DE2233950B2 - Static converter with capacitors - dischargeable at any time in half-wave into DC load at output of half-controlled rectifier - Google Patents

Abstract

The static converter has the supply transformer's secondary connected via a half-controlled rectifier bridge to the inductive load (e.g. motor). A first capacitor (C1) is connected in series with a first charging diode (D1) across the secondary. A second capacitor (C2) is coupled in series with an oppositely poled charging diode (D2) across the secondary. Two discharge thyristors (Th1, Th2) each connect one capacitor to one d.c. pole of the load. Several capacitors, diodes and discharging thyristors can be used. The capacitors may be electrolytic. The advantage lies in being able to pass the energy stored by the capacitors to the d.c. load circuit at any time and thereby improve the power factor.

Description

The invention relates to a switching arrangement for improving the power factor with a converter Energy consumers controlled with natural commutation, with capacitors via semiconductor valves are loadable and / or unloadable. Such a switching arrangement is known from DT-OS 16 38 451.

Conventional converters with phase control and natural commutation cause known inductive Reactive power, which is composed of distortion and displacement reactive power and depending on The degree of modulation can be considerable. So far has been to improve the power factor and to Stabilization of the network to the consumer on the alternating current side a corresponding capacitor bank connected in parallel and thereby compensates the reactive power directly at the consumer.

In the case of electric traction vehicles with gate control, the can be used to compensate for the reactive power necessary capacitors can no longer be accommodated in the vehicle for reasons of weight. That's why Capacitor batteries were partially installed in the substations. Through this central compensation At least the energy producers are relieved and the grid stabilized. Since the with this method Reactive power oscillating between the consumer (reactive power generator) and the compensation capacitor cannot be influenced, there is an additional load on the (overhead) line, which is the worst Trap higher than the real power can be.

In addition, the harmonics that occur can get into the network unhindered and a cause considerable waveform distortion which is very detrimental to other consumers can. The possibility of influencing frequency-dependent signal circuits illegible in rail operations can not be excluded.

Switching arrangements are also known in which the use of two or more controllable sequential bridges achieves a reduction in the reactive power occurring during the gate control with natural commutation. In addition, converter circuits are known where the reactive power that occurs can be reduced by forcing the thyristors to be extinguished and by using two or more subsequent bridges at the same time.
The invention is based on the object of releasing the energy stored in the capacitors into the DC-side load circuit at any selectable times, each within a half-cycle. According to the invention, this object is achieved by

ίο that at least one bridge unit on the AC side from a converter with it for the positive and negative half-wave parallel series connection and capacitors and charging diodes and one discharge thyristor between each capacitor and charging diode on the one hand and the DC-side output of the converter on the other hand is switched.

A further embodiment of the invention consists in that a converter is provided with more than two capacitors, two charging diodes and two discharge thyristors. If the discharge thyristors are ignited at different times, the compensation effect is increased and the harmonic content in the primary current is further reduced.
In addition, the invention can be further developed through the use of bipolar electrolytic capacitors. This significantly reduces the weight for the compensation capacity required in each case.
The advantages achieved by the invention are in particular that the targeted discharge shifts the current-time area of the fundamental wave of the mains current in the capacitive direction, thereby improving the power factor. At the same time, the energy withdrawn from the network in each half-wave in the capacitive range is fed as active energy to the consumer in the direct current circuit.

This not only reduces the reactive power shift, but also increases the active current component in the load circuit. In addition, the switched-on capacitors dampen the harmonics that occur, so that the distortion reactive power is also significantly reduced.
Since the compensation capacitors are charged via the upstream diodes and thus only draw energy from the network when the main thyristors of the converter are ignited, overcompensation of the network cannot occur.
In the event of short circuits or sudden mains disconnections, the built-in charging diodes prevent the compensation capacitors from discharging through the transformer winding, which without these charging diodes would destroy the winding if the capacitor output is high.

An embodiment of the invention is shown in the drawing and described in more detail below. It shows

Fig. 1 shows a circuit arrangement of a converter with two capacitors, two charge diodes and two discharge thyristors and

F i g. 2 an expanded circuit arrangement of a converter with four capacitors, charging diodes and discharging thyristors each.
The switching arrangement according to FIG. 1 shows a

H5 transformer 7r with the windings Wi, W2. A known asymmetrical controlled single-phase rectifier bridge (converter) with the main thyristors Ti and is connected to the secondary winding W2

72 and the freewheeling diodes G 1 and G 2 connected. A mixed current motor M with an upstream smoothing choke L, which is fed via the converter, is provided as a consumer.

According to the invention, the converter, which is known per se, has a series connection of the customer Ci and charging diode Dl and, for discharging the capacitor C 1, a discharging thyristor Th 1 for the positive half-wave and a series connection of capacitor C2 and charging diode D2 and a discharge thyristor Th for discharging the capacitor C2 2 connected in parallel for the negative half-wave.

The capacitor CX in the positive half wave or the capacitor C2 in the negative half-wave to the peak value of the pending secondary voltage ⁵ charged (positive and negative ^| is the primary winding Wl applied voltage and the main thyristors 7Ί and T2 of the power converter will not be initially ignited, then Half-waves are each related to the primary voltage). The arrangement then draws capacitive reactive current from the network once during two successive half-waves.

If there is a positive half-wave, z. B. the stored energy from the capacitor C 2, which is negatively charged, by igniting the discharge thyristor 77? 2 can be output as active energy via the consumer circuit at any freely selectable point in time in the half-wave. The capacitor C2 is not only discharged, but also the voltage of the positive half-wave that is present is charged to the opposite polarity. During the charge reversal, current flows from the capacitor C2 via the secondary winding W2, the freewheeling diode G 1, the mixed current motor M, the smoothing choke L and the discharge thyristor Th 2. The conductive discharge thyristor 77) 2 is extinguished as soon as the charging current of the capacitor C2 becomes zero. The main thyristor 7 * 1 for the positive half-wave can now be ignited in the conventional manner and the current flow can be initiated according to the selected control angle A.

By activating the discharge thyristor Th 1, the same process is then initiated for the negative half-wave.

Since, according to the invention, the ignition times of the discharge thyristors can be shifted at will during the duration of a half-wave and none at all The arrangement allows e'ne to influence the load current and the compensation current Shifting of the Stromzeilil areas and thus the Current fundamental wave, so that a significant improvement in the displacement performance is achieved and at the same time the stored energy is used as active energy.

The effect of the switching arrangement is increased if more capacitors, charging diodes and discharging thyristors are used (FIG. 2). Since the load current and the compensation current do not influence each other, the discharge thyristors 77? 2 and Th 4 (for the positive half-wave) and Th 1 and Th 3 (for the negative half-wave) can be ignited at any point in time in the relevant half-wave. If the current-time areas from the capacitors C1, C2, C3 and C4 charged via the charging diodes D1, D2, D3 and D4 are appropriately positioned, a maximum of compensation is achieved.

The circuit elements known per se for the thyristors, discharge resistors for the capacitors and small inductances to dampen the steepness of the current, among other things. are shown in FIGS. 1 and 2 for the better Overview not shown.

The pulses for driving the thyristors are generated in a manner known per se.

1 sheet of drawings

Claims (3)

Patent claims: 1. Switching arrangement to improve the power factor and to stabilize alternating current networks, in particular with energy consumers controlled by converters with natural commutation, in which capacitors can be charged and / or discharged via semiconductor valves, characterized in that at least one bridge unit from a converter with it on the alternating current side for the positive and negative half-wave parallel series connection of capacitors (Ci, C2) and charging diodes (D 1, D 2) and one discharge thyristor (Th 1, Th 2) between the capacitor (CX, C2) and the charging diode (Di, DT) on the one hand and on the other hand, the output of the converter on the DC side is switched. 2. Switching arrangement according to claim 1, characterized in that a converter with more than two capacitors, two charging diodes and two discharge thyristors is provided. 3. Switching arrangement according to claim 1, characterized by the use of bipolar electrolytic capacitors.