DE903249C - Device for the forced commutation of converters - Google Patents

Description

Device for the forced commutation of power converters for the forced commutation of converters make it possible that the commutation with Inverter operation in the third quadrant, with rectifier operation in the fourth Quadrant runs. This ensures that the converter for the three-phase network represents a capacitive load and no longer, as with natural commutation, is forced to take inductive current from the network.

The known devices for forced commutation, on their improvement the invention relates to; are based on the fact that the load current is to be detached from the Anode first to a precharged commutation capacitor and then from this on the releasing anode. It is in series with the commutation capacitor a controllable valve, which in the following is to be referred to as an extinguishing valve. The sequence of the commutation process in such a device is shown in FIG shown as a curve, namely for rectifier operation of the converter. u1 is the phase voltage on the one to be released and u2 is the phase voltage on the one to be released Anode. The quenching capacitor is on voltage before the combutation process begins uk subpoenaed. il represents the current in the releasing anode and i 'the current in the If the extinguishing valve is released or ignited at time _A will,. so there is a commutation change between the anode to be detached and the extinguishing valve instead of, within which the current i1 drops to zero and the Current, i in the extinguishing valve to the value assumed to be completely smoothed. DC current increases. This process takes place during a period iii and ends at time B. The voltage of the capacitor drops from that the original value slightly, as this is already a partial discharge of the capacitor takes place. During the following time period z, the entire direct current flows in the form of a displacement current across the capacitor, with its voltage rapidly decreases. As soon as at time C the voltage of the capacitor has reached the instantaneous value the phase voltage has decreased due to the detaching anode, a commutation process begins between the capacitor circuit and the detaching anode, which during the period of time ü2 lasts up to point D and during which the current i` drops to zero and the current i2 increases accordingly up to the value of the direct current. The DC voltage ug follows the voltage curve across the capacitor between times A and D, while the rest of the time, the phase voltage curves correspond to the strongly drawn lines.

The speed at which the commutation capacitor is charged depends on the size of the direct current of the converter. Consequently - the inclination of the line between points B and C is also dependent on the load, which in the known arrangements means that the period of time ü2 with overloads too short, but too long at low loads. As can also be seen from Fig. R, it lasts after the detached anode has gone out, which took place at time B. is, only for a very short time, until the voltage of the capacitor falls below the phase voltage the just detached anode sinks. But since at the detached discharge path the Difference between the phase voltage and the voltage across the capacitor is from this point onwards the detached discharge path in the forward direction with Stressed. As a result, the detached must be within the tent section 19E Discharge path must be deionized, otherwise burn-through is to be feared are. The available time period UE is, as I said, known to both of them Forced commutation devices only very briefly. The invention now has the task based on the above-mentioned load dependency of the process of capacitor reloading and also the deionization of the detached discharge path to increase the available time as much as possible without affecting the entire Commutation process is significantly extended. The invention accordingly seeks to reduce the commutation process in such a way that instead of following the line A, B, C it is roughly after the dashed line drawn line A, E, C runs, whereby the deioning time of the Value i9, v would be increased to the much larger value YE. According to the invention the two intended goals are achieved by running in parallel with the capacitor an additional current path is provided via a choke, which after termination the transfer of power to the capacitor by igniting an auxiliary valve located in it is released and @the charge reversal of the capacitor, which was previously only due to the load current occurred, accelerated. From the moment the throttle is ignited of the auxiliary valve is connected in parallel to the capacitor, flows through the throttle an additional discharge current of the capacitor, so that its voltage is significantly changes more rapidly than if the discharge occurred only through the load current. It a period of time becomes much steeper in the commutation process the capacitor voltage switched on, and it is thereby possible without the total Ko @ mmutierungszeit is significantly extended, the capacitor so large measured that its tension in the period of time, 4n which initially only the load current flows through it, even with the highest load on the converter changes relatively slowly. This can; but those to de: ionize the detached Discharge path available time can be increased significantly.

An embodiment of the invention is shown in FIGS although for the case that the converter is arranged in zero point connection. the three converter anodes are labeled A1, A2 and As. In the same discharge vessel like these anodes there is also the extinguishing anode A4,, but it is also in a special one Discharge vessel can be accommodated. This quenching anode or the one formed by it Discharge path is in series with the commutation capacitor K. Lg is one Smoothing choke in the direct current circuit. In parallel with the capacitor K lies now a choke coil L in series with two oppositely connected auxiliary discharge vessels VH i and hH2, which are both controllable and work with an arc-like discharge to like. It is assumed that there is rectifier operation and the capacitor is preloaded in such a way that its lower occupancy is positive and its upper occupancy is negative Possesses potential. If now during the burning time, for example the anode A1, the anode A4 is ignited by releasing the grid in front of it, begins first the capacitor K to take over the current from the anode A1 to be detached. After this partial commutation process is finished and also one for deionization , the anode A1 has passed sufficient time, the auxiliary valve hH1 is released, and the capacitor, the voltage of which at this point in time may be even greater than the phase voltage at A1 begins to flow through the throttle L and the auxiliary valve VE, in addition to discharging. Under the influence of the inductance of the inductor L charges the capacitor turns to the opposite voltage direction, whereupon the auxiliary valve VH1 goes out and the further capacitor charging with it opposite Sign again only takes place under the influence of the load current. Finally, the detaching anode A2 is ignited, whereupon, as described above, the current passes from the capacitor to this anode. The extinguishing anode A4 goes out, and no further change in the charge of the capacitor K takes place. The charge of the capacitor now has the wrong one for the next commutation process Sign. The capacitor must first be reloaded again, and this The purpose of this is the auxiliary valve h112. This will be between two successive commutation processes ignited, whereupon the capacitor under the influence of the inductance of the choke L again to the correct sign reloads.

The process described is shown in a curve in FIG. 3 for rectifier operation. At point A, the extinguishing anode A4 is ignited. At point B the quenching anode has taken over the entire load current and the capacitor K is gradually discharged. If the capacitor is suitably dimensioned, the voltage change at the capacitor proceeds so slowly that the capacitor voltage does not fall below the value of the phase voltage at the anode to be removed within the required deionization time i9E. After the deionization time OL has elapsed, at time E, the auxiliary valve hHl is ignited, and an extraordinarily rapid charge reversal of the capacitor to the opposite voltage value now takes place in accordance with the curve EF. During this period of time, the current i11 i flows through the auxiliary valve. At time C, the slave anode is released, and at time D it has taken over the full load current. At time G or at the latest before the start of the next commutation process, the auxiliary valve Y112 is ignited, whereupon the capacitor recharges itself and is now ready for the next commutation process. The current 412 flows through the auxiliary valve V112. It can be seen that the intermediate time between the overlapping sections ü1 and ü2 is no longer dependent on the level of the load current, but is only determined by considering a sufficient deflation time OE. This deionization time can be kept so long, even with the highest load on the converter, that there is no longer any need to fear through-ignition of the detached anode. The speed at which the capacitor recharges between points E and F depends on the natural frequency of the oscillating circuit formed from its capacitance and the inductance of the choke L. The speed of recharging is limited during this period of time only with regard to the load capacity of the auxiliary discharge vessels hH1 and h112, in which the current naturally reaches a higher peak value the faster the recharging takes place.

4 shows the commutation process in a device according to the invention shown for inverter operation. A fundamental difference compared to the commutation process in rectifier operation does not exist, and the indicated letters have: exactly the same meaning as in Fig. 3.

From what has been said above, it can be seen that a special charging voltage source is not required for the commutation capacitor. However, the application of the invention for converters whose discharge paths are arranged in a Graetzian circuit is particularly simple. In this case, one and the same commutation capacitor can be used alternately in the two groups of discharge paths of the Graetz circuit to extinguish an anode, the charge reversal of the capacitor between the individual commutation processes, which is necessary for zero-point switching, is omitted. An exemplary embodiment for this is shown in FIG. 5. The converter consists of two groups of discharge paths hl ', l2 , h3 and hl ", h2', VJ / ' The capacitor K has one assignment directly at the zero point of the secondary transformer winding. hi 'connected to the two DC poles of the converter arrangement. In parallel with the capacitor, there is again a throttle L in series with two auxiliary valves h11 and h11' connected in parallel in opposite directions.

Assume that the capacitor K is charged so that its upper occupancy has positive and its lower negative potential. If now a discharge path of the left group, z. B. hi, deleted ", the auxiliary valve VL 'is released. The commutation process now takes place exactly as shown in FIG Rather, after the first commutation process has ended, the capacitor is charged so that its voltage has the correct sign for a subsequent commutation process in the other discharge path group, for example to delete the discharge path V, "*. This commutation process is initiated by igniting the extinguishing valve VJ, the rapid charge reversal of the capacitor via the throttle L now being initiated by igniting the valve h11 '.

Since both commutation devices according to the invention are the starting times the first and the second commutation can be changed independently of one another, can determine the active power in both rectifier and inverter operation and the reactive power can be controlled separately from each other. The establishment after the invention can also be used to switch off the inverter in the event of malfunctions or short circuits on the AC side. In this case all will Discharge routes blocked, with the exception of the extinguishing valve, which is currently burning or is about to ignite. Commutation then occurs between one of the main anodes after the extinguishing valve in question, after which the The extinguishing valve burns until the direct current has dropped to zero. Since the Capacity of the quenching capacitor is relatively large, loads: I this one only on a low voltage.

It may be advisable to use the throttle flush L with highly saturated Equip iron core. This gives the current flowing through the auxiliary valves a more favorable course, and there is the risk of reignition for the auxiliary valves significantly reduced. As a result of the short but high current surges that are passed through the auxiliary valves flow, a considerable residual ionization could arise in these namely reduces the resistance to flashback. Since the course of the flowing through the auxiliary valve Current, if the choke is strongly saturated, no longer, as in Fig. 3 and 1, .approximately sinusoidal, but a pronounced peak possesses, so in this case is the point in time at which the over the throttle leads Parallehveg to the capacitor is released, to be brought forward accordingly.

The same goal, the risk of re-ignition caused by residual ionization for the auxiliary valves can also be achieved by the Capacitance of the commutation capacitor selects relatively small, where .then the throttle I_ no longer needs to be designed as a saturated throttle. Under certain circumstances it can even be without an iron core. To .that used for deionization; g to keep the available time i5E (cf.Fig. i, 3, .4) at a sufficient size, In this case, the capacitor must be charged to a higher initial voltage (Point A), which can be achieved by a suitable choice of the position of point C. This does not change anything in the circuit according to the invention, and it remains the same Commutation process independent of the load:

Claims (8)

PATENT CLAIMS: i. Device for forced commutation of converters, in which the load current of .the detached anode is initially triggered by a extinguishing valve connected in series with the precharged commutation capacitor on .the commutation capacitor and then from this to the releasing anode passes, characterized in that parallel to: the capacitor an additional Current path is provided via a choke, which after the end of the power takeover released on the capacitor by igniting an auxiliary valve located in it and the charge reversal of the capacitor, which was previously only due to the load current occurred, accelerated. 2. Device according to claim i, characterized in that that the capacitor is dimensioned so that its voltage even with the highest load current still greater during a time sufficient to deionize the detached anode remains as the phase voltage of this anode and the release of the parallel current path to him only after this time has elapsed. 3. Device according to claim i, characterized characterized in that the releasing anode is only released after the in the auxiliary valve lying in parallel flow takes place. d .. Device according to claim 3, characterized; that the release of the releasing discharge path in Dependence on the voltage on the capacitor takes place as soon as this occurs during the transfer reached a predetermined value. 5. Device according to claim i, characterized in that that in the parallel flow path there are two auxiliary valves connected in parallel in opposite directions, which are released alternately. 6. Device according to claim 5, characterized in that that when the converter is switched to zero, the isolating circuit is between zero and the cathode of the converter is located and the second auxiliary valve is in the parallel flow path to the capacitor between two successive commutation processes for the purpose of renewed reloading of the capacitor is released. 7. Device according to claim 5, characterized in that with converters in Graetz circuit the one Kon.densatorbeligung with the transformer zero point, the other via an extinguishing valve each with both DC poles is connected and the two auxiliary valves in the P.arallelstromweg alternately in successive Commutation processes are released. 8. Device according to claim i, characterized characterized -that the one lying in the parallel current path to the commutation capacitor Choke coil is equipped with an iron core, which is under the influence of the Charging current of the capacitor is very saturated. G. Device according to claim i or one of the following, characterized in that in the parallel current path to the commutation capacitor lying auxiliary discharge paths are only ignited when the load on the converter is below a predetermined limit. ok Procedure for extinguishing a converter in the event of a fault using a device according to one of claims i to 8, characterized in that all discharge paths with the exception of the extinguishing valve which is currently burning or which is to take over the power supply.