DE740198C - Arrangement for the compensation of the corona discharges at the earth fault point of high voltage AC power lines - Google Patents

Description

Arrangement for compensation -des at the earth connection point of AC power lines High voltage occurring active current from corona discharges is known you can the on AC power lines with your earth fault of a phase on the To extinguish the capacitive earth leakage current that occurs in the long-distance line, that earth connection extinguishing devices are provided, either as in the star point of the pipeline @ switched-on Erdsclhlußdrosselspule_ are formed or also as a so-called quenching transformer.

It is known that these earth fault extinguishing devices are not sufficient if the pipeline is operated with high voltage (e.g. zzo kV). In this Trap get namely in case of an earth fault of one phase of the earth line the two other phases' with star connection of the feeding transformer a ratio r: 3 higher voltage, and these two other phases develop a very considerable one Radiation current (corona discharge) against the earth. This radiant current that a Active current, but must flow back into the line via the earth fault. Since this active current flowing through the earth fault is caused by the compensation devices described, which only respond to capacitive current, cannot be erased, so comes the arc does not extinguish at the earth connection point. There are already a few Means suggested -% north to this earth leakage active current, from the earth leakage point bring away and thereby eliminate the arc. According to a well-known proposal the earth fault point is bridged by a switch. If in addition the reactive current is already inductively quenched at the earth connection point, then flows through this switch only the residual current. These However, the arrangement still has the disadvantage that the earth fault is not completely de-energized; because still a part of the active residual current flows through the earth connection point according to the resistance ratios at the parallel connection of the earth fault point: e and bypass switch. aside from that in the event of a double earth fault, the bypass switches are switched from. Short-circuit currents flowed through and therefore increase the short-circuit currents. These switches must therefore Be circuit breakers, which increases their cost very significantly.

The invention also relates to a device for compensation the active current occurring at the earth connection point of AC transmission lines, which compared to the known facilities by greater simplicity and reliable Effect. According to the invention is between the afflicted with a ground fault Line -and the earth in series with one, ohmic or a reactance the secondary winding of a compensation transformer switched, its primary winding is fed from the long-distance line with a voltage of such a phase position that that of the secondary voltage of the compensation transformer via the earth connection point generated current cancels the earth fault active current.

The invention is explained in more detail below with reference to several exemplary embodiments of the drawing. First, Fig. I shows a three-phase long-distance line with phases i, 2 and 3, which is used to extinguish an earth-fault reactive current at its star point via an earth-fault choke coil q. is grounded. 5 illustrates a phase 3 trunk line ground fault. Two types of currents are then formed via phases i and 2 of the long-distance line to earth, firstly the capacitance currents Je,. and Jc. ,, illustrated by capacitors 6 and 7. In addition, as a result of their voltage, which has risen sharply with respect to earth, the phase lines i and 2 now develop active radiation currents Jw and Jtv., Which are illustrated by the ohmic resistances S and 9. While the capacitive currents Je, and Jc2 with the help of the quenching coil q. are brought away from the earth fault point 5, this is not the case with regard to the earth fault active currents. According to the diagram in Fig. 2, the active earth fault currents Jw and Jw are set. at the earth connection point 5 to form a resulting Wirl: Strom Jw together.

Fig.3 of the drawing now shows an arrangement according to the invention, the brings the active current at the earth connection point 5 to extinction. Between the star point of the transformer feeding the transmission line and the earth is the primary winding a compensation transformer is connected, the secondary winding of which is connected in series with an ohmic resistance i i with the help of switch 12 on the one hand to earth, on the other hand, it is connected to phase 3 of the long-distance line, which has an earth fault is. In the # arrangement of Fig. 3, the voltage on the secondary winding of the Compensation transformer i o the same phase position as that in the event of a ground fault Voltage of that phase of the line transformer (phase 3 of FIG. 3) which is currently Has earth fault. The active current flowing through the earth fault is due to the corona current on phases i and 2 of the pipeline. Furthermore, the one that feeds the line Secondary winding of the line transformer connected in star. As a result, take in the event of a phase 3 earth fault, phases * i and 2 of the long-distance line with respect to earth Voltages illustrated by the dashed-line voltage diagram of FIG. 2 are. Phase i of the long-distance line has a size and in relation to the earth the phase position is a voltage that is determined by the vector sum of the dashed Voltage vectors 3 and i of Figure i is illustrated. Likewise, the phase takes 2 a voltage with respect to earth, which is determined by the vector sum of the dashed Voltage vectors 3 and 2 is given. But they also have the same phase position corona currents emanating from phases i and 2 of the long-distance line, their vectors are fully drawn in Fig. 2 and denoted by Jw and Jw. The vector sum of Jw, and Jw., which actually occurs at the earth fault, is now (dash-dotted VectorJtv of Fig. 2) with the voltage of phase 3 of the line transformer in Phase or also in phase with the occurring on, compensation transformer i o Secondary voltage. This secondary voltage can therefore be 1 to suppress the active current used at the earth connection point. One can also describe the process in such a way that that through the described connection of the secondary winding of the compensation transformer the active earth fault current is extracted from the earth fault position and via this secondary winding is conducted, as this secondary winding opposite the path across the earth fault creates a resistance-free path for the earth fault active current. A short circuit of the a phase of the long-distance line is prevented by the resistor i i. the Switches 12, 13 and 4 serve for the secondary winding of the compensation transformer optionally to be connected to the phase of the long-distance line that currently has an earth fault. This Optional connection can also be made with the help of relays, which are approximately dependent on the voltages the three phases of the pipeline are controlled, are carried out automatically, since the voltage of the earth faulted phase of the long-distance line decreases to a very high low amount.

Fig.q. the drawing shows an embodiment of the invention, in which the compensation transformer io with its primary winding to the undervoltage side of the star-star connected main transformer feeding the line is. Its secondary winding is between the star point of the one connected to the long-distance line The high-voltage side of the main transformer and the earth are switched. The primary winding of the compensation transformer. is set with the help of Sehalter 12, 13 or i q. optional connected to that phase voltage of the main transformer, the corresponding Long-distance line phase has the earth fault. With this arrangement, the secondary side must of the compensation transformer develop a much higher voltage than in the arrangement of Fig. 3, since in the closing over the Erdüchlußstelle Circuit of the secondary winding of the compensation transformer also the voltage the phase 3 of the line transformer is switched on and therefore by a corresponding Partial voltage of the secondary winding of the compensation transformer are canceled got to. The power of the compensation transformer io is therefore greater than that of the Circuit according to Fig. 3. On the other hand, the circuit according to Fig. Q. the very essential Advantage aüf that the switches 12, 13 and 14 are only designed for low voltage.

Because the one in series with the secondary winding of the compensation transformer switched ohmic resistance i i causes losses, so you can replace it also use a reactance (a choke coil or a capacitor). -Because, however, the voltage across this inductor compared to that across the ohmic resistance i i occurring voltage is rotated by 90 ° in phase, so must also this Voltage overcoming secondary voltage of the compensation transformer a: corresponding have changed phrase positions. One must therefore the primary winding of the compensation transformer : also supply a voltage with a changed phase position, which can be achieved by connecting the Primary winding to a healthy phase of the line can be achieved. This will reaches that of the secondary winding over the choke coil and over the earth fault -: generated electricity again has a phase position that corresponds to the phase position of the one to be eliminated Earth fault active current: is opposite.

Fig. 5 of the drawing shows such a circuit. Instead of Ohmic resistance i i of Fig. Q. occurs the choke coil 15. In addition, it is now the primary winding of the compensation transformer using switches 12, 13 and 14 not connected to the voltage of the phase of the main transformer, whose assigned long-distance line has an earth fault, but to such a phase (phase i in Fig. 5), which has no earth fault. Fig.6 shows the vector diagram the voltages of the circuit; which extends from the top of the secondary winding of the compensation transformer via phase .3 of the transmission line voltage, via the ground connection point 5 and the inductor 15 to the lower end of the secondary winding closes. In this circuit according to: the diagram of FIG. 6 Uzl the Secondary voltage of the compensation transformer. Uz. is the one on the choke coil 15 occurring voltage, while the fully drawn vector is the voltage of the phase 3 of the trunk line illustrates. Since the current of this circuit is identical to that of the Choke coil 15 occurring voltage Uz .. includes a phase angle of 9o °, so @er represents the voltage of the earth line phase 3: a with earth fault Active current. It is therefore, as can be seen from the explanations relating to FIGS. 2 and 3, Suitable for the compensation of the active earth fault current.

The arrangement according to Fig. 7 differs from that of Fig. 5 thereby; that the primary purpose of the compensation transformer is: a suitable one Line-to-line voltage connected to the low-voltage side of the main transformer is. E, s: a phase-to-phase voltage is used, which is between that with earth fault affected phase of the pipeline and a phase not subject to earth fault occurs. With this arrangement, the beginning and the end of the primary winding of the compensation transformer via the switch pairs 12, 13 and j 14 to the low voltage side of the main transformer. Fig. 8 shows the voltage diagram in the secondary circuit of the compensation transformer that closes via the earth connection point 5 i tors. The phase position of the secondary voltage Uzl of the compensation transformer is due to the phase position of the 'concatenated voltage between phases i and 0 given. Uz. is again the voltage occurring at the choke coil 15. As : can be seen when the long-distance line phase voltage remains the same the Voltages Uzl and Uz. much smaller than with the arrangement according to Fig. 5 or according to the diagram in fig. 6. The compensation transformer io and the choke coil 15 therefore only need to show a correspondingly lower performance. On the other hand However, in the arrangement according to Fig. 7 there are six switches on the primary side of the compensation transformer required, while in Fig. 5 only three such switches are necessary. as well needs according to Fig. q. only one switch to be operated in the case of Erdsehlußfall while As shown in Fig. 7, two switches must be operated.

The circuit according to Fig. 7 is also suitable for connection to delta windings of the main transformer. Fig.9 of the drawing shows such a circuit. The primary winding of the compensation transformer is here via the SChalterpaa.re 12, 13 and i ¢ optionally to one phase of the delta-connected auxiliary winding 16 can be connected to the main transformer. The mode of operation of this circuit is the same however not the circuit in Fig. 7, but the one shown in Fig. 5 or in Fig. 6, since the voltages that can be tapped off at the delta winding 16 have phase positions, which correspond to the phase voltages of the pipeline and not to the line-to-line voltages.

Those in series with the secondary winding of the compensation transformer switched reactors can be built so that they do not have any saturation linear dependence of the current flowing through the choke coil as a function of the voltage appearing on the choke coil. The characteristic the choke coil can be the non-linear dependence of the on the long-distance line occurring corona current can be adjusted by the voltage of the long-distance line. Man achieved in that the compensation current supplied by the compensation transformer the active earth fault current always exactly cancels or this active earth fault current does not increases linearly with the voltage of the long-distance line.

The device according to the invention can also be used to to compensate reactive currents at the earth fault. All that is required is that the compensation transformer develops a secondary voltage component, which generates a reactive current at the earth fault, which corresponds to the earth fault reactive current counteracts. The device according to the invention can then be used to relieve the known Extinguishing devices for the reactive current at the earth connection point are used or also to a replacement of these facilities. To the arrangement according to the invention the respective operating conditions, i.e. the respective operating voltage and the To be able to adjust the line length, either the compensation transformer can be controllable on its secondary or on its primary side as well. with of the secondary winding of the compensation transformer in series connected active or reactances.

As can be seen from the exemplary embodiments, the arrangements according to the invention readily in systems with already existing inductive earth fault quenching can also be installed.

Claims (3)

PATENT CLAIMS: i. Arrangement for the compensation of the at the earth connection point from high voltage AC power lines, from corona discharges resulting active current, characterized in that between the with earth fault affected line and earth connected in series with an effective or reactive resistance the secondary winding of a compensation transformer is connected, the primary winding of which is fed from the long-distance line with a voltage of such a phase position that the current generated by the secondary voltage via the earth fault point is the earth fault active current cancels. 2. Arrangement according to claim i, characterized in that an ohmic shear Resistor connected in series with the secondary winding of the compensation transformer and the primary winding depends on the voltage between the neutral point of the long-distance line feeding transformer and earth. 3. Arrangement according to claim i, characterized in that the secondary winding of the compensation transformer in series connection with an ohmic resistance between earth and the star point the winding of the transformer feeding the long-distance line connected to the long-distance line is connected and that the primary winding of the. Compensation transformer of the Phase voltage on the low-voltage side of the transformer feeding the long-distance line is fed, wherein the transformer feeding the long-distance line is a star-star connection its main windings. .l. Arrangement according to claim i, in which in series with the secondary winding of the 'compensation transformer connected a choke coil is characterized by that the primary winding of this transformer from. the transformer feeding the pipeline with a voltage of this type Phasing fed sore that of the secondary winding over, the earth fault generated current cancels the earth fault active current. 5. Arrangement according to claim q., Thereby characterized in that the secondary winding of the Koimpensationsxransformators in series with a choke coil between the star point and the earth of the to the long-distance line connected side of the connected with its main windings in star-star Main transformer is connected, while the primary winding of the compensation transformer fed by the phase voltage of the low voltage side of the main transformer which is assigned to a phase of the trunk line that has no earth fault. 6. Arrangement according to claim q., Characterized in that the secondary winding of the 'compensation transformer in series with a choke coil between -the star point and the earth of the side of the connected to the long-distance line with its main windings in star-star connected main transformer is connected, while the primary winding the Kompensati, onstransformators expediently from the low-voltage side of the main transformer with a chained: voltage is fed that is between that with earth fault and a phase of the long-distance line that is not subject to an earth fault. Arrangement according to Claim q., Characterized in that the secondary winding of the compensation transformer in series with a choke coil between the star point and the earth of the to the Long-distance line connected to the side of the with its main windings in star-star switched main transformer is switched, while the primary winding of the Kompensatioinstra sformators from a delta-connected auxiliary winding of the Main transformer is fed from a voltage, the phase position of which is the phase voltage one not afflicted with earth fault. Phase of the pipeline. B. Arrangement according to claim i, in which in series with the secondary winding of the compensation transformer a choke coil is connected, characterized in that the voltage of the Choke coil depending on which one it is through. flowing, compensation current not lineaxl increases, the nonlinear characteristic of the inductor increasing of the corona current of the long-distance line depending on the long-distance line voltage is. 9. Arrangement according to claim i, characterized in that with the help of the compensation transformer reactive currents at the earth fault can also be compensated. i o. arrangement according to Claim i, characterized in that either the compensation transformer or the ohmic or reactive resistances connected in series with its secondary winding or both are adjustable. i i. Arrangement according to claim i, characterized in that that the long-distance line also has inductive earth fault quenching, e.g. B. with the help of a earth-fault reactor switched to the neutral point or with the help of a quenching transformer, having.