DE1613872C - Protection arrangement against inverters tilting a power converter system - Google Patents

Description

The invention relates to a protection arrangement against an inverter tilting also in the Inverter operation working converter system, which is used to feed the armature circuit of an externally excited DC drive is provided, with a charged capacitor, which when the occurrence of Overcurrent is discharged through a winding of the DC drive.

One cause of malfunction in controlled power converter systems is the failure of the extinguishing effect at the moment current-carrying valve in inverter operation, the so-called inverter tilting. In inverter operation In a converter system, the fed DC motor works as a generator. The direction of energy is opposite to that in rectifier operation. Is caused, for example, by overload If the system exceeds the step limit of the inverter, the current is drawn from the current-carrying one Valve not properly passed on to the next valve. The current continues to flow when the associated voltage has already become positive. In doing so, the voltage of the inverter has reversed and is connected in series with the generator voltage in the same direction. The result is a short circuit Increase in valve currents. In addition to high loads, the cause of the inverter tipping is in particular load surges or short circuits, failure of the control device of the converter system Voltage surge on the DC side or a

ίο Sudden drop in voltage of the feeding AC voltage, for example when the pantograph of an electric traction vehicle is lifted off. In the case of the overcurrent high-speed switches often used in systems with gas discharge valves, the time until the faulty valve branch is relieved can be, for example, 100 rn / sec. This switching delay may no longer be permissible under certain circumstances, especially when thyristors are used as converter valves. With fast-switching fuses, a switch-off time of around 10 m / sec can be achieved, but the response of the fuse results in an interruption of the downstream valve branch and thus generally an interruption in the operation of the system. The known grid barriers with contactless electronic switching elements respond almost without inertia in the event of a malfunction, but remain ineffective if the inverter fails because the malfunctioning valve is not extinguished.
. From the German Auslegeschrift 1,087,254 an arrangement for rapid de-excitation or for rapid excitation reversal of inductive DC circuits, in particular for re-exciting the field of DC machines, is known. The exciter winding of the DC machine connected to a DC voltage source is constantly connected in parallel via a switching rectifier with a capacitor with a high-value resistor connected in parallel. The capacitor is held by a voltage source at a charging voltage which is equal to the

permissible overvoltage that may occur when the field winding is switched off. The switching rectifier keeps the charging voltage away from the inductive excitation circuit during normal operation. When de-energizing, the The polarity of the field winding of the DC machine is reversed with a reversing contactor. In the first part of this conditional equalization process in which the self-induced voltage occurring at the field winding __ exceeds the permissible overvoltage and thus the specified charging voltage on the capacitor the. Induction voltage across the switching rectifier and the parallel connection in series with it derived from the capacitor and the high resistance. So here is via the switching rectifier a part of the energy content of the exciter winding released during the switching process is above recorded by the capacitor at a defined voltage limit. In the second part of the equalization process, in which the induction voltage is applied to the If the value of the supplying direct voltage has dropped, the switching rectifier blocks and the further de-excitation takes place with constant DC voltage.

It is also known (Elin magazine, June 1965, p. 9 to 18, especially picture 9 and 16), a To arrange protection arrangement of the type mentioned in the armature circuit of a direct current drive. To the DC drive operating as a generator is the series connection of two thyristors, one valve and one to about 2.5 times the nominal armature span

3 4

voltage charged capacitor connected in parallel. Excitation winding 2 of a not shown in the figure - a short-circuit-like increase in the armature current, th DC machine of 600 kW, for example, i.e. the occurrence of an overcurrent, is detected by the DC output of a converter 8 in a current consumption single-phase midpoint circuit with converter connected to an electronics unit ; then the thyristors 5 tuen 3 and 4, especially thyristors, fuses are triggered by the electronics. The capacitor discharges 5 and 6 and a transformer secondary winding 7 is charged, with the valves of the converter connected, which is not shown in the figure being extinguished, via the armature winding. A resistor is arranged in the primary winding discharge current path of a single-phase alternating current. The network of this resistance at a frequency of 16 ² werstand fed / ₃ Hz resulting in discharging voltage drop io the can. The excitation circuit contains a reset switch that switches off the converter system via a relay. capacitor 10, which by means of a suitable switching-on oscillation of the capacitor charge takes place device, in particular an auxiliary thyristor 11, which does not take place. A disadvantage of this protective arrangement exciter winding 2 and the direct current output of the voltage is that the converter 8 can be connected in parallel with direct current drives. A control device 12 is assigned to the high-power thyristor with a thyristor in the capacitor 15 11. The branch does not manage and that both the condensate control device 12 can preferably be designed as a function of the gate and the thyristors for very high voltages from the phase position of the valve current in the armature and currents must be designed. circuit, which can be recorded by means of a current transformer,

The invention is based on the last-mentioned state of receiving a signal from the supplying mains voltage. Technology. It is based on the task of a 20 shifts the end of the valve flow in relation to Protection arrangement against overcurrents in alternating to a mains-synchronous voltage, this is the case with converter operation a converter system, which the thyristor to step the adjustable time value Supplying the armature circuit of an externally excited DC 11 is given an ignition pulse and the one in the Current drive is used to create the polarity indicated in FIG If a fault occurs in the armature circuit, 25 discharges automatically. The signal to the control device 12 a quick de-excitation of the direct current drive can, under certain circumstances, also be activated directly from a lowering or directs. can be derived from a failure of the mains voltage.

The present invention makes use of In order to increase this capacitor charge can according to the measure, a charged capacitor for the invention advantageous a special circuit, Fast de-excitation in the excitation circuit of the direct current 30 the so-called Greinacher circuit can be provided, to use instinct. The invention consists of a charging capacitor 15 and two diodes 16 Protective arrangement mentioned at the outset in that the and 17 and a charging resistor 18 can exist, charged capacitor depending on the one can also charge voltage directly from the Armature circuit current or the transformer secondary winding 7 supplying the armature circuit voltage DC drive whose field winding 35 men and via the diode 17 and the resistor 18 specify the capacitor 10 while being disconnected from their excitation voltage source. The thyristor 11 is can be switched in parallel, and that in the case of the parallel connection, a reversing diode 20 is connected in counter-parallel the capacitance of the capacitor with the inductance. The excitation winding 2 can be used in conjunction with vity of the excitation winding forms an oscillating circuit. of the invention preferably an additional one

The capacitor is e.g. from the excitation voltage 40 auxiliary valve (thyristor) 22, which is a control device voltage source, so for example associated with the output 23, in series with a diode 24 parallel voltage of a line-commutated converter.

the and, in the event of a fault, the excitation winding in parallel At time Z ₁ , in the current direction (not shown)

switched. The discharge current of the capacitor serves teranlage the armature circuit, the valve currents can initially be detected as extinguishing current for the valves this current 45 separates, a malfunction occurs, rectifier in the excitation circuit and then as an existing valve current should at the time of the oscillating current for the excitation winding. With the reversal of the zero crossing of the valve voltage into the positive reversal of the excitation current, the armature voltage will not yet be zero, ie the polarity of the commutation for the DC drive is reversed, and this valve should no longer be possible. Then a message "Inverter switchover faulty power converter system" is subtracted from the instantaneous voltage 50 at this point in time. To be given in a pen «. A signal formed from this unfortunately-like protection arrangement, the valve currents tet the fast de-excitation and counter-excitation. They are in the armature circuit before the fuses respond at time i _; according to Fig. 2 limited by the tax and brought to zero. A particularly advantageous device 12 to ignite the quenching thyristor 11 is that with the 55 ^{pulse according} to the invention, the discharge of the capacitor protection arrangement begins, a polarity reversal of the excitation winding 10 and thus the quenching of the thyristors (valves by switching are not required, and that 3 and 4) of the converter 8 in the excitation circuit. Compared to the known protection arrangement, a concomitant use can expediently be made in the armature circuit of the more cost-effective design of the imdensator pulse of the converter valves on the inverter. 60 step limit shifted or the valves deleted

To further explain the invention and its the.

Further training is referred to the drawing. This process can also be used for short-term and

took. Fig. 1 shows an embodiment of a temporary lowering or failure of the feed protection arrangement against inverter tilting after the mains voltage as well as in the event of failure of important auxiliary devices Invention. In Fig. 2 is a de-excitation and a 65 voltages or when other disturbances occur the subsequent counter de-excitation process can be initiated. The means of the loading device a time diagram schematically illustrated. via the auxiliary capacitor 15 to a voltage

According to Fig. 1, a consumer, for example the one above the peak value of the feeding alternating

voltage of the secondary winding 7 charged capacitor 10 is initially discharged through the thyristors (valve 3 and 4), so that they practically go out at time I ₁ . The remaining charge of the capacitor 10 flows through the excitation winding 2 and gives the excitation current i _e of 250 A, for example, a slight increase. The voltage u _e at the excitation winding 2, for example 70 V, jumps to a somewhat higher value, since the inductance of the excitation winding 2 tries to maintain the current flowing. The excitation current i _e flows to the capacitor 10 and charges it. At time t ₂ the excitation current i _{e has reached} its maximum value and the excitation voltage u _{e has reached} its zero crossing. At time t _3, the current i _e in the field winding 2 swings through zero. The counter voltage u _g reaches its peak value of about 700 V. The capacitor 10 is charged and the counter excitation begins. The countercurrent -i _e reaches its maximum at time / ₄ at the zero crossing of the capacitor voltage.

As soon as the voltage u _{e has reached} the value of the threshold voltage of the diode 24, the auxiliary valve 22, which previously received an ignition pulse, takes over the current Z ₈ . It thus extends the time of the counter-excitation in the excitation winding 2. The diode 24 only serves to receive the negative reverse voltage as long as an ignition pulse is present at the auxiliary valve 22, but this cannot yet accept any current.

In connection with the invention, the auxiliary valve 22 can be _{ignited by its control device 23 at a predetermined distance from the ignition time Z 1 of} the auxiliary thyristor 11. This distance depends on the resonant circuit data of the inductance

π of the excitation winding 2 and the capacitance of the capacitor 10 and can be, for example, about 5 m / sec. From the ignition time t _{x of} the auxiliary thyristor 11 until the full counter-excitation is reached at time t ₄ , approximately 10 m / sec are not significantly exceeded. The current time area to be absorbed by the disturbed valve branch is therefore very small.

1 sheet of drawings

Claims (6)

Patent claims: 1. Protection arrangement against tipping over of an inverter which is also working in inverter operation Converter system that feeds the armature circuit of an externally excited direct current drive is provided with a charged capacitor, which in the event of overcurrents over a Winding of the direct current drive is discharged, characterized in that the charged Capacitor (10) as a function of the armature circuit current or the armature circuit voltage of the direct current drive whose excitation winding (2) is disconnected from its excitation voltage source can be connected in parallel, and that in the case of parallel connection, the capacitance of the capacitor (10) forms an oscillating circuit with the inductance of the excitation winding (2). 2. Protection arrangement according to claim 1 with a converter for controlling the excitation current, characterized by the circuit arrangement known per se, that the capacitor (10) charged to a voltage exceeding the excitation voltage and at the same time as a quenching capacitor is designed for the valve or valves (3, 4) of the feeding converter (8). 3. Protection arrangement according to claim 2, characterized by the circuit arrangement known per se, that a series connection of the capacitor (10) with an auxiliary thyristor (11) is provided is. 4. Protection arrangement according to claim 3, ^p, characterized in that the auxiliary thyristor (11) a reversing diode (20) is connected in antiparallel. 5. Protection arrangement according to one of claims 1 to 4, characterized in that the excitation winding (2) a controllable auxiliary valve (22) is connected in parallel. 6. Protection arrangement according to claim 5, characterized in that the ignition time of the auxiliary valve (22) is selected at a fixed distance from the discharge time (I ₁ ) of the capacitor (10).