SU855551A1 - Device for checking high voltage gate thyristor - Google Patents

Description

one

The invention relates to electrical engineering, in particular, to systems for protection against accidents of static converters on thyristors and can be used in high-voltage thyristor valves for direct-current power transmissions.

A device is known for monitoring the state of series-connected thyristors, which contains a voltage divider, which forms a signal bridge with a controlled valve circuit, the diagonal of which includes the reactive protection body Cll

The drawbacks of the device are low accuracy and noise immunity.

HstBecTHo a high-voltage thyristor control device containing RC circuits and Controlled impulse formation units according to the number of controlled thyristors, reactors, control impulse shaping device connected to a high-voltage cable that connects the primary circuits With the disadvantages of this device are the difficulty due to the need to isolate both transformer windings from breakdown by the full voltage of the valve and low noise immunity due to the appearance of false impulses- at. a thyristor valve with internal voltage reactors with different build-up rates.

The purpose of the invention is to improve the noise immunity of the device by eliminating the dependence on the shape

10 applied voltage.

The goal is achieved by the fact that the high voltage valve thyristor control device contains RC circuits and control pulse generation units using a number of thyristors, reactors, a control pulse driver connected to a high voltage cable that is common primary winding

20 current transformers, the secondary windings of which are connected to the thyristor control circuits, are introduced — additional current transformers according to the number of thyristors, the total primary

25 the winding of which is the aforementioned cable, a negative voltage sensor on the high voltage valve, a control unit connected to the cable and the i :: negative voltage sensor,

30, wherein the control pulse generation units are connected to the secondary cores of additional transformers.

In addition, the control pulse generation unit contains a power detector, a control pulse generator and a reset element, the energy storage device being connected to a control pulse generator to which a reset element connected to the corresponding thyristor ftC circuit is connected, through an additional transformer current to high voltage cable.

The drawing shows a diagram of the device.

The device for controlling the valve containing reactors and thyristors 2, includes RC circuits consisting of capacitors 3 and registers 4, driver 5 control pulses high voltage cable b, current transformers 7, diodes 8, negative voltage sensor 9, unit 10 control, additional current transformer 11, energy storage 2, consisting of a diode 13 and a capacitor 14, a control pulse generator 15, consisting of a resistor 16, a capacitor 17, a dynistor 18, a reset element 19 containing a thyristor 20, a pulse transformer 21.

The device works as follows.

In accordance with the voltage phase at the valve and the control angle, the shaper 5 starts the control pulses. The control pulses through the high-voltage cable 6, current transformers 7 and rectifying diodes 8 are fed to the control electrodes of the thyristors 2 of the valve. At the same time, control pulses through diodes 13 charge accumulative capacitors 14 in energy accumulators 12. When thyristors 2 are turned on, capacitors 3 are discharged through resistors 4 and through the primary windings of current pulse transformers 21, which turn on thyristors 20 in reset element 19. Thus, when the thyristors are in good condition, 2 valves do not receive power supply to the generator 15 control impulses. In the case of the thyristor 2, the corresponding capacitor 3 of the RC circuit is not charged, and therefore, the switching on of the reset element 19 stops. In this case, from the charged control pulse of the storage capacitor 14, the capacitor 17 starts to charge through the resistor 16. The charge time of the capacitor 17 to the switching voltage of the distor 18 is selected taking into account the time and the moment of generation of the control pulse until a negative voltage is applied to the valve.

At the moment of switching of the dynistor 18, the storage capacitor 14 is discharged through the secondary winding of the auxiliary current transformer 11. A low-voltage sign arriving at the input of the control unit 10 appears at the primary winding of the transformer. From the negative voltage sensor 9 for the entire duration of the application of a negative voltage to the valve, the control unit 10 is turned on, with which the specified pulse is detected. When used in generators 15 control pulses of different values (nominal values) of the resistances of resistors 16, bit capacitors 17, as well as various types of dynistors 18, it is possible to form control pulses during the breakdown of thyristors that are shifted in time. In this case, a pulse counter should be used as a control unit. When using identical elements in generators of control pulses, an integrator should be used as a control unit. In the case of breakdown of the number of thyristors above a predetermined value by the block 10, the inclusion of appropriate devices that protect the high-voltage gate can be made.

The use of the proposed device provides, in comparison with the known ones, a significant simplification of the structural implementation, and consequently, the cost of the device, as well as an increase in the reliability of the protection elements by increasing the noise immunity.

Claims (2)

1. A thyristor control device for a high-voltage valve containing RC circuits and control pulse generation units according to the number of controlled thyristors, reactors, a control pulse driver connected to a high-voltage cable, is a common primary winding of current transformers whose secondary windings are connected to thyristor control circuits , characterized in that, in order to improve noise immunity by eliminating the dependence on the form of the applied voltage, it is equipped with additional transformers According to the number of thyristors, the common primary winding of which is the mentioned cable, a negative voltage sensor on the high voltage gate, a control unit connected to the cable and a negative voltage sensor, while the control pulse generation units are connected to the secondary windings of additional transformers. 2. The device according to claim 1., characterized in that the node for forming control pulses contains an energy storage device, a control pulse generator and a reset element, the energy storage device being connected to a control pulse generator to which a reset element connected to an RC circuit is connected. 6 the corresponding thyristor, the output of the control pulse generator is connected via an additional current transformer to the high-voltage cable. Sources of information taken into account in the examination 1. USSR author's certificate No. 225302, cl. G 01 R 31/26, 1962. 2. The copyright certificate number 235157, cl. H 02 M 7/12, 1964 (prototype).