CS209704B1 - Circuitry for measuring off-time of two-way transmitting thyristors - Google Patents

Description

(54) Connection of circuit for measuring tripping time of reverse conductive thyristors

It is an object of the invention to provide a circuit for measuring the tripping time of the back-conducting thyristors.

The measurement of the switching-off time of the back-conducting thyristors is technically very demanding and is solved by a circuit comprising five auxiliary DC sources, a switch-off thyristor and a diode whose commutation charge must be selected according to the commutation charge of the measured thyristor. Despite its complexity, the circuit does not allow the measurement conditions to be changed in full.

The disadvantage of these disadvantages is eliminated by a circuit for measuring the tripping time of the reverse conductive thyristors according to the invention, characterized in that a first diode is connected in parallel to the variable direct current sources, the cathode of which is connected to a pole via a first inductance serial connection. a first capacitor whose second pole is connected to the negative pole of a variable voltage source.

The anode of the first diode is connected via a second inductance variable to the cathode of the auxiliary thyristor, the anode of which is connected to the positive pole of a variable DC voltage source, to which is connected the cathode of the second diode whose anode is connected to the cathode of the third diode inductances and the first inductance variables. The anode of the first diode is coupled to the cathode of the fourth diode, the anode of which is connected both to the cathode of the third diode, to the anode of the auxiliary diode, and to the anode of the measured conductive thyristor. to which at the same time one pole of the second capacitor is connected, the other pole of which is connected to the cathode of the auxiliary diode, which is connected via a discharge resistor to the anode of the other diode connected via a variable resistor to the cathode of the auxiliary thyristor. The auxiliary thyristor control electrode is coupled to the first output of the control pulse block, the second output of which is coupled to the control electrode of the measured back-conducting thyristor.

In the circuit according to the invention, all measuring conditions can be changed independently of each other: the amplitude and duration of the forward sinusoidal current, the magnitude of the return current constant d, its steepness to zero, the blocking voltage and its steepness. . A further advantage of the circuit according to the invention is the low value of the short-circuit current of the measured back-conducting thyristor when burned out due to the tripping time, so that it cannot be destroyed.

An example of a circuit for measuring the tripping time of the reverse conductive thyristors according to the invention is in the attached drawing. The first output of the block of protection and switching circuits is connected to the first input of the control pulse block 2, the second output is connected to the source

And a third output is coupled to a variable DC voltage source 4.

A first diode is connected in parallel to the variable DC power supply 3

5, the cathode of which is coupled to a pole of a first capacitor 8 through a series connection of a first inductor to a first variable by inductor T, the second pole of which is connected to the negative pole of a variable DC voltage source 4. The anode of the first diode 5 is connected via a second variable inductor 9 to the cathode of the auxiliary thyristor 10, whose anode is connected to the positive pole of a variable DC voltage source 6, to which the cathode of the second diode 11 is connected. 1 diode 2, are connected to the common point of the anode of the first idnukČnosti 6 and the first variable inductance seventh anode of the diode 5 is connected to the cathode of the fourth diode 13, whose anode is connected both with the cathode of the third diode] 2_ _t partly to the anode of the auxiliary diode 14, and on the other hand, with the anode of the measured back-conducting thyristor 15, the cathode of which is connected via a current sensor 16 to the negative pole by a source of variable DC voltage. One pole of the second capacitor 17 is connected to the negative pole of the variable DC power supply 4, the other of which is coupled to the cathode of the auxiliary diode 14, which is connected via the discharge resistor 18 to the anode of the other diode 11 connected to the cathode of the auxiliary thyristor. . The control electrode of the auxiliary thyristor 10 is connected to the first output of the control pulse block 2, the second output of which is connected to the control electrode of the measured back-conducting thyristor 15.

The function of the circuit for measuring the tripping time of the reverse conductive thyristors according to the invention is as follows: the measuring cycle starts by switching on the measured reverse conductive thyristor 15. Circuitry of the first capacitor 8 of variable capacitance, first variable inductance 7, third diode 12, measured back conductive thyristor 15 and current sensor 16 starts to flow a sine-shaped current whose maximum value is given by the magnitude of voltage on the first capacitor 8 and its ratio and the first variables by inductance 7. The second capacitor 17 discharges via the discharge resistor 18, the measured back-conducting thyristor 15 and the current sensor 16.

After the first capacitors 8 are overcharged to a negative value, the current flowing through the measured back-conducting thyristor 15 becomes negative and is subtracted from the current flowing from the DC variable current source 3 by the first inductance circuit 6, the third diode 12 and the fourth diode 13. After equalization of both currents, it will de-energize the third diodes 12 and the current flowing through the measured back-conducting thyristor 15

Claims (1)

P D E D Μ £ T Connection of a circuit for measuring the tripping time of the conductive thyristors, consisting of a block of protection and switching circuits, the first output of which is connected to the first input of the control pulse block and the second output of which is connected to a variable DC current source; is connected to a variable DC power supply, characterized in that a first diode (5) is connected in parallel to the variable DC power supply (3), the cathode of which is connected to the first variable inductance (6) with the first variable inductance (7) one pole of the first capacitor (8), the other pole of which is connected to the negative pole of the variable-voltage source (4), the anode of the first diode (5) being connected to the cathode of the auxiliary thyristor (10) via the second it is connected to the positive pole of a variable DC power supply (4) The voltage to which it is connected at the same time stabilizes at the value of the current which would have been previously set in the circuit of the variable DC power supply 3 by the first inductance of the third diode 12 and the fourth diode 13. The first variable inductance 7 has a large value and does not allow a change in current in the circuit of the first capacitors 8, the current sensor 16, measured by the reverse conductive thyristor 15, the fourth diode 13, the first diode 5, the first inductance 6 and the first variable inductance 7. is performed by shortening the delay time between switching on the measured reverse conductive thyristor 15 and the auxiliary thyristor 10. By switching on the auxiliary thyristor 10, voltage is applied from the source 4 of the variable of a direct voltage through the fourth diode 13, measured by a backward conducting thyristor 15, which is still conductive and via a sensor^-In this circuit, the current begins to increase with a slope proportional to the magnitude of the voltage source 4 of the variable DC voltage and inversely proportional to the magnitude of the second variable by inductance 9 and subtracted from the negative current flowing through the measured conductive thyristor 15. After equalizing these currents, the fourth diode 13 de-energizes and then, via the variable resistor 19, completes the commutation of the diode in the measured back-conducting thyristor 15. On the second capacitors 17 and hence on the measured back-conducting thyristor 15, a voltage rise is generated via the auxiliary diode 14 in the conductive state, which is dependent on the capacitance of the second capacitors 17, variable resistor 19 and voltage. The maximum voltage level is limited by a second diode 11, which dissipates the overvoltage caused by the parasitic inductance of the circuit to a variable DC voltage source 4. After commutation of the fourth diode 13 and the measured back-conducting thyristor 15, the current is closed by a circuit formed by the source 6. of a variable DC voltage by an auxiliary thyristor 10, a second variable inductance 9, a first diode 5, a first inductance 6, a first variable inductance 7, and a first capacitor 8, which charges a voltage of a variable DC voltage source 4 and disappears. After charging of the first capacitors 8, the current is closed again from the variable-voltage source 13 by a circuit formed by the first inductance 6, the third diode 12 and the fourth diode 13. A cathode of a second diode (11) whose anode is connected to a cathode of a third diode (12) connected by an anode to a common point of the first inductance (6) and a first inductance variable (7) and anode of the first diode (5) is connected to a cathode a diode (13) whose anode is connected both to the cathode of the third diode (12) and to the anode of the auxiliary diode (14) and to the anode of the measured conductive thyristor (15). a pole of a variable DC voltage source (4) to which at the same time one pole of the second capacitor (17) is connected, the other pole of which is connected to the cathode of the auxiliary diode (14) which is connected to the anode of the other diode (11) connected via a variable resistor (19) to the cathode of an auxiliary thyristor (10), whose control electrode is connected to a first output of the control pulse block (2), the second output of which is connected to a control electrode measured backward of wild thyristor / 15 /.