RU95065U1 - LUMINAIRE WITH LUMINESCENT LAMP (OPTIONS) - Google Patents

Abstract

 1. A luminaire with a fluorescent lamp, with glow electrodes, including an electronic ballast connected to a power source, the outputs of which are electrically connected to the lamp electrodes, characterized in that all the electrodes of each lamp filament are paired, and a high-frequency trigger launcher is connected in parallel with the output of the ballasts capacitor. ! 2. The lamp according to claim 1, characterized in that the pairwise connection of the lamp electrodes with the output of the ballast and with the starting capacitor is made by soldering on printed circuit boards. ! 3. The lamp according to claim 2, characterized in that the soldering is made by lead-free solder. ! 4. The lamp according to claim 1, characterized in that the connection plate of the lamp electrodes with the output of the ballast and with the starting capacitor are located inside a separate dielectric housing installed in the lamp housing. ! 5. A luminaire containing more than one fluorescent lamp, with glow electrodes, an electronic ballast connected to a power source, the outputs of which are electrically connected to the lamp electrodes, characterized in that the electrodes of each lamp filament are paired, all lamp lamps are connected in series connected electrodes of filaments, and the extreme opposite pairwise connected electrodes of the extreme lamps are connected to the outputs of ballasts, in parallel with which high frequency starting capacitor. ! 6. The lamp according to claim 5, characterized in that the pairwise connection of the electrodes of the extreme lamps with the output of the ballast and with the starting condensate

Description

The utility model relates to the field of electrical engineering and can be used in luminaires with fluorescent lamps to illuminate rooms for various purposes, including explosive rooms, where combustible and / or explosive oil, gas, chemical materials are used or are produced.

A lamp is known that contains a housing, a tubular fluorescent gas-discharge lamp with heated cathodes, a throttle-containing starter (electromagnetic) ballast, connected to a power source, for example, a 220 V power supply and a frequency of 50 Hz, and outputs - lamp electrodes (see Lumisvet Lamps. Catalog 2008 OJSC “Petushinsky Metal Plant”, Moscow). When the lamp is connected to ballasts and an alternating current source from the influence of a starting pulse, the filaments are heated and the mercury contained in the lamp is evaporated, the mercury atoms emit intensely, causing a bright glow of the phosphor, which covers the inner surface of the lamps.

The described lamp has a high ripple of the emitted light flux due to the low frequency of 50 Hz of the mains power supply. The stroboscopic effect tires the eyesight and psyche of people in rooms illuminated by such lamps. The lamp flashes when it is turned on due to an unstable discharge in the interelectrode space inside the lamp. The luminaires have a short life due to the short life of the lamps and starter due to the unstable mode of operation. Additionally, the lamps have a short service life due to burnout of the filaments or their breakage. The presence of a throttle in ballasts causes increased noise operation of the lamp, adversely affecting humans. The luminaire has a high sensitivity to changes in mains voltage and a large energy consumption of 85 to 140 W / h. Due to sparking at the contact junctions, the network-inductor-starter-starting capacitor-lamp, the lamp is not used in fire- and explosive rooms. The presence of a choke in ballasts causes loss of power at the transitions "network-choke-lamp"; when heating the filaments, there is also a loss of power, which reduces the efficiency and power factor of the lamp.

The closest in technical essence is a lamp containing a metal housing with a reflector, a tubular fluorescent lamp with heated electrodes, sockets for mounting the lamp, connecting wires and an electronic ballast (hereinafter referred to as electronic ballasts), the input of which is connected to the mains, and the outputs through electrical contacts to mounting sockets are connected to the terminals of the fluorescent lamp (see Lumisvet Lamps. 2008 Catalog of JSC Petushinsky Metal Plant, Moscow, p. 4). The electronic ballast equipment includes a frequency converter of the supply voltage from 50 to 32000 Hz and an electronic voltage regulator. The frequency converter of the supply voltage eliminates the pulsation of the light flux, the stroboscopic effect in the range visible to the human eye reduces the noise of the equipment, and the stabilizer stabilizes the supply voltage and provides a more reliable ignition of the lamp and its more stable burning regardless of surges in the supply voltage, as well as conducts soft inclusion of cathode glow. Nevertheless, the presence of filaments in the lamp causes a large consumption of electricity by heating them with the conversion of electrical energy into thermal energy, and the possibility of poor electrical, as a rule, spring contact in the four transitions "ballast-lamp control" (by the number of leads for one lamp ) causes sparking of the luminaires, which makes it impossible to use them in fire and explosion hazardous areas, while a significant part of the power is lost, which reduces the efficiency of the luminaire, The saving factor is reduced and the overall lamp life is reduced. The life of such luminaires is also short due to the fragility of the filaments (breakage, burnout) and requires frequent replacement of lamps, which are difficult to dispose of due to the presence of mercury. There is also oxidation of these contacts and their erosion in humid and dusty rooms, which limits the scope of their use.

The objective of the utility model is to reduce energy losses in the lamp, increase energy saving by eliminating the conversion of electric energy into heat, eliminating the burning of filaments, thereby increasing the lamp life, eliminating sparking of contacts, and, as a result, expanding their scope, in particular, the possibility of using the lamp in explosive and fire hazardous areas.

The problem is solved by the design of a luminaire containing a fluorescent lamp with glow electrodes, electronic ballasts connected to a power source, the output of which is electrically connected to the lamp electrodes. The difference between the proposed design of the lamp from the prototype is the following. The electrodes of each lamp filament are connected in pairs (i.e., the filament is shorted), and a high-frequency starting capacitor is connected in parallel with the output of the ballasts, and therefore the lamp.

The problem is also solved in the second embodiment of the luminaire in the presence of more than one lamp in the luminaire containing fluorescent lamps with glow electrodes, electronic ballasts connected to a power source, the output of which is electrically connected to the lamp electrodes. The difference between the proposed design of the lamp of the second option from the prototype is the following. In the second embodiment, if there are more than one lamp in the lamp, the electrodes of each filament of the lamps are also connected in pairs, all the lamps of the lamp are sequentially interconnected by connected electrodes of the filaments, and the extreme opposite pairwise connected (shorted) electrodes of the extreme lamps are connected to the outputs of ballasts (ballasts) ), while parallel to the electronic ballast output, and hence the chain of series-connected lamps, a high-frequency starting capacitor is turned on.

The number of lamps used in the lamp, and their power affect the choice of the type of ballasts of a certain power. Depending on the parameters of the used lamps and the capacitor, the latter is connected to one lamp, to two or more of them, which is determined by electrical engineering calculations based on the power of the lamps and electronic ballasts. The capacitor may be one for each pair of lamps, as shown in figure 2 and 3.

With this construction of the electrical connection of the electrodes of the lamp lamps and the lamps themselves, heating of the filaments, which in accordance with the utility model serve only as electrodes, is excluded; excludes losses on the conversion of electrical energy into heat, energy losses on their heating. Burnout of filaments is excluded. In this case, the lamp is ignited not from heating the filaments, but from the pulses of the starting capacitor, following each other with a frequency specified by the parameters of ballasts.

Almost pairwise connection of the electrodes of each filament of the lamps can be carried out when installing the lamp lamps by soldering their electrodes to the printed circuit boards, which eliminates the possibility of breaking contacts and their sparking. At the same time, used lamps can be taken for burnout or dangling filaments, which will sharply increase the terms of their use and will save the consumer. The problems of disposal of such lamps with burnt filaments by their repeated use will be reduced.

To avoid further oxidation of contacts during the use of fixtures in damp and dusty rooms, it is advisable to use lead-free (lead-free) solder.

The extreme electrodes of the extreme lamps connected to the output of the ballast and with the starting capacitor can be placed inside a separate dielectric housing located in the lamp housing together with ballasts. This will further expand the scope of fixtures in fire and explosive rooms using or producing oil, gas, and chemical products.

In figures 1-3, embodiments of the circuit diagram of the components of the lamp. In this case, figure 1 shows a connection diagram of one lamp, in figure 2 - two lamps, in figure 3 - four. The spatial configuration of the placement of several lamps may be different from the configuration of their placement, reflected in figure 2 and 3.

The luminaire is connected to a supply network 1 of an alternating voltage of 220 V and a frequency of 50 Hz and contains electronic ballasts 2 connected to the network 1, fluorescent tube lamps 3 with pairwise shorted electrodes 4 of each filament, the last of which are sealed in printed circuit boards (not shown ) Lamps 3 are interconnected in series (FIGS. 2 and 3). The lamp also contains a starting capacitor 5, also soldered at one end to one board, and the other to the other board. Depending on the power of the fixtures, their number and the parameters of the capacitor 5, the latter can be several, for example, one for each pair of lamps, as shown in figures 2 and 3.

A fluorescent lamp operates as follows.

When applying an alternating supply voltage of 180-230 V to the input of the electronic ballast 2, the supply voltage in it decreases, rectifies, stabilizes and converts to an alternating voltage of increased frequency, for example, 32000 Hz. From the output of the electronic ballast 2, the high-frequency voltage is supplied simultaneously to the inputs of 4 lamps 3 and the starting capacitor 5, the conclusions of which are sealed on the boards. With the repetition rate of the output pulses from the electronic ballast unit 2, the capacitor 5 is charged to the charge voltage and after the charge is discharged, producing an electric ignition pulse for lamps 3. Under the action of a sequence of ignition pulses of the same frequency from the capacitor 5, the mercury in the lamps 3 evaporates, intense emission of mercury atoms occurs , causing almost instantaneous (no filament) bright glow of the phosphor, which covers the inner surfaces of the lamps 3. Here there is a glow of the phosphor, initiated by a non-thermal energy Gia heated filament and directly trigger pulse electric discharge of the capacitor 5, applied to the electrodes of the lamp, i.e. electroluminescence.

Tests and comparative studies of luminaires in the form of light blocks with two and four lamps with a power of 18 W each were performed, made in accordance with the utility model and in accordance with the prototype. We used the same type OSRAM tubular fluorescent lamps and ballasts FERON 1x18 (one lamp), 1x36 (two lamps), 2x36 (four lamps), 36 W 2x36 (two lamps) for a supply voltage of 220 volts. As a result of the experiments, it was found that the energy consumption in the prototype is 73 W (four lamps), and in the scheme of the proposed utility model - no more than 53 W for the same number of lamps with the same electronic ballasts. The current consumption for the prototype in this case was 0.31 A, for a utility model 0.23 A, the leakage current for a prototype was 20 mA, for a utility model 2 times less - 10 mA, the voltage loss at the “power source - lamp” junction for the prototype were 1.8 V, for a utility model there are no losses. Accelerated the start of lamps using electric ignition starting capacitor in accordance with the utility model - almost instantly, simultaneously for all 4 lamps, compared with the prototype, in which the ignition of the lamps occurred with a delay of 1 second. As a result of tests and studies of new circuits, it was found that in the proposed utility model, fluorescent lamps that are out of order due to breakage or burnout of the heating threads, i.e. disposal of lamps with broken filament is possible. The results obtained indicate that the energy-saving light unit in accordance with the utility model is efficient and solves the problem, is economical and can be used at various facilities. Moreover, due to the long-term operation of the lamp, the lamp can increase the warranty period of their operation to five or more years, which is impossible to do in the prototype, there is no guarantee for the lamps. The service life of the lamps using the utility model is limited only by the life of the phosphor, which is 10 years.

Claims (8)

1. A luminaire with a fluorescent lamp, with glow electrodes, including an electronic ballast connected to a power source, the outputs of which are electrically connected to the lamp electrodes, characterized in that all the electrodes of each lamp filament are paired, and a high-frequency trigger launcher is connected in parallel with the output of the ballasts capacitor. 2. The lamp according to claim 1, characterized in that the pairwise connection of the lamp electrodes with the output of the ballast and with the starting capacitor is made by soldering on printed circuit boards. 3. The lamp according to claim 2, characterized in that the soldering is made by lead-free solder. 4. The lamp according to claim 1, characterized in that the connection plate of the lamp electrodes with the output of the ballast and with the starting capacitor are located inside a separate dielectric housing installed in the lamp housing. 5. A luminaire containing more than one fluorescent lamp, with glow electrodes, an electronic ballast connected to a power source, the outputs of which are electrically connected to the lamp electrodes, characterized in that the electrodes of each lamp filament are paired, all lamp lamps are connected in series connected electrodes of filaments, and the extreme opposite pairwise connected electrodes of the extreme lamps are connected to the outputs of ballasts, in parallel with which high frequency starting capacitor. 6. The lamp according to claim 5, characterized in that the pairwise connection of the electrodes of the end lamps with the output of the ballast and with the starting capacitor is made by soldering on printed circuit boards. 7. The lamp according to claim 6, characterized in that the soldering is made by lead-free solder. 8. The luminaire according to claim 5, characterized in that the connection boards of the extreme electrodes of the extreme lamps with the output of the ballast and with the starting capacitor are placed inside a separate dielectric housing installed in the lamp housing.