DE714479C - Arrangement for indirectly forced commutation of converters - Google Patents

Description

Arrangement for indirectly forced commutation of converters With indirectly forced commutation of converters by means of one or more transition and valve sections that temporarily take over the load flow from fed by a capacitor, it is known to use the capacitor with the transition path to be connected via a transformer. It has been used in practical experiments with such Circuits found that although they work satisfactorily, so long as the main valve routes each other in quite regular order, taking over from one another, a random interruption of the regular current routing of the main valve sections slightly except for the transition sections Can make an impact. At least with the current state of the art you have to go with it anticipate such accidental power interruptions in the main valve sections, and it is desirable that the work of the transition sections not be affected will. According to the invention, in the connection between the commutation capacitor and each transformer winding connecting the same with the transition sections switched on a valve line, by means of which this connection in suitable Moments can be interrupted.

Four embodiments of the invention are shown in the drawing in Fig. i to .4 shown schematically, while Figs. 5 and 6 show two timing diagrams on the Show the mode of operation of the circuit according to Figure 4.

Fig. I shows a two-anodic rectifier or inverter with the two main anodes 2 and a transition anode 3, which are arranged in the same vessel i is. Between the zero point of the transformer winding feeding the main anodes 4. and the transition anode 3 is one winding 5 of a commutation transformer switched on. At the center of the other winding 6 this Transformer is connected to the Konnnutierungskondensator 7 with its one pole, while its other pole has two oppositely reported valve sections 8, 9 is connected to the two ends of the winding 6. Every two live periods the Überganbsanorle 3 one of the two valve sections 8, 9 is kept open, whereby the upper and lower halves of the transformer winding 6 alternate with the corresponding one Secondary current leads. When the upper half of the winding carries the current, it changes the charge of the capacitor from - [- to - on the left plate, and if the lower half of the winding carries the current, the capacitor is recharged in the opposite sense. Each The valve is blocked as soon as the current flowing through it has dropped to: zero is, and the charge of the capacitor is therefore always up to the next comminutation course maintain.

To the capacitor initially after a longer or shorter interruption during operation, you can create a voltage duel To in series with a resistor and use a special valve section 11, which is in the same vessel as the valve section g connected to it on the cathode side can love.

Fig. 2 shows an example of the application of the invention to a six-anode power converter, which consists of two three-anode groups with current clean and thus works three-phase. The valve vessel is here with 21, the main anodes with 22, ciie transformer windings with ad. and the stream clean with 2o. For each three-phase group there is a transition anode 23 with a transformer winding 2, which alternately conduct the current, since a lommutation within one three-phase group is always followed by a communication within the other. A transformer winding -26 cooperating with the two windings 2,5 is connected to the commutation capacitor 27 via two oppositely switched valves 28, so that the capacitor is discharged in both directions via the winding 26 and is charged un.rl after each complete charge can be locked again. An arrangement for introducing an initial charge can be present here as in Fig. 1; it is not specially shown. The mode of operation is otherwise the same as that of the circuit according to FIG.

Fig. @ 3 shows a six-phase, six-anode rectifier or inverter with a transition anode 32 for each main anode 31. Each transition anode is with the associated main anode directly conductively connected, and is in this connection a transformer winding 33 switched on. The commutation capacitor is here divided into two 1? inlzeitei13d., 33, which are preferably of different sizes and which can each be switched on for themselves or together, to deal with fluctuations in load Take ziz into account. Each such capacitor is across two oppositely directed Valve sections 37, 38 connected to two tVicklunben 36 on the same transformer as the tVicklunben 33 love. The valve sections 37 are located in the main vessel. the valve. stretch 38 on separate slopes. The mode of operation is that of the circuit according to Fig. i essentially the same. Through the transformatory connection via Check valves was also here: the advantage achieved. that a greater number of transition anodes full of a single capacitor group divided into different units can be fed, d. H. the number of units in this group becomes independent of any number of transition sections.

Since the valve sections in this circuit only allow a single direction of passage of the 1lagnetisierungsstromes of the commutation transformer, it can be useful, in order to better utilize the transformer iron, to superimpose a DC excitation on this current, which counteracts it, so. that the iron is saturated approximately equally in both directions. For this purpose, a winding 39 fed by a direct current duel 30 is provided. A similar additional excitation can also be useful in Fig. 1 or in general in such situations where all comminuting current impulses conducted through the transformer have the same magnetic flux direction.

Fig. D. Figure 3 shows an example of the application of the invention to a Einphasenstroinricliter, which has an alternating energy, ie tircligang in both directions between two 'networks, be it only during partial periods, as in the case of a phase shift between the current and the clamping ring, or for longer periods of time. For the direction of energy from the direct current poles -o to the alternating current poles .11 -serve the main anodes .12. .13, 44, .l> and for rlie entbeg; -networked direction of energy the main anodes 46, .17, 48, .1g. The circuit is also easy to understand. that they during certain partial periods iin KU.rz_-schluß can work, creating a graduated curve shape is obtained on the currency exchange side. During these short-circuit periods all two main anodes work alternately. The current path during the different sub-periods as well as the effect of the transition anodes show the diagrams in Fig. 5 and 6, in which for each sub-period the respectively working anodes are indicated. Fig. 5 shows the current curve at a low and Fig. 6 shows the curve with a larger phase shift between current and voltage on the AC side. The staggered curve denotes in both diagrams the unsmoothed alternating voltage and the sinusoidal curve the alternating current. the Commutation voltages superimposed on the voltage curve in the case of forced co-alignment are also shown.

Let the beginning of a period be that point in time, whereby more positive AC voltage and positive or becoming positive alternating current, i.e. with the Direction of energy from direct current to alternating current network., The product of alternating voltage and alternating current is just zero before it gets positive values. The current goes then from the positive pole of the direct current network, for example via the anode 42, the alternating current network and the anode 45 to the negative pole of the direct current network. After a certain period of time I want one, in order to generate a suitably staggered voltage curve, to work in a short circuit pass over which transition .by forced commutation must take place. Of the Commutation capacitor 6o may be positively charged on its lower surface. The commutation is then initiated by releasing the transition anode 5o, which then the anode 4a peeled off. The current overflows during the transition period the anode 5o, the alternating current line and the anode 45. After the capacitor has discharged and because of the relative constancy of the current with opposite polarity, so on its lower surface has been charged again negatively, the current becomes of the anode 46, which has now been released, taken over by itself, which likewise like the still live anode 45 to the negative pole of the direct current network is directly connected. The alternating current circuit is then via the valve sections these two anodes short-circuited, and the unsmoothed voltage of the same decreases to zero.

The next stage of the process according to Fig. 5 occurs when the alternating current its direction changes while the alternating voltage is still zero. This current commutation goes by itself to anodes 47 and 44 which are the only ones .the instant ones let the current pass in the new direction. If a certain time after the last Forced commutation has passed, the anode 43 is released, which is connected to the The positive pole of the direct current network is connected and therefore the current from the to the .Minuspol connected anode 47 takes over by itself.

After a further time, forced commutation is necessary again to short-circuit the converter, which is now connected with its two poles to the positive pole of the direct current network. For this purpose, the transition anode 52 and the auxiliary anode 58 are released, whereby the capacitor, whose upper pole is now positive, discharges through the transformer winding 56 and the auxiliary anode 58, the latter in analogy to the valve sections 8, 28 and 38 in Fig. z, a or 3 has kept the capacitor blocked since the last charge. The capacitor voltage is transferred via the winding 56 to the transformer windings 54 and 55, which are connected to the transition anodes 52 and 53. The released anode 52 now takes over the current from the previously active anode 44 and leaves it to the anode 48 after the capacitor has been charged, which is why a new short-circuit circuit from the positive direct current pole via the anode 43, the alternating current circuit and the anode 48 back to the positive direct current pole goes. - The next stage is the current commutation that takes place automatically from the anodes 43, 48 to the anodes 42, 49 with the connection on the direct current side unchanged. Finally, there is a spontaneous commutation from the anode 4.9 to the anode 45 as soon as the latter is released, since the cathode of the latter is more negative than the cathode of the former. A whole period has passed through here, and the same process begins again.

If, as shown in Fig. 6, one has such a large phase shift of the current works in relation to the voltage so that current commutation does not take place, before the voltage reaches a finite value in the opposite direction towards the has reached earlier, certain changes to the described mode of action occur in that the converter then acts as a rectifier for certain partial periods is working. The anodes 46, 45 then operate during the entire first short-circuit period and the anodes 47, 44 throughout the second. At the end of the first short circuit period a forced commutation must take place to the current from the anode 45 to To transfer anode 49, and for this one uses the transition anode 53, which then Via the transformer windings 55, 56 the capacitor 6o from negative to positive Reloading potential of the lower surface. The potential of with the Anode 53 connected via the winding 55 anode 49 is increased at the same time so far, that she can take over the electricity. which from the cathode of the anode 49 to the positive pole of the direct current network, i.e. in the rectifying direction, flows.

The next stage of the process becomes the electricity quotation Direction of change, which from the anodes 49, G'.6 to the anodes .I3, 44 spontaneously goes when the alternating current changes direction. When the converter should be short-circuited next time, forced commutation is also necessary, and for this purpose the transition anode 51 is used, through which the current from the anode 4.3 is transferred to the anode 4.7, while at the same time the potential of the lower Coating of the capacitor 6o from -I- to - is changed. According to this, with unchanged Current direction the voltage can be increased to its full value, and used for this one forced lioniinutierung by means of the transition anode 52, whereby the current from 4.1 to .18 while at the same time reloading it goes over to the capacitor. Live are now the anodes d.8 and .1.7. Eventually there is a spontaneous current commutation from these anodes to the anodes 42, 45, thus ending the period.

Here, too, the valve section containing the anode 58 blocks the capacitor 6o after each reloading, so that he cannot unload himself, even if one Ignition fail and. the rhythm of the whole thing should be disturbed by it. in the Contrast. to the circuits according to Fig. 1 to 3 is in Fig..l only a single one such a shut-off valve is necessary. However, this simplification can just as well apply to the rest Embodiments are carried out if you also there the capacitor in the a sense immediately via a transition anode and. in the other sense about one Transformer discharges.

In @bb. d. Some auxiliary valve sections are also shown in order to bring about an oscillating additional load on the capacitor 6o, which serve to compensate for its voltage fluctuations when the useful load fluctuates. For one direction of discharge an anode 59 is used, which ii: can sit in the same vessel as the anode 58, and which is finitely in series with a choke coil 61, and for the other direction of discharge the anode 62 is used, which is in the same vessel as the anode d. 8 and .Ig sits and is in series with a choke coil 63. Finally, in Fig. D. a parallel capacitor 6.1, shown on the direct current side, which serves to compensate for the main part of the power pulsations which the single-phase load brings with it.

Claims (5)

PATENT CLAIMS: i. Arrangement for indirectly forced commutation of converters by means of one or more of the load current temporarily taking over Transition paths, of which at least one finite condenser through a Transformer connected, characterized in that in the connection between the capacitor and each of it g: -feed transformer winding a \, eritil segment lies, through which this connection can be broken at appropriate moments. 2. Arrangement according to claim i, with only one walkway section, characterized in that that the capacitor is connected to the middle of a transformer winding, the two halves of which he alternately feeds when unloading and loading. 3. Arrangement according to Claim i, in which all commutation current surges carried over by the transformer cause a rectified magnetization of its core, characterized in that that the transformer with a DC excitation from opposite direction is provided. Arrangement according to claim i, characterized in that one or more Transition sections in front of the capacitor directly and the remaining or the remaining transforming be fed. 5. Arrangement according to claim i with divided into several units Condenser and stretch with several transition s. characterized in that the number of capacitor units is independent of the number v! in transition sections is.