DE19619305A1 - Controlled electrical power series compensator with capacitor bank - Google Patents

Abstract

The electrical series compensation system 2 has a unit 4 that generates a synchronising signal Ss that is applied to a control stage 6 that provides firing pulses Sth1,Sth2 for operation of a pair of synchronised thyristors Th1,Th2. The series compensator is coupled 8 between voltage stages 10,12 and provides a voltage phase shift. The compensator has a compensator bank 14 and in parallel is a switched inductance 16.

Description

The invention relates to a method for switching the working area of a controlled series compensator, consisting of a capacitor bank, the one switched Choke is connected in parallel from a capacitive ar working area in an inductive working area and on one Device for performing this method.

In the case of series compensation, capacitors are usually used used in the cable train to the current-dependent voltage drop on the line and the transmission angle in stages to diminish. These are capacitor banks that as a whole or in several partial capacitors (segments) in Row can be switched on and off. Switching the on and off Capacitor happens because of a parallel power switch is opened or closed. Protection of the Kon capacitors in the event of a network short circuit is replaced by a parallel Ab conductor, through a triggerable spark gap and / or through guaranteed a parallel circuit breaker.

Furthermore, a series compensation system is known, at the through a choke connected in parallel to the capacitor the total impedance of this series compensator (similar to with the TCR (Thyristor Controlled Reactor) in the static compen sator) with a converter valve by appropriate ignition which is continuously regulated to high voltage potential. A such controlled series compensation is known under the Term ASC (Advanced Series Compensation). With a derar series compensator can control the dynamics of the rei high compensation and the overall impedance is adjustable in a certain range, the impedance of can be changed capacitively to inductively.  

Such series compensators are described in the article "Regulated Pa parallel and series compensation ", printed in the DE time writing "Elektrie", volume 45, 1991, March, pages 88 to 90, presented. In addition, is such a controlled series comm pensator, which is integrated in a transmission line, in EPRI workshop entitled "Advanced Series Compensation with Variable Impedance "from November 14th to 16th, 1990, Cincinnati, Ohio.

The function of the regulated series compensation system is based on the control of a converter valve, which by a targeted reloading process by the coil one for the Mains effective impedance. This control must repeat periodically and is on the voltage across the Kon related to the controlled series compensation system. A headset ensures time-synchronous control this converter valve. This tax rate sets ignition impulses from a synchronization signal and a desired, can be determined on this related control angle. A downstream logic still enables protective intervention, to block ignitions in the event of an accident.

The previous application area of a controlled series compensation system (ASC) was limited to the working area of the changeable capacitive impedance. However, as can be seen from FIG. 1, there is theoretically the possibility of converting the fundamental oscillation impedance of the ASCs from the capacitive working area A _kap into the inductive working area A _ind . This enables the working range of the ASC to be doubled in error-free operation (not in the overload range).

This expansion of the ASC work area results in a significant increase in the ASC dynamics for the legs flow of load flow and damping of power donation lungs in the transmission line equipped with the ASC.  

However, the previous operation of the ASC was limited to the capacitive work area. In this case, a signal proportional to the capacitor voltage is generated from the line current and fed to the headset as a synchronization signal. Together with a control voltage, which is proportional to a control angle, the headset generates ignition pulses which control the respective thyristors separately for the positive and negative voltage half-wave. As shown in Fig. 1, the operation in the capacitive region A _{kap is defined} at a control _angle S _α of 180 ° up to a system-dependent operating point at which the capacitive impedance in steady-state operation tends to infinity. This results in an increase in the capacitor voltage according to FIG. 2 by the recharging process.

If the control angle α is set to a win angle in the previous operation, which gives an inductive impedance in the stationary operation according to FIG. 1, this leads to an unstable operation, as shown in FIG. 3. The associated course of the valve current for this unstable operation is shown in FIG. 4 in a diagram over time t.

The invention is based on the object of a method and a device for carrying out the method ben, with which the controlled series compensator from a be any working point in the capacitive work area into one any working point in the inductive working range can be led, which is stable.

This object is achieved according to the invention by the features of claims 1 and 4.

The fact that when a required inductive Operating point for the error-free operation of the controlled Series compensator first a predetermined capacitive loading drive point is set for any Ar  same point of control of the series compensator Prerequisite for the transfer of the controlled serial comm pensators from any capacitive operating point in created a required inductive working point. Time the provided syn chronizing signal inverted while the Zündim pulses for the switched choke can be blocked. After this the time period provided for the switching sequence control, for example, a network period has expired, the The ignition impulses are disabled again and it is activated Head angle according to the required inductive work point available.

By this inventive method for switching the Working range of a controlled series compensator from any capacitive operating point in a required On the one hand, the inductive operating point is provided set synchronization signal electrically rotated by 180 ° and on the other hand, by outputting a predetermined work point with time-delayed blocking of the ignition pulses during this switching for, for example, half a network period the starting condition for the inductive work area is created fen.

The device for performing the Ver driving has a switching device and a lock direction up. By means of the switching device, the ge controlled series compensator on a defined operation set point from which the switchover takes place and that provided synchronization signal inverted. also this switching device generates a blocking signal with which the locking device is delayed to output the defi nated operating point for the transmission of the ignition pulses blocked from the headset to the switched throttle. After the switching time has expired, the blocking the ignition signals are canceled and there is a control angle ent speaking of the required inductive working point and one for  inverted the inductive working area Synchronizing signal provided by the switching device poses.

Advantageous embodiments of the device for implementation tion of the inventive method are the dependent claims Chen 5 to 12.

To further explain the method and the device for performing this method is based on the drawing referred to in the an embodiment is illustrated schematically.

Fig. 1 shows the operating characteristic of a controlled series compensator, the

Fig. 2 is a diagram showing the waveforms of a measured phase current and a capacitor clamping voltage of the controlled series compensator,

Fig. 3 illustrates in a diagram over time t the capacitor voltage in the transition from a capacitive to an inductive operating point without using the inventive method, wherein in

Fig. 4 is shown in a diagram over the time t of the associated Ven tilstrom that

Fig. 5 shows a single-phase equivalent circuit diagram of a known controlled series compensator with the device for carrying out the method according to the invention, which

FIG. 6 shows a block diagram of an embodiment of a switching device of the device for carrying out the method according to the invention

Fig. 7 shows in a diagram the time profiles of the conductor current and the capacitor voltage at an inductive operating point and

Fig. 8 shows the time course of the capacitor voltage during a switch from a capacitive to an inductive operating point using the inventive method, the

Fig. 9 in a diagram with time t represents the associated valve current.

Fig. 5 shows a single-phase equivalent circuit diagram of a ge-controlled series compensator 2 with a device 4 for generating a synchronizing signal S _S , which is fed to a downstream tax rate 6 . This control rate 6 ensures a time-synchronous control of two thyristors Th1 and Th2. This tax rate 6 sets ignition pulses S _Th1 and S _Th2 , which are determined from a synchronization signal S _S with a desired th, related to this control angle α. The controlled series compensator 2 , which is also known as ASC (Ad vanced Series Compensation), is integrated in a transmission line 8 as a series resistor. This happens in most cases in the course of line 8 , but also takes place at the output or input of switching stations. At the beginning and end of the line, voltage cases 10 and 12 are indicated, the voltages U _E and U _{A of} which differ in amplitude by a line voltage drop .DELTA.U and are phase-shifted in a voltage rotation angle ϑ. The voltage U _A at the beginning of the line is also called de send voltage U _A and the voltage U _E at the end of the line is also called load voltage U _E.

The construction of a controlled series compensation system 2 can be divided into three areas. The core of such a system 2 consists of a capacitor bank 14 , which is integrated in series in the transmission line 8 . Herewith he reaches a compensation of the inductive longitudinal impedance of the line 8 , which is responsible for the inductive reactive power component. Parallel to the series capacitor bank 14 , a branch consisting of a coil 16 and a converter valve 18 is connected in a controlled series compensation system 2 . As a converter valve 18 , a parallel connection of two thyristors Th1 and Th2 is Darge, which are arranged antiparallel to each other. By means of these two thyristors Th1 and Th2, the coil 16 can be switched on at predetermined times. Instead of the thyristors Tb1 and Th2, other semiconductor valves, for example GTO thyristors (gate turn-off thyristors) can also be used. By means of this branch, there is the possibility of continuously changing the effective impedance of the controlled series compensator 2 capacitively by a phase control. This allows you to limit a short-circuit current in addition to increasing the transmission power even in the event of a fault (inductive working range) on line 8 .

To protect the capacitor bank 14 , the coil 16 and the converter valve 18 against overload due to excessive Lei line currents i _L are parallel to these elements 14 or 16 and 18 a bypass 20 (bypass) and a non-linear resistance 22 , also called arrester, installed . A metal oxide varistor (MOV), for example, is provided as the non-linear resistor 22 . This electrically connected in parallel to the series capacitor 14 metal oxide varistor 22 is dimensioned so that at a predetermined voltage amplitude the arrester 22 takes over the current very quickly and thus protects the series capacitor bank 14 from prolonged overload conditions. The energy absorption capacity of a non-linear resistor 22 is of course limited due to economic considerations and thus a Se rienkompensationsanlage 2 also needs the ability to protect the series capacitor 14 with its arrester 22 against overload. This task is taken over by the parallel branch 20 . This bypass 20 consists of a bypass scarf ter 24 and a damping circuit 26th The bypass switch 24 is closed as soon as the load, ie the energy absorption capacity of the arrester 22 , is exhausted.

The actual value of the line current i _{L is} determined by means of a device 28 and leads to an amplitude input 30 of the device 4 for generating a synchronization signal S _S. The actual value of the capacitor current i _{C is determined} by means of a device 32 and the actual value of the valve current i _{Th is} determined by means of a device 34 and fed to a link 36 , the output of which is linked to the amplitude input 30 of the device 4 for generating a synchronizing signal S _S can be. An actual value of the frequency f _{L of} the transmission line 8 is fed to a frequency input of the device 4 for generating a synchronization signal S _S. The system sizes i _L , i _Th and i _C are conducted via a fiber optic system potential-free from the high-potential system 2 to the device 4 for generating a synchronization signal S _S , which is at earth potential. This potential-free transmission of the system sizes i _L , i _C and i _Th are shown by a broken line. Such an ASC system 2 is approximately known from the above-mentioned EPRI workshop.

Between the device 4 for generating a synchronizing signal S _S and the headset 6 , a switching device 42 of the device for performing the method according to the invention is arranged, the outputs of the headset 6 being provided with a locking device 44 , which is also part of the device for performing the invention according to the procedure. The switching device 42 is just if connected to the inverting inputs 46 of the locking device 44 . The switching means 42 are also adjacent to the synchronizing signal S _S related to another phase were actuating signal S _Compr and two identification signals S and S _{Inds INDT} the other phases S and T of the ASC system 2 is fed. On the output side, a control _angle signal S ' _α and a modified synchronization signal S' _{S are available} for further processing in the tax rate 6 . At the two outputs of the blocking device 44 , the generated ignition signals S _Th1 and S _Th2 for the thyristors Th1 and Th2 of the converter valve 18 are pending.

Fig. 6 shows a block diagram of an embodiment of the switching device 42nd This switching device 42 has a switching sequence control 48 , each a func tion member 50 and 52 for the capacitive and inductive Ar beitsbereich A _kap and A _ind , a device 54 for working area identification, a device 56 for inverting a synchronization signal S _S and a plurality of switches 58 , 60 and 62 . The device 54 for working area identification is connected on the aisle side to an actuating signal input 64 , at which a phase-related _actuating signal S _kompR or S _kompS or S _kompT is present. At this input 64 , a switch 58 is also connected on the input side, the outputs of which are linked to an input of the functional elements 50 and 52 . For the two function elements 50 and 52 , memories are seen in which a table of impedance values and associated control angle values are stored, each of which corresponds to a branch of the working characteristic of FIG. 1. A reference signal S _{KGW is} fed to the device 54 for working area identification via a reference input 66 . In the simplest case, a comparator is provided for this device 54 , at the output of which a phase-related signal signal S _indR is present. This phase-related identification signal S _indR is supplied to the switching sequence controller 48 , which consists of an AND _gate 68 , a monostable multivibrator 70 and two delay elements 72 and 74 . The AND gate 68 is arranged on the input side of this switching sequence control 48 and has a total of three inputs. A phase-related identification _signal S _indR , S _indS and S _{indT is} supplied to _{each input} , two identification _signals S _indS and S _{indT being supplied} via inputs 76 and 78 . The phase-related identification _signal S _indS or S _indT is generated in the switching device 42 of the phase S or T. The phase-related identification _signal S _indR is led out of the switching device 42 of the phase R via the output 80 so that it can be used in the switching devices 42 of the phases S and T. On the output side, this AND gate 68 is connected on the one hand to the control inputs 82 and 84 of the changeover switches 58 and 60 and on the other hand to the inputs of the monostable multivibrator 70 and the time delay element 72 . On the output side, this time delay element 72 is connected to a control input 86 of a changeover switch 88 of the device 56 for inverting a synchronization signal S _S. From the output side, this changeover switch 88 is connected by means of a multiplier 90 to a synchronizing signal output 92 of the switching device 42 . At the two inputs of this switch 88 there is a positive and a negative sign signal. The second input of the multiplier 90 is linked to a synchronizing signal input 94 of the switching device 42 . The output of the monostable multivibrator 70 is connected on the one hand by means of a further delay element 74 to a blocking signal output 96 of the switching device 42 and on the other hand to a control input 98 of the switch 62 . One input of this change-over switch 62 is connected to an adjustable constant element 100 and the other input is linked to the output of the functional element 52 for the inductive working range A _ind . On the output side, this change-over switch 62 is connected to an input of the change-over switch 60 , the second input of which is linked to an output of the functional element 50 for the capacitive working range A _kap and the output of which is connected to a control angle output 102 of the change-over device 42 .

Using this block diagram, the method according to the invention for switching the working range of a controlled series compensator 2 from any capacitive operating point to an inductive working point will now be described:
This functional description assumes, for example, a capacitive operating point A _K1 . For this operating point, the phase-related system control signal S _kompR = -20 Ω, and the switches of the changeover switches 58 , 60 , 56 are in position I, whereas the switch of the changeover switch 62 is in position II. Thus appear at the control angle output 102 a control _angle signal S _α = 160 ° el, at the blocking signal output 96 a blocking signal S _B = 0 and at the synchronization signal output 92 a synchronization signal S _SV = S _S. As soon as the phase-related system control signal S _{compR changes} its value from -20 Ω to +10 Ω (inductive working point A _I1 ), this is compared by the device 54 for working area identification with a predetermined reference signal S _KGW . At the output of this device 54 , the identification _signal S _{indR changes} from "low" to "high". The output signal of the AND gate 68 of the switching sequence control 48 also changes from "low" to "high" as soon as the phase-related identification _signals S _indS and S _{indT of} the phases S and T also have a "high" level. As a result of this Pe gelwechsel the switch of the switch 58 and 60 in position II, the time delay 72 is activated and the monostable flip-flop changes from "low" to "high", whereby the switch of the switch 62 also changes to position I and that Time delay 74 is started. Thus, the control _angle signal S ′ _α at the control _angle output 102 changes to a value of, for example, 140 ° el, but values between 91 ° el and 140 ° el can also be selected as desired. The upper value can be shifted specifically to the system. As a result, the ge-controlled series compensator 2 is located in an operating point that is independent of any capacitive starting operating point. The same starting position for the switchover is thus created for any capacitive operating points. The monostable multivibrator 70 is set, for example, to a Netzpe period, whereas the time delay of the time delay elements 72 and 74 is set, for example, to half a network period. After the expiry of this delay time, the blocking signal S _{B changes} from "low" to "high", where its outputs are blocked by the blocking device 44 , and the switch of the changeover switch 56 changes to the position II, as a result of which the synchronization signal input 94 present at the synchronization signal 94 S _{S is} inverted. By blocking the ignition signals S _Th1 and S _Th2 , the thyristors Th1 and Th2 of the converter valve 18 are no longer activated. This blocking leads to a DC component in the capacitor voltage u _C , which prepares the ignition in the inductive working range A _ind . As soon as the time of the monostable multivibrator 70 has expired, the signal at its output changes from "high" to "low", which means that the blocking signal S _B at output 96 changes from "high" to "low". This blocks the blocking of the ignition signals S _Th1 and S _Th2 . Since the time delay of the time delay element 72 was set to, for example, half a network period, its output signal changes together with the output signals of the monostable multivibrator 70 and the time delay element 74 from "high" to "low". At the outputs 92 and 102 of the switching device 42 are the modified synchronizing signal S ' _S = -S _S and a control _angle signal S' _α = 131.4 ° el, which by means of the phase-related system control signal S _kompR and the function _element 52nd was determined. By means of these signals S ' _α and S _SV , the ge-controlled series compensator 2 now works in the inductive working range A _ind, for example in the inductive working point A _I1 .

The inductive operation of the ASC system 2 leads to the capacitor voltage u _C leading the conductor current i _L by 90 ° ( FIG. 7). In Fig. 8, the time course of the capacitor voltage u _{C is shown} in a diagram, with a capacitive working area A _{kap being switched} to an inductive working area A _ind . A comparison with the time profile of the capacitor voltage u _C according to FIG. 3 shows that no more unstable operation occurs. The associated time course of the valve current i _Th during the switchover time is shown in FIG. 9. A comparison of this time course of the valve current i _Th with the time course of the valve current i _Th according to FIG. 4 also shows very clearly that there are no instabilities in the inductive Ar working area A _ind occur more. Likewise, the thyristors Th1 and Th2 of the converter valve 18 are loaded much less.

By means of this method according to the invention, the fundamental oscillation impedance of the ASC is transferred from the capacitive into the inductive working range by targeted modification of the synchronization method and the ignition angle. This gives you the option of doubling the working range of the ASC in error-free operation (not in the overload range) without additional effort. The expansion of the ASC work area results in a significant increase in the ASC dynamics for influencing the load flow and damping power fluctuations in the transmission line 8 equipped with the ASC.

Claims (12)

1. A method for switching the working area of a ge controlled series compensator ( 2 ), consisting of a capacitor bank ( 14 ), to which a switched inductor ( 16 ) is connected in parallel, from a capacitive working area (A _kap ) in an inductive working area (A _ind ), whereby when a required inductive operating point (A _I1 ) is determined in the error-free operation of the controlled series compensator ( 2 ), on the one hand it switches to the provision of control angles (α _ind ) of the inductive working range (A _ind ) and for a predetermined period of time a predetermined control angle ( α) is given at a headset ( 6 ) of the series compensator ( 2 ) and, on the other hand, after a predetermined time delay, on the one hand, a provided synchronization signal (S _S ) of the controlled series compensator ( 2 ) is inverted and, on the other hand, the ignition pulses (S _Th1 , S _Th2 ) be blocked for the switched throttle ( 16 ) and after the expiry of the The given time span is switched on the one hand from the predetermined control angle (α _kapF ) of the capacitive working range (A _kap ) to the provided control angle (α _ind ) of the inductive working range (A _ind ) and on the other hand the blocking of the ignition pulses (S _Th1 , S _Th2 ) is released. 2. The method of claim 1, wherein the predetermined time span corresponds to a period of a mains voltage. 3. The method of claim 1, wherein the predetermined time delay of half a period of a mains voltage ent speaks. 4. Apparatus for carrying out the method according to claim 1, this apparatus having a switching device ( 42 ) and a locking device ( 44 ), this switching device ( 42 ) on the input side with a synchronization device ( 4 ) of the controlled series compensator ( 2 ) and on the output side on the one hand with a headset ( 6 ) of this series compensator ( 2 ) and on the other hand with the blocking device ( 44 ), which in turn is connected to the outputs of the headset ( 6 ), and with further inputs of the switching device ( 42 ) phase-related plant control signal (S _kompR , S _kompS , S _kompT ) and two identification signals (S _indS , S _indT or S _indR , S _indT or S _indR , S _indS ) of the other phases (S, T or R , T or R, S) are pending. (42) a switch sequencer (48), in each case one operating member (50,52) _(Chap A, A _ind) 5. Apparatus according to claim 4, wherein the Umschalteinrich processing for the capacitive and inductive Ar beitsbereich, means (54) for working area identification, a device ( 56 ) for inverting a synchronization signal (S _S ) and several changeover switches ( 58 , 60 , 62 , 88 ), the control inputs ( 82 , 84 , 98 , 86 ) with the changeover sequence control ( 48 ) are connected. 6. The device according to claim 5, wherein the device ( 54 ) for working area identification on the output side with the switching sequence control ( 48 ) and with an output ( 80 ) of the switching device ( 42 ) and on the input side with an actuating signal input ( 64 ) of the switching device ( 42 ) are connected, the functional element ( 50 ) for the capacitive working area (A _kap ) by means of a switch on the input and output sides ( 58 , 60 ) with the control signal input ( 64 ) of the switching device ( 42 ) and with a control angle switch. Output ( 102 ) of the switching device ( 42 ) is linked, the functional element ( 52 ) for the inductive working range (A _ind ) on the input side by means of this input-side switch ( 58 ) with the control signal input ( 64 ) and on the output side via a constant element ( 100 ) having changeover switch ( 62 ) and the output-side changeover switch ( 60 ) connected to the control angle output ( 102 ) of the changeover device ( 42 ) i st and wherein the device ( 56 ) for inverting the synchronizing signal (S _S ) is connected on the input side to a synchronizing signal input ( 94 ) and on the output side to a synchronizing signal output ( 92 ) of the switching device ( 42 ). 7. The device according to claim 5, wherein the switching sequence control ( 48 ) has an AND gate ( 68 ), the output of which is on the one hand with a monostable trigger element ( 70 ), which is followed by a delay element ( 74 ), and on the other hand with a delay element ( 72 ) is linked and the phase-related identification _signals (S _indR , S _indS , S _indT ) are present at the inputs. 8. The device according to claim 5, wherein the device ( 56 ) for inverting a synchronizing signal (S _S ) has a multiplier ( 90 ), one input of which with the synchronizing signal input ( 94 ) of the switching device ( 42 ) and the other input with a changeover switch ( 88 ) is connected to the two inputs of which a sign signal is present. 9. The device according to claim 5, wherein a comparator is provided as a device ( 54 ) for working area identification. 10. The device according to claim 5, wherein a memory is provided as a functional element ( 50 , 52 ) for the capacitive or inductive work area (A _kap or A _ind ). 11. The device according to claim 4, wherein as a blocking device ( 44 ) for the ignition pulses (S _Th1 , S _Th2 ) of the switched throttle sel ( 16 ) two AND gates are provided, each having an inverting input ( 46 ). 12. The apparatus of claim 4, wherein as Umschalteinrich device ( 42 ) a microprocessor is provided.