DE2627634C2 - Self-commutated power converter - Google Patents

Description

The invention relates to self-commutated converters according to the preambles of claims 1 or 2.

The self-commutated converter takes place, for example Applied to the three T power supply of tightening and can be part of a converter, is self-commutated so-called blocking voltage-free Power converters are from the BBC-Nachrichten, January 48, 1966. Pages 45 to 58 and from IEEE Transactions on Industry Applications. July / August 1973. Page 484 known

In the circuit according to the BBC news in 1966, there are two backup capacitors in series between the DC poles of the DC voltage source supplying the DC energy to be converted. The common one The connection point of the two backup capacitors is used to connect only one quenching capacitor exhibiting circle of mutation.

The difference is with the circuit according to IEEE Transactions 1973 only provided a backup capacitor between the DC poles and the commutation circuit is directly connected to the DC poles via two quenching capacitors.

These known power converters are no longer economical when the DC voltage fluctuates greatly be used because the commutation voltage and thus the commitment capability of the Size of the DC voltage is dependent.

It is also known to measure the voltage across a commutation capacitor of a converter arrangement to regulate (DE-OS 21 58 663) or to obtain a minimum voltage by using an auxiliary voltage source is reloaded (DE-OS 20 55 176); however requires this is a considerable technical effort that is not always justifiable

From GB-PS 10 55 855 is a self-guided converter with two in series and each phase Main thyristors connected to the positive or negative pole of a DC voltage source are known. A diode is connected in anti-parallel to each of the main thyristors. The common connection point serves as a phase connection, to which the first connection of a commutation device is also connected is. The commutation device consists of the circuit of a commutation reactor, one Quenching capacitor and two anti-parallel controllable quenching valves. The second connection of the commutation device is connected to the DC voltage source via controllable valves. Furthermore is a Direct current source for charging the quenching capacitor is provided, which via controllable valves with the bo Komfnülicrüngseinrichtung is connected. This circuit also requires a considerable amount of equipment Expenditure.

From DE-OS 20 07 567 finally in connection with a device for forced commutation> 5 The series connection of an auxiliary inductance with an auxiliary valve is implemented in a self-guided converter and an auxiliary DC voltage source known as a recharging device for a quenching capacitor.

The invention is based on the object of the aforementioned in a self-commutated converter Type with little effort in terms of performance and number of extinguishing and auxiliary valves an independence from the To achieve input voltage.

This object is achieved by the features characterized in claims 1 and 2

The converter according to the invention can also be designed in a multi-phase manner. For this are each phase two main thyristors and two each anti-parallel connected diodes are provided, the connection points of the thyristor bridge arm or diode bridge arm belonging to a phase with one another are connected and can form the phase output. Alternatively, between the main thyristors and anti-parallel diodes also suction throttles according to an older proposal (DE-OS 25 52 537). The commutation reactor of the commutation device is either directly on a quenching capacitor is connected or is connected to the connection point of the two connected in series Quenching capacitors in connection with the backup capacitor connected to the DC voltage source are connected in parallel. The converter according to the invention advantageously has an excellent Commutation capability even at high switching frequencies, as the voltage on or on the quenching capacitors is automatically kept constant.

The quenching capacitor or capacitors are charged exclusively via the Auxiliary valves from the auxiliary voltage source or the further backup capacitors.

Exemplary embodiments of the power converters according to the invention are described in greater detail below with reference to the drawing explained. It shows

F i g. I a converter according to the invention,

2 shows a converter extended to three phases,

F i g. 3 one of the F i g. 1 further Stromrichfr according to the invention,

F i g. 4 the three-phase variant of the invention Converter according to F i g. 3.

F i g. 1 shows the converter according to the invention with two main thyristors 1 and 2, two diodes 3 and 4, two controllable extinguishing valves 5 and 6, three commutation valves 7,8 and 9, a quenching capacitor 10, four backup capacitors 11, 12, 13 and 14, two auxiliary inductors 15 and 16 as well as two controllable auxiliary valves 17 and 18.

The two main thyristors 1 and 2 are connected in series and form a bridge branch. The same applies to both Diode.i 3 and 4. The diodes 3 and 4 are arranged in antiparallcl to the main thyristors 1 and 2. The connection points 31 and 32 of the main thyristors 1 and 2 and the diodes 3 and 4 are connected to each other. The connection point 31 of the main thyristors I and 2 is also connected to a commutation device 21. The commutation device 21 is formed by a series connection of two controllable extinguishing valves 5 and 6 arranged in antiparallc, a commutation inductor 7 and an extinguishing capacitor 10. The quenching capacitor 10 is connected to the connection point 34 of the two series-connected backup capacitors 11 and 12. The second electrode of the backup capacitor 11 or 12 is connected to the positive or negative pole of a DC voltage source 19 which supplies the direct voltage U, i. In addition, the second electrode of each backup capacitor 11 or 12 is connected via the commutation choke 8 or 9 to the main Thynstor 1 or 2 in the forward or reverse direction and to the series connection of the diodes 3 and 4 in the forward or reverse direction. The connection point 34 of the two series-connected backup capacitors 11 and 12 is also connected to a third and fourth backup capacitor 13 and 14. The second electrode of the backup capacitor 13 or i4 is connected to the positive or negative pole of an auxiliary DC voltage source 20. The auxiliary DC voltage source 20 supplies a constant DC voltage Un- In addition, the second electrode of the third or fourth backup capacitor 13 or

14 via an auxiliary inductivity 15 or 16 and a controllable one Auxiliary valve 17 or 18 with the connection point 33 lying in series with the quenching capacitor 10 Commutation choke 7 and the ar.tiparallel arranged controllable extinguishing valves 5 and 6 in connection.

The connection point 32 of the diodes 3 and 4 stelH at the same time represents the output of the converter according to the invention.

The converter according to the invention has the following mode of operation in inverter operation:

The transfer of energy from the direct current side to the alternating current side of the converter begins, for example via the main thyristor 1, which is connected through. At the same time, all other thyristors are blocked. In In this case, a current flows from the DC voltage source 19 via the commutation disconnect 8 and the Main thyristor 1 to the ac output 22 of the converter. This state remains as long as until the controllable extinguishing valve 5 receives a pulse and is ignited. This can only be done if the Quenching capacitor 10 is fully charged with one voltage direction (as shown in FIG. 1), the connection point 34 of the four backup capacitors 11 to 14 in this case with the negative electrode of the quenching capacitor 10 is verbunoen Through this sound flows in a quenching half-oscillation a current from the quenching capacitor 10 via the commutation choke 7 and the controllable quenching valve 5. This Current is greater than the maximum value of the load current. As a result, a current flows from the difference between commutation current and load current results via diode 3. The main thyristor 1 is with the Forward voltage drop of the diode 3 and the inductive voltage drop of the line routing claimed (BBC News 1966, p. 46). The commutation current is sinusoidal. The commutation reactor 7 and the quenching capacitor 10 are designed so that the main thyristor 1 has enough time to become non-blocking. If the commutation current becomes smaller than the load current, the supply voltage changes its polarity.

The load current now flows through the diode 4. After Stromlcitdauer in the thyristor 5, when the voltage is turned on-off capacitor 10 is zero, that is, after the erasing half-wave for the main thyristor 1 he main thyristor 2 and on the other hand, the controllable auxiliary valve 18 is ignited to a ^"H , so that a current flows through the controllable auxiliary valve 18, the auxiliary inductance 16, the back-up capacitor 14, the Lcschkondtnsator 10 and the commutation choke 7, whereby the quenching capacitor 10 is charged in a charging oscillation with a polarity that is opposite to its previous charge (see Fig. 1 the polarity shown in brackets). In a similar way, a current flows through the support condenser

Sator 13, the auxiliary inductance IS, the controllable auxiliary valve 17, the commutation throttle 7 and the quenching capacitor 10, if the quenching capacitor is to be charged again after the main thyristor 2 has been cleared. By alternately switching through and blocking the main thyristors I and 2, the positive and negative potential of the DC input voltage is alternately switched through to the alternating current output 22 and a sufficient capacitor voltage or extinction voltage is always ensured in the course of the respective charging speeds.

Under idealized conditions (no attenuation in the quenching and charging circuits), stable operation results when idling, the quenching capacitor 10 being charged alternately to a voltage of the size (Ud + Uh) Ii + (Uj + Uu) I ₁ thus becomes unit: it is therefore independent of the level of the direct voltage Ud . The extinction voltage is only slightly changed by damping in the quenching and charging circuits and by loading the AC output of the converter. The arrangement according to the invention therefore enables operation with not only sufficiently high But also with constant quenching voltage with any fluctuating input voltage Ua because the auxiliary voltage Un can be kept constant in a simple manner. By charging via the auxiliary valves 17 and 18, the main thyristors 1 and 2 and the quenching valves 5 and 6 are relieved of the charging current compared to the usual mode of operation so that the load capacity of the converter in the he inventive arrangement increases.

There is of course the possibility of the in FIG. I can expand the single-phase converter shown to more, in particular to three phases (FIG. 2), without affecting the mode of operation of the converter. For the failure of a three-phase Sifümfichters two series-connected main thyristors 1 and 2, 101 and 102, 201 and 202 and two series-connected diodes 3 and 4, 103 and 104, 203 and 204 are provided for each phase. The connection points of the two main thyristors provided for one phase and the two diodes that are respectively arranged anti-parallel thereto are connected to one another. A commutation device is also provided for each phase. Each commutation device has two quenching valves connected in anti-parallel, in particular thyristors 5 and 6, 105 and 105, 205 and 206 . These are connected in series with a commutation choke 7 common to all three commutation devices and a common quenching capacitor 10. The combination of quenching capacitors from several branches of an inverter circuit is known as such (O. Mohr "Investigations on elastic multiple converters", Ib. Forschungsinstitut AEG 5 (1936 to 1937), pages U to 19) and has already been proposed for a reverse voltage-free inverter (DE-OS 25 52 5373). The structure of the multi-phase converter corresponds further to that in FIG. 1 converter shown.

F i g. 3 shows a variant of the one in FIG. 1 shown converter. The main thyristors 1 and 2, the diodes 3 and 4, the controllable extinguishing valves 5 and 6, the commutation chokes 7, 8 and 9, the controllable auxiliary valves 17 and 18 and the auxiliary inductors 15 and 16 are connected in the same way as it was in FIG to F i g. 1 related description is explained.
The backup capacitors 13 and 14 are connected with their first electrode to the two electrodes of a third backup capacitor, so that a series connection of three backup capacitors 13, 50 and 14 is formed. Two series-connected quenching capacitors 100 and 200 are connected in parallel to the backup capacitor 50. The connection point 36 of the two quenching capacitors 100 and 200 is connected to the commutation choke 7. The second electrode of the backup capacitor 13 or 14 is connected to the positive one on the one hand

ίο or negative pole of the auxiliary DC voltage source 20 connected. On the other hand, the second electrode of the backup capacitor 13 or 14 is connected to the auxiliary inductance 13 or 16 . The connection point 34 of the series-connected backup capacitors 13 and 50 is connected to both the positive pole of the DC voltage source 19 and to the commutation choke 8, while the connection point 35 of the two backup capacitors 14 and 50 is connected to the negative pole of the DC voltage source 19 and the commutation choke 9 in Connection. In this way, the quenching capacitors 100 and 200 are connected both directly to the DC voltage source 19 and via the backup capacitors 13 and 14 to the auxiliary DC voltage source 20.

The in F i g. The single-phase power converter shown in FIG. 3 can also be converted into a multi-phase power converter. The expansion takes place in a similar manner to that explained in the description associated with FIG. The series connections of main thyristors 1 and 2, 101 and 102, 201 and 202 as well as the diodes 3 and 4, 103 and 104, 203 and 204 arranged in antiparallel for each phase are connected to the commutating reactors 8 and 9. The interconnected connection points of the main thyristors 1 and 2, 101 and 102, 201 and 202 and diodes 3 and 4, 103 and 104, 203 and

204 ättlu äUCii ifi uicäcm Fun fuii je cificr ixOuliTiüiic-

connected. For each commutation device, two controllable extinguishing valves 5 and 6; 105 and 106;

205 and 206 are provided, which are connected in series with the commutation choke 7 common to all commutation devices and the common quenching capacitors 100 and 200.

For this purpose 4 sheets of drawings

Claims (3)

Patent claims: 1. Self-commutated power converter with two main thyristors in series each phase, each connected to the positive or negative pole of a DC voltage source via a commutation choke, each of which has a diode in antiparallel! and whose connection point serves as a phase connection, to which the first connection of a commutation device, consisting of the series connection of a third commutation choke, a quenching capacitor and two anti-parallel controllable quenching valves, is connected, the second connection of which is connected to the center connection of two backup capacitors connected in series to the DC voltage source is connected, the ignition of an extinguishing valve after a half oscillation of the extinguishing circuit follows the ignition of the second main valve and a charge reversal of the extinguishing capacitor, characterized by a charging circuit for the extinguishing capacitor (10), in which one electrode each via a further backup capacitor ( 13, 14) and its second electrode are connected via a series circuit of a controllable auxiliary valve (17, 18) and a further auxiliary inductance (IS, 16) to the positive and negative pole of an auxiliary DC voltage source (20) nd and charging ä ° s Losch capacitor (10) is caused by ignition of the correspondingly poled auxiliary valve (17, 18). 2. Self-commutated power converter with two in series each phase, each with a commutation choke connected to the positive or negative pole of a DC voltage source, main thyristors, each of which has a diode connected in anti-parallel and whose connection point serves as a phase connection, to which the first connection is also connected a commutation device, consisting of the series connection of a third commutation choke, two interconnected quenching capacitors and two antiparallelcr controllable quenching valves, is connected, with a backup capacitor connected between the poles of the DC voltage source, the second terminals of the quenching capacitors are connected directly to the poles of the DC voltage source, and the ignition of a extinguishing valve after a half-oscillation of the extinguishing circuit is followed by the ignition of the second main valve and a charge reversal of the extinguishing capacitors, characterized by a charging circuit for the extinguishing circuit ondensatoren (100, 200), in which their free electrodes each have a backup capacitor (13,14) and their electrodes connected to each other via a series connection of a controllable auxiliary valve (17, 18) and a further auxiliary inductance (15,16) with the positive and negative pole of an auxiliary DC voltage source (20) are connected and the charging of the quenching capacitors (100, 200) is effected by igniting the corresponding auxiliary valve (17, 18). 3. Self-commutated converter according to claim 1 or 2, characterized in that the quenching capacitor (10) or the quenching condensers (100, 200), the controllable auxiliary valves (17, 18) and the auxiliary inductors (15 and 16) for all phases are arranged together and that the anti-parallel extinguishing valves (5 and 6, 105 and 106, 205 and 206) of all phases have a common connection point.