KR0167178B1 - Discharge lamp for electronic ballast of preheating start circuit - Google Patents

Abstract

The present invention relates to a technique for driving an electronic ballast in a stable preheating method. In the preheating start circuit of a general electronic ballast, when the input AC voltage is changed, the preheating voltage for preheating the filament of the lamp is changed, thereby blackening the lamp. The phenomenon occurs, the conduction voltage is supplied to the base side of the transistor for switching transistor through the start resistance, there is a defect such as overheating when a high voltage is applied, the present invention to solve this problem, the rectification and By using the preheating starter 13 which receives the induced voltage from the booster inductor driven by the output voltage of the smoothing unit 12 and outputs the voltage for the preheating winding of the lamp, and the output voltage of the rectifying and smoothing unit 12. The main switching unit 15 for driving the main transformer T13 and the main switching unit 15 in the initial driving state are fine. After switching the operation to a main switch control unit (16) for normally driving a predetermined time elapses when implemented a pre-heating start-up circuit of the discharge lamp electronic ballast.

Description

Preheating start circuit of electronic ballast for discharge lamp

1 is a circuit diagram of a general electronic ballast for discharge lamps.

2 is a preheating start-up circuit diagram of the electronic ballast for the discharge lamp of the present invention.

* Explanation of symbols for main parts of the drawings

11: input power stabilization part 12: rectification and smoothing part

13: preheating start 14: power factor improvement

14A: power factor improvement control device 15: main switching unit

16: main switching control unit 17: lamp driving unit

The present invention relates to a technique for driving the electronic ballast in a stable preheating method, and in particular, to ensure that the high voltage required for lighting the fluorescent lamp is supplied by a separate transformer, and to reduce the blackening phenomenon due to the high voltage during the initial lighting of the lamp The present invention relates to a preheating start-up circuit of an electronic ballast for a discharge lamp suitable for lighting a lamp after preheating the lamp.

Recently, the lighting field occupies a very important position in terms of energy saving. In particular, an electronic ballast for discharge lamps having high energy saving efficiency, color rendering properties, and excellent energy saving effect is required. However, due to the characteristics of the discharge lamp, a high voltage is required and the fluorescent lamp is generally impaired at the time of initial lighting, thereby causing blackening, resulting in a decrease in color rendering and shortening the lifespan.

1 is a circuit diagram of a general electronic ballast for a discharge lamp, as shown in the input power stabilization unit (1) for stabilizing the power source by removing the noise components included in the input AC power supply, and the input power stabilization unit (1) A bridge diode (BD) and a capacitor (C4) for rectifying and smoothing the output AC voltage, a main switching unit (2) for high frequency switching of the primary coil of the main transformer (T4) by receiving the smoothed voltage; It consists of a lamp driver 3 for lighting and preheating the lamps LAMP1 and LAMP2 using the voltage induced in the secondary coil of the main transformer T4. Same as

When the input AC power is supplied through the power input terminals (H) and (N), it is through the surge voltage protection element (ZNR) and then through the capacitor (C1) and the line filter (T1) connected in parallel again. The electromagnetic wave generated inside the ballast is cut off, and the input power from which the noise component is removed is charged by the smoothing capacitor (C2), and the charging voltage is full-wave rectified through the bridge diode (BD), and then the capacitor ( Smoothed by C4).

At the initial start-up, the rectified smoothed voltage is supplied on the one hand to the middle tap t2 of the main transformer T via the DC choke coil T3 and at the same time switching via the start resistor R1 on the other hand. It is supplied to the base side of transistor Q1 and it is turned on. As a result, the current flows from the DC choke coil T3 to the tap t2 t3 → transistor Q1 → power supply terminal Vcc− of the main transformer T4.

After all of the current charged in the main transformer T4 has flowed after the transistor Q1 is turned on, that is, when the voltage of the main transformer T4 reaches the peak (saturation) of the hysteresis curve, the main transformer T4 Voltage At this time, the potentials of the taps t4 and t5 of the primary coil of the main transformer T4 are reversed to supply a higher voltage to the base of the transistor Q2, whereby the transistor Q2 Is turned on. Accordingly, the current flows through the path of the DC choke coil T3 → tap t2 → t3 → transistor Q2 → power supply terminal Vcc− of the main transformer T4.

In this state, the DC choke coil T3 was used on the base side of the transistors Q1 and Q2 to supply sufficient turn-on voltages to the transistors Q1 and Q2. At this time, resonant frequency Since the turn-on and turn-off periods of the transistors Q1 and Q2 are determined by the resonant frequency, high frequency switching is possible.

On the other hand, a current flows in the primary coil of the main transformer T4 by the switching action as described above, whereby a high voltage is induced in the secondary coil of the main transformer T4, and thus, lamps LAMP1 and LAMP2. At this time, a predetermined voltage (about 3 to 4 V) is induced in the preheating windings t8 to t9 and t10 ↔ t11 provided on the secondary side to preheat the filaments of the lamps LAMP1 and LAMP2. Once the lamps LAMP1 and LAMP2 are turned on, the current flowing through the lamps LAMP1 and LAMP2 is limited by the capacitors C6 and C7, so that the brightness of the light can be kept constant. Will be.

However, in the preheating start circuit of the general electronic ballast, when the input AC voltage is changed, the preheating voltage for preheating the filament of the lamp is fluctuated so that blackening of the lamp occurs, thereby shortening the lamp life. In addition, since the conduction voltage is supplied to the base side of the trans switching transistor through the start resistor, there is a possibility of overheating when high voltage is applied, and the switching transistor is easily burned out in the place where the lighting is frequent.

Accordingly, an object of the present invention is to provide a preheating start circuit of an electronic ballast for a discharge lamp that preheats the lamp during initial lighting to softly light the lamp at a lower voltage and eliminates straying of light due to high frequency switching.

2 is a preheating start-up circuit diagram of the electronic ballast for the discharge lamp of the present invention to achieve the above object, as shown in this, by using the EM filter and line filter to remove the noise components contained in the input AC power supply to stabilize the power supply Driven by the input power stabilization unit 11, the rectification and smoothing unit 12 for rectifying and smoothing the AC voltage output from the input power stabilizing unit 11, and the output voltage of the rectifying and smoothing unit 12. The preheater 13 receives the induced voltage from the booster inductor and outputs the preheating voltage of the lamp, and detects the output voltage of the rectifying and smoothing unit 12 and the voltage and current supplied to the main transformer T13. And a power factor improving unit 14 for supplying a constant voltage to the output terminal regardless of the input voltage by controlling the width of the pulse width modulated signal according to the detected voltage and current, and the rectification. And a main switching unit 15 for driving the main transformer T13 using the output voltage of the smoothing unit 12 and a base of the switching transistor of the main switching unit 15 for a predetermined time in an initial driving state. The main switching control unit 16 to control the voltage to be switched to a fine operation and then drive normally, and receives a preheating voltage output from the preheating starter 13 during initial driving and discharge lamp LAMP11, ( After the LAMP12 is preheated, the lamp driving unit 17 operates normally by using the voltage induced from the main transformer T13. The operation and effect of the present invention configured as described above will be described in detail.

When the input AC power is supplied through the power input terminals (H) and (N), the noise components are removed through the varistor (Z11), and then the EMI filter (T11) and the line filter (L11), which are arranged in a double structure again, ( The noise component in the normal mode and the electromagnetic wave generated inside the ballast are blocked by L12), and the input power source from which the noise component is removed is full-wave rectified through the bridge diode BD11 and then smoothed by the capacitor C14.

The power factor improving control element 14A of the power factor improving unit 14 receives the multiplier input through the resistor R12 and the input pin P3 and the feedback voltage through the resistors R22 and R23 and the input pin P1. The sensing current is supplied through the MOS transistor M11, the resistor R17 and the input pin P4, and the zero crossing current is supplied through the input pin P5, and based on the output pin P7, respectively. By adjusting the pulse width of the pulse width modulation signal supplied to the gate of the MOS transistor M11, the voltage at the output terminal can be kept constant regardless of the input voltage.

The output voltage of the rectified smoothed capacitor C14 is charged to the capacitor C11 through the diode D16. In the initial startup state, the charging voltage is supplied on the one hand to the middle tap t2 of the main transformer T13 through the DC choke coil L13 and on the other hand to the base of the transistor Q11 through the resistor R25. Is supplied to and he is turned on. At this time, the current flows from the path of the DC choke coil L13 to the tap t2 t1 to the transistor Q11 to the ground terminal GND of the main transformer T13.

After all of the current charged in the main transformer T13 flows after the transistor Q11 is turned on, that is, when the voltage of the main transformer T13 reaches the peak of the hysteresis curve, the main transformer T13 is instantaneously turned on. Reverse electromotive force is generated, and the reverse electromotive force inverts the potentials of the taps t4 and t5 of the primary coil of the main transformer T13 to supply a higher voltage to the base of the transistor Q12. Q12 is turned on while transistor Q11 is turned off. Thus, at this time, the current flows in the path from the DC choke coil L13 to the tap t2 t3 of the main transformer T13 t transistor Q12 t earth terminal GND.

As described above, initial switching is performed for a predetermined time, and time constants of the resistor R25 and the capacitor C23 of the main switching controller 16 are performed. Since the operation of the switching transistors Q11 and Q12 is stabilized from the time when the zener voltage or more of the zener diode ZD11 is supplied later, more reliable resonance operation is performed.

As described above, by adjusting the voltage supplied to the switching transistors Q11 and Q12 during the initial driving, the burnout of the transistors Q11 and Q12 can be prevented, and the reverse voltage is applied to the transistors Q11 and (during the switching operation. In order to prevent supply to Q12) and burning out, prefilling diodes D17 and D18 were added, respectively.

On the other hand, the induced voltage of the preheating winding used as the secondary coil of the booster inductor T12 during the initial lighting is applied to each of the lamps LAMP11, t6, t7, t8, t9, and t10, t11. The lamps LAMP11 and LAMP12 are preheated by being supplied to the preheating power supply terminals a, a ', (b, b') and (c, c ') of the LAMP, and the main switching controller 16 is preheated. When the preset preheating time ends, the high voltage induced through the secondary coil of the main transformer T13 is supplied to the lamps LAMP11 and LAMP, respectively, and is normally driven from this time. By C24 and C25, the current supplied to the lamps LAMP11 and LAMP12 is kept constant so that the brightness of the light can be kept constant.

For reference, in supplying the preheating voltages of the lamps LAMP11 and LAMP12, by using a booster inductor T12 having a separate rectified and smoothed voltage as a driving voltage without using a main transformer as in the prior art. Stable preheating operation is possible regardless of the variation of the input AC voltage.

As described in detail above, the present invention has an effect of preventing the blackening of the lamp and prolonging its life by supplying the preheating voltage of the lamp more stably by using a booster inductor. By adjusting the voltage supplied to the switching transistor, it is possible to light at a low voltage and to prevent overheating by a high voltage.

Claims (1)

An input power stabilizing unit 11 and a rectifying and smoothing unit 12 for receiving an input AC power and converting the pure DC voltage to a desired level; A main switching unit 15 for driving the main transformer T13 by switching the DC voltage; In the electronic ballast for a discharge lamp composed of a lamp driver 17 for lighting a lamp (LAMP11), (LAMP) by receiving a voltage induced from the main transformer (T13) by the main switching unit 15, the rectification and smoothing A preheating starter 13 which receives an organic voltage from the booster inductor T12 driven by the output voltage of the unit 12 and supplies a preheating voltage to the lamps LAMP11 and LAMP12 for a predetermined time; The driving voltage is supplied from the booster inductor T12, the output voltage of the rectifying and smoothing unit 12 and the voltage and current supplied to the main transformer T13 are detected, and a pulse width modulation signal is detected according to the detected voltage and current. A power factor improving unit 14 for supplying a constant DC voltage to the main switching unit 15 regardless of the variation of the input alternating voltage by controlling the width of? In order to prevent the low voltage lighting and overheating due to the high voltage, during the initial driving, the main switch is controlled to control the voltage supplied to the base of the switching transistor of the main switching unit 15 for a predetermined period of time, so that the main switch is operated in a fine operation. A preheating start-up circuit of an electronic ballast for discharge lamps, comprising a switching control unit (16).