RU2106771C1 - Power supply for luminescent lamp - Google Patents

Abstract

FIELD: electric engineering. SUBSTANCE: device has idle choke which has terminal for connection of positive line 8 from single-polarity pulse source and terminal for connection of lamp electrode. Negative terminal of by-pass diode is connected to output of idle choke. Positive terminal of by-pass diode is connected to terminal for connection of lamp electrode and negative line for source. In addition device has starter which is connected to terminals for connection of lamp electrodes and has at least transistor, resistor and connection element. Resistor is inserted between base of transistor and terminal of idle choke. Connection element is inserted between collector and transistor and terminal for connection of electrode. Emitter is connected to terminal of electrode. Connection element is designed as parallel circuit of capacitor and choke or resistor which is connected in parallel to one of these elements. Device heats electrodes and starts lamp or starts lamp with non-heated electrodes. EFFECT: increased functional capabilities. 5 cl, 2 dwg

Description

 The invention relates to electrical engineering, to gas discharge lamps.

 Known devices for powering fluorescent lamps, the operation of which is based on the use of unipolar pulses from a current source. Similar in content according to the applicant, are a lighting device [1], a device for powering a discharge lamp [2], a device for powering fluorescent lamps [3].

 The specified lighting device [1] contains a direct current source, a starter and a high-frequency chopper made on a transistor for receiving unipolar current pulses intended for supplying a fluorescent lamp.

 The mechanical contacts of the photo relay and starter, which control the lamp operating modes, spark, burn and emit radio interference during operation.

 A device for supplying a gas discharge lamp [2] contains a constant voltage source, a key for generating a pulse voltage, a ballast inductor, a shunt diode between the lamp connection terminal and the inductor, as well as a starter.

 A feature of this device is the need to have two power sources - main and auxiliary, while the device does not provide preheating of the lamp electrodes at startup.

 A device for supplying a fluorescent lamp [3] (prototype) contains a ballast choke with a first terminal for connecting a positive wire from a unipolar pulse source, connected by a second terminal to a terminal for connecting the first electrode of the lamp, a shunt diode connected by a negative terminal to the first terminal of the ballast reactor, and positive terminal - to the terminal for connecting the second electrode of the lamp and to the terminal for connecting the negative wire from the source of unipolar pulses, the starter connected to the terminals for connecting lamp electrodes.

 In this device, an electromechanical starter generates radio noise, and also does not provide preheating of the electrodes of the lamp, designed to start with preheating.

The aim of the invention is to solve the following problems:
a) a decrease in the level of generation of radio interference;
b) the exclusion of the possibility of a cold start of the lamp, designed for starting with pre-heating;
c) heating the lamp electrodes to the state of its hot start;
d) hot start of the lamp and maintaining its stable glow;
d) cold start of the fluorescent lamp, if it is structurally made without filaments.

 The solution of these problems allows us to ensure the stable operation of nearby radio and television equipment, to ensure soft start and extend the life of the fluorescent lamp, to achieve high-quality lighting, as well as the ability to cold start and maintain a steady glow of lamps with unheated electrodes.

 In the proposed device for powering a fluorescent lamp containing a ballast choke with a first terminal for connecting a positive wire from a unipolar pulse source, connected by a second terminal to a terminal for connecting a first electrode of a lamp, a shunt diode connected by a negative terminal to the first terminal of the ballast reactor, and a positive terminal to terminal for connecting the second electrode of the lamp and connecting the negative wire of the unipolar pulse source, a starter connected to the terminals for connecting electric sorts of lamps, it is new that the starter consists of at least a transistor, a resistor and a communication element, while the base of the transistor is connected through the specified resistor to the first terminal of the ballast choke, the collector of the transistor through the specified communication element is connected to the terminal for connecting the first electrode of the lamp, and the emitter of the transistor is connected to the terminal for connecting the second electrode of the lamp.

The specified communication element may have several options for its implementation:
- the first option - the most preferable - is a parallel connected inductor and capacitor;
- the second option is a parallel-connected resistor and inductor;
- the third option is a parallel connected capacitor and resistor;
- the fourth option - the communication element is a resistor.

 In FIG. 1 shows a circuit diagram of the proposed device with three options for performing a communication element and one option for connecting a starter transistor for fluorescent lamps with heated electrodes; in FIG. 2 is a circuit diagram with a fourth embodiment of a communication element, a second and third connection options for a starter transistor, and an embodiment in which a fluorescent lamp is structurally constructed with unheated electrodes and is designed for cold start.

 The proposed device is option 1, option 2 and option 3 (Fig. 1), option 4, option 5 and option 6 (Fig. 2) are shown connected to the source of unipolar current pulses 7 through a two-wire line consisting of a positive wire 8 and a negative wire 9. Each variant is shown with a fluorescent lamp included, where in versions 1-5, the lamp 10 has heated electrodes (filaments) 11 and 12, and in option 6 a lamp 13 is shown with unheated electrodes 14 and 15. Ballast choke 16 with the first output 17 to connect the positive wire 8 included second m terminal 18 to the terminal for connecting the first electrode 11 or 14, respectively, of the lamp 10 or 13. To the first terminal 17, the shunt diode 19 is connected with the minus terminal, and with the positive terminal it is connected to terminal 20 for connecting the second electrode 12 or 15 of the lamp 10 or 13 and for negative cable connections 9.

 A starter is connected to the electrodes 11 and 12 of the lamp 10 or the electrodes 14 and 15 of the lamp 13, consisting of a transistor 21, a resistor 22, and a communication element having four possible options. In option 1 (Fig. 1), the coupling element consists of a parallel-connected inductor 23 and a capacitor 24; in option 2, the communication element consists of a parallel-connected resistor 25 and inductor 23; in option 3, the communication element consists of a parallel-connected resistor 25 and a capacitor 24; in option 4 (Fig. 2), the coupling element is a resistor 25.

 In all cases, the transistor 21 is connected by a collector to the first electrode 11 of the lamp 10 or the first electrode 14 of the lamp 13 through a communication element, by the emitter to the second electrode 12 of the lamp 10 or to the second electrode 15 of the lamp 13, and the base through a resistor 22 to the first terminal 17 of the ballast throttle 16.

 In embodiments 1-5, where a lamp 10 is used with heated electrodes 11 and 12, the lamp filaments are connected in series between the ballast choke 16 and the starter, as well as between the starter and terminal 20.

 In all cases, a protective diode 26 is connected between the base and the emitter of transistor 21. In option 5 (Fig. 2), the base and collector of transistor 21 are connected through a zener diode 27; in option 6, the base and collector of transistor 21 are connected through a zener diode 28 and a voltage divider, consisting of resistors 29 and 30, connected between the collector and emitter of transistor 21.

 A different number of lamps 10 and 13 with circuit elements assembled according to any of the proposed options can be connected to wires 8 and 9. On the terminals for connecting to the source 7, in each version of the circuit, a toggle switch 31 and a diode 32 are installed. The toggle switch 31 is designed to turn on the corresponding lamp 10 or 13, and the diode 32 is blocking, it does not allow the possibility of supplying voltage to the circuit elements if it is not maintained during installation desired polarity of connection to wires 8 and 9.

 The device operates as follows.

 The source of current pulses 7 must have a minimum voltage of 1.5 times higher than the burning voltage of the lamps 10 and 13, and the maximum voltage can exceed the minimum voltage several times, it is limited by the electric strength of the circuit elements.

 For ignition of any of the lamps 10 and 13, the corresponding toggle switch 31 is turned on. The pulse voltage is supplied to the first terminal 17 of the ballast inductor 16 and through the resistor 22 to the base of the transistor 21. At the same time, when the next pulse edge arrives at the first terminal 17 of the ballast inductor 16, the positive potential, the diode 19 is locked and the transistor 21 opens due to the arrival of this potential to the base through the resistor 22 and more smoothly increases the current in the ballast choke 16. During the pulse, the current passes through the circuit: wire 8, toggle switch 31, inductor 16, first electrode 11 (filament) of lamp 10, capacitor 24 (at the first moment) and inductor 23 (during the pulse), collector – emitter of transistor 21, second electrode (second filament) 12 , diode 32, wire 9, inductor 16 accumulates the electromagnetic energy of the field. The main energy of the current pulse in the form of heat is released on the electrodes 11 and 12 of the lamp 10, since they have the greatest active resistance of this circuit.

 At the moment of arrival of the trailing edge of the considered voltage pulse at the first output 17 of the inductor 16, the potential drops abruptly to zero, the diode 19 is unlocked, the voltage drops at the base of the transistor 21, the latter is locked for the duration of the interval between pulses, the stored energy in the inductor 23 is discharged to the capacitor 24, and the accumulated energy of the ballast inductor 16 causes a jump in the negative potential at its second output and a voltage pulse between the electrodes of the lamp.

 In options 1-5, the inductor 16 is selected so that it, smoothing the pulses by voltage, leaves them sufficient in magnitude to ignite the lamp 10 with heated electrodes 11 and 12 and far from sufficient for its cold ignition. While the lamp 10 is cold, current does not pass through it, the lamp does not glow. When the next pulse arrives, its energy is again spent on heating the electrodes of the lamp 10 and trying to light this lamp in the inter-pulse interval with the energy of the inductor 16.

 This will be repeated until the lamp 10 is heated to a state of hot start.

 After heating the lamp 10, its ignition voltage dropped to the pulse voltage level from the inductor 16, the interelectrode space of the lamp 10 becomes electrically conductive, the current closes by the circuit: first terminal 17, inductor 16, second terminal 18, first electrode 11, gas-discharge medium of the lamp 10, the second electrode 12, diode 19, the first output 17 of the inductor 16. When the next pulse arrives at the first output of the inductor 16, the diode 19 switches abruptly, the transistor 21 is unlocked, and the current after the ballast inductor branches out into a lamp 10 and into nzistor 21. However resistance lighted discharge lamp medium is many times lower than the resistance of the starter circuit (coupling element and a transistor) because the lamp 10 passes through current is many times greater than the current flowing through transistor 21.

 If at start-up, the pulse energy was spent mainly on heating the lamp 10, then after the start this energy is spent on the glow of the lamp 10. In the intervals between pulses, the inductor 16 gives off the stored pulse energy to the lamp glow along the above-described circuit, it also smoothes the ripple of the current of wires 8 and 9, limits the current to the operating value of the lamp 10. The starter, due to the connection of the base of the transistor 21 with the first output 17 of the ballast inductor 16 through the resistor 20, works in phase with the source of unipolar pulses 7, provides a preliminary heating of the electrodes 11 and 12 of the lamp 10 during ignition, and is also in standby (standby) mode during its glow. In the case of the extinction of the lamp 10, all the current from the pulse passes through the filament of the electrodes 11 and 12, heats up the lamp and restores its glow. For the lamp 13 with a cold start, the circuit elements according to the parameters are accordingly selected and adjusted.

 In option 1 of the circuit, a coupling element made of a capacitor and an inductor, from the standpoint of low energy consumption and quick response of the starter, is most preferable.

 In the second, third and fourth versions of the circuit, the communication elements are made using a resistor. This causes unproductive energy consumption, reducing the efficiency of the device.

 The second, third and fourth options are preferably used as spare (emergency) or only in lighting devices with low-power fluorescent lamps.

 In the first four variants of the circuit, the starter transistor 21 is turned on without breakdown protection between the base and the collector and in the event of a voltage jump to a level that exceeds the allowable for this type of transistor, the base-collector junction will break and the device will fail.

 To protect the transistor 21 between the base and the collector, a high-voltage zener diode 27 can be included as shown in embodiment 5 (FIG. 2).

 Due to the fact that the fifth option is designed to use a high-voltage stabilizer 27 with a fixed voltage, it cannot be used where adjustment of the threshold for its operation is required.

 In option 6, a zener diode 28 is connected between the base and the collector of transistor 21 through a voltage divider consisting of resistors 29 and 30. In this version of the circuit, it is possible to use any zener diode 28, but you must enter the circuit into the desired operating mode by selecting resistors 29 and 30. The last version of the circuit most preferred.

 In addition to protecting the transistor 21 from breakdown, the zener diodes 27 and 28 in the fifth and sixth versions limit the voltage on the lamps while they are in warm-up mode to prevent a cold start for lamps with heated electrodes.

 A prototype of this device for powering a fluorescent lamp was manufactured on the Donetsk Railway, and passed laboratory tests at the Dnipropetrovsk Technical University of Railway Transport. According to the conclusion of DTUZhT, the device in all respects satisfies the requirements of GOST 9219-88 (test report 1-24-95 of 02.28.95 on the topic: contract No. 24.31.94.95).

 At present, the device is undergoing trial operation at the Donetsk carriage depot.

Claims (5)

 1. Device for powering a fluorescent lamp, comprising a ballast choke with a first terminal for connecting a positive wire from a unipolar pulse source, connected by a second terminal to a terminal for connecting a first electrode of a lamp, a shunt diode connected by a negative terminal to the first terminal of the ballast reactor, and a positive terminal - to the terminal for connecting the second electrode of the lamp and to the terminal for connecting the negative wire from the source of unipolar pulses, a starter connected to the terminals for connecting e lamp electrodes, characterized in that the starter consists of a transistor, a resistor and a communication element, while the base of the transistor is connected through the specified resistor to the first terminal of the ballast choke, the collector of the transistor through the specified communication element is connected to the terminal for connecting the first electrode of the lamp, and the emitter of the transistor is connected to the output for connecting the second electrode of the lamp.  2. The device according to claim 1, characterized in that the coupling element of the starter is made of parallel connected capacitor and inductor.  3. The device according to claim 1, characterized in that the communication element of the starter is made of parallel-connected resistor and inductor.  4. The device according to claim 1, characterized in that the coupling element of the starter is made of a parallel-connected resistor and capacitor.  5. The device according to claim 1, characterized in that the coupling element of the starter is a resistor.

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