DE2346189A1 - Three-phase static inverter with increased output-frequency - has DC sources in series with each commutating thyristor in each phase branch - Google Patents

Abstract

The three-phase static inverter has its output frequency raised by d.c. sources connected in series with each commutating thyristor in each phase branch. A subdivided d.c. source can be used, whose end poles are connected one to each of the two commutating thyristors in each of the three-phase branches and whose centre tapping voltage is coupled to the common commutating capacitor. Each phase branch has two subbranches, each subbranch consisting of the d.c. source, the commutating thyristor and an inductor, all in series across the main thyristor. The main d.c. supply is applied over inductors to each phase branch.

Description

SIEMENS AKTIENGESELLSCHAFT Erlangen, December 1st, 2nd SEP. Ί973 Berlin and Munich Werner-von-Siemens-Str. 50

Our reference: VPA 73/3214 Gu / Or

Converter arrangement Z JAbI og

The invention relates to a converter arrangement with controlled main valves in a bridge circuit, which are connected via upstream Commutation reactors are connected to a DC supply voltage and each of which is a controlled one Commutation valve and an uncontrolled pre-run valve are assigned, the commutation valves being the main valves lie parallel and the center point of the coamutation valves of a bridge branch over a common one Commutation capacitor is connected to the midpoint of the main valves of this bridge branch and the Free-wheeling valves each between the center of the main valves and the DC supply voltage and are anti-parallel to the main valves.

This circuit principle is applied to this by means of a main valve and the diagonal commutation valve Valve branch of the bridge, especially in no-load operation, recharging of the commutation capacitor that is independent of the input voltage and in order to achieve the load current-dependent by means of the charging throttle through which the load current flows To achieve charging of the commutation capacitor for constant closed time of the main valve.

In a known converter of this type, the output frequency is limited by the sum of the current conduction times and closed times of the two commutation valves in series of a valve branch of the bridge during a period and due to the phase shift caused by the three-phase voltage system of, for example, three valve branches in one

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2346m

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Dreiphasenumriohter (Siemens magazine 1965 _f pages 254 to 257). In such a three-phase converter, the three valve branches must be functional independently of one another. For this reason, each commutation capacitor is recharged via a main valve and the diagonal commutation valve. Accordingly, each commutation valve per period has a closed time following the recharging current control time and a further closed time following the quenching current control time. For controllable valves with a pricing time of around 180 / usee and an average current carrying time of around 50 / usec, theoretically a minimum duration of a period of around 1250 / usec results for the series connection. This corresponds to a maximum theoretical output frequency in converter operation of approx. 800 Hz. Due to the mostly shorter release times of the commutation valves, this value for the converter output frequency can be slightly exceeded in practice.

So-called slow commutation valves with a release time of about 180 / usec have to be due to the high

t
Reverse voltage can be used during the erasing process

occurs due to the circuit, because in the known converter circuit shortly before the end of the charge reversal at the commutation valve, double the amount of the DC input voltage is present at.

The increase in the converter output frequency is counteracted by the circuit properties that for each commutation valve two current conduction times and two subsequent ones There must be closed seasons per period. This makes the maximum possible output frequency about halved. In addition, practically the entire quenching circuit inductance is located as a load-current-carrying charging choke or Commutation reactor in series with the main valve to be extinguished. This commutation valves with the double blocking capability of the main valves and thus about ten times the currently shortest available release times necessary.

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In a "known converter circuit for output frequencies over 800 Hz every commutation valve is on Oscillating circuit assigned (DT-OS 2 036 715); Each oscillation circuit is connected to the bridge strand of the associated Main valve inductively coupled. For the commutation capacitors an external voltage source is provided as a recharging device, with each commutation capacitor can be switched to the terminals of the external voltage source via a controllable loading valve. This well-known A converter circuit requires a considerable amount of circuit technology.

It is therefore the object of the present invention to determine the output frequency in a converter of the type described at the outset to increase with simple means. This object is achieved according to the invention in that each commutation valve a DC voltage source is connected in series. Preferably, between the two commutation valves of a bridge arm, a subdivided DC voltage source can be arranged, the poles of which with the Commutation valves and their center tap is connected to the common commutation capacitor.

The DC voltage sources in the commutation circuits keep the amplitude of the voltage across the commutation capacitor independent of the feeding DC supply voltage and the output power are constant, without any special Switching operations of the controlled valves would be required. The load-independent commutation device according to the invention allows the output load to be switched on and off as required in the entire range between idle and Full load. A converter arrangement according to the invention is therefore particularly suitable as a reserve voltage generator for full load transfer at the moment of failure or also for

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Supply of inductive loads, which are in operation Filters have to be switched on or off.

Implementation examples of the invention and its in the subclaims Embodiments marked are described in more detail with reference to the figures.

Fig. 1 shows a schematic representation of an inventive Converter.

The three-phase converter shown contains the controlled main valves 1a to 1c and 2a to 2c in a bridge circuit. The main valves are connected to the terminals via commutation chokes 3a to 3c and 4a to 4c connected upstream 5 and 6 of a DC supply voltage E. The DC supply voltage can preferably be one from a three-phase network be fed rectifier arrangement with a DC link. The main valves are anti-parallel switched uncontrolled free-wheeling valves 7a to 7c and 8a to 8c in parallel, each between the center point the main valves and one pole of the DC supply voltage are connected. The main valves are controlled Commutation valves 8a to 9c and 10a to 10c with series throttles 11a to 11c and 12a to 12c connected in parallel, with the midpoint of the commutation valves of a bridge branch each via a common Commutation capacitor 13a with a choke 14a with the center point of the main valves of this bridge branch connected is. Each commutation valve has a DC voltage source 15a to 15c and 16a to 16c in series switched.

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The DC voltage sources 15a to 15c and 16a to I6c cause by their power output via the extinguishing circuit current a compensation of the losses in the commutation, so that no reloading of the commutation capacitors 13a to 13c is required from the DC supply voltage E via the controlled commutation valves. Even with the maximum possible DC supply voltage E can not ignite the main valves during the release time Commutation valves take place, since the commutation capacitors are switched to one by appropriate selection of the voltage F Voltage Ui, to be charged:

UL> E + F-
Λ j max

The converter load can be switched between no-load and full load as required, because the voltage U-, is held constant at a value via the commutation capacitors 13a to 13c, which is used to delete a certain maximum current value is sufficient.

FIG. 2 shows some characteristic voltage profiles of the converter arrangement according to the invention according to FIG. 1 shown. Show it:

2a shows the voltage curve H ₁ at the main valve 1a, FIG. 2b the voltage curve Uq at the commutation valve 9a, FIG. 2c the voltage curve U- at the commutation capacitor 13a,

FIG. 2d shows the voltage profile U ″ at the main valve 2a, FIG. 2e the voltage profile U ₁₀ at the commutation valve 10a.

It can be seen that the shortest possible half-cycle duration required for the highest possible output frequency is given by the sum of the four times the main valve closed time Ti. And the commutation _{valve closed time * s} »

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The only requirement is that each commutation valve is conductive only once per period, namely during the extinguishing current flow for its associated main valve. In addition must at the end of the quenching current conduction of the commutation capacitor 13a to a voltage U-,> E + P be reloaded so that E + P - U-, as a sufficiently negative voltage at the commutation valve is pending and thus cannot become conductive without an ignition pulse if during its pricing time the other main valve is ignited.

On the other hand, the largest permissible DC supply voltage E is limited by the maximum permissible period E Peak blocking voltage of the commutation valves.

Pig. 3 shows a particularly simple embodiment of one according to the invention Converter arrangement.

The three commutation valves 9a to 9c have a common DC voltage source 17 and a common commutation valve choke 18 connected in series. In the same way, the commutation valves 10a to 10c are the DC voltage source 19 and the commutation valve choke 20 connected in series. One group of main valves each are connected together to the main valve chokes 21 and 22.

Pig. 4 shows another embodiment of a converter arrangement according to the invention.

The commutation valves 9a to 9c are in turn shared DC voltage source 23 and commutation valves 10a to 10c are preceded by a common DC voltage source 30. Each of the main thyristors 1a to 1c and 2a to 2c have their own chokes 24a to 24c and 25a to 25c assigned by the diodes 26a to 26c and 27a to 27c

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are decoupled. Each of the commutation valves 9a to 9c and 10a fcis 10c are chokes 28a to 28c and 29e ″ to 29c upstream.

Pig. 5 shows a further embodiment of an inventive Converter arrangement.

The commutation valves 9a and 10a of a bridge arm are connected to the poles 31 and 32 of a subdivided DC voltage s source 33 connected to its center tap 34 the common commutation capacitor 13a is located. The tapping ratio of the commutation reactors 35a to 35c and 36a to 36c determine the desired tension ratio. The commutation valves therefore do not have to be in addition to Voltage of the commutation capacitor in question block the DC supply voltage and therefore have the same blocking voltage and the same release time as the main valves. With this embodiment there are output frequencies possible up to about 5000 Hz.

6 shows the use of a converter according to the invention arrangement for a reserve voltage source.

The converter 40 with its commutation circuits is synchronous with the main generator 41 and is common with it connected to the consumer 42 and ready for operation. As long as the main generator 41 is working, received the main valves do not have any ignition pulses and therefore remain blocked. So if the main generator 41 fails, this is disconnected from consumer 31 by contactor 43, the main valves receive ignition pulses with the correct frequency and phase, so that when the intermediate circuit voltage is set accordingly, the last one recorded by the consumer immediately Performance can be delivered.

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7 shows the use of a converter arrangement according to the invention for a circuit * with the by closing and Switching off capacitive filters of an inductive load. Transient processes with excessive current amplitude appear.

The converter arrangement 50 according to the invention generates a three-phase three-phase system RST for feeding hysteresis motors 51. The filter capacitors 53 R, 53 S and 53 T can be connected to the filter chokes 54 R, 5 * S, 54 T from the contactor 52 can be switched on and off.

Such a circuit is generally suitable for cases where both the Power factor as well as the power consumption of the consumer is changed. In known converter circuits In such applications, load changes can only be made for partial loads in such a way that with the associated overcurrent surges, the maximum permissible extinguishing current values are not exceeded. at a converter arrangement according to the invention on the other hand these overcurrents can be limited in a simple manner by changing the ignition time of the relevant Commutation valve moved forward in the overcurrent half-shaft will. This advancement of the ignition point is permissible up to the duration of the recharging current required up to now.

2 claims
7 figures

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Claims (2)

- 9 claims VPA 73/5214 (1.y converter arrangement with controlled main valves in Bridge circuit via commutating reactors connected upstream are connected to a DC supply voltage and each have a controlled commutation valve and a uncontrolled free-wheeling valve is assigned, the Commutation valves are parallel to the main valves and the midpoint of the commutation valves of a bridge branch Via a common commutation capacitor with the center point of the main valves of this bridge branch is connected and the one-way valves respectively between the midpoint of the main valves and the DC supply voltage and anti-parallel to the main valves are, characterized in that each commutation valve (9a to 9c, 10a to 10c) has a direct voltage source (15a to 15c, 16a to 16c) connected in series is. 2. converter arrangement according to claim 1, characterized in that that between the two commutation valves (9a, 10a) of a bridge branch there is a subdivided voltage source (33) is arranged, whose poles (31, 32) with the commutation valves (9a, 10a) and their center tap (34) is connected to the common commutation capacitor (13a) (Fig. 5). 509813/0121 AO Blank page