SU1274162A1 - Device for supplying power to gaseous-discharge lamp - Google Patents

Abstract

The invention relates to electrical engineering and m. used to power short-arc ultra high pressure mercury lamps; . The purpose of the invention is to increase the reliability of the device by automatically controlling the current of the gas discharge lamp according to the optimal linear law depending on the voltage variation on it during ignition, during the opening period and during operation. The device contains a power source 1, an adjustable converter 2, a resistive sensor 3, a voltage divider 4 and a non-linear functional converter 5. The device automatically provides a piecewise-linear approximation of the required non-linear law of regulating the lamp current depending on the voltage on the gas discharge gap at the moment of ignition , at the flare-up and in the steady-state S mode, which allows to increase by (L the ignition reliability in the arc discharge lamp, to exclude accidental extinction during the flare-up process and in the established lamp operation mode 2 ill.

Description

The invention relates to electrical engineering and can be used to power, for example, short arc mercury ultra-high pressure lamps. The purpose of the invention is to increase the reliability of the device by automatically adjusting the current of the gas-discharge lamp according to an optimal non-linear law depending on the change in the voltage across it during ignition, during the period of operation. FIG. 1 shows a device for feeding a gas discharge lamp; in fig. 2 shows the dependence of the change in current through the lamp 1 when the voltage on it changes, and is ensured in the case of a device. The device for supplying the gas-discharge lamp (Fig. 1) contains a source 1 of constant voltage, a guided converter 2 of voltage, connected by an input to the output of the source of constant voltage 1, and outputs respectively to a negative and first positive bus. , a resistive current sensor 3 connected between the first and second positive buses, a resistive divider 4 voltage, one of the terminals connected to the second positive bus, and a midpoint connected to the control input of the adjustable voltage converter 2 nonlinear functional converter 5 on three zener diodes 6,1 6, 3, four series-connected resistors 7.1 - 7.4, the free terminal of the resistor 7.1 is connected to the negative bus, and the free terminal of the resistor 7.4 is connected to the second the output of the reznstivny divider 4 voltage, and pam resistor 7.5, to the common point of resistors 7.2 and 7.3 connected through a resistor 7.5, the anode of the Zener diode 6.1, to the common point of resistors 7.3 and 7.4 - the anode of the Zener diode 6,, 2, the cathodes of the Zener diodes 6.1 and 6.2 are connected to the second positive bus, to the common point of resistors 7.1 and 7.2 n dklyuchen anode of zener 6.3, the cathode of which is connected to the free terminal of the resistor 7.4 The device operates as follows. 622 When the voltage at the load is less than that of the 6.1 to 6.3 zener diodes and closed, the feedback signal supplied to the control input of the adjustable voltage converter 2 is determined by the sum of the signals taken from the resistive current sensor 3 and the resistive voltage divider 4, connected to the negative bus in series with resistors 7.1–7.4, which causes the current to be adjusted for 1 c of the load according to direct AB (Fig. 2). When increasing the voltage on the load to the value U, (point b, fig 2) the voltage drop on the series-connected resistive voltage divider 4 and resistors 7.3 and 7.4 becomes equal to the stabilization voltage of the Zener diode 6.1, Zener diode 6.1 opens and with further increase of the voltage on the load greater than CDd., series-connected resistors 7.5 and Zener diode 6.1 shunt resistive divider 4 and resistors 7.3, 7.4, providing a breakthrough direct AB at point B and changing 1 load current with a further increase in voltage to the load ZEC a straight BG (Figure 2). At point J, corresponding to the voltage U, the voltage across the resistive divider 4 and resistor 7.4 becomes equal to the stabilization voltage of the Zener diode 6.2, the latter opens, providing a direct RG breakdown at point D and adjusting the current with further increase the voltage on the load is greater than Ufv along the direct HD (FIG. 2). The forward drive goes parallel to the abscissa axis, ensuring the flow of direct current through the load on this area a little more than point D when voltage is applied to the load, equal ujt drop the voltage across the series-connected resistors 7.2-7.4 becomes equal to the stabilization voltage of the Zener diode 6.3, the latter opens, providing a sharp break at point D and, accordingly, a sharp decrease in the load current to zero when the voltage on the load changes from U. to U, U by TOijH: ,, f direct DE (FIG. 2). At the initial moment of operation of the device, a single voltage is applied to the load in the form of a short-arc mercury lamp, after turning on the source 1 of a constant voltage at the output of the adjustable voltage converter 2 u move the value of which, using a feedback circuit formed by the resistive current sensor 3 by the resistive voltage divider 4 and the nonlinear functional converter 5, is stably maintained at a level slightly higher than the minimum required for ignition of the U-axc arc discharge lamp in the gas discharge lamp U, axc, FIG. 2).

After the ignition of the arc discharge gap g-; 1W €; on a gas discharge pampa falls from U. d6 U ,,,, gpe Uj, voltage drop in:;; Cold with low pressure of mercury vapor filling it, and the current through the lamp is maintained at a level not less, at which the arc discharge can still exist (ABDHD broken, FIG, 2). During the ignition period of the gas discharge lamp, the discharge current is regulated along direct AB (Fig. 2) as the voltage across it increases from to (J, which ensures that the clamp is supplied with the power necessary for its reliable and fast ignition. With sharp increases in voltage During this period, up to U. The regulation of the discharge current is carried out along a direct HD (Fig. 2), ensuring the flow of current through it is not less than.

In the steady state operation of the lamp after its ignition, the voltage on it during the service life increases monotonically from U to U, and the current of the lamp varies along a straight & b (Fig. 2), ensuring that its nominal power is maintained throughout its life.

Thus, this device automatically provides a piece-line approximation of the required non-linear law of regulating the lamp current depending on the voltage across the gas discharge gap at the time of ignition, during heating and in the steady state. This makes it possible to increase the reliability of ignition in the arc discharge lamp, to exclude accidental extinction during the process of heating and in the steady state operation.

lamps, provides low idle power consumption while the lamp is still not lit (or when the lamp fails to ignite due to its failure). The device does not require adjustment when the lamp is replaced, and also allows to increase the lamp life during its long-term operation due to the automatic maintenance of its nominal power on it when the primary supply voltage changes and the combustion voltage changes. In addition, the circuit implementation of the proposed device is quite simple.

The use of a device for powering short-arc mercury lamps of type DRSh 100-2 in special light-beam oscillographs powered by autonomous sources of direct current operating in the mode of frequent switching-on makes it possible to significantly increase the reliability of recording information.

Claims (1)

Invention Formula A device for powering a gas discharge lamp, containing a constant voltage source, an adjustable voltage converter connected by an input to the output of a constant voltage source, and outputs to a negative and first positive voltage, respectively, a resistive current sensor connected between the first and second positive buses , a resistive voltage divider, one of the terminals connected to the second positive bus, and a midpoint connected to the control input of an adjustable voltage converter, from In order to increase the reliability of the device by automatically adjusting the current of the gas discharge lamp according to the optimal nonlinear law depending on the voltage variation on it during ignition, during the heatup and during operation, a non-linear functional converter on three zener diodes is introduced into it , four series-connected resistors, the free output of the first of which is connected to the negative bus, and the free output of the fourth resistor to the second output The resistive voltage divider and the fifth resistor are connected to the common point of the second and third resistors through the fifth resistor anode of the first Zener diode, to the common point of the third and fourth resistors - the anode of the second Zener diode, the cathodes of the first and second Zener diodes 127/1662 are connected to the second positive spike, to the common point of the first and second resistor is connected to the anode of the third Zener diode, the cathode of which is connected to the free output of the fourth resistor. ./ hol f / r-t 1L If. 1 cr (rig 2