SU484813A1 - Flash lamp supply device - Google Patents

Description

one

The invention relates to the field of quantum electronics and can be used to power a flash lamp, in particular an optical quantum generator pumping lamp (laser), operating in the mode of both single and frequently repeated pulses, with smooth control of the energy stored in the working capacitor bank, which, in turn, is discharged onto the pumping lamp of the active laser body.

A device for regulating the energy discharged to the pumping lamp is known, based on the charge of the working capacitor bank and then discharging it to the pumping lamp of the active laser body. The battery is charged from a high-voltage power supply through a main controlled valve. When the voltage on the capacitor bank reaches the voltage supplied by the UEJUNA, the controlled valve is closed. This is achieved by connecting an auxiliary capacitor to its working electrodes using an additional control valve. The auxiliary capacitor is charged up to a voltage that is above the set level on the working capacitor bank. Polarity

The charge of the connected auxiliary capacitor is such that it creates a reverse voltage on the main control valve. The auxiliary capacitor is charged through a resistor from a high-voltage rectifier and transformer. The electronic control circuit for each cycle of operation of the device generates 3 pulses: the beginning of the charge of the working capacitor bank, the end of the charge of this battery the pulse of ignition of the pump lamp.

The drawbacks of the known device are caused by the fact that the pump level is controlled by interrupting high charging currents, and consists in the presence of an additional auxiliary capacitor bank, in the presence of a separate high voltage rectifier connected to the auxiliary capacitor battery, galvanically separated from the main charging circuit. Finally, there is a relatively large number of expensive, low-reliability controlled valves.

Claims (1)

A feature of the proposed device, which simplifies it and increases its reliability, is that a capacitor bank is connected to a chain of an accumulative inductive network and a key device consisting of an uncontrolled valve and counter parallel with its connected thyristor, the control electrode of which is connected to the output of the unit setting the pulse frequency and synchronized with the supply voltage, and an ignition transformer is connected to the output of a level comparator providing ignition of the lamp When reducing the voltage across the battery to a predetermined operating value. FIG. 1 is a schematic diagram of the device; Fig. 2 is a time chart of the operation of the device, reflecting the nature of the voltage variation on the working battery. The device contains a power transformer 1, a charge rectifier 2, a working battery of capacitors 3, a key device consisting of an unguided valve 4 and a thyristor 5 that are connected in parallel to the connected, an accumulative inductance 6, a pulse transformer 7 for igniting a lamp-8, bls ( 9, which sets the frequency of the flash, and the compa- rator of level 10. The device operates as follows: The working battery of capacitors 3 is charged directly from the power network rectifier to the amplitude value of the output voltage. The time tj to the control input of the thyristor key from block 9, synchronized with the mains voltage, is given a pulse opening key. As a result, the oscillating circuit 1, consisting of a working capacitor bank 3, a cumulative inductance 6 and a key device 4.5, the oscillating process starts.The capacitance of the capacitor bank 3 and the magnitude of the cumulative inductance 6 are selected so that the resonant frequency of the circuit formed by them is approximately twice the frequency of the power supply network. After opening the thyristor key, the battery of capacitors starts to discharge to cumulative inductance 6 (time interval tg-t This process continues until t, while the voltage across the battery contoured by the level comparator 10 drops to a predetermined value. And corresponding to the required energy pumping V. (| 1 moment t, a level 10 comparator through an ignition transformer 7 gives an impulse p; firing the laser pumping lamp 8 of the active body, and the necessary amount of energy remaining in the battery during the time (ii - b) is discharged to the lamp 8. Vibrating The process started with 8 circuit 3.6 continues, as a result of which the capacitor battery is discharged first to the opposite polarity (time i,), and after half more, to the original, i.e. operating polarity ( In this case, the first half-period (to-tj), the current flows through the right-hand valve chain, and the second half-period (tj-ti,) in the opposite direction through the uncontrolled valve, which ensures reliable locking of the thyrisors. Thus, after completing the recharging cycle in the 3.6 circuit, a part of the energy diverted to the moment of the flash of the lamp 8 into the inductance is transferred to the capacitor battery, which keeps the device high AP. After charging the battery with rectifier to the maximum output voltage UQ, the device is ready for the next operating cycle. Smooth regulation of the energy applied to the lamp is accomplished by changing the level of comparing and supplying an ignition pulse to the lamp at the right time. The moment of application of the opening pulse to the controlled valve is synchronized with the supply voltage. The most typical way to synchronize a pulse is to feed it at the time of the voltage supply at the output of the rectifier to a zero value. However, a time shift of the specified pulse to the left (advance) or to the right (delay) with respect to the instant of voltage drop at the output of the rectifier to zero value is possible. When the triggering pulse of the thyristor is shifted to the left (advance), it is necessary that during the transfer of energy from the capacitor bank 3 to inductance b and the subsequent discharge of the battery to the pump lamp, the voltage on the capacitor battery is higher than the voltage at the output of the power rectifier. The magnitude of the time shift of the pulse, which opens the thyristor switch, is governed by the ratio of the frequency of the power supply network and the resonant frequency of the oscillating circuit 3.6. The device eliminates the possibility of pulsed overloads of the charging valves (and hence the power transformer), because the charging voltage after the preceding flash of the lamp does not increase abruptly, but increases from almost zero sinusoidally. Moreover, the condensate battery is already partially recharged due to the energy diverted to the moment of the previous outburst to accumulate an inductance. All this allows refusing the charge current-limiting elements (resistors, chokes), which reduce the efficiency of the entire device. The valve elements of the key device also do not experience overloads, as they participate only in smooth oscillatory processes. . In addition to supplying ECG pumping lamps, the proposed device can also be used in various processes where a frequently repeated charge of a capacitive storage device is required and then discharged to an energy consumer with control of the energy removed from the storage device. An example is the electrospark processing of mettschlov, the formation of Yutkin's electrohydraulic effect, the powering of various impulse devices, etc. The invention The device for powering a flash lamp, in particular a pump lamp of optical quantum generators, operating in the mode of both single and frequently repeated pulses, with a smooth regulation of the radiation energy, contains a power rectifier and a working battery of capacitors discharged A lamp ignition transformer, characterized by TeMf, which, in order to simplify the device and increase its safety, a chain of accumulative inductance and a key device is connected to the capacitor battery consisting of an uncontrolled valve and a coupled thyristor counter-parsed with it, the control electrode of which is connected to the output of the unit setting the pulse frequency and synchronized with the supply voltage, and the ignition transformer is connected to the output of the comparator of the level providing ignition of the lamp when it decreases voltage on the working battery to the maximum value.