CS240843B1 - Circuit for processing optical control pulses of power semiconductor devices - Google Patents

Abstract

The purpose of the connection is to obtain signals of sufficient intensity? necessary for switching the power semiconductor component. The power supply terminal (12) of the DC power supply (1) is connected to the power supply terminals (22, 32, 52) of the power monostable flip-flop circuit (2), the optoelectric converter (3), the feedback block (5) and to the input terminal (42) of the blocking circuit (4). The zero terminal (14) of the power supply (1) is connected to the zero terminals (24, 34, 44) of the power monostable flip-flop circuit (2), the optoelectric converter (3) and the blocking circuit (4). The input terminal (13) of the power supply (1) is connected to the first output terminal (23) of the power monostable flip-flop circuit (2), the second output terminal (25) of which is connected to the input terminal (51) of the feedback block (5). The input terminal (21) of the power monostable flip-flop circuit (2) is connected to the output terminal (31) of the opto-electric converter (3), the input terminal (33) of which is connected to the output terminal (43) of the blocking circuit (4), the input terminal (41) of the blocking circuit (4) being connected to the output terminal (11) of the power supply (1). The most suitable application area is the area of power semiconductor converters, in particular high voltage converters.

Description

Circuit for processing optical control pulses of power semiconductor devices

The purpose of the connection is to obtain signals of sufficient intensity _? necessary to switch power semiconductor components.

The DC power supply terminal (12) is connected to the power terminals (22, 32, 52) of the power monostable flip-flop (2), the optoelectric converter (3), the feedback block (5) and the blocking input terminal (42). circuit (4). The neutral terminal (14) of the power supply (1) is connected to the neutral terminals (24, 34, 44) of the power monostable flip-flop (2), the optoelectric transducer (3) and the blocking circuit (4). The input terminal (13) of the power supply (1) is connected to the first output terminal (23) of the power monostable flip-flop (2), the second output terminal (25) of which is connected to the input terminal (51) of the feedback block (5). the power monostable flip-flop (2) terminal (21) is coupled to the output terminal (31) of the optoelectric converter (3), the input terminal (33) of which is connected to the output terminal (43) of the interlock circuit (4); ) of the blocking circuit (4) is connected to the output terminal (11) of the power supply (1).

The most suitable application area is the field of power semiconductor converters, especially high voltage converters.

240 643

240 843

The invention relates to a circuit for processing optical control pulses of power semiconductor devices connected to the potential of a power semiconductor device using a control optical input signal. The invention relates to the field of control of power semiconductor converters.

The prior art known solutions solve this problem by simple circuits which place considerable demands on the optimal arrangement of the optical connection path and on the quality of the optoelectric converter. The consequence of the operation of the above mentioned connections are also the dynamic parameters of the control pulse, which do not satisfy when switching series-connected power semiconductor devices. In addition, these connections do not allow to achieve the desired characteristics of the control pulse over a wide range of thyristor voltage and control angles.

The above drawbacks are overcome by the circuitry for processing the optical control pulses of the power semiconductor devices of the invention. It is based on the fact that the DC power supply, which includes a switched-on semiconductor component, from which the DC power supply is supplied, is connected to the power terminal of the monostable flip-flop, the block of the feedback block, the power terminal of the optoelectric converter. and one blocking circuit input terminal. The DC terminal of the DC power supply is connected to the neutral terminal of the power monostable flip-flop circuit, the neutral terminal of the optoelectric converter and the neutral terminal of the blocking circuit. The DC input terminal is connected to one output terminal of the power monostable flip-flop whose other output terminal is connected to the input terminal of the feedback block and the input terminal of the power monostable flip-flop is connected

240 843 with an output terminal of an optoelectric converter whose input terminal is connected to the output terminal of the blocking circuit. The second input circuit of the blocking circuit is connected to the second output terminal of the DC power supply ·

The power monostable flip-flop block has an input terminal for supplying an input signal connected on the basis of the first transistor. The emitter of this transistor is connected via one diode to the power terminal so that the anode of this diode is connected to this terminal. A resistor is connected to the base of the first transistor, which is connected to the power terminal by the other end. The collector of the first transistor is connected via a limiting resistor to which a parallel acceleration capacitor can be connected, based on a second transistor whose emitter is connected to the first output terminal, between which only the leakage resistor is connected between the neutral terminal or its combination with a parallel diode . A diode whose anode is connected to the emitter and a cathode with one end of the leakage resistor and the first output terminal can be connected between the emitter of the second transistor and the beer output terminal. The collector of this second transistor is connected to a second output terminal, one end of a collector resistor to which an accelerator capacitor can be connected in parallel, and one end of a coupling capacitor, the other end of which is connected to the anode of the other diode. on the other hand, to one end of the feedback resistor, the other end of which is connected on the basis of the first transistor.

The block of the optoelectric converter can be created by a phototransistor, whose emitter is connected to the input terminal of the converter and whose collector is connected to its output terminal, either directly or via a limiting resistor. The phototransistor base is connected to the neutral terminal via a base resistor via a supply resistor and a power terminal, and via a diode-type resistor.

The optoelectronic converter block can be formed by means of a photodiode, the cathode of which is connected to the supply terminal and the anode to the base of the transistor, and at the same time via a leakage resistance to the neutral terminal. The transistor emitter is connected to the input terminal and the collector to the output terminal

- 5 240 843 converter terminal, either by cell ^ or via limiting resistor * ·

The blocking circuit with two input terminals consists of a transistor, a separation diode, a Zener diode, and a pickup diode.

A series resistor is connected to the first input terminal, the other end of which is connected to the anode of the diode. The separating diode cathode is connected to the second input terminal. The anode of the separation diode is further coupled to both the cathode of the Zener diode, the anode of which is connected on a transistor basis, and the cathode of the pickup diode, of which the anode is connected to the zero terminal. The transistor collector is connected to the output terminal and the emitter to the neutral terminal. A leakage resistor is connected between the transistor base and the neutral terminal.

The basic advantage of the circuitry according to the invention is that the circuitry makes it possible to generate control pulses for switching the power semiconductor component at any control angle and thus the maximum control range can be used. The amplitude of the control pulses satisfies the requirements for switching the largest known thyristors, even in series shifting. Another advantage is that the circuit according to the invention generates control pulses of a constant set length, irrespective of the length of the optical input signal. The control pulse is generated only if the switching conductor component has a blocking voltage of the minimum set value and at the same time the voltage of the source is higher than the set minimum value. The control pulse generation is repeated for the duration of the optical input signal until the thyristor closes. A further advantage is that the circuit according to the invention makes it possible to report on the existence of a control pulse and thus at the same time of the correct operation of the switched-mode DC power supply, the monostable power flip-flop of the optoelectric converter. A further advantage is that the optical control pulse processing circuit, operating at the potential of the switched power semiconductor component, requires no additional power supply and is only connected to the control pulse generator optically.

The circuit according to the invention is explained in more detail with reference to the accompanying drawings, in which: FIG.

Fig. 2 shows an example of a power monostable flip-flop circuit, Fig. 3 shows an optoelectric converter connection, Fig. 4 another example of an optoelectric converter connection, Fig. 5 shows a blocking circuit connection, and Fig. 6 example of the feedback block connection.

Fig. 1 shows a block diagram of a thyristor control pulse processing circuit consisting of a block of a DC power supply 1 supplied from a voltage on a switched-on power semiconductor component, in this case a thyristor which is part of this block and controlled by control pulses. the circuit 2 which amplifies and shapes the control pulse from the optoelectric converter block which receives the optical signal A and converts it into an electrical signal, the blocking circuit 6, which provides blocking of the control pulse in case of DC supply voltage drop or blocking voltage of switched thyristors and finally a feedback block 2 which transmits an optical signal B. The DC power supply terminal 12 is connected to the power terminal 22 of the power monostable flip-flop 2, to the optoel power terminal 32. The neutral terminal 14 of the DC power supply 1 is connected to the neutral terminal 24 of the power monostable flip-flop 2, to the neutral terminal 34 of the optoelectric converter 2 and to the neutral terminal of the optoelectric converter 2. circuit £. The input terminal 12 of the DC power supply 1 is connected to the output terminal 23 of the power monostable flip-flop 2, the input terminal 21 of which is connected to the output terminal 31 of the optoelectric converter 2. the input terminal 41 is connected to the output terminal 11 of the DC power supply 1. The output terminal 25 of the power monostable flip-flop 2 is connected to the input terminal 51 of the feedback block 2 · j.

An optical signal A is introduced into the optoelectronic converter 2, which is converted here into an electrical signal. This electrical signal is applied to a power monostaoil flip-flop 2 in which

5 240 843 is provided and opens an end transistor whose switching results in a control pulse n 'of the thyristor control electrode being supplied from the source 1. The blocking circuit 6 in its output stage generates a pulse generation terminal in the optoelectronic converter 2 in the event of a failure at the thyristors or at the source. At the same time as the control pulse is sent, a signal is sent to the feedback block, which indicates that the signal has been generated.

Fig. 2 shows an example of a power monostable flip-flop 2 circuit. The input signal is supplied from the input terminal 21 based on the amplifier transistor V21. The emitter of transistor V21 is connected via diode V25 to the power terminal 22, such that diode V25 is connected to the power terminal 22 by an anode. A base resistor R21 is connected between the power terminal 22 and the input terminal 21. From the collector of transistor V21, the signal is routed through a limiting resistor R2 based on transistor V22. An accelerating capacitor C22 may be connected in parallel to the limiting resistor R2. The emitter of transistor V22 is connected to the output terminal 25. A leakage resistor R25 or a cathode diode V25 to the emitter of transistor V22 or a parallel resistor R25 to diode V2J may be connected between the output terminal 25 and the neutral terminal 24, 25 is connected diode V26 whose anode is connected to the emitter of transistor V22 and cathode with one end of resistor R25 and output terminal 25 «The collector of transistor V22 is connected with the other output terminal 25. one end of coupling capacitor C21 and one end of collector resistor R25« The collector resistor R25 is connected to the power terminal 22. An acceleration capacitor C25 can be connected in parallel to the collector resistor R25. The other end of the coupling capacitor C21 is connected to the anode of diode V24 and to one end of the feedback resistor R22, the other end of which is connected to the base of transistor V21. The V24 cathode is connected to the power terminal 22.

FIG. 5 shows one example of optoelectric transducer wiring. The optical input signal A is applied to an optoelectric transducer formed by a phototransistor VJ1 whose collector is connected to the output terminal 51 either directly or via a limiting resistor R54. The phototransistor emitter V51 is connected to the input terminal 55. The phototransistor base V51 is connected via a base resistor R52,

6 240 843, which is connected, via the supply resistor R51, to the supply terminal 52, and to the terminal 54 via a resistor R55. Instead of the resistor R55, a diode 752 can be connected to the terminal 54 by a cathode.

Fig. 4 shows another example of optoelectric converter 2 connection. · The optical input signal A is applied to an optoelectric transducer consisting of a photodiode V52 _t whose cathode is connected to a power terminal 52 and an anode to transistor V51 and one end of a leakage resistor R51. the end of resistor R 51 is connected to neutral terminal 21 · The emitter of transistor V51 is connected to the input terminal 22. * The collector of transistor V51 is connected to the output terminal 51 either directly or via a limiting resistor R52.

FIG. 5 shows an example of a blocking circuit 4. This block is formed by a transistor V41. A diode V42, a Zener diode V45, and a catch diode V44 ' are connected to the first input terminal 41 with one end of a series resistor R4I ' whose other end is connected to the anode of the diode V42. Its cathode is connected to the second input terminal 42 _{r. The} anode of the separation diode V42 is further coupled to the cathode of the Zener diode V45. whose anode is connected to the base of transistor V4L _t and secondly to the cathode of catch diode V44 whose anode is connected to the neutral terminal 44 «The collector of the transistor V41 is connected to the output terminal 43 and the emitter to the neutral terminal 44 'between the base of transistor V41 and the zero terminal M and ^'e plugged bleeder resistor R42.

Fig. 6 shows an example of the feedback block 2 connection * A limiting resistor R51 in series with an electroluminescent diode V51 is connected between the input terminal 51 and the power terminal 52. The anode is connected to the power terminal 52. The output of the feedback block is an optical signal. B.

The function of the individual blocks in FIGS. 2 to 6 is apparent from the description of the function of the block diagram in FIG. 1.

Claims (5)

SUBJECT OF THE INVENTION 240 843 1. Connection of a circuit for processing optical control pulses of power semiconductor devices connected to the potential of a power semiconductor device and using an optical input signal, consisting of a DC power supply, of which the switched semiconductor component is powered. (1) is connected with its power terminal (12) to the power terminal (22) of the power monostable flip-flop (2), to the power terminal (32) of the optoelectric converter (3), to the power terminal (52) of the feedback block (5) to the input terminal (42) of the blocking circuit (4), the neutral terminal (14) of the DC power supply (1) is connected to the neutral terminal (24) of the power monostable flip-flop (2), to the neutral terminal (34) of the optoelectric converter and with the blocking circuit (4) neutral terminal (44), the DC input terminal (13) The power supply (1) is connected to the first output terminal (23) of the power monostable flip-flop (2), whose second output terminal (25) is connected to the input terminal (51) of the feedback block (5) for transmitting the optical signal (B). (feedback), while the input terminal (21) of the power monostable flip-flop (2) is connected to the output terminal (31) of the optoelectric converter (5) for converting the optical input signal (A) and whose input terminal (33) is connected to the output terminal (43) of the blocking circuit (4), wherein the input terminal (41) of the blocking circuit (4) is connected to the output terminal (11) of the DC power supply (1). 2. Circuit for processing of optical control pulses of power semiconductor devices according to claim 1, characterized in that the block of power monostable flip-flop (2) with input terminal (21) for input signal has this terminal (21) connected on the basis of amplifying transistor (721), whose emitter is connected via a diode (723) to the power terminal (22), the diode (723) is connected to the terminal (22) by anode, the base resistor (R21) being connected to the power supply - 8 240 843 terminal (22) and the other end based on transistor (721), the collector of which is connected via transistor (722) via a limiting resistor (24) or through a parallel combination of limiting resistor (524) and accelerator capacitor (C22) whose emitter is connected to the first output terminal (23) between which and the neutral terminal (24) is connected either a leakage resistor (525), or a parallel combination of a leakage resistor (R25) with a didda (725), or and a first output terminal (23) connected to a diode (726) whose anode is connected to the emitter of transistor (722) and a cathode with one end of the leakage resistor (525) and to the first output terminal (23) while the collector of transistor (722) is connected with a second output terminal (25), one end of the collector resistor (523) or one end of the parallel resistor combination (523) and the accelerator capacitor (023) and one end of the coupling capacitor (021), the other end of which is connected to the dio dy (724) and one end of the feedback resistor (R22), the other end of which is connected to the base of the transistor (721) and the cathode of the diode (724) is connected to the power terminal (22). 3. The circuit for processing the optical control pulses of the power semiconductor component according to claim 1, characterized in that the optoelectric transducer block (3) is formed by a phototransistor (731), whose emitter for input optical signal input is connected to the input terminal (33). (a) the collector of which is connected to the output terminal (31) either directly or via a limiting resistor (534), the base of the phototransistor (731) being connected via a base resistor (532) and a power resistor (531) and a power terminal 32 / a. There is a pre-resistor (533) to the zero terminal (34) or heavier and df © dUi_Z732 / to « ¹ connected to the rsalura (34) · 4. The circuit for processing the optical control pulses of power semiconductor devices according to claims 1 and 2, characterized in that the optoelectric converter block (3) is formed by a photodiode (732), the cathode of which is connected to the power terminal (32) and the anode is connected. on the one hand to the base of the transistor (731) and on the other hand via a leakage resistor (531) to the zero terminal (34), the emitter 9 240 843 of the transistor (731) is connected to the input terminal (33) and the collector of the transistor (731) is connected to the output terminal (31) either directly or via a limiting resistor (R32). 5. Circuit arrangement for processing optical control power semiconductor devices according to Claims 1 to 4, characterized in that the blocking circuit (4) consists of a transistor (741), a separating diode (742), a Zener diode (743) and a collecting diode (7). 744), wherein one end of the series resistor (R41) is connected to the first input terminal (41), the other end of which is connected to the anode of the diode (742), the cathode of which is connected to the second input terminal (42) and the anode of the diode. 742) is connected to the cathode of the Zener diode (743), the anode of which is connected on the base of the transistor (741), the collector of which is connected to the output terminal (43) and emitter to the zero terminal (44) and 744), the anode of which is connected to the neutral terminal (44), and a leakage resistor (R42) is connected between the base of the transistor (741) and the neutral terminal (44).