SU1570039A1 - Method of power supply of gas-discharge lamp with series-connected induction ballast from ac circuit - Google Patents

Abstract

The invention relates to electrical engineering and can be used when powering a gas discharge lamp from an AC network. The purpose of the invention is to increase the service life of a gas discharge lamp and inductive ballast by eliminating current surges in valve mode. The goal is achieved by the fact that in the mode of a dark glowing and asymmetrical arc mode for 0.1 - 0.2 times the lamp energized, the supply voltage is applied with a phase cut angle of 90 - 110 °, and then with a phase cut angle of 0 - 40 °. 1 il.

Description

The invention relates to electrical engineering and can be used to power gas discharge lamps from an AC network.

The purpose of the invention is to increase the service life of the gas discharge lamp and inductive ballast by eliminating current surges in valve mode.

The drawing shows a diagram of a device that implements a method for feeding a gas discharge lamp.

The device contains a phase-regulating element 1, a ballast choke 2, a gas discharge lamp 3, an ignition device 4, a relaxation generator 5, controlling the operation of the phase-regulating element 1, a logic element AND 6, current sensors 7 and voltage

8, a diode bridge 9, a transistor 10, a relay 1 1 with normally closed contacts 12, resistors 13-15, a capacitor 16.

The device works as follows.

When the supply voltage is switched on, the relaxation generator 5 begins to generate and apply to the phase regulating element 1 control pulses in the range of 90-110 °. At the same time, through the shunt chain 15 and 16, the supply voltage is supplied to the igniter 4, which in turn supplies the lamp 3 with high-voltage ignition pulses. After lamp 3 has been broken down, during its ignition period, when there are stages of dark, glow and asymmetric arcs J

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i.e. current surges may occur, the lamp 3 is forcibly re-ignited. The phase of the regulating element 1 is unlocked, and therefore the lamp 3 is re-ignited during this period at an angle of 90-110. After a time interval equal to (0.1-0.2) tp and determined by the parameters of element 6 with sensors 7 and 8, when the discharge in the lamp 3 changes to a symmetrical arc, the need for further forced reloading is no longer necessary. The signal from the element 6 blocks the transistor 10, which leads to de-energizing the relay 11 and connecting the control electrode and the anode of the phase-regulating element 1, and, therefore, to reducing the phase cut-off angle to almost zero.

The boundaries of the phase cut-off angle ranges are chosen based on the following considerations. At angles of phase cut-off after a breakdown in the mode of dark, glowing and asymmetrical arc discharge less than 90 °, the valve effect starts to develop in the starting mode, and at angles greater than 110 °, current pauses occur, causing the lamps to go out.

In the symmetric arc discharge mode, the phase cut-off angle should not exceed 40 s, as in schemes With inductive ballast for large

Q 5 0

50

five

In the corners there are current pauses leading to the lamp extinguishing.

The difference of the method is the change in the phase cut-off angle of the supply voltage during the transition from the starting to the operating mode, and after pro, in the dark, glow and asymmetrical arc discharge mode, this angle is 90-110, and in the symmetric arc mode - 0 -40 °.

Using the proposed method will increase the service life of the lamp and drossel by 30% by eliminating current surges during the lamp heating period.

Claims (1)

Invention Formula A method for supplying a gas discharge lamp with a series-connected inductive ballast from an AC network, consisting in supplying a phase-controlled supply voltage thereto, characterized in that, in order to increase the service life of the gas discharge lamp and inductive ballast by eliminating current surges into valve mode, in the mode of dark, glowing and asymmetric arc discharge for 0.1-0.2 of the normalized lamp reheat time, the supply voltage is applied with the phase cut-off angle 90-1 10 and then with the angle AZOV cutoff 0-40 °.