RU2112989C1 - Thyristor quality control device - Google Patents

Abstract

FIELD: electrical engineering; quality control in thyristor design and manufacture. SUBSTANCE: device has forward current pulse source, reverse voltage pulse source, forward voltage pulse source, first controlled switch, reverse control current pulse source, control unit, terminals for connecting thyristor under test, zero current sensor, second controlled switch, third controlled switch, current sensor, first time interval meter, second time interval meter, first storage unit, second storage unit, comparison unit, indicator. EFFECT: provision for automating thyristor quality control process.

Description

 The invention relates to electrical engineering and can be used in the design and manufacture of thyristors.

 A device is known that contains a direct current pulse source connected to a control key, a tested device and a measuring resistor, a reverse voltage pulse source, a control unit, an oscilloscope (GOST 24461-80).

 By measuring the turn-off time using this device, you can control the quality of thyristor manufacturing. However, this device does not detect poorly made rectifier elements of the thyristor having a lower value of the critical inclusion charge in the local region located under the cathode emitter junction.

 A device is known that contains counter-connected sources of direct current and reverse voltage pulses, a source of direct voltage pulses, a first controlled key, a source of reverse control current pulses, a control unit, terminals for connecting the anode, cathode and control electrode of the tested thyristor, and a terminal for connecting the tested anode the thyristor is connected to the positive terminal of the direct voltage pulse source and to the terminal of the first controlled key, the input of which is connected to the positive water of the direct current pulse source and to the negative terminal of the reverse voltage pulse source, the terminal for connecting the control electrode of the tested thyristor is connected to the negative terminal of the reverse current pulse source and to the first output of the control unit, the positive terminal of the reverse current pulse source is connected to the cathode terminal of the thyristor under test, the second output of the control unit is connected to the input of the direct current pulse source, the third to the input of the source reverse voltage pulses, the fourth - with the control input of the first controlled key, the fifth - with the input of the direct voltage pulse source (Electricity, N 10, 1977, p. 82-84).

 This device allows you to identify poorly made rectifier elements of the thyristor, having a reduced critical charge in the local region located under the cathode emitter junction, by twice measuring the off time. Moreover, the first measurement is performed with the reverse control circuit of the rectifier element turned off, the second measurement with the reverse control circuit of the rectifier element turned on and if it is present at the time the direct current through the thyristor decreases to zero. If during the repeated measurement, the value of the switching-off time of the rectifier element turns out to be shorter than during the first measurement, then this rectifier element has a lower value of the critical inclusion charge in the region located under the cathode junction, i.e., it is made poorly.

 The disadvantage of this device is the inability to automatically determine the manufacturing quality of the thyristors associated with manual switching of the reverse current control circuit of the tested thyristor and calculating the difference between the shutdown times in the first and second measurements.

 The objective of the invention is the automation of the quality control process.

 This object is achieved in that in a device containing counter-connected sources of forward current and reverse voltage pulses, a direct voltage pulse source, a first controlled key, a reverse current pulse source, a control unit, terminals for connecting the anode, cathode and control electrode of the tested thyristor, moreover, the terminal for connecting the anode of the tested thyristor is connected to the positive terminal of the direct voltage pulse source and to the terminal of the first controlled key, the input of which connected to the positive terminal of the direct current pulse source and to the negative terminal of the reverse voltage pulse source, the terminal for connecting the control electrode of the tested thyristor is connected to the negative terminal of the reverse current pulse source and to the first output of the control unit, the positive terminal of the reverse current pulse source is connected to a terminal for connecting the cathode of the thyristor under test, the second output of the control unit is connected to the input of a direct-current pulse source ok, the third - with the input of the reverse voltage pulse source, the fourth - with the control input of the first controlled key, the fifth - with the input of the direct voltage pulse source, the zero current sensor, the second and third controlled keys, the current sensor, the first and second time interval meters, the first and second storage blocks, a comparison unit, an indicator, and a terminal for connecting the cathode of the tested thyristor is connected to the output of the current zero sensor, the first output of which is connected to the negative terminal of the pulse source direct current and to the positive output of the reverse voltage pulse source, the second output is connected to the input of the second controlled key, the output of which is connected to the first input of the first time interval meter, and the third output of the current zero sensor is connected to the input of the third controlled key, the first output of which is connected to the input pulses of a reverse control current pulse, and the second with the first input of the second time interval meter, and to the first output of the current sensor, the input of which is connected to the negative output of the source nickname of direct voltage pulses, the second output of the current sensor is connected to the control input of the second controlled key, the third output of the current sensor is connected to the input of the control unit, the fourth with the second input of the first time interval meter, the fifth with the second input of the second time interval meter, the sixth with the control input of the third managed key, the output of the first meter of the time interval is connected to the input of the storage unit, the output of which is connected to the first input of the comparison unit, the output of the second meter the time interval is connected to the input of the second storage unit, the output of which is connected to the second input of the comparison unit, and the output of the comparison unit is connected to the indicator.

 The drawing shows a block diagram of a device.

 The device contains a source of 1 pulses of direct current, a source of 2 pulses of reverse voltage, a source of 3 pulses of direct voltage, the first controlled key 4, a source of 5 pulses of reverse current control, a control unit 6, terminals 7, 8, 9 for connecting the test thyristor, a zero sensor 10 current, second controlled key 11, third controlled key 12, current sensor 13, first time interval meter 14, second time interval meter 15, first storage unit 16, second storage unit 17, comparison unit 18, indicator 19. Source The nickname of 1 forward current pulses and the source of 2 reverse voltage pulses are interconnected in the opposite direction. Terminal 7 for connecting the anode of the tested thyristor is connected to the positive terminal of the source of 3 forward voltage pulses and to the output of the first controlled key 4, the input of which is connected to the positive terminal of the source 1 of direct current pulses and to the negative terminal of the source of 2 reverse voltage pulses.

 Terminal 9 for connecting the control electrode of the tested thyristor is connected to the negative terminal of the source 5 pulses of the reverse control current and to the first output of the control unit 6. The positive terminal of the source 5 pulses of the reverse control current is connected to terminal 8 for connecting the cathode of the thyristor under test. The second output of the control unit 6 is connected to the input of the direct current pulse source 1, the third to the input of the reverse voltage source 2, the fourth to the control input of the first control key 4, and the fifth to the input of the direct voltage pulse source 3. Terminal 8 for connecting the cathode of the test thyristor is connected to the input of the current zero sensor 10, the first output of which is connected to the negative terminal of the direct current pulse source 1 and to the positive terminal of the reverse voltage pulse source 2, the second output is connected to the input of the second controlled switch 11, the output of which is connected with the first input of the first meter 14 of the time interval, and the third output of the sensor 10 zero current is connected to the input of the third managed key 12, the first output of which is connected to the input of the pulse source 5 in the reverse control current, and the second with the first input of the second meter 15 of the time interval, and to the first output of the current sensor 13, the input of which is connected to the negative terminal of the direct voltage pulse source 3, the second output of the current sensor 13 is connected to the control input of the second controlled key 11 , the third output of the current sensor 13 is connected to the input of the control unit 6, the fourth is with the second input of the first time meter 14, the fifth is with the second input of the second time meter 15, the sixth is with the control input the fourth managed key 12. The output of the first time interval meter 14 is connected to the input of the first storage unit 16, the output of which is connected to the first input of the comparison unit 18. The output of the second time interval meter 15 is connected to the input of the second storage unit 17, the output of which is connected to the second input of the comparison unit 18. The output of the comparison unit 18 is connected to the indicator 19.

 The device operates as follows. According to the "Start" signal, the control unit 6 includes a direct current pulse source 1, a first controlled key and a thyristor under test. A direct current pulse is supplied from a source 1 of direct current pulses. After a specified period of time at the moment when the direct current pulse reaches the amplitude value, the control unit 6 includes a source of 2 reverse voltage pulses, which is used in the device to form a slice of the direct current, reverse current pulses through the tested thyristor and reverse voltage pulses on the tested thyristor. At the time of decreasing the direct current through the thyristor to zero, the current zero sensor 10 provides a signal through the open second controlled key 11 to the first input of the first meter 14 of the time interval. After the pulse reaches the forward current of zero value through the thyristor from the source 2 pulses of the reverse voltage, the current flows in the opposite direction.

 The first controlled switch 4 is open for the passage of reverse current pulses through the thyristor under test. After the shutoff properties of the thyristor are restored in the opposite direction, the passage of the reverse current pulse stops, and the reverse voltage is applied from the source of 2 reverse voltage pulses to the tested thyristor. After a predetermined time interval determined by the control unit 6, the direct voltage pulse source 3 is turned on, and a direct voltage pulse with a predetermined amplitude and slew rate is applied to the tested thyristor. The control unit 6 discretely reduces the time interval between the moment of direct current transition through zero and the moment of application of the direct voltage pulse. Block 6 also sets the frequency of reduction of this time interval. The decrease in the time interval continues until this interval becomes so small that the tested thyristor is not able to withstand the application of the direct voltage pulse and it switches to the moment of switching on the source 3 of the direct voltage pulses, the first controlled key 4 is locked. As the first controlled key 4, for example, a thyristor with a reverse recovery time longer than that of the thyristor under test can be used. At the moment of switching the test thyristor from the current sensor 13, a signal is supplied to the second input of the first meter 14 of the time interval, the output of which forms a time signal corresponding to the time interval from the transition of the current through zero to the moment of switching the tested thyristor. This time signal is supplied to the input of the first storage unit 16. At the same time, a signal is supplied from the current sensor 13 to the control input of the second managed key 11 and to the control input of the third managed key 12. The key 11 is locked and the key 12 is unlocked. Also, from the current sensor 13, the signal is supplied to the input of the control unit 6, which forms a repeated test cycle. But in this case, when the direct current passes through zero, the signal from the current zero sensor 10 enters through the open third controlled key 12 to the first input of the second meter 15 of the time interval and to the input of the source 5 of reverse control current pulses.

 A current flows through the control circuit of the thyristor under test in the opposite direction from the source 5 pulses of the reverse control current. The duration of the reverse control current pulse must be greater than the duration of the reverse voltage pulse at the thyristor under test. When the control unit 6 reduces the time interval between the moment of direct current transition through zero and the moment of application of the direct voltage pulse, the tested thyristor switches, and the current sensor 13 provides a signal to the second input of the second meter 15 of the time interval. At the output of the second time interval meter 15, a time signal is generated corresponding to the time interval from the transition of the current through zero to the moment of switching the tested thyristor. But in this case, the measurement is made in the presence of reverse current in the control circuit.

 This time signal is supplied to the input of the second storage unit 17. From the outputs of the first storage unit 16 and the second storage unit 17, temporary signals are supplied to the first and second inputs of the comparison unit 18. The signal from the output of the comparison unit 18, equal to the difference of the input signals, is fed to the indicator 19, which outputs the result of the subtraction. By the value of the readings of indicator 19, one can judge the quality of manufacturing rectifier elements of thyristors. So, at zero value, the rectifier elements are made qualitatively, at values greater than zero, the rectifier elements have a reduced critical charge in the local region located under the cathode emitter junction, that is, are made with a defect.

 Thus, the proposed device eliminates manual switching of the reverse current control circuit of the tested thyristor and calculates the difference in the recovery time of the locking properties during the first and second measurement cycles, that is, the proposed device allows you to automate the determination of the quality of thyristor manufacturing.

Claims (1)

 A device for determining the manufacturing quality of thyristors, containing counter-parallel connected sources of direct current and reverse voltage pulses, a direct voltage pulse source, a first controlled key, a control reverse current pulse source, a control unit, terminals for connecting the anode, cathode and control electrode of the tested thyristor, the terminal for connecting the anode of the tested thyristor is connected to the positive terminal of the direct voltage pulse source and to the first power terminal the first controlled key, the second power input, the output of which is connected to the positive terminal of the direct current pulse source and to the negative terminal of the reverse voltage pulse source, a terminal for connecting the control electrode of the tested thyristor is connected to the negative terminal of the reverse current pulse source and to the first output of the control unit, the positive terminal of the reverse current control pulse source is connected to the terminal for connecting the cathode of the tested thyristor, the second block output the control is connected to the input of the inclusion of the source of direct current pulses, the third output of the control unit is connected to the input of the source of the reverse voltage pulses, the fourth output of the control unit is connected to the control input of the first controlled key, the fifth output of the control unit is connected to the input of the source of direct voltage pulses, characterized in that introduced a zero current sensor, second and third controlled keys, a current sensor, the first and second time interval meters, the first and second storage units and, a comparison unit, an indicator, and the input circuit of the current zero sensor is connected between the terminal for connecting the cathode of the tested thyristor and the negative output of the direct current pulse source, the first output of the current sensor is connected to the control input of the second managed key connecting the output of the current zero sensor to the first input of the first the time interval meter, and the other output of the current zero sensor through the third controlled key is connected to the input of the pulse source of the reverse current control and to the first input of the second of of the time interval controller, the control input of the third controlled key is connected to the first output of the current sensor, the input circuit of which is connected between the negative terminal of the direct voltage pulse source and the terminal for connecting the cathode of the tested thyristor, the second output of the current sensor is connected to the control input of the second controlled key, the third - with the second cycle enable input of the control unit, the fourth with the second input of the first time interval meter, the fifth with the second input of the second time meter the output of the first time interval meter is connected to the input of the first storage unit, the output of which is connected to the first input of the comparison unit, the output of the second time interval meter is connected to the input of the second storage unit, the output of which is connected to the second input of the comparison unit, and the output of the comparison unit is connected to indicator, while the control unit is designed to generate at its outputs two cycles of pulses after applying a signal to its starting input, with each cycle consisting of several after pulse patterns, in each of which the beginning of the pulses at the first, second and fourth outputs of the control unit coincides with the beginning of the pulse sequence, the beginning of the pulse at the third output of the control unit is shifted to the backward position relative to the beginning of the pulse sequence by the first time interval, and the beginning of the pulse at the fifth output the control unit is shifted in the direction of lag relative to the beginning of the pulse sequence by the third time interval, while the third time interval is greater than the second o time interval and decreases with increasing number of pulse sequences.