SU99690A1 - Device for protection of high-voltage valve-mounted safety device from overvoltages - Google Patents

Description

It is known that the protection of high-power high-voltage converter units from overvoltages arising from a sudden current interruption in one of the burning valves can be achieved by automatically forcing current into one of the valves of the same group, which will result in the flow of rectified current and overvoltages will be drastically reduced.

A disadvantage of the known devices of this type, in which this forced connection is provided as a result of using an overvoltage during a break, and switching a capacitor between the anode and control grid of each valve, is the possibility of the inverter tipping over and "interruptions in the operation of the installation."

In addition, it is not always acceptable to consider an increase in capacitive coupling between the grid and the anode of the valve.

The proposed device for protecting a high-voltage valve installation, in which a sudden current interruption in one of the burning valves is accompanied by automatic forced ignition of another valve, is based on the use of a sharp drop in the current in the emergency valve circuit.

For this, according to the invention, the primary windings of the transformers are connected in series with the secondary windings of the supply transformer and into the cathode chains of the cathode valves, the secondary winding of each of which is connected to the grid-to-cathode gap through a series-connected resistance.

This makes it possible to provide increased stability of the operation of the converter plant as a whole.

The drawing shows a schematic diagram of a scaled-phase bridge converter installation with a device for protecting it from overvoltages arising from a sudden current interruption in one of the burning valves.

In series with the star-connected secondary windings of the transformer supplying the installation

The primary windings of control transformers 1, 2 and 3 without ferromagnetic cores are included. These three transformers control the anode group of valves BJ, OT and 55. The primary and secondary windings of these transformers are isolated from one another on the secondary phase voltage of the supply transformer.

The cathode chains of the gates B2, B4, B6 are cathode groups. They include primary claddings of control transformers 4 and 6 and 5 respectively, which control the gates of the cathode group. These transformers are insulated by winding and made of several hundred volts.

If an arc is broken in any valve, then a quick unipolar change in the current in the primary winding of the corresponding control transformer 1-6 will cause an EMF in the secondary winding, approximately proportional to

N, where M is the coefficient of mutual induction between the windings of the control transformer, and i is the magnitude of the interrupting current.1; i

As a result, on the grid of the locked valve of this group, which was supposed to be lit in order of priority (for example, valve B4 after valve B2; valve EOI after valve B1, etc.), through separation capacitors 7 (and in parallel with resistor 8) a potential is applied. The valve is ignited, which prevents the rectified current from falling.

In the secondary windings of control transformers emf Induced not only in case of an emergency current interruption in the arc, but also during normal switching.

However, the rate of change of current in the valve during the normal switching process is much less than when the arc is broken. As a consequence, the small eds will be, induced by

in the secondary windings of control transformers.

The parameters of the coupling capacitors 7 and the resistance 8 are chosen so that, with relatively slow / normal switching processes, the voltage drop Uc on the capacitor 7 is much greater than the voltage drop UK on the resistance 8.

With very fast processes that occur when an arc breaks, this ratio between voltage drops Uc and Ufj changes, and you can always choose the ratio between capacitors 7 and resistance 8 to.

Consequently, the separation capacitors 7 play the role of a filter that, during normal switching, does not pass a positive potential to the grid of the locked valve and provides the ignition positive potential at an emergency break in the arc of the valve.

Subject invention

A device for protecting a high voltage valve converter installation from overvoltages arising from a sudden current interruption in one of the burning valves by means of an automatic forced hall and another valve of the same group, characterized in that, in order to increase the stability of the installation, sequentially with secondary the windings of the supply transformer and the cathode chains of the cathode group valves include the primary windings of transformers without ferromagnetic cores, the secondary winding of each of which The grid – cathode of the adjacent valve is connected to the gap through serially connected separation capacitors and a parallel-connected resistance, which passes a positive potential to the control grid only in the event of an emergency current interruption.

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