DE739625C - Arrangement for the forced commutation of the anode currents of converters - Google Patents

Description

; Arrangement for forced commutation of the anode currents of converters Power converters, be it rectifiers, inverters or frequency converters, which may work with the consumption of reactive power, d. H. either a primary AC grid load inductively or on a capacitively loaded secondary alternating current network work, can transfer the current from an anode to the commutate next. If the requirement is that the converter has reactive power should generate, d. i.e. either phase-compensating to a primary alternating current network act or work on an inductively loaded secondary network, the Commutation in some way- be forced because the anode that carries the current should take over (hereinafter referred to as the incoming anode), in the transitional moment otherwise always a lower potential than the previously current-carrying one (in the following called the ceding). In patent 671,651 one arrangement became one Forcing commutation described, consisting of a transition anode, the one is exposed to short-term positive and negative voltage wave in such a way; that it takes over the current first from the outgoing anode and then to the incoming one hands over. The arrangement was in the patent only for inverters and frequency converters described. The present invention relates to the use of an arrangement for forced commutation of the anode currents of converters by means of an auxiliary or Transition anode according to patent 671 651, which has a higher voltage than the anode to be detached in the power supply, then the Current conduction takes over and finally after humiliation of her Voltage - under the main anode next in the phase sequence the current to the latter outputs, in rectifier circuits for phase compensation of the feeding AC network.

Some embodiments of the invention are shown in Figs. 1, 3 and 5 to 8 of the drawing shown schematically, while Fig. 2 and 4 corresponding Show timing diagrams.

Fig. I corresponds to Fig. I of the main patent and differs from this essentially only in that the direct current circuit contains a load, indicated schematically as a resistor, instead of a current source, and the alternating current circuit contains a current source indicated between its transformer terminals instead of a load . Incidentally, the main anodes of the converter, also in Figures 3 and 6 with 5 and 6, their grid with 25 and 26, the transition anode with 4, its voltage source with 3, the cathode with 13, the equalizing inductor in the DC circuit with 14 and the winding parts of the transformer are denoted by 15, 16, 17.

The mode of operation of the arrangement according to Fig. I is indicated schematically in Fig. 2. Here, E,;, EG and E4 denote the voltages at the anodes 5, 6 and q., All related to the transformer zero point. Without the aid of the transition anode 4, the current would only pass from the anode 5 to the anode 6 shortly after the voltage E'5 has dropped below the voltage Es, ie in the single-phase embodiment shown after the zero crossing of both voltages. On the other hand, if you press the anode a. the voltage E4, which should preferably be adjustable in phase; so this anode takes over the current as soon as E'4 is above Eä and the transition anode is released from its grid. E4 is then quickly lowered to below the value of EG, the anode 6 taking over the current if its grid allows this. The amplitude value of E4 should be slightly higher than that of Eä or EG so that commutation is also possible when the voltage of the working anodes has its maximum value, ie a quarter of a period before the zero crossing. If you turn E4 to an even earlier phase position, you get the reversal direction, ie the mode of operation described in the main patent.

If one only expects to let a converter arranged in the manner just described work as a rectifier, one finds that it is not necessary that the voltages of the main anode grid are based on the transition anode, but the former can also have a fixed phase position. It is only important that the grid of the outgoing anode has a negative potential during commutation and that of the incoming anode has a positive potential. If the voltage of the transition anode itself can be regulated as desired, this condition is always fulfilled if the grid voltage of each anode is about a quarter period or more early than the anode voltage. In this way phase-shifted voltages E "" and E = 6 of the grids 25 and 26 are also shown in Fig. 2, but refer to the cathode potential as the zero line, while the anode voltages refer to the transformer zero.

If a capacitor is used as the voltage source for the transition anode, as described in several embodiments of the main patent, one can by connecting a choke coil io in parallel to this capacitor 7, as shown in Fig. 3, and by working the transition anode 4 during correspondingly measured time periods the desired voltage wave in a very simple way without the help of a special valve section, as shown in the timing diagram of Fig.4 shows. The upper part of this figure shows the current i7 of the capacitor, the lower part the tension 'e7 of its lower coating compared to the upper one. Of the The lower capacitor plate asked for the positive voltage7 at the moment of release the transition anode. If you look at the period of overlap between the outgoing The anode and the transition anode, the capacitor then immediately begins to move by discharging a current i7, which is the difference between that through the choke coil 14 approximately constant held load current and also approximately constant Represents current through the inductor i o. By setting the Grid voltage for the occurring main anode is now made the discharge time t "for the capacitor so long that its lower layer receives a negative voltage .e7, whose numerical value, taking into account the losses, is the value of the original voltage e7 should exceed something. Then let the incoming main anode take over the current, so that the transition anode is de-energized.

The inductor coil io connected in parallel with the capacitor 7 should be so large that the current flowing through it is not significantly changed during a period. All the time it carries a current in the direction of the transition anode and from the value silo, and during the time tu the current in the anode becomes equal to the sum of the current of this inductor and the discharge current i7 of the capacitor. When the current through the transition anode ceases, the current through the choke coil is forced to take its way through the capacitor and charge it with a positive voltage on the lower layer, so that the initial position is restored.

Instead of the end of the choke coil facing away from the transition anode directly to the upper layer of the capacitor 7 or to the transformer zero point to connect, @ as shown in Fig.3, you can @es at a point higher Connect the potential of the main circuit, whereby the mean value of the in Fig. 4 the capacitor voltage shown receives a correspondingly increased potential; d. H. the transition anode does not need to assume such a strongly negative potential, but can even remain positive in certain cases. Especially with low Control of working multiphase converters needs the potential of the Junction anode generally does not become negative for commutation itself, and it is then desirable that the negative value also for the charge of the current source is not necessary. In general it can be said that if the discharge of the Transition anode only drives so far that its mean potential is slightly lower than the mean potential of the rear end of the charging inductor facing away from the anode the charge does not require an additional power source or valve section, but by itself. The connection point of the rear end of the choke coil can the cathode itself or a point between. this and the transformer zero point if such a point is accessible.

To interrupt the discharge at the desired moment, you can possibly the "grid potential of the occurring main anode from the potential of the Make transition anode directly dependent, for example by changing the capacitor voltage reversed via a transformer, this voltage is superimposed with a suitable basic voltage and press it on the grille.

To the capacitor 7 of the transition anode without the help of a special To charge the valve section, you can also use the circuit shown in Fig. 5 Use capacitor, which also has the advantage that it is independent Commutation of two rectifier groups connected by a suction throttle is used can be, which is why it is shown in the application to such. The rectifier can be connected to a three-phase network and is in two three-phase groups with separate zero points connected by a suction throttle 40. With the Both group zero points are anodes through transformer windings 41, 42 43, 44, and a third winding 45 of the same transformer is connected to the Capacitor 7 connected. The currents of the two transition anodes load here the capacitor alternately in both directions, which is why for its renewed Charge no special choke coil is required. The capacitor can also be in two Capacitors are divided, each with a transformer winding directly can be connected. However, through the trans.-Jormatory circuit you get the possibility of the capacitor voltage independent of the converter voltage to choose. The circuit enables the use of two separate zero points, but it does not presuppose it, since the two windings 41 and 42 @ both can also be connected to a common zero point.

The two arrangements shown in Fig. 3 and 5 for supplying the Transfer anodes can also be used for inverting and frequency converting as for rectification. They work satisfactorily as long as the power converter is used works steadily, but since they both require a permanent state, they can e.g. B. ineffective if there is no ignition. One of that limitation Free arrangement is shown in Fig. 6. It has been worked out for rectifiers and corresponds to the one that applies to inverters (Figure 4 of the main patent). Deviating from this Figure is the anode of the blocking cell 12 in relation to that of rectifiers positive cathode to the transformer zero point, or generally to the cathode side the equalizing throttle 14 of the DC circuit connected. The lower covering of the capacitor 7 is positively charged from the cathode when the blocking cell 12 is released, and through the inductor io this charge is increased to a higher level Value than the DC voltage - driven by the rectifier. When sharing the transition anode 4, the capacitor discharges, as usual, through it. The amendment Fig. 4 of the main patent, which is shown there in Fig. 5 and which consists of that the blocking cell with a transformer connection with the transition; anode is accommodated in the main vessel, can of course in a corresponding manner can also be applied to the embodiment just described.

In the case of converters with several connected by a suction throttle, el Zero points can you can also use the circuit shown in Figure 7, - which was applied there to a rectifier, but also to inverters is possible. Like Fig. 5, it has two three-phase groups that are controlled by a suction throttle 4o are connected, between the zero point and the cathode the direct current load i and the compensation throttle 14 are switched on. The suction throttle has two secondary windings 47, 48 provided between the positive coating of the capacitor 7 and the transition anodes 43 and 44 are switched on, while the negative coating of the capacitor immediately is connected to the zero point of the suction throttle. The charge on the capacitor takes place here via a special valve circuit with a blocking cell 12 and one Choke coil i o, - as in Fig. 6, and must take place six times during each period. Compared to Fig. 5, the circuit according to Fig. 7 has the advantage that if necessary the resulting primordial symmetry between the two three-phase groups is not a non-uniform one Magnetization through the winding 47, 48 can arise. If this circuit is on a power converter is applied which is divided into three by a three-phase choke coil connected two-phase groups, the capacitor current will only be 2/3 of the in the illustrated version amount to the existing value, which is why the circuit in certain cases it is recommended.

Finally, Fig. 8 shows an example of the application of the invention a frequency converter. With this one can always have two different commutation processes differentiate, namely that in the cycle with the period change of the primary alternating current taking place, which can be viewed as a rectification, although the direct current usually only between the cathode and the transformer neutral point by a choke coil 58 flows, and which take place in time with the secondary alternating current, end the is to be regarded as a pure alternation. The latter commutation process can for example by transition sanod.en according to Figure 7 of the main patent, with which figure the figure 8 described here in relation to the general circuit agrees, but also in the manner shown here by phase compensation or an oscillating circuit on the AC side, which is created by a capacitor 5o and a choke coil 5 i is indicated. In the rest are the designations the parts shown are the same as in Fig. 7 of the main patent, i.e. H. 31 for the primary and 32 for the secondary main transformer, 2 for the actual load circuit, 35 for the working anodes and 13 for the common cathode.

According to the invention, the primary (rectifying) mutation takes place here with the aid of two transition anodes 53, 54, through which capacitors 55, 56 discharge. This? can via the middle of a choke coil 57 connecting its anode sides be charged to a common potential in the manner already described. In this way, the converter can phase compensate for the primary alternating current network works.

Claims (7)

PATENTANsrRtlt; iii :: i. Use of an arrangement for forced commutation the anode currents of converters by means of an auxiliary or transition anode Patent 671 65i, which has a higher voltage at the time the commutation begins than the anode to be detached in the current conduction receives, then the current conduction takes over and finally, after lowering their tension below the next in the phase sequence Main anode delivers the current to the latter, in rectifier circuits for phase compensation of the spewing alternating current network. 2. Arrangement according to claim i, characterized in that the phase position of the grid voltages of the main anodes is shifted in advance of that of the associated main anodes by about a quarter period and remains shifted by this amount for each bet ne 'bsstatus of the rectifier. 3. Arrangement according to claim i in Veriv: ending of a capacitor as a current source for the transition anode, characterized by such a grid control for the incoming anode that it does not take over the current from the transition anode before the capacitor has discharged so far that the mean potential of the junction anode becomes slightly lower than the potential of one with the junction anode through a large one Inductance connected point of the main circuit. 4. Arrangement according to claim 3, characterized in that the inductance is directly parallel to the capacitor is switched and that the discharge of the latter is driven so far that the mean potential of the transition anode is somewhat negative in relation to the transformer zero point will. 5. Arrangement according to claim 3, characterized in that the 'grid voltages the main anodes on the voltage of the Commutating capacitor directly are dependent. 6. Arrangement according to claim i when using a capacitor as Power source for the transition anode, characterized in that two together there are inductively coupled transition anodes that alternately carry the current and thereby one or more capacitors: alternately with different polarity :charge. 7. An amendment; ! the arrangement; according to claim 6 for power converters with two or more groups of anodes connected via a suction throttle, thereby characterized in that the transition anodes are transformed via the suction throttle are coupled and connected to a capacitor which is always in the same Direction discharges and charges via a special auxiliary device. B. Arrangement for charging the feed capacitor for the transition anode according to claim i, characterized in that characterized in that, a; special auxiliary valve is provided, its anode directly connected to the cathode side of a compensation choke lying in the direct current circuit is.