SU656241A1 - Method and device for igniting pulse gas-discharge lamp - Google Patents

Claims (2)

Noise L9MPA operating at frequencies of several hertz and below. This goal is achieved by the fact that in the method of ignition of a flash lamp, by supplying ignition pulses to the lamp electrodes, the lamp electrodes with an accidental Skip flash give the low voltage pulses with an increased, for example, two orders of magnitude to a given flash frequency. A series of these pulses stops automatically after the next flash of the lamp. With this method of supplying the impulsive pulses, in the case of a missed pass, there is a slight delay of the next flash, which visually cannot even be registered by the observer. Such a method can be implemented by a device consisting of a power source, a charging unit, an extra capacitor ns and an ignition pulse generator containing an element defining a pulse ignition frequency in which a new element is that the indicated element is made sensitive to misses of flashes. . This causes the igniter generator of their pulses to respond to the missed flash. The element that sets the frequency of the ignition pulses can be made in the form of a high-resistance resistor, which is connected in parallel with a series-connected low-resistance resistor and a zener diode. FIG. Figure 1 shows a functional diagram of the device illustrating the proposed method for igniting the discharge of flash lamps; in FIG. 2 shows an electric circuit of an apparatus for carrying out a method for firing gas discharge flash lamps; on fng. 3 - timing diagrams of the directions of the elements on the electric circuit of the device and the current through the lamp. The device contains a power source 1, a charging unit 2, a storage capacitor 3, an ignition pulse generator 4 with a flash-sensitive element 5, a pulsed gas discharge lamp 6 with ignition electrode 7. The essence of the new ignition method is that 3 through block 2 from the power source 1 to the nominal operating voltage of the lamp, the generator 4 produces a clock ignition pulse arriving at the electrode 7, the lamp 6 flashes, and the capacitor 3 is discharged, after which follow charging cycle. If the lamp does not light up when the ignition pulse is applied and a skip occurs, the sensitive element 5 switches the ignition pulse generator to the mode; work with an increased (for example, two orders of magnitude) frequency of sending ignition pulses. In this case, the second or next subsequent pulse ignites the lamp, a flash occurs, and the generator returns to the normal clock frequency of sending pulses equal to the given flashing frequency. The charging unit 2 is represented, for example, as a single-stage converter consisting of a transistor 8 into the base circuit which includes an ohmic voltage divider consisting of resistors 9 and 10 and feedback winding 11 of transformer 12. The primary winding 13 of transformer 12 is included in the x-ray circuit of transistor 8, and the output Refusal 14 through a rectifying diode 15 is connected to a storage capacitor 3. Parallel to the capacitor 3 is connected a lamp 6 and an ignition pulse generator 4 containing a resistor 16 connected to the zener diode 17, the thyristor 18 and the capacitor 19. The element sensitive to flashes of the flashes consists of a resistor 16, parallel to which are connected in series the resistor 20 and the zener diode 21. The primary winding 22 of the transformer 23 is connected to the capacitor 19, and the secondary winding 24 of the transformer 23 is connected to the electrode 7 azhigani lamp 6. The device operates sledukndim manner. From source 1, power is supplied to a single-ended converter 2, which, during a return stroke, produces in the winding 14 a current pulse fed through a diode 15 to charge capacitor 3. The voltage across capacitor 3-Ui is shown in FIG. 3. With a charged capacitor 3, the current through the resistor 16 is supplied to the capacitor 19 (voltage diagram of Fig. 3). The parameters of the elements 16, 19 and the ignition voltage of the Zener diode 17 are chosen so that when the voltage of the lamp 6 is reached on the capacitor 3, the Zener diode 17 is ignited and 24 5 appears on the winding (voltage diagram 2.4 - burning pulse during discharge the capacitor 19 through the thyristor 18 to the coil 22. 22. This causes the lamp 6 to ignite, accompanied by the discharge of the capacitor 3 and the passage of a current pulse 3g shown in Fig. 3 through the lamp. If the lamp does not light up, the capacitor 3 will remain charged Condensation the torus 19 is discharged, as a result of this, the zener diode 21 is affected by the total voltage of the capacitor 3, which must be greater than the threshold ignition voltage of the zener diode 21. Under these conditions, the stabilizer 21 is ignited, and the high-resistance resistor 16 is bridged a low-resistance resistor 20. The dwell of the charging circuit is sharply reduced, and the generator goes into a mode of generating ignition pulses at a higher frequency, which is shown in FIG. 3 is reflected by built-in pulses on the diagrams and l. After the flash of the lamp 6, the capacitor 3 is discharged to a voltage less than the extinguishing voltage of the zener 21, the zener diode 21 goes out and the whole circuit goes into generation mode with a predetermined flash frequency. This ignition pulse generator circuit can be used with almost any kind of charging device. The use of a new method of ignition of flash lamps in light-signal devices eliminates the possibility of accidentally missing a flash of a lamp when working in flashing mode and eliminates the need for special devices to increase the voltage on the lamp before the flash and create the backlight and discharge gap, which are usually used to reduce the likelihood of missed flashes. With a slight complication of the igniting device, it eliminates visible misses of the flashes of the pulsatile lamp. In addition, devices made in accordance with the new method have an important operational advantage: the activation of a sensitive element indicates a deterioration in the ignition characteristics of a flash lamp and indicates the need to replace it. Claim 1. The method of igniting a gas-discharge flash lamp by applying ignition pulses to lamp electrodes, characterized in that, in order to eliminate visible misses of flashes, voltage is pulsed from an increased, for example, two orders of magnitude, to the lamp electrodes frequency with respect to the specified flash frequency. 2. A device for carrying out the method for igniting a gas-discharge flash lamp according to claim 1, consisting of a power source, a charging unit, a storage capacitor and a generator of ignition pulses, containing an element behind the trigger frequency of ignition pulses, characterized in that of the ignition pulse generator to the} mode of the high-frequency sending of these pulses / the indicated element is made sensitive to the misses of the flashes. 3. The device according to claim 2, which is based on the fact that the element setting the frequency of the trace no ignition pulses, made in the form of a high-resistance resistor, in parallel with which included a low-resistance resistor and a zener diode connected successively connected. Sources of information taken into account during the examination 1. I. Marshak. And a source of light of light. M.-L., Tosenergoizdat, 1963, p. 336. 2.Mik I. and Craggs D. Edited by Komelkov V.S. Electrical breakdown B gases. M., I960, p. 6O5. FIG. 2 nineteen , -l.x ....