations L and R is only switched off by both lines i and 2 in an emergency. The time which the overcurrent relay 143 1 needs to close its normally open contact is increased by the time of the switches 21 and 22 until they have completed the switch-off, for example 1.5 seconds, while the time setting of the relay devices 41 and 42 is up to 2.3 seconds.

Two push buttons 164 are also shown in FIG. 2; when actuated, either a relay 1 63 or a relay 165 is energized. When relay 163 closes its unspecified contact, the excitation circuit of an overcurrent relay is short-circuited. When the relay 165 is excited, the excitation circuit of the overcurrent relay 143 is short-circuited via its normally open contact 166. When they respond, these two overflow relays 16o and 143 establish a connection between the line r35 and the positive pole of the local power source, so that the tripping relay: s 133 responds and switches 2i and 22 open. The overcurrent relays 143 and 16o have time delay devices 154 and 162, respectively, of different time settings, so that you can selectively set a lower or higher time delay by pressing one or the other push button 164. If the relay 165 is energized by pressing the push button 164 quickly, a contact 167 is thereby also opened at the same time, via which the line 99 of the counting relay arrangement is connected to the positive pole of the local power source. This counting device is thus made ineffective at the same time when the relay 165 is made to respond by the pushbutton 164. The winding of a drop flap relay 175 is connected to the line 135. The winding of a second drop flap relay 134 is connected to the line 99. If the lines 135 and 99 are connected to the positive pole of the local power source: e; z. B., the line 99 via the contact 167 and the line 135 via the normally open contact 153 of the overcurrent relay 143 or via the normally open contact 161 of the overcurrent relay 16o; so one or the other drop flap relay is energized.

To achieve; that a separation takes place in the station D, when, for example due to excessive overload, the trolley wire voltage drops to a value at which a proper operation of the traction motors is no longer possible, a voltage drop relay 170 is provided which is connected via a voltage converter 171 of the trolley wire voltage in Station D is energized. When the voltage drop relay drops out, a timing relay 173 is energized via its contact 172, which is then closed. After a certain time this closes its contact 174 and thus energizes the drop flap relay 175 and the Auslös.erelais 133. This relay opens the switches 21 and a2 and thus also the switch zd. The timing relay can be designed in any known manner. In the exemplary embodiment, it has a short-circuit ring 176 and a delay device 1 77.

In .den Fig: 3 and 4 other circuits are indicated with their Help the jumble of stations L and R can be detected.

In the circuit according to FIG. 3, the switch 21 of the line i in of station D when a normally open contact i8o of an overcurrent relay 181 closes triggered. The overcurrent relay is fed by a current transformer 182 and has a pick-up delay 183. A voltage drop relay is used as the starting device i $ 4 provided, which is in the secondary circuit of a voltage converter 185 and normal Line voltage holds a normally closed contact 186 open. When the voltage drops the contact 186 is immediately closed and .due a relay 187 switched on; which delays a short circuit of the excitation coil of the overcurrent relay 181 eliminated. When the mains voltage returns, however, contact 188 of the relay is activated 187 not immediately again due to the delay device 189 and thus also that Relay 181 not short-circuited again immediately: When relay 187 is de-energized rather, contact 188 does not close until after a long time has elapsed. It the relay 184 should now match the rms value of the line voltage as quickly as possible follow, but not the fluctuations in the Mömentan value of the voltage.

In the circuit according to FIG. 4, the arrangement for monitoring the The voltage drop is replaced by a tube igo that controls an auxiliary relay igi: When the voltage returns, on the other hand, a second tube is used to respond, which controls an auxiliary relay 193. This second auxiliary relay can have a certain time delay own. The tubes igo and 192 are grid-controlled discharge tubes with a narrow anode 195 and a cold, large-area cathode 196. These tubes respond as soon as the grating 197 is sufficient, even temporarily receives high positive voltage with respect to the cathode.

The discharge tubes are controlled by the line voltage with the interposition of a voltage converter Zoo, a full-wave rectifier toi with a choke coil 2o2 and an ohmic resistor 2o3. The choke coil 202 is intended to keep out the harmonics caused by the rectification and can also be replaced or supported by other means for this purpose, for example by using capacitors 204. At a tap point 205 of the resistor 203 is the positive pole of the local battery for the Relay excitations connected. The anodes 195 of the two tubes are also connected to this pole of the direct current battery. Further connections 2o6 and 207 on the resistor 2o3 are located on both sides of the tap 205 and are connected to the grids of the two discharge tubes. Resistors 2o8 and 209 are provided to limit the grid current.

The igo tube for detecting the voltage breakdown has an anode 195, which is connected to the positive pole of the local battery via a break contact 2ii of the auxiliary relay 193 is connected, which is in action when the voltage is restored should kick. The cathode 196 of the tube i 9o is connected to the negative terminal of the local battery connected with the interposition of the excitation coil of the auxiliary relay igi, which to take action when the tension is reduced. In this circuit lies also auxiliary contact 213 of line switch 21. The auxiliary contact is opened, when the switch falls. The second tube i92, which respond when the voltage returns should, has an 'anode 195, which is connected to the positive pole of the local battery below Interconnection of the coil of the auxiliary relay 193 is connected, which on return the mains voltage should come into operation. Your cathode 196 is with a sliding contact connected to the negative pole of the resistor 2r5, the positive pole of which with the positive pole of the local battery is connected. The negative pole of resistance 215 is also connected to the negative pole of the local battery via auxiliary contact 213. Between the sliding contact on the resistor 215 and the cathode 196 of the tube i 92 there is a normally open contact 217 of the relay that responds when the voltage is sent i9.1. The diagrams in 5 and 6. The relays iSi and 193 each have an armature attraction slowing down Delay device 183 or 194.

The rectified voltage is shown in FIG. 5 by curve 22o: This voltage would appear across resistor 203 if there were no inductances in series with this resistor. The mean value of this rectified voltage corresponds to the line 221 in the diagram. This value would appear at the resistor 203 if the inductance of the choke coil 202 were infinitely large or if the elimination of the harmonics resulted in a complete smoothing. In reality, however, a voltage occurs at resistor 203 which lies between these two limit states given by curves 22o and 221 and which is shown, for example, by dashed curve 222.

Fig. 5 shows a period in which the line voltage strives for a minimum value. At a certain lower voltage limit, which May be represented by the line 223, the discharge vessel i 9o should respond. This occurs at the moment in which the dashed curve 222 the lens 223. cuts. If the voltage increases, as soon as the line voltage has reached a certain A slightly higher selected value corresponding to line 224 reaches the discharge vessel 192 ignite. This occurs at the moment in which the dashed curve 222 intersects line 224 for the first time.

Fig.6 explains the voltages in the Ahoden and grid circle of Discharge vessels occur. The potential differences relate to the potential the cathodes of the tubes. In the illustration in Fig. 6 it is assumed that .the The potential of the anodes of both discharge vessels can change while the cathodes always have the same potential. In the circuit of FIG. 4 have the reverse the cathodes of both tubes have almost the same potential. .

In the discharge vessel igo (Fig. 4) the grid has that in Fig. 6 potential with respect to the cathode indicated by the line 226. The potential is lower than that of the anode, which is represented by line 225. If the Line voltage decreases, the potential of the grid increases and approaches that Potential of the anode. At a certain limit value of the grid potential, which by line 229 is shown, the tube igo (Fig. 4) is ignited and thereby the auxiliary relay is energized. This eliminates the short circuit by means of the normally closed contact 218 of relay 181 ud, d simultaneously applies voltage to the by means of contact 217 Cathode of tube 192, which comes into action as the line voltage increases. When the current on line i for actuation ides through current transformer 182 fed relay 181 is sufficient, it responds and switches after its delay time Via the normally open contact i8o, the release coil for the line switch, which is not specified in detail 21 a.

When the line voltage returns to the normal value again, the grid potential of the discharge vessel 192, which is represented in FIG. 6 by the line 228, increases as the voltage drop across the resistor 203 (FIG. 4) increases to the anode potential, which is shown in FIG represented by line 227 is added. As soon as a critical limit value, represented by the line 23o in FIG. 6, is reached, the discharge vessel 192 (FIG. Q.) Responds, whereby the relay 193 is energized. This opens its normally closed contact2ii after a certain delay time. As soon as it is open, the anode circuit of the discharge vessel igo is interrupted, so that the relay igi returns to the rest position. This in turn has the consequence that the anode circuit of the second discharge vessel 192 is also interrupted by opening the contact 2i7, whereby the relay 193 is also de-energized. At the same time, the overcurrent relay i8 i is short-circuited again:

Claims (2)

PA TRNTANSPRÜCFiR: i. Arrangement for the detection of oscillations at Electrical energy generators coupled to one another several times via lines are dull Generating stations; characterized in that a call separation of the existing Coupling only takes place if all coupling lines are in operation the same phenomena occur. 2. Arrangement according to claim i, characterized. that the disconnection of the coupling from the corresponding behavior of voltage drop or overcurrent relays of the coupling lines. 3: arrangement according to claim i or a, characterized in that the fluctuations in the current strength or the voltage level must be done periodically at a predetermined frequency. q .. arrangement according to claim i or following, characterized in that the device for Detection of the oscillation through the decrease in voltage and through the return contains ignited discharge vessels at normal voltage.