DE2827736C2 - Control of GTO thyristors - Google Patents

Description

The invention relates to a control circuit according to the preamble of claim I. Such maintenance is described in DE-OS 26 06 304.

In the English Technical terminology referred to as “gate turn-off silicon controlled reciifier” or “GTO” for short. These CTO thyristors have the same basic regenerative semiconductor structure with 4 layers and 3 Transitions on and can also be switched on by pulses like a conventional tyhristor. you The difference to the conventional tyhristors, however, is that they are generated by applying a negative Switch off the voltage at the control connection. It is therefore necessary to turn off a GTO thyristor not required as with conventional tyhristors, to reduce the anode current.

The circuit specified in DEOS 26 06 304 shows one possibility, such as the one for ignition and Blocking a GTO thyristor continuously alternately (i.e. frequency-dependent) on the necessary pulses Control connections can be given. The transformer is not used to isolate poles between the sleuer connection of the thyristor and the pulse-generating control

A potential-free control of GTO thyristors In practice, however, it is desirable or even absolutely necessary in many cases. The invention aims therefore to achieve control using potentially separating components.

Since a GTO thyristor uses pulses to ignite

given the one polarity and to lock the opposite polarity on the control terminal need to be, it is conceivable to use two pulse transformers assigned to the respective pulse polarity

(Transformer) to be used for electrical isolation. However, this circuit has the disadvantage that when Fntmagnetisierung of the transformer creates an opposite current, which inadvertently locks in the event of a low load or ignition causes.

The invention is based on the object of a

potential-free, frequency-independent control by means of Single pulses or a pulse chain using only one pulse transmitter for the and turn off a GTO thyristor, the starting after each current pulse Demagnetization of the pulse transformer has no effect on the current via the control connection of the Has thyristor.

This object is achieved according to the invention in the control circuit specified at the outset by the characterizing features of claim 1 solved

The control circuit is very simple in its structure, because only one to achieve the potential freedom Regardless of the frequency, positive or negative single or multiple pulses can be applied Transformer is used whose demagnetizing current can only flow on the primary side, because in each case one of the secondary-side Zener diodes prevents a grid current.

Advantageous refinements of the invention are specified in the subclaims J5 and are described below explained in more detail.

An exemplary embodiment of the control circuit according to the invention is to be described with the aid of the drawing will. It shows

F i g. 1 the basic circuit diagram of the control circuit and Fig. 2 the time courses of current and

Voltage at selected points in the circuit.

Fig. 1 shows a control circuit of a GTO tyhristor Vb. its anode with A. its cathode with K and its control connection (grid) with C.

For the purpose of potential separation of the pulse setting stage from the grid-cathode path of the thyristor Vb , a transformer Π is provided, in which the winding

ίο sense of the primary winding between the connections 1 and 2 and the secondary winding between terminals 3 and 4 each by a point is marked.

In the secondary circuit of the transformer Tl. By the

Vi control current ir. For the tyhristor V6 flows, two oppositely connected in series Zener diodes V 4 and V 5 are arranged. In addition, a capacitor Cl and a resistor Rr are parallel to the secondary winding

The primary winding of the transformer T 1 can optionally be applied to a supply voltage U _s (towards 0 V) by means of switches 51, 52 and S3, which are preferably designed as semiconductor switches and via one of the resistors R 1 or R2.

To demagnetize the primary winding, two diodes V2 and V3 are provided which, depending on the flow through the primary winding, are connected to a further Zener diode V1 through the switch 51

will.

The switches SI, S2 and S3 are operated via three amplifiers N 1, Λ / 2 and / V3. The ON-OFF sign! for the GTO thyristor V6 controls the amplifier Ni via a switch-off delayed stage D 4. Together with the chain pulses from a pulse generator DX , the ON-OFF signal also controls amplifier N 2 via an UN D link D 2. The output signal of stage D 4 controls amplifier A / 3 with a monostable stage D 3.

Points characteristic of the operating mode of the circuit described below are denoted by a to Jt in FIG. 1. These points are denoted accordingly in FIG. 2 the potential curve plotted.

In the example chosen, during the ON time (thyristor V 6 is ignited) a pulse sequence (chain pulse) is to be specified on control terminal G of thyristor V6. At the end of the ON time, the tyhristor V6 should be extinguished with a single pulse. It is shown in FIG. 1 the status »ignition«.

If the thyristor V 6 is to be ignited, the AND element D2 will link the potential curves a & f = g and use these pulses to control the switch S2 in accordance with curve g . As a result, the supply voltage Ub is applied to the primary winding (1-2) of the pulse transmitter TX and, for this purpose, in series to the resistor R 1. In Fig.2 it was assumed that half of the voltage is applied to the transformer 7 * 1 and the resistor /? ! so divides. The magnitude of the current can be determined with the resistance value. The voltage of the primary side of the transformer TX is imaged on the secondary side ais potential difference d-k, so that via the Zener diodes V4 in the forward and V5 in α reverse direction and the control terminal-to-cathode path of the to be fired thyristor V6 a current / '<-; is driven. During the pulse time, a magnetizing current ί _μ also flows (cf. in FIG. 2 the curve of ί _μ ), which is impressed by the main inductance of the transformer T. and at the end of the chain pulse, when switch S2 opens, would like to continue flowing. This is possible via the circuit switch Si, primary winding (1-2) of the transformer 7 * 1, diode V 2, Zener diode Vl ₁ whereby the voltage direction at the transformer TX 4 ·> changes and the amount is essentially determined by the Zenerdi & Je Vl. Dk-'se voltage should now be selected so high that, on the one hand, demagnetization can take place during the pulse pause (ί _μ = 0 A), on the other hand, the voltage is lower than the voltage of the Zener diode V4; because this counter-voltage at V4 ensures that, despite the voltage being applied between points r / and k in the opposite direction, no control current ic (cf. in FIG. 2 the course of ία) flows in the opposite direction. This current would unintentionally extinguish the thyristor, but this is not possible because the Zener voltage at the Zener diode V4 is greater than the driving voltage between points d and k. The capacitor C1 should be selected to be large compared to the capacitances of the Zener diodes V4 and V5, so that no current peaks occur even with the changeover switch. The process described can now, as shown in FIG. 2 can be repeated as often as desired.

At the end of the ON time, the thyristor V6 should be deleted. The potential at point a consequently becomes zero and causes switch S2 to open, after the demagnetization time (stage D4) to switch over switch S1 and, via the negating input of monostable stage D 3, a single pulse h. is via the amplifier Λ / 3 the switch S3 during a short, defined period of time closes Thus, the supply voltage Ub with reversed polarity than during the ignition of the primary side of Iuipulsübertragers Tl set (terminal 2 is positive, terminal 1 negative). In series with this there is again a current-determining resistor R 2, which in practice has a lower resistance than the wideband R 1, since a greater current is required to block a thyristor than to trigger it. The secondary voltage corresponding to the potential difference dk between points d and k drives a clearing current via the cathode control connection path, which initially represents a short circuit, and via the Zener diode V5 in the forward direction and the Zener diode V4 in the reverse direction. As the evacuation current becomes smaller, the negative voltage on the cathode control connection section increases up to the open circuit voltage, since the cathode control connection section then blocks and thus the cathode-anode section also blocks. At the end of the evacuation pulse, the switch S3 opens, and the demagnetization current ί _μ flows through the diode V3, the Zener diode Vl and the switch Sl until it becomes zero. During this time there is positive voltage at the pulse transformer Ti , the size again being determined by the Zener diode Vl. Exactly as in the case of demagnetization after ignition, the driving secondary voltage must also be smaller than the Zener voltage of the Zener diode V5 in the case of the demagnetization after blocking. so that no current flows that would re-ignite the tyhristor V6.

For this purpose 2 sheets of drawings

Claims (4)

Patent claims: ! .Control circuit with one transformer for one Thyristor which can be switched on and off via its control connection, characterized in that control pulses of both polarities can be applied to the primary winding of the transformer and the Secondary winding of the transformer with the control terminal and the cathode of the thyristor two zener diodes connected in series with one another, the zener voltage of which is smaller than the voltage at the transformer when it is magnetized, but greater than when it is Demagnetization. 2. Control circuit according to claim 1, characterized in that parallel to the path control connection — cathode of the thyristor, a capacitor is connected, the capacity of which is large opposite the capacity given by the two Zener diodes. 3. Control circuit according to one of claims 1 or 2, characterized in that the Primary winding of the transformer via a switch and alternately depending on the flow of the A further Zener diode is connected to the transformer via a diode, the Zener voltage of which is smaller is than the respective Zener voltage of the Zener diodes on the secondary side of the transformer. 4. Control circuit according to one of claims 1 to 3, characterized in that optionally switchable, the series resistances in the series that determine the ignition and clearing currents for the thyristor Circuit with the primary winding of the transformer are provided.