DE702079C - Selective protection device for direct current networks - Google Patents

Description

Selective protection device for direct current networks The invention relates on selective protection devices for direct current networks. With AC networks such protective devices are already known and largely developed. These protective devices are used in networks when a Short circuit or a similar load case, only those parts of the Switch off the network, which are immediately adjacent to the short-circuit location and that to leave the rest of the network unchanged in operation. It is known as The main criterion for the response of the selective protection devices is the impedance value the short-circuit path used, with the direction of energy an additional exerts selective influence on the response of the selective protection device.

Direct current networks now differ from alternating current networks in With regard to their protection in essential points. In the case of direct current networks, the Resistances of the power lines in stationary operation in contrast to AC networks purely ohmic character. There are no reactances. Even with sudden ones Changes in current are offset by the inductive effects of the individual power supplies their ohmic resistance value almost completely, if not large for this purpose and expensive DC chokes are provided.

Occurring short circuits in direct current networks grow extraordinarily suddenly and reach proportionally much higher values than with AC networks. For the shutdown of direct current short-circuits, if damage to the Network or parts of the system are to be avoided, is a different order of magnitude the disconnection time in question than with AC networks. Since also with direct current it is not possible to distinguish between continuous and impulse short-circuit currents, so are then special measures and short switch-off times are required if the short circuit occurs intercepted and interrupted or at a tolerable level while it was being created Measure should be reduced. One must therefore work with switch-off times, which are best smaller than o, oi s and if possible not exceed the value of 0, i s.

The invention relates not only to selective protection devices for those networks in which each network section z. B. from a separate converter plant is fed, but especially for extensive meshed direct current networks with several dining outlets working in parallel, e.g. B. Power converter plant or DC power plant, primarily also to DC high-voltage networks. This should the control pulses and the control devices exclusively from values of the direct current network are derived and act on them, d. H. So, with the presence of Stroinrichterwerke the current and voltage values on the alternating current side should be used to operate the Selective protection not used «-erden, as z. B. with some known Selective protection devices of rectifier systems happen.

So the present invention is, not just, that a selectivity practically only between the connection of two feeding points of the Establish direct current network, which is not directly related to the rest of the direct current network are meshed, as is known from the known so-called selective protection devices is e.g. B. with reverse current high-speed switches, which immediately when reverse current occurs and with forward current only respond in about four times as long, but the selective protection of network connections which are connected to other network connections can be linked directly and which can be selectively separated and switched off can be.

All of the above requirements are met by the subject matter of the present invention using inertia-free tube relays, the response of which depends on the size or in particular depends on, namely in that the anode current of four pulse tubes controlled in this way influences the grid voltages of several control tubes according to its size, so that one or more control tubes respond, whereby a time staggering for further control commands takes place.

The ratio at the monitoring point is the starting criterion for the selective protection device according to the invention or the reciprocal value chosen, with each network point having a certain value assigned «- is, if exceeded, the protective device responds, or a certain value - , below which the protective device responds. The value which increases along a line like a lyrian, allows a sharper separation of the various response limits, depending on the distance of the network line protecting the network from the nearest feed point.

The known high-speed switches come into consideration as the main switching elements or, if there are no such options for high performance and tension, the detour the disconnection of the power supply units to be protected by short-circuiting them inertia-free power valves, whereby the tripping of the circuit breaker, z. B. a compressed air switch, the response of this short-circuiting valve follows.

Of course, where the network conditions allow, also to switch off the short circuit, the grid control device from the converter or the control of the ignition of arc valves according to Marx can be used.

Furthermore, according to the invention, the issuing of commands for the response the selective protection device at the same time from the absolute value of current and Voltage and / or made dependent on their temporal change over time will. If it is particularly long distances in direct current high-voltage networks, in this way use can also be made to advantage of telemetry transmission devices of the known type be made.

The object of the invention is illustrated in the drawing, for example. Fig. I shows an example of the voltage and current ratios of a double-fed line. In contrast to alternating current networks, in direct current networks the voltage and power ratios are rigidly linked with one another, so that voltage regulation is not possible independently of the power regulation. As a result, however, there is a clear connection between the power flow, the current and the voltage and thus also with the ratio Fig. I shows one fed at a and b respectively. along the line sections. Line with the main consumer points i, 2 and 3. Ji, J2 and J3 are the respective load currents. At c there is a short circuit with the current JK. Diagram B shows the current curve in the line during normal operation and in the faulty state. In the undisturbed state, yes, the current in line section a1, J, 2 is that in section 12, etc .; your short-circuit case may correspond to the currents Jkai, Jkt2, and so on. The short-circuit current itself is the sum of Jh2o and Jh, o.

Diagram C illustrates the voltage relationships and the course of 1. At the feed points a and b, the same output voltage U, may prevail. The voltage curve during normal operation is shown by the line U ″, in the event of a short circuit, the line UK. The curve of U ″ or UK is also a measure of the ratio The course of - in undisturbed operation "shows the line The line is always measured when there is a malfunction Voltage points to the right and left of the route section to be protected, i.e. in the incoming and outgoing line. Of course, the consumer can be switched off selectively if it represents a short-circuit load.

An embodiment of the selective protection device according to the invention is shown in Fig.2. At io a measuring voltage proportional to the mains voltage U is supplied, at 2o a measuring voltage proportional to the mains current T. Each of these measuring voltages flows through a resistor ioo or zoo. With the adjustable taps ii and 12, a control voltage is tapped from the two measuring voltages, which is used for the formation of quotients or z. B. switched against each other will. This measurement voltage resulting in this way causes a voltage drop across resistors 13 and 23. The grid 3o of a high vacuum tube 4 is connected to the resistor combination 13 and 23 on one side via the grid resistor 32, and on the other side a fixed reference voltage supplied by a battery 1. This battery is connected in such a way that the negative pole faces the grid via resistors 23, 13 and 32 and the positive pole is connected to the cathode of the pulse tube .4. The voltage of the battery can of course be adjusted and regulated as required. Likewise, this voltage can also be regulated continuously or in stages by any operating variable during operation.

At a certain arbitrarily determinable ratio of the grid 30 of the tube 4 becomes positive, and the pulse tube 4 thus lets current through. By appropriate selection of the tube characteristics, it is then possible to give the anode current of the pulse tube 4 flowing through the tube load resistor 41 a certain ratio to the measured value. With the resistor 41 through this anode current of the tube 4 coming about voltage drop can now be controlled any number of control tubes, z. B. the tubes 5, 6, 7 etc. The grids of these tubes are connected via grid series resistors 45, 46, 47 etc. via an arbitrarily adjustable tap 42 to the resistor 41, while the associated cathodes are connected to different bias voltages via the bias battery 4o be e.g. B. through the connections 405, 406, -407, etc. The positive side of this bias is always connected to the respective associated cathode of the interrupters 5, 6 and 7.

The work of the tube arrangement is briefly explained in Fig. 3. Depending on the control voltage u41 at the resistor 41, a course of the value is given by the measuring arrangement and the tube characteristics of the pulse tube 4 assigned. Let x "be the value of reached at which the tube 4 just responds; 141 still has the value zero. With increasing then u41 becomes larger. If you now select the grid biases on the control tubes so that the control tube 5 only then responds; when the control voltage 1c41 has reached the value 5 ', the tube 6 only when u41 has the value 6', etc., one achieves that the size of the respective ratio of a very specific number of responses the control tubes 5, 6, 7, etc. corresponds.

If you now use the response of the control tubes 5, 6, 7, etc. to cause the shutdown of the associated line sections at certain time intervals, the desired selective protection effect is achieved. "If the response criterion is the value are used, according to the explanations for Fig. i, large values of assign the shortest possible switch-off times. The response of the control tubes 5, 6 and 7 is carried out in the correct order, namely so that the tubes with the longer switch-off times respond first, then those with the smaller ones.

Various devices can be used with the anode currents of the control tubes being controlled. 55 is the anode battery for the control tube 5, 51 is a load resistor, at which a further actuating voltage via freely adjustable taps 5a can be tapped, and 53 z. B. a switching coil for breaking a circuit 54.

Of course, the anode current of the control tube can also be used 4 immediately to activate the correct timed shutdown the main switching devices are used.

The example of an electrical timing control is shown in Fig. Q. indicated. As already mentioned, the use of mechanical time relays is no longer an option for the short switching times available. You can then z. B. use arrangements in which the slope of the current rise when the circuit is switched on is determined by appropriately sized inductors. In Fig.d. 8 denotes a choke with taps t; 5 to t8 of the choke winding. 14 is the current source of the inductor circuit, 15 is the load resistor. 17 is the connection point of the throttle circuit on the various control tubes 5, 6, 7 of the device according to Fig.2. If the throttle circuit is closed via the tap t;, the current rise in the resistor 15 takes place relatively slowly. If one assigns the control tube to the device according to Fig. 2, then one achieves that a small value of -a large shutdown time is assigned. If the choke circuit z. B. closed via the tap t7, the current rise in resistor 1 takes place relatively quickly, ie the large value of is assigned a short switch-off time, if in this case the choke circuit is switched on via the control tube 7 of the device according to Fig.2.

The time regulation by the throttle can, as already mentioned, also take place continuously by corresponding `` '' ormagnetization of the throttle proportional to the anode current of the control tube q. the device according to Fig. 2. The connection of the throttle circuit can depend on the absolute value of I, U, or In general, the premagnetization of the choke can be used to shift the time characteristic of the choke circuit. 9 shows such a bias coil. In the exemplary embodiment shown, it is fed by the battery 22 via the variable resistor 26 and your arbitrarily adjustable tap 25 via: the switch 2.I. As with all such control stations, the setting of 25 can either be done manually before commissioning or during operation, independently, depending on any network variables, switching states of the network, or by remote control. The voltage available at resistor 15 in the inductor circuit of the device according to Fig. For this purpose z. B. placed one pole of the resistor 15 via the grid pre-resistor 16 to the grid 27 of the tube 28, while the other pole is connected via the grid bias battery 29 to the cathode of the tube. The anode current of the tube 28 can then be tapped at the terminals 35. Depending on the different steepnesses of the rise in current in the choke circuit, the voltage at resistor 15 exceeds the negative bias voltage of battery 29 at different times, and ignition then takes place accordingly. The tube 28 can again be a high vacuum tube; but it can also be a hot cathode tube with which larger currents can be handled. When using direct current for these actuating circuits, one only has to ensure that the circuit of the hot cathode tube is interrupted once, even if only briefly, after the switching elements have responded.

The actual switching off of the power supplies to be protected can be done by a quick switch take place, as shown briefly on the basis of a switch according to Fig is explained. It means 6o the holding magnet with the impact armature 61 and the cross yoke 62. 63 is the main power disconnecting solenoid. 64 is the main current path which runs through the holding magnet 6o forms an open loop. 65 is the switch-off contact, which is actuated by the drop anchor. 66 is the main current coil of the opening solenoid 63. For example, the holding magnet 6o is premagnetized by the coil 67 in such a way that that with the forward current of the armature by the magnet 63 or not at all is only torn loose from the magnet 6o with very large currents, while on the other hand in the event of a reverse current, an immediate switch-off can take place, as far as this it is asked for.

If the coil 67 is suddenly short-circuited, it can be achieved that the switch will operate without additional delay for medium and smaller currents, so comes to switch off immediately.

The coil 67 is fed, for. B. from the battery 68 via the Circuit breaker 69 and a series resistor 70. The short-circuiting of the coil takes place via the tube 28, which corresponds to the tube 28 of the device according to FIG. The series resistor 15 corresponds to the resistance 15 of the device according to Fig. 4. At 59 the arbitrarily adjustable connection of the control voltage takes place for the grid 27 of the tube 28 with the grid bias battery 29. At 7o takes place z. B. ' the connection of the choke circuit according to Fig.4.

Instead of interrupting the premagnetization of the holding magnet 6o can of course also occur suddenly and additionally magnetization of the Activate the switch-off magnet 63.

Since the tube 28 is advantageously a hot-cathode tube, in which the starter of the arc can be regulated through the grid, but not its interruption, the tube circuit must be automatically interrupted after the switch operation in order to be ready again through the grid after the Quick switch has been switched on again. This can e.g. B. done by the contact 69 connected to the anchor 61.

The entire protective device consists of a relay chain, consisting of the monitoring and control relay according to Fig. 2, the timing circuit according to Fig.4, the quick switch actuation circuit and the actual quick switch. The shortest possible switching time is determined by the switching time of the high-speed switch fixed, while the response times of the tube relays are only fractions of a millisecond turn off. The whole facility can be combined like a radio and be built up.

For high-voltage and high-performance direct current networks, for which no suitable high-speed switch is currently known, the following method can be used for selective disconnection, as shown schematically in Fig. 9. This figure shows part of a - DC transmission line. 70, 71 and 72 are the main tapping points, while 73 to 78 represent selective protection devices. S011 the line section 70-7r can now be protected from a short circuit at point 71 or in section 7r-72 or in section j0-71 itself, then line section 70-71-7z at point 70 via a virtually inertia-free power valve short-circuit which z. B. from the selective relay 75 via the remote transmission device 79, the remote transmission channel, z. B. telephone line or line-directed high-frequency connection, acts on the grid control device 8o of the valve 8i inertia, unless the timing circuit according to Fig.4 prescribes a certain switching time. The valve 81 short-circuits the line 70-7r to earth via an adjustable control resistor 82. At this ground resistor 82 can, for. B. a suitable operating voltage can be tapped, which brings the circuit breaker 83 via the opening coil 84 to switch off when the valve 81 responds. The resistor 82 can now be dimensioned in such a way that it completely eliminates the short-circuit current in the power supply unit to be protected or reduces it to an amount that can be endured without damaging effect until the circuit breaker 83 has switched off. On the other hand, the resistor 82 must be dimensioned so that the short-circuit current through the valve 81 does not cause the selective protection of the preceding power supply unit to respond, e.g. B. the response of the selective relay 73.

Any known power converter arrangement can be selected as the power valve will. In Fig. 9 z. B. thought of the use of an arc chamber according to Marx been. In the valve 81 86 the two main anodes are then represented, 85 the ignition anode, whose response is actuated by the control device 8o.

Fig. Io shows possibilities of the effect of the selective protection device on the grid control of power converter arrangements. The power converter is denoted by 9o, its anodes by 9i, the grids by 92 and the cathode by 93. 94 is the grid control battery, although any other suitable direct current source can of course also be used in place of the batteries mentioned, 95 are the load resistances of the grid pre-voltages; 96 the grid resistors. The other accessories are omitted from the drawing for the sake of simplicity. 97 is the grid transformer with the primary winding 98, the secondary winding 99 and a premagnetization and / or saturation winding z05: The control voltage supplied to this winding can be supplied by a rotary transformer z06 which is regulated in some way. Can be used for selective shutdown. now z. For example, winding 105 could suddenly be connected to battery i08 through tube r07, with the grid control of tube 107 being applied to terminals i09. The tube 107 can, for. B. represent the location of the tube 28 of Fig. 4 or 5.

It can also take the place of a complete shutdown of the converter still step a voltage reduction, z. B. by Dlötzliche appropriate phase shift jer grid control voltage in the sense of a voltage reduction. One such possibility is z. B. indicated by the device iio. The grid control voltage flows through a phase shifter circuit, which, for example, consists of the parallel connection of an Ohinschen Resistance i i i with an inductance 112 exists. This can be used for the purpose of sudden phase shift of the grid control suddenly short-circuited «-ground or the short circuit of the same can suddenly be interrupted, which is shown in Fig the switch 113 is indicated, which for the sake of simplicity as a mechanical switch is shown, its actuation by the coil i i-. he follows; on which the selective protection device works.

Of course, the specified solvents can be changed as desired and be expanded. Pliotocell relays can be used to generate impulses, at which z. B. the differences in brightness of light threads measured and for impulses which correspond to the value of L. ' and J are proportional. As a time relay Here, heat relays, such as light wires of various strengths, etc., can occur.

The activation of the selective protection can also be made dependent on the respective size of J and LT as well as on their change over time and or In Fig. C z. B. shows how the absolute value of J and L 'can be used for switching purposes. At i 1 5, the measured variable proportional to L 'or J is supplied. This 1leßstrom flows through the resistor 11E, at which z. B. an arbitrarily adjustable control voltage i 17 can be tapped, while at the same time a switching tube i i9 can be controlled via the arbitrarily adjustable contacts 118 in a known and repeatedly described manner. 120 is the switching coil of the anode circuit breaker if the tube ii9 is a hot cathode tube, while 121 represents a direct connection if the tube iig is a vacuum tube which is continuously adjustable through the grid. At 122 the connection of the apparatus to be operated, such as, for. B. the quick switch actuation, if this should trigger immediately at a certain current value, regardless of the selective effect. The switch i i-1 in the arrangement according to FIG. Io can also be made to respond at 122.

Fig.7 shows one way of using the value or appropriate control variable can be obtained. At 123 it becomes the value or corresponding INIeß size via the resistor 12q. the transformer 125 -supplied. On the secondary side, a voltage is taken from the freely selectable taps 126. This can now be compared via the resistor 127 to a constant, arbitrarily adjustable comparison voltage, which z. B. is supplied by the battery 128. As soon as the supplied value exceeds a certain level, so that the negative grid voltage of the battery 128 becomes smaller than the voltage at the resistor 127, the grid of the tube iig receives a positive voltage via the resistor 129, and the tube i 19 ignites. The anode current of the tube can be picked up via the circuit breaker 13o at the terminals 131, and a measured variable of the desired type is thus obtained. B. depending on the value - or with your response to the selective protection in the individual network sections, a short-term reduction in the supply voltage at the feed points can be connected by reducing the voltage accordingly with the help of the grid control by z. B. the device iio of Fig. Io is fed from the terminals 131 of the arrangement according to Fig. 7 with the appropriate interposition of a suitable power source. The procedure can be such that only the voltage of the feed point which is initially located at the disturbed network point is reduced.

Finally, the simultaneous interaction of several measured variables can be used to regulate the selective protection device, as indicated in Figure 8. At the terminals 132 z. B. an the i value corresponding value can be used. The terminals 133 and 134 may -den terminals io and 2o the establishment - in fig 2 correspond.. The combination voltage, which z. B. a value is equivalent to. : With the tube 138 it is also indicated that via the terminals 139 of some other reference variable, e.g. B. on the mode of operation, whether a feeder draws power as a result of regenerative braking of DC traction vehicles, the effect of the selective device can be made dependent. The resulting measurement voltage is compared with the reference voltage iq.i via the resistor iqo by means of a controllable tap and the difference voltage between these two voltages is used to control the grid of the tube 142 via the series resistor: d 143, as already described several times. At 144, the actual switching pulse can then be picked up.

Claims (15)

PATENT APPLICATION: -i. Selective protection device for direct current networks using inertia-free tube relays, the response of which depends on the size or in particular depends, characterized in that the anode current of the impulse tube controlled in this way influences the grid voltages of several control tubes according to its size, so that one or more control tubes respond, whereby a time staggering for further control commands takes place. 2. Arrangement according to claim i, characterized in that that the measuring voltage exciting the tube by hand or automatically during operation is changed depending on the changing operating voltage. 3. Arrangement according to Claim i, characterized in that the grid control voltage of the control tubes is adjustable. q .. Arrangement according to Claims i to 3, characterized in that the anode circuits of the control tubes each act on the grid of a trigger tube via a winding of a choke coil, so that large values of or small values of small switching times are assigned. 5. Arrangement according to claim. q., characterized by that the choke coil is premagnetized. 6. Arrangement according to claim q., Characterized characterized in that the anode current of the control tube of the selective relay is additionally also serves to premagnetize the time circuit choke. 7. Arrangement according to claim i to io, characterized in that the response of the trigger tube is the immediate Switching off a quick switch causes. B. Arrangement according to claims i to io, characterized in that the response of the trigger tube the instantaneous ignition causes a discharge path to short-circuit the power supply unit to be protected. 9. Arrangement according to claim i to 8, characterized in that the response of the Trigger tube instantly to the grid voltage or ignition device of converter assemblies acts. ok Arrangement according to Claim 9, characterized in that the response the trigger tube, the instantaneous reduction of the DC voltage of power converter arrangements caused by appropriate modulation of the control grid. ii. Arrangement according to claim io, characterized in that the short-circuiting discharge path has a adjustable resistance, adaptable to the respective network conditions, connected to earth is. 12. The arrangement according to claim 8 and i i, characterized in that the response the discharge path automatically switches off the associated circuit breaker causes. 13. Arrangement according to claim 7, characterized in that the switching off .of the high-speed switch via the trigger tube by short-circuiting the Holding coil and / or the polarizing coil of the holding magnet is effected. 1q .. Arrangement according to Claims 1 to 13, characterized in that, in connection with the activation of the selective protection, the power converter arrangement which is initially located on the disturbed network path is dependent on the value or by - inertia-free grid modulation is regulated in such a way that the direct current voltage output is briefly reduced. 15. Arrangement according to claim i to 1q., Characterized characterized in that the response of the pulse relay is also made dependent depends on the absolute magnitude of the current and / or or the voltage and / or or the change in the current or voltage rise over time.