NL7906407A - FORCED COMPUTERIZED CURRENT DIRECTOR WITH A LOCK-FREE VOLTAGE. - Google Patents

Description

V * VO 8058

Brown, Boweri 4 Cie Aktiengesellschaft.

Mannheim-Kafertal, Federal Republic of Germany.

Forced commutated current straightening device with a blocking voltage-free circuit.

The invention relates to a compulsively commutated current directing device with a blocking voltage-free circuit with a commutator circuit, consisting of controllable current directional valves arranged in anti-parallel connection, a commutator capacitor 5 and a commutator choke, with a load circuit consisting of controllable current directional valves, in anti-parallel context therewith attached non-steerable flow directional valves and chokes, and with two capacitors arranged between positive and negative DC terminals, and which device can be used, for example, to generate an AC voltage, starting from a DC voltage, or to generate an AC voltage, assuming an alternating voltage with a different frequency.

A typical for a compulsively commutated current directing device with blocking voltage-free circuit, typical example is known from 15 ΞΤΖ-Α, Band? C, (1969), H. 1fc, pp. 353 - 357 (J. 3renneisen and A.

Schönung, "Bestimmungsgroszen des selbstgefüirien Stromrichters in sperrspannungsfreier Schaltung bei Steuerung nach dem Unterschwingungs-Verfahren").

For the description of such a device, reference is also made to an article by HW van den Boom and E. Kohlhuber, entitled "Beanspruchung von Thyristoren in Wechselrichterschaltungen", VDE-Buchreihe, Vol. 11 "Energieelektronik und regulatede Antriebe", p. 135-150, VDE-Verlag, Berlin 1966.

During the operation of such current rectifiers, the drawback can arise that commutation processes undergo an asymmetrical shift. As a result, the commutator chain has to be oversized. In the most unfavorable case, such an asymmetry in the commutator current can cause an operating failure in the current director.

30 79 0 6 4 0? * Λ 2

The object of the invention is to provide a compulsively commutated current-directing device with a blocking voltage-free circuit, which compensates for possibly occurring asymmetries in the communication process.

According to the invention, this problem is solved by the fact that an e-mutation condenser is fitted between the controllable flow directional valves of the commutation chain and the strocan devices of the load chain; and that an attenuation circuit is provided between the commutation capacitor and the current directional valves of the commutation circuit, which can be driven via current directional valves with positive and negative potential of the supply DC voltage.

The advantages deriving from the invention are particularly apparent in that asymmetric shifts of the commutation processes are compensated, in other words, high voltages at the commutation capacitor are avoided, while each commutation procedure starts with a defined commutation capacitor voltage .

The attenuation circuit can herein comprise either two or three branches. In the two-branch embodiment, each branch comprises a series circuit consisting of a resistor and a flow rate valve.

In the three-branch embodiment, two branches are driven through current directional valves by the positive and negative potentials of the DC supply voltage, and one branch includes a resistor 25 and is disposed between the commutation capacitor and the commutation circuit current directional valves.

Compared to the two-branch embodiment, the three-branch embodiment is simpler, since this embodiment has only one resistor. As a rule, however, a resistor will also be provided in the three-branch / each-branch embodiment in order to protect the current directional valves of the attenuation circuit.

In all embodiments of the attenuation circuit, it is furthermore possible, in an advantageous embodiment of the invention, to incorporate a 7906407 r-3 choke in series with the individual resistors.

In the following, thy ristors are used as steerable flow directional valves, while diodes are used as non-steerable flow directional valves. Depending on the application case, 5 steerable valves (for example thyristors) or non-steerable valves (diodes) In the exemplary embodiments discussed below, diodes have been used as flow directional valves in the attenuator circuit.

To further illustrate the invention, the only embodiments thereof will be described below with reference to the drawing. In the drawing: Fig. 1 shows a one-phase current straightening device with a weakening circuit according to the invention; Fig. 2 shows a possible embodiment of a weakening circuit; fig. 3-8 variants of the design of the attenuation circuit.

In Figs. 1, 3, h, 5, 6, 7 and 8 is a one phase according to the example.

invented, compulsory commutated current device with bioconductor voltage-free circuit shown. Two capacitors C. and C2 connected in series are arranged between a positive DC voltage supply terminal 1 and a negative DC voltage supply terminal 2. The DC supply voltage is indicated by ü. The positive DC voltage supply terminal 1 is connected via a choke to a connection point 3 between a controllable current directional valve, hereinafter referred to as main thyristor T ^, and an anti-parallel non-controllable current directional valve, which is further described below as the copper diode D ^ will be called. The anode of the main transistor J and the cathode of the main diode Ti are connected to the junction point 3. Further connections of the current controllers T ^ and D ^ are connected to an output terminal k.

The negative DC voltage supply terminal 2 is choke-connected to a junction 5 between a controllable flow directional valve T ^, hereinafter referred to as main thyristor, and an anti-parallel non-controllable flow directional valve Dg in the further main diode below Dg.

The cathode of the main thyristor Tg and the anode of the main diode Dg are connected to this connection point 5. The other connections of these current converters Tg and Dg are connected to the output terminal h.

The circuit formed by the main thyristors T1 and Tg, the main diodes D1 and Dg, as well as the inductors and Lg is referred to as a load circuit. This load circuit is supplied with DC voltage via terminals 1 and 102 and comprises, in addition to the output terminal h located on the AC voltage side, another output terminal 6, which is connected to the connection point between capacitors C.j and Cg.

A commutation circuit is arranged between the output terminals Π and 6. This commutation circuit consists of a commutation capacitor C1, a commutation choke Lg and two anti-parallel controllable flow directional valves Tg and Tj, which will be further referred to as auxiliary thyristors Tg and Tj below. Seen separately, the auxiliary thyristors Tg and Tj are connected to the output terminal 6 and a connection point 7. In the configurations of Figures 1, 3, U and 5, a commutation capacitor Cg is provided between the connection point 7 and another connection point 8, while the commutation choke Lg arranged between the connection point 8 and the output connection k.

The commutation choke Lg and the commutation capacitor Cg are instead interchanged in the configurations according to Figs. 6, 7 and 8, so that the commutation capacitor Cg is arranged between the connection k and the connection point 8, while the commutation choke Lg is arranged between the terminals 7 and 8. In addition to this description which applies to FIGS. 1 and 3 to 8, the following illustrate the different attenuation circuit designs for the individual embodiments.

In the configuration according to Fig. 1, a branch forming part of the attenuation circuit, consisting of a resistor 7906407 r '5 and a diode Dg, is arranged between the connection point 7 and the positive DC voltage supply connection 1. Another branch forming part of the attenuation circuit and consisting of a resistor R 1 and a diode D 2, 2 k is arranged between the connection point 7 and the negative DC voltage supply terminal 2. The circuit shown in Fig. 1 can be extended by series with the resistors and E ^ each time a choke is fitted. In addition, the diode ... can be connected to the connection point 5 and the diode Dg to the connection point 5. Alternatively, the diode D ^ can be connected to a tap of the choke and the diode Dg to a tap of the choke L ^.

If the commutation choke Lg and the commutation capacitor Cg are interchanged with regard to their position, other variants arise in addition to the connection possibilities already mentioned. The joint connection of the two branches of the attenuation circuit can then optionally be done with the connection point 7, in other words between the auxiliary thyristors Tg-h. and the choke Lg, with a tap of the choke Lg or with the connection point 8, in other words are connected between the choke Lg and the capacitor Cg.

Fig. 2 shows a weakening circuit shown in the further exemplary embodiments of Fig. 3-3. The in fig.

2 configuration consists of three star-shaped individual branches of a weakening circuit with three connection contacts A, 3 and C, as well as a common connection point 9. Between the connection contact A and connection point 9 there is a -5 series circuit consisting of a diode D ^ optionally fitted with a resistor 3 ^ or optionally choke Dg. Between the connection terminal 3 and the connection point? a series circuit consisting of a diode with optionally a resistor E ^ and optionally a choke coil L, - is arranged, while between the connection terminal C and the connection point 9 a resistor R <_ is optionally connected in series with a choke coil Dg , is applied.

In the embodiment shown in Fig. 3, this attenuation circuit according to Fig. 2 is connected to its terminal socket A to a positive DC supply terminal 1, while its terminal socket 3 is connected to the negative DC power supply terminal 2, while the terminal C is connected with the connection point 7

In another exemplary embodiment shown in Fig. U, the connection contact A is connected to a tap of the choke, the connection contact B to a tap of the choke and the connection contact C to the point 7.

In a variant of the exemplary embodiment according to Fig. 5, the connection contact A is to the connection point 3, the connection contact B to the connection point 5 and the connection contact C to the connection.

bmdingspunt 7 connected.

In the exemplary embodiments of FIGS. 6, 7 and 8, as already noted, the commutation choke and the commutation capacitor are swapped in place compared to the exemplary embodiments of FIGS. 1, 3, b and 5. In the embodiment of FIG. ? FIG. 6, the attenuation circuit is connected via its terminal contact A to the positive DC power supply terminal 1, its terminal B to the negative DC power supply terminal 2, and its terminal C thereto.

In the embodiment according to Fig. 7, the connecting contact is A.

20.

connected with a tap of the choke, the connection contact B with a tap of the choke and the connection contact C with a tap of the commutation choke.

In the exemplary embodiment shown in Fig. 8, the connection contact A is with point 3, the connection contact B is with point 5 and

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J the connection contact C is connected to point 8.

In addition to the variants indicated above, other symmetrical and asymmetrical combinations of the connections of the attenuating circuit within the compulsively commutated current straightening device are possible.

30. . ....

To illustrate the operation of a device designed according to the invention, the exemplary embodiment shown in Fig. 1 is considered below, in which the attenuation circuit consists of two series circuits, each consisting of a diode and a resistor (R ^ / D ^ and which directly with the positive and negative potential of the power supply 7906407 ~ 3 τ

DC voltage U are connected (DC supply terminals S

1 and 2) and are connected jointly between the auxiliary thyristors and commutation capacitor. For a description of the occurring commutation processes, reference is made to the state of the art, for instance the aforementioned article by J. Brenneisen and A. Schöning "Bestimmungsgroszen des selbstgefïihrten Stromrichters in sperrspannungsfreier Schaltung bei Steuerung nach dem Unterschwingungs-Verfahren", A, Band 90 (1969), H. 1H, pp. 353-357, especially p. 353, left column, last paragraph to p. 35 ^, left column, second paragraph. A flow straightening device according to the invention is also suitable for the "Unterschwingungsverfahren" referred to there. In addition, the operation of a compulsively commutated (self-powered) flow scanner is described in detail in the article by H. ¥. van den Boom and Ξ. Kbhlhuber, "Beanspruchung von Thyristoren in Wechsel-15 richterschaltungen", VDE-Buehreihe, Vol. 11, "Energieelektronik und regelde electrical Antriebe", pp. 135 - 150; VDE-Verlag, Berlin 1966, in particular page 139, third paragraph to page IKU, second paragraph.

In a current straightening device 20 designed according to the invention it is achieved that too high a voltage developed at the commutation capacitor via the branch containing the conductive main valve T ^ and the associated branch R ^ / B ^ and H ^ / B ^ respectively, due to discharge. this capacitor can be returned to a voltage value given by the intermediate circuit DC voltage. Therefore, each commutation procedure starts with a defined commutation capacitor voltage.

Various criteria can be decisive for the realization of the attenuation circuit. Two sizing concepts are of practical significance.

According to one concept, it is possible to design the attenuation circuit as a low-impedance circuit. An excessively high voltage of the commutation capacitor is quickly reduced by the low-resistance attenuation circuit. The dimensioning assumes that the compensating procedure (charge effect) takes place in the region ^ 5 - of the aperiodic boundary case (vibration of the RC network R ^, 7906407

w- -V

8 and Rg, respectively), in other words, short discharge times are involved. As a result, the asymmetry in the commutation process is fully compensated immediately after each commutation. Moreover, a good blocking voltage limitation is hereby achieved with respect to the auxiliary hy-ristors T ^ / T ^.

According to the other conception, it is possible to design the attenuation circuit as a high-impedance circuit. If asymmetry of the commutation current develops only slowly during the operation of the current straightening device, it is also possible to develop such a development by means of a high-impedance attenuation circuit with a large discharge time constant (Re-network R ^, R ^, C ^) respectively. to go.

In. In this situation, an asymmetry under the circumstances is only compensated for after several commutation cycles. However, it is an advantage that the current load of the attenuation circuit is thereby reduced.

In the three-branch embodiment of a weakening circuit, the resistor R 1 serves primarily to eliminate asymmetric commutation processes, in other words, the value of this resistor R 1 determines the evolving discharge times. The low-impedance resistors R ^ and R ^ act primarily as protection for diodes D, _ and Dg. In the two-branch embodiment of the attenuation circuit, the two resistors R1 and R2 serve to reduce excess voltages on the commutation capacitor, the values of the resistors determining the adjusting discharge times.

In most cases it is sufficient to design the attenuation circuit only with resistors and diodes. In order to dimension the evolving discharge processes, in particular with regard to their frequency (for example, a compensation procedure 30 in the range of the aperiodic limit case is desired), it is optionally possible to charge the inductors in the individual branches of the attenuation circuit. to take.

7906407

Claims (4)

1. Forcibly commutated interlocking circuit-free current directional device with a commutation circuit consisting of controllable flow directional valves arranged in anti-parallel relationship, a commutation capacitor and a commutation choke, with a load circuit consisting of controllable directional control valves, arranged in anti-parallel relationship thereto non-controllable directional control valves and chokes, as well as with two capacitors arranged between positive and negative direct current supply terminals, characterized in that the commutation capacitor (C ^) is arranged between the controllable directional control valves (T ^) of the commutation circuit and the current directional valves T2, D ^, Dg) of the load chain; and between the commutation capacitor (C1) and the current directional valves (T ^, T ^) of the commutation circuit, a sagging circuit is provided, which can be fed via the current directional valves with a positive and a negative potential of the supply voltage. Device according to claim 1, characterized in that the attenuation circuit comprises two branches, each of which includes a resistor (H ^, Hg) and a flow directional valve (D ^, D ^). Device as claimed in claim 1, characterized in that the attenuation circuit comprises three branches, two branches of which two branches can be supplied with the positive and negative potential of the supply DC voltage via current directional valves (Dj., Dg), and one branch a resistor (Hr), as well as is arranged between the commutation capacitor (C_) and the flow directional valves (Tj of the commutation chain) Device according to claim 3, characterized in that all three branches of the weakening circuit resistors (R ^, R ^, R ^). Device according to one or more of the preceding claims, characterized in that the weakening circuit always comprises a choke arranged in series with a resistor. 3C _______ 7906407