SU501500A1 - Device for switching on powerful tubular gas discharge lamps - Google Patents

Description

formatter. This transformer is necessary to increase the voltage of the pulses produced by the control generator in order to ensure reliable ignition of the arrester. However, the presence of this non-standard element in the device complicates it. In addition, each type of arrester corresponds to its breakdown voltage, the parameters of the auxiliary transformer must be selected specifically.

The aim of the invention is to simplify the design of the start-igniter device by excluding from the circuit an auxiliary pulse transformer.

This goal is achieved by the fact that a pulse transformer is provided with an additional winding connected through a diode or NSDSr to the control pulse generator, and the third discharge electrode is connected via an additional capacitor to the coil of the secondary winding of the transformer connected to the lamp. With such a device, the ignition of the discharge is provided by a pulse on the high-voltage winding, which is induced when a pulse from the control pulse generator is applied to the additional winding. Thus, the need for an auxiliary pulse transformer is eliminated, and the design of a pulse transformer is made slightly more complicated, since the number of turns in the additional winding is very small (one or two turns).

Due to the fact that the voltage of the pulse induced on the secondary winding is high, ignition of arresters with a large range of breakdown voltages can be ensured, and the parameters of the pulses firing the lamp do not change with a significant increase in the discharge voltage of the probe during its service life, which increases device reliability. In addition, it is possible to use different types of arresters without changeover, which facilitates mass production.

The drawing shows a diagram of the start-ignition device for high-power pipe valves for gas discharge lamps.

The device consists of a power source 1 (in this embodiment, a transformerless voltage doubled rectifier) to which a working capacitor 3 is connected through a resistor 2, the discharge circuit of which is formed by a three-electrode discharge 4 and the primary winding 5 of the pulse transformer, in series with the secondary winding b lamp 7 is turned on. The end of the winding 6 connected to the lamp 7 is connected via a capacitor 8 to the control electrode of the discharge element 4. The capacitor 8 has a small capacity but is designed for th voltage appearing across the coil 5, as such a capacitor can be used coaxial cable segment using as electrodes "chly and braid of the cable. The transformer has an additional winding 9 connected to the control pulse generator 10. In this case, a generator is used on the spark discharge, and if the discharge has a sufficient amount of discharge suppression voltage, the generator is directly connected to winding 9, but connection is possible a diode to avoid the loss of energy of the discharge of the working capacitor 3. The control generator 10 can be performed on a dynistor or thyristor; in this case, it is connected to the winding 9 also directly. The breakdown voltage between the electrodes of the discharge 4, included in the circuit of the discharge capacitor

3, should exceed the voltage at the output of the power source 1 and 1.5 times or more, so that spontaneous breakdowns would not be possible. When the device is connected to AC power at the output of the power source 1

a voltage appears which is used to charge capacitor 3 through a resistor 2, and the charge can occur before the full voltage of source 1, since it is not enough for the self-test of discharge 4. When the generator is 10

produces a pulse applied to the winding 9 on the boost winding 6, a high-voltage pulse is induced, insufficient to form a discharge in the lamp 7, sufficient to ignite the discharge 4, which

is punched and the working capacitor 3 is discharged to the primary winding 5. This causes high-frequency oscillations, and a high-voltage high-frequency pulse appears on the secondary winding 6, penetrating

lamp 7. Part of the energy of this pulse penetrates through the capacitor 8 to the discharge 4, but since the capacitance of the capacitor 8 is small, this part of the energy is insignificant. The described process is repeated at the frequency determined by the frequency of operation of generator 10, prior to ignition in the lamp / arc due to mains voltage, after which the device is disconnected from the network.

Claims (1)

Invention Formula A device for switching on high-power tubular-gas-discharge lamps, for example, xenon lamps, powered by an alternating current network, containing a power source to which a working capacitor is connected, the discharge circuit of which is formed by two electrodes of a three-electrode spark discharge with a sealed housing, the voltage between them is greater than the voltage of the power source, for example, 1.5 times or more, and the primary winding of the pulse transformer, the secondary winding of which is connected in series with the lamp being lit, and a control pulse generator, characterized in that, in order to simplify the design of the device, the pulse transformer is provided with an additional winding connected to the control pulse generator, and the third discharge electrode Dnika is connected via an additional capacitor to the end secondary winding connected to the lamp. W