CS217883B1 - Ignition pulse generator connection - Google Patents

Abstract

The circuit is made of a monolithic integrated circuit, which is powered via an isolation transformer of the transistor pair, thermistor and optoelectronic coupling elements. The ignition pulses are shifted by changing the variable resistance, formed from the transistor pair and fixed resistors. The transistor pairs together with the thermistor serve for temperature compensation. The output pulses from the monolithic integrated circuit, depending on their polarity, pass through one or the other pair of optoelectronic elements, in which they activate GaAs diodes, shining in the infrared region of the spectrum. The silicon phototransistors of the respective optoelectronic coupling elements open and open the assigned phototransistors via auxiliary circuits.

Description

The invention relates to the connection of an ignition pulse generator with optoelectronic couplers for controlling the input current of small single-phase converters.

Ignition pulse generators are designed for phase-controlled opening of thyristors or triacs, which are supplied with alternating voltage. At its output, the generator provides pulses suitable for opening thyristors. The output pulses of the ignition pulse generator can be shifted in phase with respect to the alternating voltage of the thyristors. In this way it is possible to continuously vary the voltage dependence on the load.

So far, a number of different types of ignition pulse generators have been used, which can be divided into two groups according to the way of phase shifting the output pulses with respect to the supply - synchronization voltage. The first group uses digital circuits to shift the output pulses. As digital circuits, counters, flip-flops or registers are used to measure the desired delay time of the output ignition pulse from the intersection of the supply voltage of the thyristors with zero supply voltage level. In this case, the registers or counters count pulses from the clock source.

The clock source is usually realized by means of a crystal controlled oscillator. The desired value of the output pulse offset is entered in digital form and digital generator must be used when controlling the generator with an analog controller. Digital circuits for pulse phase shifting are expensive, complex and expensive and therefore not suitable for controlling small thyristor converters. the cost of the pulse generator would be the bulk of the price of the inverter. The second group uses the analog principle to control the phase shift of ignition pulses.

In this method, the saw voltage is most often generated, wherein the beginning of the saw voltage is synchronized by the intersection of the supply voltage of the thyristors with a zero supply voltage level. The saw voltage is then compared with the analog value of the desired ignition pulse offset position. The moment the phase shift of the output ignition pulses is determined, the moment the saw voltage increases to the level of the pulse position offset desired value.

The saw voltage can be obtained, for example, by charging capacitors from a constant current source. The capacitor is usually reset by a switch when the thyristor supply voltage passes through the zero level. The analog mode of phase shift of ignition pulses is in comparison with digital circuitry simplified, cheaper, but requires complicated adjustment, demanding selection of components with respect to the required accuracy of ignition output pulses. Another disadvantage of this analog method is that it must be supplemented with output isolation transformers which are powered by the pulse shaping circuit.

These drawbacks are overcome by the connection of an ignition pulse generator with optoelectronic couplers in which the pulse source is formed from the monolithic integrated circuit, capacitors and resistors of the invention. SUMMARY OF THE INVENTION The second wiring input terminal is connected to one input resistor terminal, the other terminal of which is connected to one adjusting resistance terminal, the base of the first transistor pair, the collector of the second transistor, and the base of the second transistor of the transistor pair.

The second transistor emitter of the transistor pair is coupled to one terminal of the thermistor, the second terminal of which is connected to the first input terminal of the wiring, to the third pulse control input, and to the emitter of the first transistor of the transistor pair. The collector of the first transistor of the transistor pair is connected to the second terminal of the adjusting resistor and to one terminal of the limiting resistor.

The second output of the limiting resistor is connected both to the second control input of the pulse source and to the first control input of the pulse source via a separation resistor. The first power supply input of the pulse source is coupled to one terminal of the secondary winding of the isolation transformer, the other of which is connected to the second power supply input of the pulse source, the cathode of the diode of the fourth optoelectronic coupler and the anode of the first optoelectronic coupler. The cathode of the first optoelectronic coupler diode is coupled to the diode of the second optoelectronic coupler, the cathode of which is coupled to the anode of the first diode.

The cathode of the first diode is connected to the output of the pulse source and to the anode of the second diode. The cathode of the second diode is coupled to the diode of the diode of the third optoelectronic coupler. The cathode of the third optoelectronic coupler diode is coupled to the diode of the fourth optoelectronic coupler. The power terminals are connected to the primary windings of the isolation transformer.

The advantage of this connection is that it is simple, it can be realized from cheap and commonly available components. It does not require adjustment or output isolation transformers. It allows phase control of the moment of opening of the thyristors by a DC signal, which is galvanically isolated from both the thyristor circuits and the synchronizing AC voltage. Engagement is. reliable and allows to isolate the thyristor circuits from the high insulation strength control circuits without costly and difficult to produce isolation ignition transformers. The connection is particularly suitable for controlling single-phase thyristor sources.

An example of a circuit according to the invention is shown schematically in the drawing.

A second wiring input terminal 16 is connected to one terminal of the input resistor 14.

The second terminal of the input resistor 14 is connected to one terminal of the adjusting resistor 11 with the base 013 of the first transistor of the transistor pair i, the collector 016 and the base 014 of the transistor of the transistor pair i. The transistor pair 1 is a circuit in which two transistors of the same type are housed in one housing. A pair of silicon-planar epitaxial transistors n-p-n for differential amplifiers can be used as this circuit.

The second terminal of the thermistor 13 is connected to the first wiring input terminal 15, the third control input 026 of the pulse source 2 and the emitter 012 of the first transistor pair 1 transistor. The collector 011 of the first transistor pair 1 is connected to one limiting resistor terminal. 10 is coupled to the second control input 025 of the pulse source 2 and to one terminal of the divider resistor 6. The second terminal of the partition resistor 6 is connected to the first control input 024 of the pulse source g. The pulse source 6 is a monolithic integrated circuit for phase control of thyristors and triacs; in which the output pulses that are not galvanically separated are shifted by changing the resistive resistance of the resistor.

As a pulse source 2, a conventional linear IC may be used, complete with resistors and capacitors to adjust the IC's power supply. The first power input 021 of the pulse source 2 is connected to one terminal of the secondary winding of the isolation transformer 12.

The second terminal of the secondary winding of the isolation transformer 12 is connected to the second supply input 022 of the pulse source 2, the cathode of the diode of the fourth optoelectronic coupler 6, and the diode of the first optoelectronic coupler J.

The diode cathode of the first optoelectronic coupler 2 is coupled to the diode of the second optoelectronic coupler 6. The diode cathode of the second optoelectronic coupler i is coupled to the anode of the first diode χ. The cathode of the first diode X is coupled to the output 023 of the pulse source 2 and the anode of the second diode g. The cathode of the second diode 8 is coupled to the anode of the third optoelectronic coupler g. .

All optoelectronic couplers g to p are the same. Each optoelectronic coupler g to δ is formed by tight optical coupling of a GaAs diode glowing in the infrared region of the spectrum with a silicon phototransistor with maximum sensitivity in the same region of the spectrum.

The wiring works as follows. The pulse source 2 is powered and its output pulses are synchronized by an alternating voltage having the same phase as the voltage on the controlled thyristors. The supply voltage is applied to the first power supply terminal 17 and the second power supply terminal 18.

Further, the supply voltage is applied via the isolation transformer 12 to the first supply input 021 of the pulse source 2 and to the second supply input 022 of the pulse source 2. The output pulses at the output 023 of the pulse source 2 can be phase shifted against alternating voltage on the thyristors by changing the resistive divider that is connected to the control inputs 024 to 026 of the pulse source 2. The resistive divider is fed from a pulse source 2 from its first control input 024 and its third control input 026. The resistive divider is comprised of a fixed resistive resistor 2 and a variable resistor.

The variable resistor is formed as a series combination of a fixed limiting resistor 10 and a variable resistor which forms the transition of the collector 011 of the first transistor of the transistor pair J with the emitter 012 of the first transistor of the transistor pair χ. The values of the variable resistance of the resistive divider that is connected to the second control input 025 of the pulse source 2 are controlled by the voltage applied to the first wiring input terminal 15 and the second wiring input terminal 16. This voltage pushes a current that is dependent on the magnitude of the non-five and the value of the input resistance 14 into the base transition 013 - emitter 012 of the first transistor of the transistor pair X.

This current controls the magnitude of the transition resistance of the collector 011 - emitter 012 of the first transistor of the transistor pair χ. This also controls the potential of the second control input 025 of the pulse source 2, which determines the magnitude of the phase shift of the output ignition pulses. The thermal compensation of the input current is effected by a thermal compensation circuit that is connected in parallel to the base transition 013 - emitter 012 of the first transistor of the transistor pair.

The thermal compensation circuit consists of a thermistor I3 and a diode.

The second transistor of transistor pair χ is located in the same housing as the first transistor of transistor pair i, and since it is of the same kind, it operates in the same proportions and together with a suitably selected thermistor 13 compensates for changes in resistance at the junction of the collector 011 - base 013 of the first transistor of the transistor pair X as a function of temperature.

The basic opening of the first transistor of the transistor pair χ, and hence the basic position of the pulses, is adjusted by the adjusting resistor 11 connected between the collector 011 and the base 013 of the first transistor of the transistor pair χ. The output pulses of the pulse source 2 can be shifted by input voltage at the input terminals 15 and 16 of the wiring. Shifting of output pulses can be performed in the range from 5 ° electric to 174 ° electric at the frequency of supply voltage of thyristors 50 Hz,

The basic position of the 5 ° electrical pulses is determined from the intersection of the supply voltage with the zero axis. This basic position is set by the adjusting resistor 11 at zero input signal. The output pulses and the pulse source 2 are at the second supply input 022 of the pulse source 2 and at its output 023. The output pulses are of dual polarity. With a positive half-period of the synchronizing supply voltage, the output pulses have a positive polarity. With a negative half-period of the synchronizing supply voltage, the output pulses have a negative polarity.

Positive polarity output ignition pulses are applied via a second diode 8 on a series of diodes OaAs of a third optoelectronic coupler 2 and a fourth optoelectronic 5to coupler 6. The negative polarity output pulses are applied via a first diode 6 to a series-coupled GaAs diodes of the first optoelectronic coupler. and a second optoelectronic coupling member 6. Thus, the first diode 8 and the second diode 8 not only serve to divide the output ignition pulses of positive and negative polarity, but also limit the diode load GaAs of all optoelectronic couplers J to 6 with a reverse voltage.

The output pulses from the pulse source 2 push current into the series connected GaAs diodes of the optoelectronic couplers. GaAs emit in the infrared spectrum and the silicon phototransistors of the respective optoelectronic couplers J to 6 are opened and the associated thyristors are opened via auxiliary circuits not shown in the drawing. Optoelectronic couplers j to 6 also serve to galvanically isolate the pulse source circuit 2 from the thyristor circuit. The thyristors are usually connected to a single phase full-bridge bridge, each bridge thyristor being controlled by its own optoelectronic element.

The invention will be used to control the input current of small single-phase inverters designed to power the excitation of small motors, DC magnets and DC magnetic couplers.

Claims (1)

SUBJECT OF THE INVENTION Connection of an ignition pulse generator with optoelectronic isolators in which the pulse source is formed from a monolithic integrated circuit, capacitors and from? characterized in that the second input terminal (16) is connected to one terminal of the input resistor (14), the other terminal of which is connected to one terminal of the adjusting resistor (11), to the base (014) of the second transistor of the transistor pair ), whose eraitor (015) is connected to one terminal of a thermistor (13), the other terminal of which is connected to the first wiring input terminal (15), the third control input (026) of the pulse source (2) and the emitter (012) of the first transistor a transistor pair (2) whose collector (011) is connected to a second terminal of the adjusting resistor (11) and one terminal of a limiting resistor (10), the other terminal of which is connected to the second control input (025) of the pulse source (2); via a dividing resistor (9) with a first control input (024) of the pulse source (2), the first power input (021) of which is connected to one terminal of the secondary winding of the isolation transformer (12), the other of with a second power input (022) of the pulse source (2), a cathode of a diode of a fourth optoelectronic coupler (6) and a diode of a first optoelectronic coupler (3), the cathode of which is coupled to the diode of the second optoelectronic coupler (4) the cathode is connected to the anode of the first diode (7) whose cathode is connected to the output (023) of the pulse source (2) and to the anode of the second diode (8) whose cathode is connected to the anode of the third optoelectronic coupler (5) connected to the diode of the diode of the fourth optoelectronic coupler (6) and the power supply terminals (17, 18) of the wiring are connected to the primary windings of the isolation transformer (12).