SU1563577A1 - Device for supplying pulse gas-discharge lamp - Google Patents

Abstract

The invention relates to electrical engineering and can be used to power pulsed gas discharge lamps pumping lasers operating in 6 L frequency mode. The aim of the invention is to increase the efficiency and reliability of the device. The device allows the formation of steep edges of the current pulse of the lamp and ensuring the establishment of parameters without using a stabilized high-voltage power source. This is achieved by connecting the throttles 5 in parallel to the connected in series capacitor 2 and thyristor 4. The leading edge of the current pulse through the lamp is formed when the capacitor 8 is discharged, and the tip of the current pulse is formed by the throttles 5. 3 sludge.

Description

W

with

U1

0

СЈ ЈЛ

s |

The invention relates to electrical engineering and can be used to power pulsed gas discharge lamps pumping lasers operating in frequency mode.

The aim of the invention is to increase the efficiency and reliability of the device.

FIG. A diagram of the device for powering a pulsed gas-discharging lamp} in FIG. 2 is a control block diagram; Fig. 3 shows timing diagrams explaining the operation of the device, where 1d is the current through the flash lamp; 1 - current drossel; U4 and U. are the voltage across the first and second capacitors.

 The device contains a power source 1 of direct current, the positive terminal of which is connected to the same plate of the first capacitor 2 and the first terminal to connect a pulsed gas discharge lamp 3 to the negative terminal of power source 1 is connected to the second plate of the first capacitor 2 and connected cathode the first thyristor 4, the throttle 5, the second b and the third 7 thyristors, the anodes of which are interconnected directly, and the cathodes through the second capacitor 8, the fourth 9 and the fifth JO of the thyristors whose anodes are connected according to This is connected with the cathodes of thyristors 6 and 7, diode II, the second terminal for connecting a pulsed gas discharge lamp 3, a control unit 12, to the input of which a current sensor 13 is connected, the anode of the thyristor 4 being connected to the anode of the thyristor 6 and through a series-connected current sensor J3 and The choke 5 with the positive output of the power source 1. The second output for connecting a pulsed gas discharge lamp through the secondary winding of the pulse transformer 14 is connected to the combined cathodes of the thyristor 10 and diode I3, the anode of which is connected to the cathode of the thyristor 9 and p are positive side of the power source 1 is primary

the winding of the pulse transformer 14 is connected to the unit on duty arc 15,

The control unit 12 consists of a delay unit 16 (Fig. 2), a comparison unit 17 and three generators 18-20 of thyristor control pulses, You; the stroke of the first generator 18 is connected to the control input of the thyristor 4, the input of the generator 19 is connected to the output of the node

five

0

five

0

five,

17, and the output with the input of the delay node 16 and the control inputs of the thyristors b and 10. The generator 20 input with the output of the delay node 16, and the output with the control inputs of the thyristors 7 and 9. Moreover, the input of the comparison node 17 is connected to the sensor current 13.

A device for supplying a pulsed gas discharge lamp operates as follows.

Prior to the formation of a pulsed gas discharge lamp 3 in the pump current pulse, the capacitor 8 is charged from an auxiliary low-power power source with a voltage approximately equal to the operating voltage of the lamp (120%). In the future, this auxiliary source

I v

Power in the operation of the circuit does not accept, therefore, in FIG. 1 not shown. The capacitor 2 is charged from the power source 1 to the voltage lf (Fig. 3), with a considerable spread of this voltage from pulse to pulse (± 20%). In the pulsed gas discharge lamp 3, a spark ignition is initiated by the ignition transformer 14, the on-duty arc unit 15 converts it into a powerful arc discharge, which is then maintained throughout the entire operating time of the device. The current of this arc discharge (the current of the pilot arc) flowing through the lamp 3 is three orders of magnitude less than the pump current, therefore in FIG. 3 ok not shown.

At time t0, the control electrode of the thyristor 4 passes a triggering pulse from the control unit 12, the thyristor 4 is turned on and the capacitor 2 discharges into the inductor 5. At the time t, when the current i. in the throttle

5 reaches a predetermined value. Equal to l.0.81t, the control unit 12, receiving a signal about the current ig, in the inductor 5 with the help of the current sensor 13 produces a triggering pulse

to thyristor control electrodes

6 and 10. The latter turn on, capacitor 8, charged before voltage U, discharges along the circuit thyristor 10 - secondary winding of transformer 14 - lamp 3 - capacitor 2 - thyristor 4 - thyristor 6. At the same time, starting from the moment tf, in the lamp 3, the front of the pump current pulse is generated,

and through the thyristor 4 flows a current equal to the difference ia-i- / |. Since in con51563577

The sensor 8 is stored energy, neobdimy only to form the front

la shi ka nako ko nu vyu

the current pulse of the ift is pumping, then its capacitance is small and the front of the current pulse C is steep. This leads to a decrease in energy loss and a decrease in the heating of the active element of the laser during the formation of a current pulse of pumping and an increase in the efficiency of the device,

At the time t2, when the current 1L in the lamp 3 reaches the value of the current i. in choke 5 (Fig. 3), the thyristor 4 is turned off due to the fact that the reverse voltage of the capacitor 8 is applied to it. The discharge of the capacitor 2 therefore stops and, from the time t, the capacitor 2 starts to charge again from the power source 1, Despite the initial voltage U (the charge of the capacitor 2 can vary from pulse to pulse in wide limits, the energy stored in

five

ten

The laser generation of the formation of the tip of the current pulse i in the lamp 3 is terminated. For this, the control unit issues unlocking pulses to the control electrodes of the thyristors 7 and 9, which are turned on. Since at time t, the voltage of the capacitor 8 changes sign (FIG. 3), when the thyristor 7 is turned on, the opposite voltage of the capacitor 8 is applied to the thyristor 6, the reverse voltage of the condenser 15 through the thyristor 9 is also applied to the thyristor 10 diode, Thyristors 6 and 10. as a result, are closed, and the current ia throttle 5 from time t $ closes along a new circuit: thyristor 7 - capacitor 8 20 thyristor 9. At time t, lamp 3 is excluded from the current flow path ia throttle 5 and current irt through it almost immediately ceases (Fig. 3). This increases the efficiency of the device.

choke 5 to the moment t, does not change et-25 and reduces the heating of the active element from pulse to pulse. This is a cc laser, since the flow of current through which is switched on at

TGM h i3rv.JJp 4T -Ji.ri ate 1 I-1

thyristors 6 and 0 always occur at the same fixed set value In. current i. in the inductor 5. Consequently, the thyristor 4 is turned off after a time interval, occurs at the same current value i l. In choke 5, i.e., the energy stored in choke 5 by the time t4 is unchanged from pulse to pulse, although the device does not include a stabilized power source. The elimination of a stabilized power source allows us to simplify the design and design of the device, and increase the reliability of its operation. The current ia of the throttle 5 (FIG. 3) from the time t is closed by the following circuit: thyristor b - capacitor 8-45 thyristor 10 - secondary winding of the transformer 14 - lamp 3. In lamp 3, the peak of the pump pulse is formed from the moment tz (Fig. 3 ) mainly due to the energy of the throttles 5. The amplitude of the pump current pulse (± 20%) is adjusted by changing in the control unit 12 the magnitude of the current I, the time t, to which the control unit 12 55 pulses to turn on the thyristors b and 10. A deeper adjustment of the pump current is achieved Changing the capacitance of the capacitor 2.

the lamp after the occurrence of a lasing pulse leads to useless energy loss and elite

30 heat the active element of the laser. Electromagnetic energy of throttles 5, containing with it by the time tj, passes by the time interval Cj - t4 (Fig. 3) into electrostatic energy

., - capacitor. Voltage Pg of capacitor 3 first changes its sign again, and then reaches the initial value U2 (Fig. 3). The return voltage on the capacitor 3 is approximately

40 is less than the initial voltage U4t, so the capacitor 8 operates in a partial rather than a full recharge mode, which increases its service life and reliability of operation, and consequently, increases the reliability of the device as a whole. The capacitor 3 to the beginning of the formation of each pump pulse is charged to the same voltage, although there is no powerful high-voltage stabilized power source in the device circuit. Eliminating such a power source makes it possible to simplify the device for powering a pulsed gaseous discharge lamp and increasing it; tsgzyust, so klk high-voltage stabilized power source is the most complex and least reliable device that determines the complexity and reliability

At the moment t the pulse is generated.

five

0

The laser generation of the formation of the tip of the current pulse i in the lamp 3 is terminated. For this, the control unit issues unlocking pulses to the control electrodes of the thyristors 7 and 9, which are turned on. Since at time t, the voltage of the capacitor 8 changes sign (FIG. 3), when the thyristor 7 is turned on, the opposite voltage of the capacitor 8 is applied to the thyristor 6, the reverse voltage of condenser cp pp 3 is also applied to the thyristor 10 and the diode, Thyristors 6 and 10. as a result, are closed, and the current ia throttle 5 from time t $ closes in a new circuit: thyristor 7 - capacitor 8 thyristor 9. At time t, lamp 3 is excluded from the current flow path ia throttle 5 and current irt through it almost immediately ceases (Fig. 3). This increases the efficiency of the device.

and reduces the heating of the active element of the laser, since the flow of current through

the lamp after the occurrence of a lasing pulse leads to useless energy loss and elite

heating the active element of the laser. Electromagnetic energy of throttles 5, containing with it by the time tj, passes by the time interval Cj - t4 (Fig. 3) into electrostatic energy

- capacitor. Voltage Pg of capacitor 3 first changes its sign again, and then reaches the initial value U2 (Fig. 3). The return voltage on the capacitor 3 is approximately

less than the initial voltage U4t, therefore, the capacitor 8 operates in a partial rather than a full recharge mode, which increases its service life and reliability of operation, and consequently, increases the reliability of the device as a whole. The capacitor 3 to the beginning of the formation of each pump pulse is charged to the same voltage, although there is no powerful high-voltage stabilized power source in the device circuit. Eliminating such a power source makes it possible to simplify the device for powering a pulsed gaseous discharge lamp and increasing it; tsgzyust, so klk high-voltage stabilized power source is the most complex and least reliable device that determines the complexity and reliability

 7156

of the device as a whole. At the moment the cycle of operation of the device ends.

It should be noted that the above described is not the first cycle after the device was turned on (but any one, starting from the fourth, fifth cycle, since the device’s operation in the first few cycles does not fundamentally differ from the one described, but the initial one (Capacitor Voltage 8 and, consequently, the amplitude of the pulse of the pump 1 Current comes to steady-state values over several cycles of operation, I

The next cycle of operation of the device for powering a pulsed gas-discharging lamp starts after the pump pulse period ijn has elapsed from the moment of te. The control unit generates a trigger pulse, which is supplied to the control electrode of the thyristor 4, then the operation of the circuit is similar to, described above,

dmula inventions

A device for supplying a pulsed gas discharge lamp containing a DC power source, to the positive terminal of which the first capacitor of the same name is connected to the first terminal for connecting a pulsed gas discharge lamp to the negative terminal of the power source, the other face of the first capacitor is connected and the cathode of the first is connected thyristor, droshselt V GO U

P

five

0

five

eight

the swarm and thyristors, the anodes of which are interconnected directly, and the cathodes through a second capacitor, fourth and fifth thyristors, the anodes of which are connected respectively to the cathodes of the second and third thyristor, a diode, a second terminal for connecting a pulsed gas discharge lamp, the control unit, to the input of which is connected to a current sensor, characterized in that, in order to increase the efficiency and reliability of the device, the anodes of the first, second and third thyristors are combined and connected through a series-connected current sensor and a choke to the floor A second power supply terminal, a second terminal for connecting a pulsed gas discharge lamp is connected to interconnected cathodes of the fifth thyristor and a diode, the anode of which is connected to the fourth thyristor cathode and a positive terminal of the power source, and the control unit is designed as a delay node, comparison node and three thyristor control pulse generators, the output of the first of which is connected to the control input of the first thyristor, the start input of the second generator with the output of the reference node, and the output to the input of the node 3 Derzhko and the control inputs of the second and fifth thyristors start input of the third delay generator output node, and an output with the control inputs of the third and fourth thyristors, wherein comparing input connected to the input of the control unit.

First breath

nineteen

Second breathing

jfc

Phie. /

Claims (1)

swarm and -feter thyristors, the anodes of which are directly connected to each other, and the cathodes through the second capacitor, the fourth and fifth thyristors, the anodes of which are connected respectively to the cathodes of the second and third thyristors, a diode, a second terminal for connecting a pulsed discharge lamp, a control unit, to the input of which is connected to a current sensor, which requires that, in order to increase the efficiency and reliability of the device, the anodes of the first, second and third thyristors are combined and connected through series-connected current sensors and chokes a positive terminal of the power source, the second terminal for connecting a pulsed discharge lamp is connected to the cathodes of the fifth thyristor and the diode connected between them, the anode of which is connected to the cathode of the fourth thyristor and the positive terminal of the power source, and the control unit is designed as a delay unit, a comparison unit and three thyristor control pulse generators, the output of the first of which is connected to A device for powering a pulsed discharge lamp, containing a DC power source, the positive output of which is sub-. the same plate of the first capacitor is switched on and the first output for connecting a pulsed discharge lamp, another plate of the first capacitor is connected to the negative output of the power source and connected to the control input of the first thyristor, the input of the second generator start-up with the output of the comparison unit, and the output with the input the delay node and the control inputs of the second and fifth thyristors, the start input of the third generator with the output of the sound control node, and the output with the control inputs of the third and fourth thyristors, and the input of the node 'comparison is connected to the input of the unit uptod of the first thyristor,