SU1224896A1 - Device for checking conditions of converter thyristor - Google Patents

Abstract

The invention relates to electrical engineering and can be used to monitor the state of thyristors and to protect transducers made according to bridge and zero circuits. The purpose of the invention is to extend the functionality by determining a breakdown type of failure, eliminating a false failure signal in the event of a load current decreasing to zero in the intermittent current mode when a control pulse or a repeated pulse is applied to the thyristor and determining the type of fault. The device co-supports 1 and 2 isolation, controlled thyristor 3, thyristor 4, current sensor 5, trigger 7. The introduction of a pulse shaper 6, a BAN 8 element, an AND 9 element, a delay element 10 is used to monitor the state of a single thyristor converter with any number of phases. The number of such devices is determined by the number of transducer arms. The presence of two outputs from each device allows the indication of a malfunction, to determine the location and nature of it. 1 il. (O N wffuKo i u (Y Is3 Yu 4 00 CO O) M monu ind1 // atstsi and ol1k g} 1 / e- ni

Description

The invention relates to electrical engineering and can be used to monitor the state of thyristors and to protect transducers made according to bridge and zero circuits.

The purpose of the invention is to extend the functionality by determining a breakdown type of breakdown at the time of its occurrence, eliminating a false failure signal if the load current decreases to zero in the intermittent current mode when a control pulse or a repeated pulse is applied to the thyristor and determining the type of fault.

The drawing shows the functional diagram of the device.

The device for monitoring the thyristor status of the converter contains the first 1 and second 2 isolators (which can be used as optocouplers), the inputs of which are respectively connected to the control transitions of the monitored thyristor 3 and thyristor 4 of the next order phase switch the same group of valves, sensor 5 of the current of the controlled thyristor, the output of which

through the pulse shaper 6, it is connected to the first input of the trigger 7, the prohibition element 8, the first (inverse) input of which is connected to the output of the junction 1, and the second (direct) to the output of the current sensor 5, element 9, the first input of which is connected through the delay element 10 to the output of the first isolation element 1, and the second to the inverse output of the trigger 7, the second input of which is connected to the output of the second isolation element 2.

The device works as follows.

In normal operation, the converter is in continuous load current mode after the application of a control pulse to the thyristor 3 through which the current flows. From the output of the element 1 uncoupling to the pen, the inverse input of the element BANCH 8 enters “1 due to the fact that there is a drop in voltage on the control of the thyristor 3 transition. Pa the second direct input of the element BAN 8 also enters output "Oh, i.e. signal indicating the health of the thyristor.

At the same time, the first input of the element And 9 enters “1, and its second input,“ O, from the inverse output of the trigger 7, due to the arrival at the first input of the trigger 7 of the installation pulse from the driver 6 of the pulses when a current occurs in the thyristor 3. This leads to the presence at the output of the element P 9 "Oh, also indicating the health of the thyristor 3.

If the thyristor 3 was pierced before the control pulse, then when it appears, the first input of the BANCH element will go “O, because the voltage at the control transition will drop to zero, and the second input will be fed to“ 1 ”

current flow through the thyristor 3. As a result, at the output of the element BANGE 8, the “1. In the case of the probe thyristor 3, after the arrival of the control pulse, as in the previous case, the first inverted input of the BANCH element is received “O, and the second -“ 1. As a result, at its output “1.

If the thyristor is punctured by reverse voltage while the thyristor is operating, another

0 phase of the same group of gates, then "O" also goes to the first input of the BANCH element 8, since the control pulses do not reach the thyristor 3, and the second - "1" due to the flow of the reverse emergency current through the thyristor 3. As a result, “1 at the exit. Thus, in any case, a probe thyristor 3 pa of the output of the BENEFIT element 8 appears "1", which is a breakdown signal of the type.

das.ly thyristor 3 has a fault type

"A break, then when a control pulse arrives at it, no current flows and the adjusting pulse is not supplied to the first input of the trigger 7, the inverted output of the trigger 7 to the second input of the element And 9 enters

5 "1, due to the fact that a reset pulse was applied to the second input of trigger 7 from the output of the second isolator at the time of turning on the thyristor 4 of the next phase; At the first input of the element AND 9, through the element of delay 10 it enters the "1, as a result of which the output appears" 1, indicating a fault of the type "break. During normal operation of the thyristor 3, under the action of the current sensor 5 signal, the pulse shaper 6 generates a pulse that sets the trigger 7 to the position to which corresponds to “On the inverted output, in this case,“ 1 second of the first element of the first isolation 1 must go to the first input of the And element 9 after the current flows through the thyristor 3 and on the code

0 trigger 7 is set to “O. For this purpose, the signal from the output of the first isolation element 1 to the first input of the And 9 element is fed through the delay element 10.

In the mode of intermittent currents, when pos-.: Ic of the first reset, the load current decreases to zero, the output of the BAN 8 element remains "O, since its state at the current, the rav bullet, does not depend on the value of the signal received from the first element 1 times, and it can be zero at

Q control with a single pulse and a pause in a burst of pulses or - “1 at the moment of applying the pulse.

This device is used to monitor the state of one thyristor of the converter with any number of phases. The number of such devices for the entire transducer55 is determined by the number of its arms. The second element of the thyristor control used in this unit when monitoring thyristor 4 you0

five

plays the same role as the first element of the 1 isolation in the control of the thyristor 3, and the first element of the 1 isolation during the control of the thyristor of the previous phase performs the same role as the second in the control of the thyristor 3.

The presence of two outputs from each device makes it possible to determine the nature and location of the malfunction after switching off the converter at the expense of the same signals by bringing them to the display unit.

Claims (1)

Invention Formula A device for monitoring the thyristor status of the converter, containing the first and second isolation elements, the inputs of which are intended to be connected to the control transitions of the controlled thyristor and thyristor, respectively, of the next order of the phase of the same group of gates, current sensor intended for series connection 0 five into the power circuit of the controlled thyristor, and a trigger, the first input of which is connected to the output of the current sensor, characterized in that, in order to extend the functionality by detecting the shadow of the breakdown type at the time of its occurrence, eliminating a false failure signal in the event of a decrease in load current to zero in the mode of intermittent currents when applying to the thyristor a packet of control pulses or a repeated pulse and determining the type of malfunction, the pulse shaper, the AND, the BAN and the delay element are entered, while the current sensor output through the pulse shaper is connected to the first trigger input, the second input of which is connected to the output of the second isolating element, and the inverse output is connected to the first input of the And element, the second input of which is connected to the output of the first isolation element and the first input of the element BAN, the second input of which is connected to the output of the current sensor.