DE2846645C2 - Converter circuit - Google Patents

Description

40

The invention relates to a converter circuit for line-commutated and self-commutating operation, with a one or more sequence-controlled bridge circuit, which consists of parallel branches, in each of which one first thyristor, one diode and one second thyristor are connected in series, with the free Electrodes of the first thyristors are connected to one another, further being to the connection point of first thyristors and diodes quenching capacitors are connected between the parallel branches and wherein Finally, at the connection points between the diodes and the second thyristors, the poles of AC voltage sources are connectable.

Rectifier circuits for electric traction vehicles, which are designed as sequence-controlled, erasable bridge circuits are known. Thereby means Sequence control the series connection of partial converters, whereby only one converter is the whole Control area while all others are in one of the two control end positions. Sequence control is possible with both fully controlled and semi-controlled bridge circuits.

In connection with the sequential control it is known to have an approach and section control, d. H. one so-called sector control to be provided.

In addition to the sequential control on the DC side, it is also the sequential control on the AC side several power converters known

In particular from DE-OS 25 30 961 a rectifier circuit of the type described above known as the bridge circuit without commutation thyristors for one- and two-quadrant operation is suitable and which allows the fundamental power factor adjust between mains voltage and mains current within wide limits, so that a Power factor optimization is made possible with relatively little circuit complexity. To the realization The known circuit contains devices for deleting straight conductive thyristors. These extinguishing devices enable partially network-controlled and partially self-guided operation.

Circuit arrangements are also known which allow a direct current consumer to be switched off supply different voltage levels to a constant DC voltage source. From the DE-OS 23 46 180 is, for example, such a DC chopper circuit for pulse control of the voltage an inductively affected consumer known in which a controllable main valve by the consumer and a DC voltage source is arranged and the one extinguishing device connected in parallel to the main valve has, which from the series connection of a quenching capacitor with at least one controllable Extinguishing valve exists. l) it is further the consumer a controllable free-wheeling valve is assigned that can be ignited when the voltage on the quenching capacitor exceeds a predetermined limit value, which is above the DC voltage value of the DC voltage source and below that of the breakdown voltage of the main valve. This known circuit arrangement has however, the disadvantage that it is limited to inductive consumers and especially for consumers with Counter voltage is unsuitable.

The present invention is based on the object of providing a converter circuit of the initially mentioned mentioned type to the effect that it can be used both as a rectifier and as a DC converter can be used.

This object is achieved in that a DC voltage source is provided which is connected to the free Electrode of two second thyristors can be connected that between the free electrodes of all the second Thyristors capacitors are connected and that a contactor is provided, the first set of Contacts the AC voltage source with the associated connection points and its second set of contacts connects the free electrodes of the second thyristors to one another as long as the Circuit works as a rectifier and the DC voltage source is switched off. and its contacts are open as long as the circuit works as a DC power controller and the DC voltage source is switched on is.

This results in the advantages that the known rectifier circuit without additional semiconductor elements can only be used as a DC converter by using a contactor that the Extinguishing device manages without inductance even in DC chopper operation, and that the ignition and The quenching sequence of the controllable thyristors can be chosen so that there is a load-dependent commutation results, d. H. that the size of the quenching capacitor voltage is freely selectable. In addition, the inventive

Proper switching in DC converter operation also suitable for consumers with counter voltage

They are preferably in series with the DC voltage source a DC switch and a choke coil are arranged. The choke coil forms together with the the capacitors connecting the free electrodes of the second thyristors have a filter circuit for smoothing that in DC power control mode of the DC voltage source extracted current pulses. The DC switch is used to operate the rectifier when the free electrodes of the second thyristors are interconnected, the DC voltage source of disconnect the converter circuit.

The invention is to be explained in more detail in the form of exemplary embodiments with the aid of the drawing.

F i g. 1 shows a single-stage ignitable and erasable circuit arrangement, connected as a bridge rectifier for single-phase alternating current;

Fig.2 shows a two-stage ignitable and erasable Circuit arrangement, connected as a DC power controller;

the F i g. 3 and 4 show different curves of the DC voltage at the output of the circuit arrangement according to FIG. 2.

The in F i g. The converter circuit shown in the figure is a bridge circuit for line-commutated and self-commutated operation. Two parallel branches can be seen in which a first thyristor nt, π 3, a diode π 1.1, π 3.1 and a second thyristor π 2, π 4 are connected in series. The free electrodes of the first thyristors n \. η 3 are interconnected. A direct current smoothing choke Ld is connected to this connection point, at which the output voltage Ud, which can be controlled in terms of its magnitude, can be tapped. At the connection points between the first thyristors n \, η 3 and diodes n 1.1. π 3.1 a quenching capacitor CL is connected between the parallel branches. Ap the connection points between diodes π 1.1, π 3.1 and the second thyristors π 2, π 4, the two poles of a single-phase AC voltage source Uw are connected via a transformer TR . A first contact k 1.1 of a contactor (not shown), which allows the alternating voltage Uw to be connected or disconnected as desired, is arranged in the one line coming from the transformer TR. The free electrodes of the second thyristors π 2, π 4 are connected to one another via a second contact λ 2.1 of the contactor and form the negative pole of the output voltage Ud.

A capacitor CF is connected in parallel with the second contact Ar 2.1, to which in turn a series circuit comprising a filter inductor LF. a DC switch Sunc! a DC voltage source Uc is connected in parailel. Since in the present example the circuit arrangement is connected as a rectifier with the aid of the contacts k 1.1, k 2.1, the direct voltage source Ur is disconnected from the circuit via the open direct current switch S.

The in F i g. 1 is suitable for two-quadrant operation and allows both the control and the section control. The start of the output voltage Ud is influenced by the ignition of the second thyristors π 2. η 4 and the section of the output voltage Ud is influenced by the ignition of the first thyristors η 1, η 3.

By opening the contacts k 1.1, £ 2.1 of the contactor and closing the DC switch S, the switchover from rectifier mode to DC converter mode is carried out. The circuit then works as follows: First the thyristor π 3 is ignited. Then the thyristor π 1 is ignited. Finally, the thyristor π 2 is ignited. With regard to the extinguishing device, the converter valves π 2, π 1.1 and η 4, η3Λ can be viewed as shut-off valves.

During the freewheeling phase, the two thyristors π 1, π 2 are in the blocked state and the thyristors π 3, π 4 are in the conducting state

ίο condition. The output-side direct current flows through the thyristor π 4, the diode π 3.1, the thyristor π 3, the output inductor Ld and the load (not shown). Above the blocked thyristor η 1, the positive blocking voltage is the voltage on the capacitor CL

The commutation of the output current from the freewheeling circuit into the circuit with the DC voltage source Uc takes place in two steps. First the thyristor η 1 is ignited. The output current commutates immediately via the quenching capacitor CL to the thyristor η 1. The change in the capacitor voltage is determined by the output current.As soon as the polarity of the capacitor voltage has changed compared to that of the initial state and the voltage value that occurs at the capacitor CL is sufficient to ensure reliable commutation of the output direct current to the left bridge branch, the thyristor η 2 is triggered The output current then commutates immediately into the circuit, consisting of the direct voltage source Ud, thyristor π 2, diode π 1.1 and thyristor η 1. The commutation of the output direct current from the circuit via the direct voltage source into the freewheeling circuit is initiated by triggering the thyristor η 3

J5 With the help of a suitable control device, the voltage at the quenching capacitor CL can be set as a function of the output direct current so that the period of time during which a negative reverse voltage is applied to the thyristor π 1 is always the same

«O the closed season of the thyristor η 1 is. This is achieved by a load-dependent setting of the voltage on the quenching capacitor CL . The lower control limit of the circuit arrangement in DC chopper operation, which is dependent on the smallest output DC current and the voltage swing at the Lörch capacitor CL, can be designed more favorably due to the constant closed season.

F i g. 2 shows a circuit arrangement which, compared to that shown in FIG. 1, is designed for two-stage operation and therefore contains a third bridge branch with a first thyristor π 5, a diode η 5.1 and a second thyristor π 6 . The position of the contactor contacts Ar 1.1. k 1.2. k 2.1. Ar 2.2 is drawn for DC converter operation. For this reason, the DC switch 5 is also closed.

The Fig.3 and 4 show the time course of

DC voltage Ud in FIG . 2 in DC power converter operation. The voltage curve shown in FIG. 3, in which the output equal voltage Ud only rises to a maximum of half the height of the direct current source Uc , is obtained when, in addition to the right-hand bridge branch acting as a free-wheeling circuit for the consumer (not shown in FIG. 2) , consisting of first thyristor η 3, diode π 3.1 and second thyristor η4, only the middle bridge arm, consisting of first thyristor n5. Diode π 5.1 and the second thyristor π 6 is ignited, as in the description of FIG. 1

was explained. The only voltage source then used is the capacitor CF2, which as a result of being connected in series with the other capacitor CFI is only charged to half of the direct voltage Ua. >

The course of the output DC voltage Ud shown in FIG. 4 results even if the left bridge branch of FIG. 2 consists of the first thyristor n \. Diode /il.l and second thyristor /; 2 alternately with the middle bridge branch, consisting of first thyristor π 5, diode π 5.1 and second rhyristor η 6 is ignited. These voltage curves of the DC output voltage Ud enable the smoothing reactor Ld to be dimensioned in a favorable manner.

From a comparison of FIGS. I and 2 one can see immediately that the circuit arrangement according to the invention can also be expanded in a simple manner for three-stage and multi-stage operation in which further bridge branches, consisting of the first thyristor. The diode and the second thyristor are arranged in parallel and are connected to one another and to the single-phase AC voltage source // μ by means of clearing capacitors CL and filter capacitors Cf ' and contacts k. With an increasing number of stages, the frequency of the output DC voltage is further reduced both in rectifier operation and in DC converter operation, which reduces the repercussions on the feeding networks, in particular on the AC voltage network.

The converter circuit according to the invention is suitable for feeding consumers from both an AC voltage network as well as from a DC voltage network. Typical area of application are electric multi-system traction vehicles.

For this purpose 2 sheets of drawings

Claims (2)

PATENT CLAIMS: 1. Converter circuit for mains-commutated and self-commutated operation, with a single or multiple sequence-controlled bridge circuit, which consists of parallel branches, each of which has a first thyristor, a diode and a second thyristor connected in series, with the free electrodes of the first Thyristors are connected to one another, with quenching capacitors also being connected between the parallel branches at the connection points of the first thyristors and diodes, and finally the poles of AC voltage sources can be connected to the connection points between diodes and second thyristors, characterized in that a DC voltage source (Ug) is provided that can be connected to the free electrodes of two second thyristors (n 2, π 4), that capacitors (CF, CFX, CF2) are connected between the free electrodes of all second thyristors (n2, π 4), and that a contactor is provided is whose first set of contacts (k 1.1, k 1.2) d ie AC voltage sources (Uw) with the associated connection points and its second set of contacts (k 2.1, kZ2) connect the free electrodes of the second thyristors (n 2, η 4) to one another, as long as the circuit works as a rectifier and the DC voltage source (Uc) is switched off, and its contacts fit 1.1, k 1.2, K 2.1, Ar 2.2) are open as long as the circuit works as a DC power controller and c'i DC voltage source (Uc) is connected. 2. Converter circuit according to claim 1, characterized in that; n Se ^ e to the DC voltage source (Uc), a DC switch (S) and a choke coil (LF) are arranged.