KR0133918Y1 - Ballast for fluorescnet lamps - Google Patents

Abstract

The present invention relates to a ballast for a fluorescent lamp that can increase the life of the lamp and improve the efficiency of the ballast by facilitating the lighting even at low voltage by instantaneously increasing the starting voltage when the fluorescent lamp is turned on, the AC power supply (AC) Through the primary coil T _{1 of the} transformer T and the heater coil H ₁ of the fluorescent lamp L and the secondary coil T ₂ of the transformer T, the capacitor C and the fluorescent lamp L In constructing a ballast B connected in series between the heater coils H ₂ , a bidirectional trigger diode S is connected in series between the secondary coil T ₂ of the transformer T and the capacitor C. It is a ballast for a fluorescent lamp characterized in that the SLC resonant circuit is configured.

Description

Ballasts for Fluorescent Lamps

1 to 2 are explanatory views of a conventional starter type ballast and an LC resonant circuit.

(A) and (b) of FIG. 3 are circuit diagrams for explaining the present invention.

* Explanation of symbols for main parts of the drawings

L: Fluorescent B: Ballast

C: condenser T: transformer

T ₁ : Primary coil T ₂ : Secondary coil

H ₁ : heater coil H ₂ : heater coil

S: Bidirectional Trigger Diode (Sidac)

The present invention relates to a ballast for fluorescent lamps, and more specifically, to increase the starting voltage when the fluorescent lamp is turned on instantaneously to facilitate the lighting even at low voltage and low temperature conditions can improve the life of the lamp and improve the efficiency of the ballast. It is.

In general, in the conventional ballast, as shown in FIG. 1, when the AC power source AC is applied, argon glow discharges while current flows through both electrodes of the glow starter GS composed of bimetal, and at this time, the argon glow discharge When the movable electrode and the fixed electrode are contacted by the heat generated by the preheating current flows through both cathodes of the fluorescent lamp (L), the movable electrode is cooled and falls from the fixed electrode while being lit. ) Inductance voltage is generated to start the fluorescent lamp (L).

However, such a starter ballast has a problem such as wasting unnecessary power since the glow starter GS blinks for about 7 seconds when turned on and has a very late turn-on time.

In addition, in FIG. 2, the AC power source AC is connected to one coil T ₁ of the transformer T and the heater coils H ₁ (H ₂ ) of the fluorescent lamp L and the secondary coil T of the transformer T. ₂ ) It is configured by connecting in series between the condenser (C) and the heater coil (H ₁ ) (H ₂ ) of the fluorescent lamp (L), when the AC power is applied, the current is the primary coil of the transformer (T) ( T ₁₎ and by the reactor of the fluorescent lamp (L) the heater coil (H _{1) (1} primary winding (T ₁₎ and a condenser (C) a sufficient voltage is formed, and transport (T) at the same time as the heating in H ₂₎ of the The LC resonant circuit is configured to generate a high secondary voltage at the heater coils (H ₁ ) and (H ₂ ) at both ends of the fluorescent lamp (L). It turns on while the peak voltage is applied to the organic secondary voltage by the reactor of the secondary coil T ₂ and the capacitor C.

However, such a ballast is not lighted well at low voltage, it does not light up even at low temperature, the heat generation state of the mechanism itself is high, and the starting voltage is high, which causes blackening of the lamp. Many problems, such as shortening the life of the.

Therefore, the present invention was devised to solve all the problems of the conventional ballast. The bidirectional trigger diode S is connected in series between the secondary coil T ₂ of the trigger diode S and the capacitor C. The purpose of this invention is to provide a ballast for a fluorescent lamp which is configured to facilitate the lighting without a glow starter lamp even in low voltage and low temperature conditions, and to prolong the life of the fluorescent lamp.

In order to achieve this purpose, a bidirectional trigger diode (S) is connected in series between the heater coil (H ₂ ) and the condenser (C) to generate a momentary lighting trigger on the bidirectional trigger diode (S) when AC power is applied. It can be easily turned on even under low voltage and low temperature.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

3 is a circuit diagram of the ballast of the present invention, (a) is a state applied to a compact fluorescent lamp (bulb lamp fixture), (b) is a circuit diagram of a state applied to a linear fluorescent lamp.

AC power source AC passes through primary coil T ₁ of transformer T, heater coil H ₁ of fluorescent lamp L, and secondary coil T ₂ of trigger diode S. Bidirectional trigger between the secondary coil (T ₂ ) and the condenser (C) of the transformer (T) in constructing a ballast (B) in series between the heater coil (H ₂ ) of the fluorescent lamp (L) and Ballast for a fluorescent lamp characterized in that the SLC resonant circuit is configured by connecting the diode (S) in series.

When AC power is applied to the fluorescent lamp ballast of the present invention connected as described above, the current is transferred through the primary coil T ₁ of the transformer T and the heater coil H ₁ of the fluorescent lamp L. A sufficient voltage is formed by flowing to the secondary coil T ₂ , the condenser C, and the bidirectional trigger diode S and the heater coil H ₂ .

Therefore, since the SLC resonant circuit is composed of the primary coil T ₁ of the transformer T, the capacitor C, and the bidirectional trigger diode S, the heater coil H ₁ (H ₂ ) of the fluorescent lamp L is formed. At the same time as the heat is generated, a high voltage is formed, and a resonance state is caused by the reactor of the primary coil T ₁ of the transformer T and the capacitor C and the bidirectional trigger diode S, so that the heater coils at both ends of the fluorescent lamp L Higher secondary voltages are generated between H ₁ ) and H ₂ .

When cathode heating proceeds due to this phenomenon, the organic secondary voltage by the secondary coil T ₂ of the transformer T and the reactor of the capacitor C and the bidirectional trigger diode S is 0.5 due to the higher peak voltage. The lighting starts at -1 second.

After the start of the lighting as described above, the contact pressure is formed and the power factor is improved by the SLC phenomenon of the bidirectional trigger diode, the coil, and the condenser. As a result, a high power factor is formed. The voltage is kept reduced to prevent unnecessary power waste.

As described above, according to the fluorescent lamp ballast of the present invention, when the AC power (AC) is applied by connecting the bidirectional trigger diode (S) in series between the heater coil and the condenser, the instantaneous lighting is turned on in the bidirectional trigger diode (S). It is a very useful design that has the effect of extending the life of the fluorescent lamp and improving the efficiency of the ballast by generating a trigger to easily turn on even at low voltage and low temperature.

Claims (1)

AC power source (AC) the transport (T) of the primary winding (T ₁₎ and the heater coils of the fluorescent lamp (L) (H ₁₎ and trans capacitor (C) via the secondary winding (T ₂₎ of the (T) and In the ballast constructed by connecting in series between the heater coil (H ₂ ) of the fluorescent lamp (L), the bidirectional trigger diode (S) between the secondary coil (T ₂ ) and the condenser (C) of the transformer (T). Ballast for fluorescent lamps characterized in that it comprises an SLC resonant circuit connected in series.