SU824489A1 - Device for igniting gas-discharge tube - Google Patents

Description

The invention relates to electrical engineering and can be used for ignition of powerful xenon arc lamps powered by AC power and used for lighting ’quarries, seaports, airports, railway stations, etc. A device for ignition of discharge lamps, containing a power source, connected via its input through a switch to an AC mains, and connected to the inputs of a clock pulse generator and an ignition pulse generator, the output 15 clock pulse generator having a double-winding pulse transformer, a secondary winding which is connected to the control input of the ignition pulse generator, at the output of which a pulse transformer is installed, connected by the secondary winding of the sequence but with the lamp has two pulse transformer II]. However, the device is complex and relatively expensive.25 The closest to the proposed device is for ignition of gas discharge lamps, containing a power source, connected via its switch input to the terminals for 30 connection to an alternating current network, the output connected to the input of the pulse generator and to the input of the generator ignition pulses, the outputs of which are connected to the individual primary windings of a three-winding pulse transformer, the secondary winding of which is connected to the control input nerator of impulses. ignition and to the terminal for connecting a discharge lamp, and the end of the secondary winding of a pulse transformer and the second terminal for connecting a discharge lamp are connected to the terminals for connection to the supply network [2].

However, the device has a complex three-winding pulse transformer, which increases its cost and reduces reliability.

The purpose of the invention is to simplify the device and reduce its cost.

This goal is achieved by the fact that in a device for igniting a gas discharge lamp containing a power source connected by an input through a switch with outputs for connecting to an alternating current network, and by an output connected to the input of a clock pulse generator and to the input of an ignition pulse generator, the output of which is connected to the primary pulse transformer winding, the control input is connected to the beginning of the secondary winding of the pulse transformer and to the output for connecting a discharge lamp, and the end of the secondary winding a pulse transformer and a second terminal for connecting a discharge lamp are connected to the capacitor plates and with terminals for connecting a supply network, the output of the clock pulse generator is connected to the primary winding of the pulse transformer.

The drawing shows a circuit diagram of a device.

It contains a power source 1, connected through an input through a switch 2 to the terminals for connection to an alternating current network, and 20 connected to the input of a clock pulse generator 3, consisting of an adjustable resistance 4, a capacitor 5, a diode 6, and a spark gap 7, and to the input of the generator 25 • 8 pulses of ignition, consisting of a resistor 9, capacitors 10, 11 and a three-electrode spark gap 12. The output of the generator 3 clock pulses and the generator 8 pulses of ignition are connected to the terminals of the primary winding of the pulse transfer rmatora 13, the secondary winding of which is connected to the start control input of the pulse generator 8 minutes to lamp ignition, and the secondary winding ends of a pulsed transformer 13 and the second terminal of the lamp 14 are connected to terminals for connection to a power line to which the capacitor 15 is connected.

The device operates as follows 40.

When the device is connected to the AC mains, a voltage appears at the output of the power source 1, which charges the capacitor 10 through the resistor 9, and the charge can be carried out up to the full voltage of the power source 1, since this voltage is not enough for the breakdown of the spark gap 1'2 without supply, I initiate is the _t impulse to the control electrode. ' The generator 3 begins to send pulses to the primary winding of the pulse transformer 13 with a frequency determined by the parameters of the generator circuit. For each pulse on the secondary winding of the transformer 13, high voltage pulses are induced, insufficient in magnitude to ignite the discharge in the lamp 14, but sufficient to initiate a discharge in the spark gap 12, which breaks through, and the working capacitor 10 is discharged to the primary winding of the pulse transformer 13. In this case, high-frequency oscillations, and a powerful high-frequency high-voltage pulse appears on the secondary winding, piercing the lamp 14. Due to the fact that the generator 3 has a mouth, θ updated diode 6, the connection of the gene The actuator 3 directly to the primary winding of the pulse transformer 13 does not prevent the occurrence of high-frequency oscillations in the circuit formed by the capacitor 10, the discharge 12, and the primary winding of the transformer 13, therefore, the device operates reliably. The process is repeated with a frequency determined by the generator 3. After stable ignition of the lamp 14, the device is disconnected from the network.

A device for igniting a powerful gas discharge lamp simplifies the design of a pulse transformer while ensuring the reliability of the device, therefore, in conditions of mass production, the cost of the devices is reduced.

Claims (1)

Ignition pulse generator, whose output is connected to the primary winding of a pulse transformer, the control input is connected to the beginning of the secondary winding of the pulse transformer and to the output for connecting the gaoraorad of the lamp, and the second terminal for connecting the gas discharge lamp is connected to the plates capacitor and leads for connecting the mains, the output of the clock pulse generator is connected to the primary winding of the pulse transformer. The drawing shows a circuit diagram of the device. It contains a power source 1 connected by its input via switch 2 to the terminals for connection to the AC network, and the output connected to the generator input 3 clock pulses consisting of adjustable resistance 4, capacitor 5, diode 6 and spark spark 7, and to the generator input -8 ignition pulses, consisting of a resistor 9, capacitors 10, 11, and a three-electrode spark 12, the output of the generator 3 clock pulses and the generator 8 pulses of ignition are connected to the output of the primary winding of the pulse transformer The matera 13, the secondary winding of which is initially connected to the control input of the generator 8 pulses of ignition and to the lamps ne, and the ends of the secondary winding of the transformer pulse 13 and the second terminal of the lamp 14 are connected to the terminals for connection to the supply network to which the capacitor 15 is connected. The device works as follows. When the device is connected to the AC mains, a voltage appears at the output of the power source 1, which through the resistor 9 charges the capacitor 10, and the charge can be carried out before the full voltage of the power source 1, since this voltage is not enough to break down surge 12 without initiating a pulse to the control electr. Generator 3 begins to send pulses to the primary winding of the pulse transformer 13 with a frequency determined by the parameters of the generator circuit. At each pulse, high-voltage pulses, insufficient in magnitude for ignition of the discharge in the lamp 14, are induced on the secondary winding of the transformer 13 - but sufficient to initiate the discharge in the discharge 12, which pierces, and the working capacitor 10 is discharged to the primary winding impulse transformer 13. High-frequency oscillations occur, and a powerful high-frequency high-voltage pulse appears on the secondary winding, penetrating the lamp 14. Due to the fact that diode b is installed in generator 3, The generator 3 directly to the primary winding of the pulse transformer 13 does not prevent the occurrence of high frequency oscillations in the circuit formed by the capacitor 10, the voltage 12 and the primary winding of the transformer 13, therefore the device works reliably. The process repeats at a frequency determined by the generator 3. After stable ignition of the lamp 14, the device is disconnected from the network. A device for igniting a powerful gas discharge lamp simplifies the design of a pulse transformer while ensuring the reliability of the device operation, therefore, under mass production conditions, the cost of devices is reduced. Apparatus of the Invention A device for igniting a gas-discharging lamp containing a power source connected by an input through a switch to outputs for connection to an AC network, and an output connected to the input of a generator of clock pulses and to the input of a generator of pulses of ignition whose output is connected to the primary winding of a pulse transformer and the control input is connected to the beginning of the secondary winding of the pulse transformer and to the output for connecting the gas discharge lamp, and the end of the secondary winding of the pulse transformer nsformatora and for connecting the other terminal of the discharge lamp connected to the capacitor plates and a pin for connecting the mains supply, characterized in that, in order to simplify the device and reduce its cost, the clock pulse generator output is connected to the primary winding of the pulse transformer. Sources of information taken into account in the examination 1. USSR author's certificate 561310, cl. H 05 B 41/23, 01.29.73. 2; USSR Author's Certificate 501500, cl; H 05 B 41/23, 14.05.74.