SU1069094A1 - Constant voltage converter for supplying flash bulb - Google Patents

Description

2. The converter according to claim 1, characterized in that, for the sake of simplicity, a dynistor is used as a thyristor, the closing button is connected parallel to the dynistor, the second bypass bias resistor is connected to the cathode of the discharge, and its first output is with minus output high voltage rectifier.

3. The converter according to claim 1, characterized in that, in order to increase the sensitivity of the on and off switch, a thyristor is used as a thyristor, the control transition of which is shunted with a button and a chain of series-connected additional capacitor and additional resistor, an additional resistor is connected to the thyristor anode, an additional capacitor is connected to its control electrode, the connection point of the additional resistor and capacitor is connected to the negative terminal of a high the second is connected to the cathode of the arrester.

4. The converter according to claim 1, which is connected with the fact that, for the purpose of galvanic isolation of high-voltage and low-voltage circuits, a thyristor is used as a thyristor, the control transition of which is shunted by a closing button, an additional capacitor is connected between the control electrode of the triristor and the second output of the resistor displacement, and a pulse transformer is introduced, the primary winding of which is connected between the negative terminal of the high-voltage rectifier and the cathode, and the secondary winding - in series with the displacement resistor.

The invention relates to electrical engineering and is intended to power pulsed photo flashes.

A known DC voltage converter is used to power pulsed photo flash units l.

The disadvantage of this converter is the lack of its automatic shutdown at the moments of readiness to the flash

Closest to the invention is a DC / DC converter for supplying a photo flash, comprising a transistor inverter, a high voltage rectifier, and an automatic on and off switch, equipped with a 2J discharger.

The disadvantages of this converter are its low cost and reliability due to frequent switching on due to the discharge of the storage capacitor of the photo flash through the resistive divider of the output voltage and the winding of the on / off relay.

The purpose of the invention is to increase the efficiency and reliability of the converter.

This goal is achieved by the fact that a thyristor connected in series to the inverter power supply circuit is connected to the DC converter for supplying the photo flash containing a transistor inverter, a high-voltage rectifier and an automatic on and off switch equipped with a spark switch. the bias resistor of the inverter base transistors, the closing button, two capacitors, the first of which is connected between the positive output of the high-voltage rectifier and the cathode of the arrester, and the second between a minus terminal of the high-voltage rectifier and an anode of the discharger; and a limiting resistor connected between the positive terminal of the high-voltage rectifier and the anode of the discharge capacitor.

In order to simplify the converter, a dynistor can be used as a thyristor, the closing button is connected parallel to the dynistor, the second output of the bias resistor is connected to the cathode of the arrester, and its first output is connected to the negative terminal of the high-voltage rectifier.

In order to increase the sensitivity of the on and off switch, a thyristor can be used as a thyristor, the control transition of which is triggered by a closing button and a chain of series-connected additional capacitor and additional resistor, the additional resistor connected to the anode of the trinistor, the additional capacitor with its control electrode , the point of connection of an additional resistor and a capacitor is connected to the negative terminal of the high-voltage rectifier, and the second d biasing resistor connected to the cathode of the arrester.

For the purpose of galvanic isolation of high-voltage and low-voltage circuits, a thyristor can be used as a thyristor, the control transition of which is shunted by a closing button, an additional capacitor is connected between the control electrode of the trinistor and the second output of the bias resistor, and a pulse transformer is inserted, the primary winding of which is connected between the negative terminal the output of the high-voltage rectifier and the cathode of the arrester, and the secondary - in series with the bias resistor.

Kah FIG. 1 is a schematic diagram of a constant voltage converter for powering a photo flash with an automatic switch on and off based on a dynistor; on. FIG. 2 is the same with the on-off automatic switch based on the trinistor in FIG. 3 - the same, with an automatic switch on and off to the base of a trinistor with a pulse transformer.

The constant voltage converter (Fig. 1) contains a terminalNTTJ 1 and 2 for connecting a primary power source, an inverter consisting of transistors 3 and 4, a bias resistor 5, a downstream transformer 6, a closing button 7, a distor 8, a high voltage rectifier 9 , the first and second capacitors 10 and 11, the limiting resistor 12, the bit 13, the output jacks for connecting the flash lamp 14 and 15.

The Converter operates as follows.

 . At terminals 1 and 2, the voltage is supplied from the primary source pi. tannin. A plug is inserted into slots 14 and 15. A photo flash is connected through the power cord (its storage capacitor is not shown in Fig. 1 with the converter.) When the button 7 is closed, the voltage is applied to the inverter and the current through the transistors 3 and 4 and the transformer winding 6. When starting the button 7, the circuit opens, the current sharply becomes zero, which leads to overvoltage on the windings of transformer 6 due to the occurrence of self-induced emf. Under the influence of self-induced emf, distor 8 breaks through and starts to conduct in the forward direction. Inverter transistors 3 and 4 alternately switch

A variable rectangular voltage is generated on the windings of the transformer 6.

The rectifier 9 charges the storage capacitor of the flash (via slots 14 and 15) and, simultaneously, the capacitors 10 and 11. When the voltage on all the above-mentioned capacitors reaches the voltage of the discharge discharge 13, a gas discharge occurs in the discharge 13 and the capacitor 10 is quickly discharged through the discharge circuit 13 and the bias resistor 5. The discharge current of the capacitor 10 causes a voltage

on a resistor 5 of such a polarity that it closes the transistors 3 and 4 along the bases, the generation fails, the load current of the primary source becomes zero, the distor 8

turns off and the circuit is de-energized. The resistor 12 prevents the discharge of the capacitor 11 during the burning of the discharge element 13.

At the time of exposure, the storage capacitor of the photo flash and, simultaneously with it, the capacitor 11 is discharged through a flash lamp. The discharge current of the capacitor 11 flows through the bias resistor 5. A pulse of discharge current of the capacitor 11 on the resistor 5 causes a voltage drop of such a polarity, which, being applied to the anode of the dynistor 8, turns it on. The inverter self-raises, the storage capacitor of the flash unit is charged, and, after its charging, the converter automatically switches off as described.

A DC / DC converter with a circuit breaker on and off at the base of the matrix (Fig. 2) contains terminals 1 and 2 for connecting a power source, an inverter consisting of transistors 3 and 4, a bias resistor 5, a step-up transformer 6, a closing button 7, a high voltage “Rectifier 9, first and second capacitors 10 and 11, limiting resistor 12, discharger 13, output

sockets for connecting the flash lamp 14 and 15, additional resistor 16, trinistor 17, additional capacitor 18.

The scheme works in a similar way. During operation of the circuit, when the voltage on the capacitor 10 reaches the voltage of the discharge gap 13, a gas discharge occurs in discharge 13,

and the capacitor 10 is discharged through the discharge circuit 13 and the resistors 5 and 16. The resistor 16 limits the voltage across the bases of the transistors 3 and 4. The discharge current of the capacitor 10

causes a voltage drop across the resistor 5 of such polarity that it closes the transistors along the base circuits, the generator breaks, the load current of the primary source becomes zero, the trinistor turns off and the circuit is de-energized. In the exposure ex- ample, the storage capacitor of the flash and, simultaneously with it, the capacitor 11 is discharged through a flash lamp. The discharge current of the capacitor 11 flows through the resistors 5 and 16. The discharge current of the capacitor 11 causes the pulse voltage across the resistor 16 applied by a plus to the control electrode, and a minus to the anode of the trinistor. With this pulse, through the capacitor 18, the trinistor opens, the converter turns on and charges the storage capacitor of the lamp-flash 1. After the next charge of this storage capacitor, the circuit automatically turns off as described. DC / DC converter, Based on a trinistor with a pulse transformer (Fig. 3 holds terminals 1 and 2 for connecting a primary current source, an inverter consisting of transistors 3 and 4, a bias resistor 5, a swinging transformer b, and a closing button 7, high-voltage rectifier 9, first and second capacitors 10 and 1.1, limiting resistor 12, discharger 13, output sockets 14 and 15 for connecting a flash lamp, trinistor 17, additional capacitor 18, pulse transformer 19. The circuit works similarly given. When the voltage on condensate 10 reaches the voltage of the discharge gap 13, gas discharge occurs in discharge 13, and the capacitor 10 is quickly discharged through ridge 13 and the primary winding of the impulse transformer 19. The primary winding of the impulse transformer 19 induces in its secondary winding a voltage pulse of such polarity that it closes the transistors 3 and 4 along the base circuits, the generation fails, the load current from the source BH iHoro source becomes equal to Hyjrto, trinisgor 17 is turned off, and the circuit is de-energized. At the moment of exposure, the storage capacitor of the flash and, simultaneously with it, the capacitor 11 is discharged through a pulsed flash. The discharge current of the capacitor 11 flows through the primary winding of the transformer 19, the pulse of the discharge current of the capacitor 11 induces in the secondary winding of the transformer 19 a voltage pulse of such a polarity which, being applied.1 through the capacitor 18 to the control (t. To the tristor electrode 17 , opens it. The inverter self-raises, the storage capacitor lampr-flash is charged and, after its charging, the circuit is automatically turned off, as described. I Thus, at the time of exposure, the converter automatically turns on AET discharge divshiys exposure during storage capacitor of the flash lamp and a) ztomaticheski turned off. At the same time, in the off state, due to the absence of discharge paths in the output peep paths of the storage flash photocapacitor, the latter retains its charge for a rather long time. In connection with the ethical charging of the storage capacitor is not required in the intervals between exposures, which increases the efficiency of the proposed converter. The absence of mechanical ratios increases the reliability of the converter.

Claims (4)

. (54) (. 57) .1. A DC-FLASH CONVERTER FOR POWER FLASHING, containing a transistor inverter, a high-voltage rectifier and an on / off switch equipped with a spark gap, distinguishes by the fact that, in order to increase efficiency and reliability, a thyristor is inserted into it, connected in series with the inverter power circuit, and its anode connected to the first output of the inverter transistor base bias resistor, a closing button, two capacitors, the first of which is connected between the positive terminal of the high-voltage rectifier and the cathode of the arrester, and the second between the negative terminal of the high-voltage rectifier and the anode of the arrester, and a limiting resistor connected between the positive terminal of the high-voltage rectifier and the anode of the arrester. SU „„ 1069094 Figure 1 2. The converter according to π. 1, characterized in that, for the sake of simplicity, a dynistor is used as a thyristor, and the closing button is connected parallel to the dynistor, the second output of the bias resistor is connected to the cathode of the discharge cathode, and its first output is connected to the negative terminal of the high-voltage rectifier. 3. The converter according to π. 1, characterized in that, in order to increase the sensitivity of the on and off automaton, a thyristor is used as a thyristor, the control transition of which is shunted by a closing button and a chain of additional capacitor and additional resistor connected in series, and the additional resistor is connected to the thyristor anode by an additional capacitor - with its control electrode, the connection point of the additional resistor and capacitor is connected to the negative terminal of the high-voltage rectifier, and the second terminal of the bias resistor is connected to the cathode of the arrester. 4. The converter according to π. 1, characterized in that, in order to galvanically decouple the high-voltage and low-voltage circuits, b a trinistor is used as a thyristor, the control transition of which is shunted by a closing button, an additional capacitor is connected between the control electrode of the trinistor and the second output of the bias resistor, and a pulse transformer, the primary winding, is introduced which is connected between the negative terminal of the high-voltage rectifier and the cathode, and the secondary one is connected in series with the bias resistor.