SE436238B - Rectifier system with at least two series-connected rectifier bridges - Google Patents

Description

10 40 7812920- “2 2 occurs in the realization of the inventive arrangement. 7 The invention is described in more detail below with reference to attached drawings. There, Fig. 1 shows the wiring diagram for a first embodiment of the rectifier system according to the invention,> Fig. 2 voltage and current profile to clarify the action the method of the plant according to Fig. 1, Fig. 3 the wiring diagram 1 <° PP ~ diagram for an experimental circuit with a rectifier system for a second embodiment of the rectifier system, according to the invention and fig. 5 is a diagram for illustration of the magnitude of equivalent disturbance currents, measured by the rim circuit of Fig. 4. 2 Fig. 1 shows the wiring diagram for a first embodiment of the invention. The rectifier system shown in the figure is so built, that each rectifier circuit is divided into several controlled rectifiers. rectifier bridges 311 and 321, resp. 312 and 322. In accordance herewith also the secondary associated with each rectifier circuit is the winding divided into several parts, so that a first and a second rectifier circuit is located on the left resp. right side of the primary winding 200 of the transformer 2. In the first rectifier circuit then the series-connected rectifier bridges 311 and 321 are on theirs DC side connected to a DC circuit with a smoothing circuit Reactor 41 and a DC motor 51. Furthermore, the AC clamps are on the rectifier bridges 311 and 321 connected to the associated secondary windings 211 resp. 221. In the second rectifier circuit the controlled rectifier bridges 312 and 322 are connected in series with each others and on their DC side connected to a DC circuit with a smoothing reactor 42 and a DC motor 52. Respectively AC terminals on the two rectifier bridges 312 and 322 are connected to associated secondary windings 212 resp. 322. Pri- the measuring winding 200 is connected to an AC source (not shown).

Phase control in such a circuit is usually done in this way way, that the phase positions of the two controlled rectifiers in each rectifier tarkrets is controlled one at a time. For example, the controlled lik- the rectifier bridge 311 and then the rectifier bridge 321 at the end that of the control of the rectifier bridge 311. Further controlled in it second rectifier circuit first the rectifier bridge 322 and thereafter the rectifier bridge 312 when the control of the rectifier ceases 322. value than the reactance of the secondary winding 212, as well as the secondary winding In this case, the reactance of the secondary winding 211 has another The reactance of the secondary winding 221 differs from that of the secondary winding 222 40 (A 78112920-2 reactance. The above two differences in reactance lead to different mutation times for the two rectifier circuits, thereby transmitting the tone components of the current through the current source are reduced.

For example, in the event that two (left and right) rectifiers circuits together feed a single load, it is desirable that the rectifier circuits emit an equal output power. In such a case is that recommend that the two rectifier circuits be given the same internal total reactance but has different reactance characteristics. This means that in Fig. 1 the opposite left and right secondary windings are carried out with equal internal reactance, while the upper and lower reactants The secondary windings have different internal reactances. More particularly the internal reactance of the secondary winding 211 is made as large as the the reactance of the customer winding 212, as well as the secondary winding 221 internal reactance equal to the reactance of the secondary winding 222, the internal reactance of the secondary winding 211 has a value other than the the reactance of the customer winding 221. About the rectifier bridges 311 and 321 is controlled in that order in the left rectifier circuit, and the rectifier bridges 322 and 312 are controlled in that order in the right the rectifier circuit, the two secondary windings, which are connected with two rectifier bridges, which are simultaneously controlled, different with respect to their internal reactances. Thus the left and the different right rectifier circuit from each other with respect to commutation time it, thereby obtaining the advantage that the harmonic components in the feed current can be reduced.

Pig. 2 shows the mode of operation of the circuit described above. the arrangement in case the primary and secondary currents are such, that both the controlled rectifier bridges 311 and 322 emit maximum ground voltages, and the controlled rectifier bridges 321 and 312 emits arbitrary voltages. In the figure, i111 indicates electrical current on the rectifier bridge 311 AC side, i112 electric ulrñm på lilríllnrhrygg fl n fi 371 vüxelsïrömssidu, i1¿1 elektrisk current on the rectifier bridge 322 AC side, i122 electric current on the rectifier bridge 312 AC side, í1 the electric current, which passes through the primary winding ZOO of the transformer 2, and v grazes the two rectifier bridges 311 and 322 with the same ignition angle the applied alternating voltage. As can be seen from the figure equal to zero and emits maximum voltage. In this case, one is achieved shift ¿lt1 between the times when the respective commu- ring ceases. Meanwhile, the rectifier bridges 321 and 312 are below control, and a shift (Eat, is achieved relative to the time cessation of the commutation in order to thereby compensate 40 7812920-2 and 24 the offset -¿§t1. This results in the output power from it the left rectifier circuit and the output power of the right rectifier the circuit equalizes. Because of this, differences occur in the overlapping angles of the commutation and between the firing angles, whereby harmonic components in the primary current can be reduced.

Pig. 3 shows the wiring diagram for a second embodiment of the rectifier system. This embodiment is a modification of the embodiment shown in Fig. 1, in that secondary winding 211 and 212 in Fig. 1 210, and also the secondary windings 221 and 222 are combined to are combined into a single one, namely 7 a single one, namely 220. Thus, the rectifier bridges 311 and 312 AC terminals connected to the common secondary winding 210, and the rectifier bridges 321 and 322 of the rectifier bridges 321 and 322 are connected to the common secondary winding 220. The remaining The circuit circuit is the same as that shown in Fig. 1 such an embodiment of the coupling rectifier bridges 311 and 321 in the left rectifier circuit and the rectifier bridges 322 and 312 in the right rectifier circuit is controlled in said order, the plant can, if necessary, be controlled so that the two secondary connected to simultaneously controlled rectifier bridges, have mutually different internal reactances, so the above-mentioned advantage is obtained even in this case.

Fig. 4 shows the circuit diagram of an experimental circuit, which is suitable for confirming the advantages of the invention, and may also be used used as a further embodiment of this. In the experimental circuit includes two separately operating transformers 21 and 22, which are * connected in parallel and on the primary side connected to an AC source, and which on the secondary side are connected to separate, control then rectifier circuits. In the experimental circuit, the transformer has 21 secondary windings 211 and 2120 - 2160, while the transformer 22 has secondary windings 221 and 2220 - 2260. To the one with the transformer the rectifier circuit connected to the feeder 21 hears a series connection of a controlled rectifier bridge 311, uncontrolled rectifier bridges 3120 - 3160, a smoothing reactor 41, a resistor 81 and a direct current motor 5.

The rectifier circuit connected to the transformer 22 includes one series connection of a controlled rectifier bridge 321, uncontrolled rectifier bridges 3220 - 3260, a smoothing reactor 42, a resistor 82 and the DC motor 5. The DC motor 5 is common to the two DC motors. the rectifier circuits. However, since the internal resistance of the motor 5 is considerably lower than the resistance of each of the resistors 81 and f, p 7812920-2 82, it can be considered that the terminal voltage of the motor 5 is independent of the play of the current passing through the motor 5. Thus one can also consider that the two rectifier circuits each have their own circuit and together feed a load. With 9 is a load designated, which is driven by the DC motor 5. As shown in the figure are the uncontrolled rectifier bridges 3120 - 3160 and 3220 - 3260 cup- " added the transformers 21 and 22 via switches S12 - S16 resp. S22 - S26. The switches are used as follows.

Thus, an operation is to be described in which the output is gradually increased. the power of the DC motor 5 from zero in the first rectifier the circuit. First, all switches S12 ~ S16 are kept open, 0Ch the controlled rectifier bridge 311 is operated with phase control, during setting the direct current to a desired constant value; for increase of the output voltage from the rectifier bridge 311. As soon as this output voltage reaches the maximum value, the switch S12, .and the control signal are closed for the controlled rectifier ridge §11 is removed. Hereby comes the output voltage from the rectifier bridge S120 to reach its maximum value, while the output voltage from the controlled rectifier bridge 311 returns to zero. If the voltage across the secondary winding 211 is made equal to voltage across the secondary winding 2120, a takeover or switching the output power between the rectifier bridge 3120 and the controlled one rectifier bridge 311. After this changeover, the rectifier bridge 311, and when its output voltage reaches the maximum value, occurs next shift. In this case, the switch S13 is closed, so that the output voltage from the rectifier bridge 3130 reaches its maximum value, and the switch S12 is opened, the control signal for the rectifier bridge 311 being so that the respective output voltages from the rectifier bridge 3120 and the controlled rectifier bridge 311 both return to zero. In it case the voltage across the secondary winding 2150 is made twice as large as the voltage across the secondary winding 211 or 2120, they are taken over voltages taken from the controlled rectifier bridge 311 and rectifier bridge 3120, by the output voltage from the rectifier bridge 3130.

Then the switches S14, S15 and S16 are closed in turn, at the same time as the output voltages from the rectifier bridges 311 and 3120 ggupprepat is controlled. If the voltage across each of the secondary windings 2140, 2150 and 2160 are made twice as large as the voltage across the customer winding 211 or 2120, the change occurs nine times, while the rectifier bridge 311 undergoes phase control ten times. Further operated The rectifier bridges 321 and 3220 - 3260 and the switches S22-S26, While maintaining said voltage conditions in the secondary winding 7812920-2 -e 221 and 2220-2260 in the second rectifier circuit, at the same as in the first rectifier circuit, as well as the phase control is also repeated ten times in the second rectifier circuit. In the case of circuit the circuit according to Fig. 4 has the two rectifier circuits, which only each has its own controlled rectifier bridge, the same function_and : of 40 as two rectifier circuits, each with ten controlled rectifier brews. " to which the required results can be obtained by easily experimental. In the arrangement according to Fig. 4, differences transformers 21 and 22 from each other with respect to tansen, seen from the respective two secondary windings, namely the following pairs: 211 and 221, 2120 and 2220, 2130 and 2230, etc.

In the circuit embodiment described above, where the AC source lan emits a voltage of 200 V, a voltage of 71 V occurs over each of the secondary windings 211, 2120, 221 and 2220, and a voltage of 142 V across each of the secondary windings 2130 - 2160 and 2230 - 2260; in this case an experiment was carried out, which gave a constant current control of 15 A for each rectifier circuit at operation of a load of 375 kW.

Pig. 5 shows measured values of the equivalent interference current JP, which is included in the primary current, which passes through the primary winding the transformer in the above experiment. In the figure gives the mark along the abscissa that the steering angle changes ten times, namely each time from 180 ° to 00 in the direction from left to Right. Furthermore, curves A or B show the measured values of it equivalent interference current J in the case that only the first resp. the other rectifier circuit is operated. Curve C indicates half of each measured value (or the value per rectifier circuit) of the equivalent disturbing current J in the event that the first and the second the tark circuit is operated simultaneously. From these curves the following can be deduced: (1) When each rectifier circuit is operated separately, the equivalent E2) Den the jitter current jp during the course of a phase control. is, as shown in curves A and B, equivalent disturbance current J different for the two rectifier circuits, since the reactance in the trans- the formator winding is different for the two rectifier circuits. (3) When the two rectifier circuits are operated simultaneously, the increase becomes of the equivalent disturbance current J is small, and in total it is kept equivalent disturbance current at low level in comparison with single operation of each rectifier circuit.

In the circuit shown in Fig. 4, the switches S12 - S16 and S22 - S26 are replaced by electronic switches. Example- 7 7812920-2 In this way, all uncontrolled rectifier bridges are replaced by controlled bridges which are constructed in the same way as the controlled rectifier bridges s 311 and 321, and the typhistors included in them are controlled to and from. -_..-...-_ ~~

Claims (4)

7812920-2 8 Patent claims A rectifier system with at least two rectifier bridges (311, 321) connected in series, each connected to a secondary winding (211, 221) on a transformer device (2), at least one rectifier bridge being controllable, characterized in that at least two rectifier circuits are arranged, each formed by at least two rectifier bridges (311, 321; 312, 322), and that the secondary windings (211, 222; 212, 221) of the simultaneously controlled rectifier bridges (311, 322; 312, 321) have different large effective reactances. 1 ' Plant according to Claim 1, characterized in that the respective secondary windings for non-simultaneously controlled rectifier bridges (311, 312; 321, 322) are merged into a single secondary winding (210; 220). Plant according to claim 1, characterized in that the transformer device consists of two transformers (21, 22) to the respective secondary windings (211, 2120, 2130, 2140, 2150, 2160; 221, 2220, 2230, 2240, 2250, 2260) a rectifier circuit (311, 3120, 3130, 3140, 3150, 3160; 321, 3220, 3230, 3240, 3250, 3260) is connected. Plant according to claim 1, characterized in that the respective sums of the reactances of the secondary windings (211, 221; 212, 222) of the rectifier circuits (311, 321; 312, 322) are equal.