KR910002615B1 - Apparatus for discharge lamps - Google Patents

Abstract

Starter lights lamp by applying oscillator voltage to filament coils of lamp, while improving demerits of an stable lighting, large power consumption and heavy stabilizer in the old glow-type starting lamp. It also has improved another types of electronic fluorescent lamp in high cost, bigger size, long asscembly hour and etc. This method eliminates a protection cirlcuit by preventing transistor of generating heat. The starter comprises power supply (1), output voltage divider (2) for fluorescent lamp (FL) and filament (F2), oscillator (3), voltage amplifier (4) of oscillator voltage to eliminate heat generation at (TR1)(TR2) and triacs (TRI1)(TRI2) shorting two terminals of (F1) (F2).

Description

Electronic fluorescent starter

1 is a circuit diagram showing an electronic fluorescent starter of the present invention.

Figure 2 is a circuit diagram showing another embodiment of the filament control unit of the electronic fluorescent starter of the present invention.

3 is a circuit diagram when two fluorescent lamps are turned on by the electronic fluorescent lamp starter of the present invention.

* Explanation of symbols for main parts of the drawings

1: power supply unit 2: voltage division unit

3: oscillator 4: power amplifier

5: filament control unit FL, FL ₁ , FL ₂ : fluorescent lamp

TRI ₁ , TRI ₂ : triac DIA ₁ , DIA ₂ : diaac,

BD: Bridge Diode TR ₁ , TR ₂ : Transistor

FU: fuse R ₁ - _R 3: resistance

T ₁ , T ₂ : transformer C ₁ -C ₅ : condenser

D ₁ -D ₄ : Diodes F ₁ , F ₂ , F ₁₁ , F ₂₁ , F ₂₂ : Filament

RD ₁ -RD ₅ : Reed switch L: Coil

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic fluorescent lamp starter which applies an oscillation voltage of an oscillation unit to a filament of a fluorescent lamp to light it.

Conventionally, the glow starter which turns on a fluorescent lamp mainly using the glow discharge of a glow lamp was used. However, since the glow starter takes a lot of time due to the glow discharge of the glow lamp, the lighting speed of the fluorescent lamp is very slow, the lighting of the fluorescent lamp is unstable due to the step-down and rise of the input AC power, and the power consumption is high. There was a heavy weight defect.

In addition, a rapid starter has been developed to improve the lighting speed of the fluorescent lamp. However, while the rapid starter fluorescent lamp is turned on at the moment, the weight is very heavy and expensive, and it is rarely spread.

In order to improve the defects of the glow starter and the rapid starter, an electronic fluorescent starter using a semiconductor device has been recently developed and widely used.

The electronic fluorescent lamp starter preheats by applying a constant voltage to both filaments of the fluorescent lamp and applies an oscillating pressure of the oscillation part to the filament to turn on the fluorescent lamp.

However, the electronic fluorescent starters that have been developed and used in the past have instantaneous lighting of fluorescent lamps, are light in weight, but require many parts, which increases the production cost of the product, is large, and takes a lot of time to manufacture. When the AC power input is low, the lighting of the fluorescent lamp becomes unstable, and even after the fluorescent lamp is turned on, a constant voltage is continuously applied to the filament to consume a lot of power, and a lot of heat is generated in the transistor that performs the oscillation operation of the oscillator. Therefore, various defects, such as the need to provide a protection means according to the generation of heat, are contained.

Therefore, the main object of the present invention is to provide an electronic fluorescent starter having no defects as described above.

Another object of the present invention is to provide an electronic fluorescent starter which can reduce the number of parts required, reduce the production cost of the product, reduce the size and weight, and can be simply manufactured.

It is still another object of the present invention to provide an electronic fluorescent starter which amplifies the oscillation voltage of an oscillation part and applies it to a filament of a fluorescent lamp to prevent the generation of heat in a transistor, thereby preventing the generation of heat in the transistor, and stably lighting the fluorescent lamp without the protection means according to the generation of heat. It is.

It is still another object of the present invention to provide an electronic fluorescent starter which shortens the filament of the fluorescent lamp when the fluorescent lamp is turned on so that the fluorescent lamp is lit brighter.

In order to achieve the above object, the electronic fluorescent lamp starter of the present invention rectifies AC power applied to a power supply terminal to supply an operating voltage, and divides the operating voltage output from the power supply unit to provide an operating reference voltage to the filament of the fluorescent lamp. By applying a voltage dividing unit, an oscillation unit that is oscillated when an AC power is applied, a power amplifier that amplifies the oscillation voltage of the oscillation unit, and an oscillation voltage of the oscillation unit induced by a secondary coil of a transformer to a filament of a fluorescent lamp And a filament controller for shorting both terminals of the filament of the fluorescent lamp as the fluorescent lamp is turned on.

With the above configuration, the electronic fluorescent lamp starter of the present invention, when AC power is applied, the power supply rectifies and smoothes the AC power and supplies the operating voltage, and divides the operating voltage into the fluorescent filament after the voltage divider divides the voltage. The oscillator oscillates with AC power as the trigger voltage, and the power amplifier amplifies the oscillation dry pressure of the oscillator. As the fluorescent lamp is turned on, the filament controller short-circuits the filament of the fluorescent lamp to eliminate power consumption in the filament, and the fluorescent lamp is turned on very brightly.

Hereinafter, with reference to the accompanying drawings will be described in detail the electronic fluorescent starter of the present invention having the above object and configuration as follows.

FIG. 1 is a circuit diagram showing an electronic fluorescent starter of the present invention. As shown therein, a smoothing capacitor is connected to power terminals A and B to which an AC power source AC is applied through a fuse FU and a bridge diode BD. Condenser (C ₂ ) (C ₃ ) and diode (D ₁ ) (D ₂ ) connected to (C ₁ ) and resistor (R ₁ ) to form a power supply (1), and connected in parallel to the output terminal of the power supply (1). ) Was connected in series, and the connection point CON was connected to one terminal of the filament F ₂ of the fluorescent lamp FL to form a voltage dividing unit 2.

Then, the power supply terminal B is connected to the base of the resistor R ₂ and the transistor TR ₁ through the capacitor C ₄ and the dia A DIA ₁ , and the connection point is connected through the diode D ₃ . transistor emitter and transmitter (T ₁₎ the primary coil (T ₁₁₎ to the secondary coil (T ₁₂₎ of configuring the oscillation unit 3 and transformer (T ₁₎ connected to the (TR ₁₎ is the resistance (R ₃₎ a via connected to the base of the transistor (TR _2), configuring the emitter of the power amplifier connected to a collector of said transistor (TR ₁₎ portion (4) of the transistor (TR _2), and the secondary coil of the transformer (T ₁₎ (T ₁₃₎ is a fluorescent lamp (FL) filament (F ₁₎ the filament (F ₂₎ the other terminal of the filament (F ₁₎ coupled to one terminal through a capacitor (C ₅₎ of the through the coil (L) the other While connecting to the terminal, connect the secondary coil (T ₃ ) to the gate of the triac (TRI ₁ ) (TRI ₂ ) through the resistor (R ₄ ) and the diaak (DIA ₂ ), and the triac (TRI ₁ ) (TRI both electrodes of ₂₎ Connected to both terminals of the filament (F ₁₎ (F ₂₎ formed the filament control unit 5.

Referring to the operation and effect of the present invention configured as described above in detail.

When the AC power source AC is applied to the power supply terminals A and B, the AC power source AC is rectified through the fuse FU of the power source unit 1 and bridged via the bridge diode BD. After smoothing to DC voltage by C ₁ ), the operation suppression is applied to the oscillation section 3 and the power heavy section 4, while also charging the capacitors C ₂ and C ₃ of the voltage division section 2 while being divided. The applied voltage is applied to the filament F ₂ of the fluorescent lamp FL.

The AC power source AC of the power supply terminal B is applied as an oscillation start voltage to the base of the transistor TR ₁ through the capacitor C ₄ and the diaak DIA ₁ of the oscillation unit 3, so that the transistor TR ₁ ) The oscillation unit 3 oscillates while repeating the on and off, and the oscillation voltage generated in the primary comil T ₁₁ of the transformer T ₁ in accordance with the oscillation of the oscillation unit 3 is generated by the power amplification unit 4. The secondary coil T ₁₂ of the transformer T ₁ is applied to the base of the transistor TR ₂ through the resistor R ₃ , so that the transistor TR ₂ is repeatedly turned on and off while the transistor TR ₁ is turned on. By increasing the collector current, the oscillation voltage of the oscillator 3 is amplified.

In addition, the oscillation voltage induced by the secondary comil T ₁₃ of the transformer T ₁ in accordance with the oscillation of the oscillation part 3 is applied to the fluorescent lamp FL through the coil L, and the fluorescent lamp FL is turned on. The oscillation voltage of the secondary coil T ₁₃ is applied to the gate of the triac TRI ₁ (TRI ₂ ) through the resistor R ₄ and the diaak DIA ₂ of the filament controller 5 so that it is turned on and turned on. amount filament (F ₁₎ (F ₂₎ of the fluorescent lamp (FL) is a triac (tRI ₁₎ (tRI _2), so a short-circuit condition according to the conduction is not the warm-up voltage to the filament (F ₁₎ (F ₂₎ applied to the As a result, power consumption is reduced, and the voltages applied to the filaments F ₁ and F ₂ are all used to turn on the fluorescent lamp FL so that the fluorescent lamp FL is very brightly lit.

In addition, since the transformer (T ₁ ) to rotate the core to vary the inductance, the error of the primary coil (T ₁₁ ) and secondary coils (T ₁₂ , T ₁₃ ) of the transformer (T ₁ ) can be easily adjusted.

FIG. 2 is a circuit diagram showing a multi-tone embodiment of the filament controller used in the electronic fluorescent starter of the present invention. As shown in FIG. ₂ , the reed switch RD is connected to both filaments F ₁ and F ₂ of the fluorescent lamp FL. ₁ ), (RD ₂ ) are connected respectively, and the reed switch RD ₁ (RD ₂ ) is installed adjacent to the coil L, and the reed switch RD ₁ (RD ₂ ) is connected to the magnetic lines of the coil L. Caused a short circuit.

The voltage of the connection point CON of the present invention voltage division unit 2 is applied to the filament F ₂ , and the voltage induced by the secondary coil T ₁₃ of the transformer T ₁ is applied to the coil L. When applied to the filament (F ₁ ), the fluorescent lamp (FL) is turned on, and as the voltage induced by the secondary coil (T ₁₃ ) passes through the coil (L), a magnetic force line is generated in the coil (L) and the magnetic line Since both contacts of the reed switch RD ₁ (RD ₂ ) are short-circuited, the filament F ₁ (F ₂ ) of the lit fluorescent lamp FL is shorted through the reed switch RD ₁ (RD ₂ ), and the filament Since preheating voltage is not applied to (F ₁ ) (F ₂ ), power consumption is reduced, and all of the voltages applied to the filament (F ₁ ) (F ₂ ) are used to turn on the fluorescent lamp (FL) so that the fluorescent lamp (FL) It lights up very brightly.

3 is a circuit diagram of connecting two fluorescent lamps with the electronic fluorescent lamp starter of the present invention and lighting them. As shown therein, the secondary coil T ₁₃ of the transformer T ₁ is converted into a primary coil (T ₂ ). T ₂₁ ) is connected to one terminal of the filament F ₁₁ of the fluorescent lamp FL ₁ , and the connection point CON of the voltage dividing unit 2 is connected to one terminal of the filament F ₂₁ of the fluorescent lamp FL ₂ . The capacitor C ₆ is connected between the other terminals of the filament F ₁₁ and F ₂₁ , and the secondary coil T ₂₂ of the transformer T ₂ is connected to the filament of the fluorescent lamp FL ₁ (FL ₂ ). F ₁₂₎ (F ₂₂₎ commonly connected to the other hand, the filaments _{(F 11) (F 21)} (F 12, F 22) connected in parallel to the reed switch _{(RD 3) (RD 4)} (RD 5) in the, and that a reed switch (RD _3, RD ₅₎ the transformer (T ₂₎ transformer (T ₂₎ the lines of magnetic force of a lead switch (RD ₃ -RD ₅₎ of the installation to be adjacent to the short-circuit was allowed.

In the present invention as described above, the voltage of the connection point CON divided by the voltage dividing unit 2 is applied to the filament F ₂₁ of the fluorescent lamp FL ₂ , and induced to the secondary coil T ₁₃ of the transformer T ₁ . the primary coil of the voltage transformer (T ₂₎ the primary coil as soon applied to the filament (F ₁₁₎ through (T ₂₁₎ as well as trans (T ₁₎ the primary coil (T ₁₃₎ is trans (T ₂₎ the voltage of the ( in T ₂₁₎ it is induced to the secondary coil (T ₂₂₎ so applied to the filament (F ₁₂₎ (F ₂₂₎ of the fluorescent lamp (FL ₁₎ (FL ₂₎ fluorescent lamp (FL ₁₎ (FL ₂₎ is lit, and trans the filaments of the fluorescent lamp (FL ₁₎ (FL ₂₎ lights up, so the magnetic lines of force generated from (T ₂₎ contact the short circuit of the reed switch (RD ₃ -RD ₅₎ as applied to the reed switch (RD ₃ -RD ₅₎ ( F ₁₁ ) (F ₂₁ ) (F ₁₂ , F ₂₂ ) are short-circuited through the reed switch RD ₃ (RD ₄ ) (RD ₅ ).

As described in detail above, the present invention amplifies the oscillation voltage of the oscillation part so that the fluorescent lamp is turned on, so that no heat is generated in the transistor, and thus, there is no need to provide other protection means to generate heat, and the lighting of the fluorescent lamp is stable. When the fluorescent lamp is turned on, shortening of the filament of the fluorescent lamp reduces unnecessary power consumption, and all the voltages applied to the filament are used to turn on the fluorescent lamp so that the fluorescent lamp is very brightly lit and the number of parts used is small, which reduces the production cost of the product. It saves, reduces size and weight, and has a simple manufacturing effect.

Claims (3)

In the electronic fluorescent starter which applies the oscillation voltage of the oscillation part 3 to the fluorescent lamp FL filament F ₁ through the coil L, and turns on the fluorescent lamp FL, the output voltage of the power supply part 1 is divided | segmented and the fluorescent lamp is carried out. A voltage division part 2 applied to the filament F ₂ of FL and an oscillation part induced from the primary coil T ₁₁ of the transformer T ₁ of the oscillation part 3 to the secondary coil T ₁₂ ( As the power amplifier 4 amplifies the oscillation voltage of 3) and the fluorescent lamp FL is turned on, it is brought into a conducting state, and both terminals of the filament F ₁ (F ₂ ) of the fluorescent lamp FL are shorted. Electronic fluorescent starter characterized by consisting of triac (TRI ₁ ) (TRI ₂ ) to make. In the electronic fluorescent starter which applies the oscillation voltage of the oscillation part 3 to the filament F ₁ of the fluorescent lamp FL through the coil L, and turns on the fluorescent lamp FL, the output voltage of the power supply part 1 is made into fluorescent lamp ( The voltage division part 2 applied to the filament F ₁ of FL and the oscillation part 3 induced from the primary coil T ₁₁ of the transformer T ₁ of the oscillation part 3 to the secondary coil T ₁₂ . ), power amplifier (4) for amplifying the oscillating voltage, the filament (F ₁₎ (F ₂₎ of the fluorescent lamp (FL) is connected in parallel are connected in accordance with the lines of magnetic force of the coil (L) the filaments (F ₁ An electronic fluorescent starter characterized by comprising a reed switch (RD ₁ ) (RD ₂ ) which makes both terminals of (F ₂ ) short circuited. The method of claim 2, wherein the secondary komil (T ₁₃₎ of the transformer (T ₁₎ is coupled to one terminal of the filament (F ₁₁₎ of the fluorescent lamp (FL ₁₎ via the primary coils (T ₂₁₎ of the transformer (T ₂₎ and The connection point CON of the voltage dividing part 2 is connected to one terminal of the filament FL ₂₁ of the fluorescent lamp FL ₂ to connect the capacitor C ₆ between the other terminals of the filament FL ₁₁ and FL ₂₁ . connection and the secondary coils (T ₂₂₎ is a fluorescent lamp (FL ₁₎ filaments (FL ₁₂₎ (FL ₂₂₎ commonly connected to the two fluorescent lamps (FL _1, FL ₂₎ in the (FL ₂₎ of the transformer (T ₂₎ the Electronic fluorescent starter, characterized in that configured to turn on.

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