RU2422940C1 - Method of igniting powerful gas-discharge lamp - Google Patents

Abstract

FIELD: physics. ^ SUBSTANCE: method of igniting a gas-discharge lamp involves applying power voltage across the inter-electrode space of the lamp, checking integrity and preheating electrodes of the lamp by passing current. Preheating of the electrodes is stopped after a certain period of time after igniting the lamp. The electrodes are heated in steady state when the lamp is burning. ^ EFFECT: more on-off cycles and longer service life of powerful gas-discharge lamps owing to a mode for mild formation of the cathode spot. ^ 2 dwg

Description

The invention relates to the field of lighting and is intended to control the ignition and combustion of low-pressure discharge lamps of high power, in particular ultraviolet (UV) bactericidal lamps used for disinfection of various environments.

In lamps of this type, radiation occurs due to the excitation of a gas discharge between spiral electrodes coated with an emission layer. Typically, ignition of discharge lamps is carried out in a starter circuit or using an electronic ballast (ECG).

In the starter circuit, the lamp ignites when the supply voltage is applied after the electrodes are heated and the starter is turned off. However, this mode of lamp ignition negatively affects the state of the emission coating of the electrodes due to a significant temperature effect, which can lead to its dispersion or evaporation.

In modern lighting technology, a method of ignition using an electronic ballast (EPRA) is used to ignite lamps, which helps to prevent damage to the electrodes and ensure the initial emission of electrons by preheating the electrodes with a high-frequency current of several tens of kilohertz. This method is characterized by the fact that the heating of the spirals is usually combined with the voltage supply to the lamp. Then, a high-frequency high-voltage starting pulse is applied to the lamp, which provides ionization, gas discharge and lamp ignition. After the occurrence of a gas discharge, the mode of maintaining the lamp burning occurs, an important requirement of which is the limitation of the lamp operating current. The use of electronic ballasts during lamp ignition provides the most optimal saving mode for the lamp electrodes in comparison with the starter method and increases its service life.

Particularly relevant is the problem of extending the service life of gas discharge lamps with a power of more than 300 W operating at high currents of several amperes and low pressures (less than 1 torr). The service life of such lamps is much shorter than that of small and medium power lamps, since due to their characteristics - large mass and developed surface area - the electrodes of such lamps carry an increased thermal load and fail more quickly. Therefore, the development of a method of ignition and maintaining the burning of a lamp with a gentle mode of action on the electrodes is an important technical task in the creation and operation of high power lamps.

There is a known method of controlling a lamp, which consists in sequentially supplying a supply voltage to the interelectrode distance of the lamp, heating the electrodes by applying heating voltage to the electrodes, sending a request about the state of the lamp electrodes using identification means connected to the lamp, analyzing the result of the request (interrupting the process in case of a negative request result or continuation of the process with a positive result of the request), subsequent application of the ignition voltage to the interelectrode distance Nia for driving a gas discharge in the lamp electrode heating termination by disconnecting from the power voltage after the start of the discharge in the lamp and maintaining a gas discharge by applying a burning voltage (US Patent №6906337, H01J 61/02, 2004 YG). This method allows you to control the condition of the lamps and prevent the start of blown lamps, which is especially important for multi-tube disinfection systems. However, in the indicated sequence of operations, the lamp electrodes are exposed to a significant negative effect, due to the fact that initially applying voltage to the electrode interelectrode distance and to the cold electrodes causes a subsequent surge of the electrode preheating current and a violation of its temperature balance, which leads to cracking of the emission coating of the electrodes, intensive spraying (evaporation) of the electrode material and the separation of particles of this coating into the plasma of the gas discharge, and sedimentation of the product in spraying onto the walls of the lamp envelope. These processes reduce the life of the electrodes and lamps, reduce the number of on-off cycles and the efficiency of the light source, cause a decrease in the intensity of UV radiation.

The closest analogue of the proposed invention is the method of ignition of a gas discharge lamp, described in patent RU 2319323, Н05В 41/02, 2006, which consists in applying a supply voltage to the interelectrode distance of the lamp, passing current through the lamp electrodes, sending a request for the integrity of the lamp electrodes and analysis query results, preheating the lamp electrodes by passing current, applying an ignition voltage to the interelectrode gap of the lamp, and maintaining the lamp current until normal a new operating mode of combustion, in which the electrodes are heated in a stationary mode.

This method significantly eliminates the aforementioned disadvantages of the analog due to the fact that during the preheating of the pre-electrodes there is no current in the lamp, and the ignition voltage of the lamp is supplied after the pre-heating of the electrodes. After ignition of the discharge, the electronic ballast provides a mode of maintaining and stabilizing the lamp current at a given level, and the electrodes are heated in a stationary mode, in which the electrode heating current is reduced several times compared to the initial heating current. The method provides the most favorable mode for preserving the lamp electrodes, reducing the effect of evaporation of the emission coating of the electrodes, and allows to increase the lamp life and the number of on-off cycles.

The main disadvantage of the prototype method is the limitation of its application by lamps of low and medium power and the inefficiency of its use for high-power discharge lamps.

Since the electrode assemblies of high-power lamps carry a significant thermal load, special devices, such as screens, special types of cathodes, are used to reduce it, or powerful tri-helical electrodes are used, as in the present invention. To ensure a long service life, the tri-spiral electrodes are filled with a large amount of emission material, which is ceramic made of alkaline earth metal oxides. In contrast to the electrodes of medium and low power lamps, which, due to their relatively small size, are not susceptible to significant temperature gradients on the emission coating, which operates when the lamp is ignited in the cathode spot mode, the tri-helical electrodes of high-power lamps with large sizes and developed surface area are subject to period of high heat loads. A feature of the ignition of high-power lamps is the rapid formation of a cathode spot with a temperature of about 1100 ° C on a large surface of a massive electrode with a relatively low temperature. Significant temperature gradients that arise in the initial period of the lamp can lead to cracking of the ceramic emission layers having low thermal conductivity and to loss of their adhesion to the tungsten core.

The above processes lead to a deterioration in the performance of both the electrodes and the lamp as a whole, since the products of atomization and evaporation of the coating of the electrodes are deposited on the walls of the lamp bulb and lead to a decrease in the radiation intensity. Thus, the method of lamp ignition, adopted as a prototype, does not take into account the design features of the electrodes of high-power lamps and the process of rapid formation of the cathode spot on their surface and does not provide a significant service life.

The problem to which the invention is directed is to implement a method of igniting a powerful gas discharge lamp, which allows you to create the optimal saving mode of the so-called “soft” cathode spot formation, taking into account the peculiarities of the electrode properties and the nature of the thermal processes that occur during the lamp ignition period.

The technical result obtained from the use of the invention is to expand the scope of the method for high-power discharge lamps, increase the number of on-off cycles and lamp life.

The specified technical result is achieved due to the fact that in the method of igniting a gas discharge lamp, which includes supplying a voltage to the electrode interelectrode distance, passing current through the lamp electrodes, sending a request for the integrity of the lamp electrodes and analyzing the request results, preheating the lamp electrodes by passing current, applying the lamp ignition voltage and maintaining the lamp burning current when heating electrodes in a stationary mode, according to the invention edvaritelny display electrodes is stopped after lamp ignition.

The invention is illustrated by drawings, where in Fig.1. oscillograms of voltage U _l on the lamp, current I _l of the lamp discharge and current I _{prog of} heating the electrodes when the lamp is ignited are presented according to the prototype method; and figure 2 presents the waveform of these parameters according to the proposed method.

As follows from figure 1, in the starting period, the voltage U _l on the lamp is practically absent, while the current I _l of the lamp discharge is also zero, and the current I _{about the} preheating of the electrodes is constant and maintained for a considerable period of time (up to tens of seconds) at a given level. In the known method, at the time of ignition of the lamp t _{1, the} preliminary heating of the electrodes is stopped, the operating voltage U _l is applied to the interelectrode distance of the lamp, an arc discharge arises and the operating current I _l of the lamp discharge is established. The electronic ballast goes into the stationary mode of maintaining and stabilizing the lamp current at a given level, and the electrodes are heated in a stationary mode, in which the current value I _{st of} heating the electrodes is several times lower than the value of the current I _about preheating and is maintained at this level during stationary burning lamp.

In the proposed method of ignition of high-power gas-discharge lamps to solve the technical problem, the advantages of the prototype are preserved and a two-inverter electronic ballast circuit with independent heating of the electrodes in the starting period and the absence of voltage on the lamp is used, however, according to the invention, to pre-heat the electrodes lamp continue after occurrence of the arc discharge in the lamp, maintaining the value electrode heating current at an initial level _of I in those ix specific time interval and then stopped. In the mode of stable combustion of the lamp, the heating of the electrodes is carried out in a stationary mode by passing current I _st. whose value is much less than I _about .

The invention is illustrated by the time dependences of the lamp parameters shown in FIG. 2, from which it follows that the current I _{about the} preheating of the electrodes is not reduced several times immediately after the occurrence of the arc, but is kept constant Δt = t ₁ -t ₂ , V This period of time, the electrodes operate in a cathode mode without a cathode spot (surface) due to the temperature sufficient for such a mode. After a decrease in temperature due to a decrease in the heating current, the electrodes cool, allowing a “soft” formation of a cathode spot with an already working arc on an already heated surface. In this case, there is no significant destruction of the emission layer of even the largest and most massive electrode assemblies.

The method is as follows. To ignite a 500 W gas discharge amalgam lamp emitting in the bactericidal UV range, an electronic ballast circuit is used with independent heating of the electrodes in the starting period and the absence of voltage on the lamp with two controlled inverters, for example, described in RF patent No. 2319323, in which two inverter units operate in current stabilization mode. The lamp ignition device comprises a filter 1, a rectifier 2, a power factor corrector 3, a controlled inverter 4 for heating the electrodes, a controlled inverter 5 for maintaining the lamp current and a control unit 6. The controlled inverters 4, 5 are connected to the lamp 14 and the control unit 6. The inverter 4 stabilizes the current of the electrodes both before the lamp is ignited and in the period Δt after it (current of preheating the electrodes), depending on the program in the control unit, and the second inverter 5 maintains and stabilizes the lamp current and electrode heating current during lamp operation (electrode heating current in stationary mode). A constant stabilized voltage of +380 V is supplied to the lamp, supplying both inverters 4, 5, which, after supplying power, are locked by the control signal of the control unit 6. The control unit 6 interrogates the state of the electrodes and, subject to their integrity, turns on a controlled inverter for heating the electrodes 4, which supplies the electrodes set current I _about preheating the electrodes, the value of which is 4.1-4.3 A. The time for preheating the electrodes is about 24-28 seconds. Then, in the process of preheating the electrodes, when the inverter 4 is operating, the control unit 6 includes a controlled inverter 5, which provides the high voltage necessary for a gas discharge to occur in the lamp. After ignition of the arc discharge in the lamp, the control unit 6 puts the inverter 5 in the mode of stabilization of the lamp current I _l , 2.5-5.0 A, and the inverter 4 for heating the electrodes continues to work for a predetermined time Δt (from 1 to 4 seconds) after ignition of the lamp while maintaining the current of preheating the electrodes of the initial value, which ensures a “soft” transition to the cathode spot mode. At the starting period of the lamp ignition and pre-heating ends, after which the light passes in a stationary heating mode, consisting in the fact that when burning lamp current I _st heating electrodes was decreased to 0.4-0.6 A, which is several times smaller compared to the preheating current.

As a result of the application of this ignition method, the number of switching cycles for high-power discharge lamps increases from 2000-5000 times to 100000 times.

Claims (1)

A method for igniting a gas discharge lamp, including supplying voltage to the electrode electrode distance, passing current through the lamp electrodes, sending a request for the integrity of the lamp electrodes and analyzing the results of the request, preheating the lamp electrodes by passing current, applying the lamp ignition voltage and maintaining the lamp burning current at the implementation of the heating of the electrodes in stationary mode, characterized in that the preheating of the electrodes is stopped after ignition l mpy.

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