KR860000026B1 - Lighting device of fluorescent lamp - Google Patents

Abstract

A fluorescent lamp starter adapts a high-frequency switching regulator to get high-intensity illumination and reduce the flicker phenomenon. The starter comprises a selfexciting oscillator inserted in an inductor(T1), a protecting circuit for the oscillator placed on taps(2,4) of the transformer(T2), and an inductor(T3) which is connected inseries to coil(L1) of the transformer. The winding of the transformer(T2) is wound in series and formed for collector(L0) and step-up coil(L1).

Description

Fluorescent lamp lighting device

1 is an overall configuration diagram of the present invention.

2 is a fluorescent lamp lighting circuit using a known push-pull transistor inverter circuit.

3 is a waveform diagram, and FIG. 3 (a) is a waveform diagram of a fluorescent lamp output current.

FIG. 3 (b) is a waveform diagram showing the current waveform of each transistor collector.

3 (c) is a waveform diagram showing voltage waveforms at both ends of a high frequency parallel resonance Lo Co tank circuit.

3D is a waveform diagram showing voltage waveforms across the bases of the transistors TR ₁ and TR ₂ .

4 is an iron core (core) hysteresis characteristic of a trans.

5 is an equivalent circuit diagram of a constant current power supply viewed from the output side of the fluorescent lamp lighting circuit of the present invention.

The present invention relates to a fluorescent lamp lighting device in the prior art, but many related to the fluorescent lamp lighting device, but the use of choke coil type ballast has a lot of closures such as poor lighting and power consumption due to the decrease and rise of the power supply voltage and recently improved The electronic lighting device has shortened the lighting time and improved the on-start state, but the illuminance, which is the basic element of fluorescent light dimming, is remarkably lowered from the regulated power supply voltage. Therefore, the standard illuminance cannot be satisfied. It has the disadvantage of increasing power loss.

The present invention is to provide a lighting device containing a number of advantages, such as reducing the above drawbacks in the conventional fluorescent lamp lighting device, while reducing power consumption, remarkable improvement of power factor, improvement of illuminance, instantaneous lighting, etc. When described in detail as follows.

As shown in FIG. 1, the AC power is rectified by a known rectifier circuit to make a DC power, and the terminal 1 of the inductor T ₁ and one of the resistors R ₃ are connected to the B + pole of the DC power. Inductor (T ₁₎ terminal # 2 transformer (T ₂₎ connected to the center terminal 3 of the coil (Lo) and trans (T ₂₎ the coil (Lo) each of the transistors across the terminal 2, No. 4 (TR _1, of the TR ₂ ) are connected in parallel to both ends of the collector and capacitor (Co).

Connected to a terminal # 1 of the transformer (T ₂₎ terminal 1, once the inductor (T ₃₎ and the cathode terminal is connected to a first one of the inductors (T ₃₎ terminals # 2 fluorescent lamp (FL1) of. In the case of one fluorescent lamp, the cathode terminal 2 of the fluorescent lamp FL1 is connected to the terminal 4 of one end of the coil Lo of the transformer T ₂ via a switch SW ₁ , and two or more fluorescent lamps are n. In this case, the transformer is connected in series to the cathode terminal 2 of the fluorescent lamp FL1 without the switch SW ₂ interposed therebetween, and the transformer SW ₂ is connected to the cathode terminal 2 of the last fluorescent lamp FL2 connected in series. Terminal 5 of (T ₂ ) is connected. The B-pole of the DC power supply is connected to the emitters of the transistors TR ₁ and TR ₂ and the anode of the diode ZD ₁ , respectively.

Resistance (R ₃₎ the other is trans to both ends of the diode cathode and the bias resistor (R _1, R ₂₎ connected in parallel to the serial connection point (6) of the bias resistor (R _1, R ₂₎ of the (ZD ₁₎ of The coil LF of T ₂ and the bases of the transistors TR ₁ and TR ₂ are respectively connected. The overall circuit of the present invention includes the functions of an input current limiting and protection circuit, a collector tuned self-oscillating oscillation circuit, a high frequency parallel resonant circuit, a boost and an output current limiting circuit.

That is, when DC power is supplied to the B + pole terminal and the B-pole terminal in FIG. 1, the B + voltage passes through the transistors TR ₁ , R ₂ , R ₃ through the bias resistors R ₁ , R ₂ , and R ₃ for start-up of the push-pull transistor inverter circuit. The forward bias voltage is applied to the base of TR ₂ ), while the B + voltage is applied to the collectors of transistors TR ₁ and TR ₂ via the collector coil Lo of the inductor T ₁ and the transformer T ₂ . The B-voltage is applied to the push-pull inverter to cause high frequency oscillation. Here, the inductor T ₁ restricts the inflow of input overcurrent from the input power supply to the transistor of the push-pull inverter according to the overcurrent of the load generated when the fluorescent lamp as a load starts to discharge. To protect them from destruction.

Therefore, the inductor T ₁ serves as a constant current source for the entire push-pull inverter circuit, and also serves as a high frequency choke coil which prevents high frequency frequencies oscillating from the inverter from flowing back to the input power source and causing high frequency interference to the outside. The diodes ZD ₁ connected to the resistors R ₁ and R ₂ and their series connection points 6 not only supply a stable bias voltage to the base of the push-pull inverter transistors TR ₁ and TR ₂ but also provide stable high frequency oscillation of the inverter. It will play a role.

The inverter circuit composed mainly of the transistors TR ₁ and TR ₂ and the transformer T ₂ of the collector tuned self-oscillating arc causes high frequency oscillation, and the high frequency oscillation voltage is the collector of the transistors TR ₁ and TR ₂ . The inductance of the coil Lo of the transformer T ₂ connected to the parallel resonance of the capacitor Co is parallel resonance in the Lo Co tank circuit. As shown in FIG. In order to improve the crest factor of the fluorescent lamp current, which is an essential condition for the life, and to use this tank circuit as a high-frequency voltage power source and to obtain the discharge start voltage of the fluorescent lamp, both ends of the coil Lo of the transformer T ₂ (2, The coil L ₁ and L ₂ are connected on the extension line of 4) to form a boosting circuit, and the number of required fluorescent lamps can be discharged.

In particular, in the conventional fluorescent circuit lighting inverter circuit, as shown in FIG. 2, the output side of the inverter circuit is an LC series resonant system, whereas the present invention shows an inverter circuit output side as shown in FIGS. LC parallel resonant method is applied.

식으로 나타나게 되어 이때 저항 R는 탱크코일(Lo)의 순수저항성분이며 이것이 상당히 작으므로 결과적으로 출력전원의 내부임피단스 Zo는 대단히 커지게 된다. 즉 출력측에서 입력측으로 보면 정전류전원이 된다. 따라서 본 발명의 인버터출력측 Lo Co 병렬공진 방식은 형광램프 점등시 아크방전 전압 전류의 부저항특성 때문에 발생하는 과전류 상태 및 부하측 단락시 발생하는 과전류 상태를 완전히 제한할 수 있게 된다 .The features of the present invention are briefly considered. When the inverter Lo Co high frequency parallel tank circuit of the present invention becomes parallel resonant, the internal impedance Z z of the high frequency voltage power source is

In this case, the resistance R is the pure resistance component of the tank coil Lo, which is quite small, and as a result, the internal impedance Z of the output power becomes very large. In other words, when viewed from the output side to the input side, it becomes a constant current power supply. Therefore, the inverter output side Lo Co parallel resonance method of the present invention can completely limit the overcurrent state generated due to the negative resistance characteristic of the arc discharge voltage current when the fluorescent lamp is turned on and the overcurrent state generated when the load side short circuit occurs.

And it will be briefly described by comparing the push-pull transistor inverter circuit of the present invention and the conventional push-pull transistor inverter circuit. As shown in FIG. 2, the conventional fluorescent lamp lighting circuit using the push-pull transistor inverter circuit has one main and one auxiliary transformer, each having two transistors Q ₁ , Q ₂ and a DC power supply on the primary side of the main transformer T ₁ . Connect as shown in the figure and connect the fluorescent lamp to the secondary side (n ₂ ) through the inductor (L ₁ ), but wind some windings and connect it to the primary of the auxiliary transformer (T ₂ ) In this manner, the base currents of the two transistors Q ₁ and Q ₂ can be supplied.

In addition, the fluorescent lamp is turned on to maintain a high voltage in the secondary by adjusting the primary and secondary winding ratios of the main transformer T ₁ , and connects the capacitor C ₁ as shown in the inductor L ₁ . This can be done by causing a series of linear resonances. However, the fluorescent lamp lighting circuit using the push-pull transistor inductor circuit of the present invention has only one main transformer (T ₂ ) without an auxiliary transformer, and has two transistors (TR ₁ , TR ₂ ) and a capacitor on the primary side of the main transformer (T ₁ ). Connect (Co) in parallel and connect DC power through inductor (T ₁ ) as shown in the drawing, and coil (L ₁ ) with boost winding on both ends of coil (Lo 1) on the primary side of transformer (T ₂ ). , L ₂ ) is mounted as single winding transformer and connects fluorescent lamp through inductor (T ₃ ). In the secondary of the main transformer T ₂ , the two transistors TR ₁ and TR ₂ and the base current can be supplied by resistance distribution. Of course, the fluorescent lamp is turned on by allowing the coil Lo and the coils L ₁ and L _{2 on the} primary side of the main transformer T ₂ to be induced with a high voltage by adjusting a single winding ratio. By the way, since the characteristics and role of the high frequency oscillation inverter transformer (T ₂ ) is the most essential element in the push-pull transistor inverter of the present invention, it will be briefly considered. The transformer T ₂ is a saturation transformer using an iron core having a BH curve of a square hysteresis as shown in FIG. 4 to make a stable and reliable oscillation operation of the transistor inverter of the present invention.

In the inverter of the present invention, the base emitter-voltage Vbe of the transistors TR ₁ and TR ₂ and the characteristics V _be -I _b of the base current I _b are not all the same. On the other hand, since the h _fe of the transistors TR ₁ and TR ₂ are not all the same, the collector currents of the transistors TR ₁ and TR ₂ flowing through the base currents a ₁ and I _B1 are different in magnitude. .

Now assume it is, the voltage induced is a collector current (IC ₁₎ of the transistor (TR ₁₎ transistor base coil (LF) of the lower is larger than the collector current (IC ₂₎ transformer (T ₂₎ of the (TR _2). The induced voltage is distributed by the bias resistors R ₁ and R ₂ to increase the base current of the transistor TR ₁ and to decrease the base current in the transistor TR ₂ . Thus IC ₁ increases and IC ₂ decreases. As a result, the induced voltage of the base coil LF is increased, so that TR ₁ operates to increase the base current and decrease the base current of TR ₂ . In this way, TR ₁ turns ON and TR ₂ turns OFF in one instant. In this state, a power supply voltage is applied to the collector coil of TR ₁ at the center tap of the coil Lo of the transformer T ₂ .

As time elapses, as shown in FIG. 4, since the excitation current of the transformer T ₂ flows, the self-activation force H increases, and accordingly, the magnetic flux density starts at 0 and increases in the direction of the arrow, and then the magnetic flux density. When the point a reaches the point a, the magnetic flux density does not change even when the excitation current increases, and eventually becomes a magnetic saturation state. At this time, the magnetic flux in the same direction decreases rapidly, and the base current of TR ₁ also drops sharply. As a result, the transistor TR ₁ transitions from the saturated state to the unsaturated state. TR ₁ reduces the collector current (IC ₁ ).

According to this flowing woman begins to current is reduced, so that an electromotive force that is a counter electromotive force of trying to continue to flow the IC ₁ by the collector coil (Lo / 2) the inductance of the TR ₁ occurs which decreases the base current of the TR ₁ opposed to the TR ₂ This results in increasing the base current. As a result, TR ₁ is OFF and TR ₂ is momentarily inverted. If this condition continues, the magnetization force (H) of FIG. 4 is reversed, and the magnetic flux density (B) reaches point b in the direction of the arrow. Here, the magnetic saturation of the moja as described above occurs, and TR ₁ is turned on and TR ₂ is turned off, such an inversion operation is repeatedly repeated, and the inverter continues the high frequency oscillation operation.

가 된다) 형광램프의 발광효율(조도)이 상당히 증가하게 된다. 따라서 본 발명의 형광등점등 장치는 큰 절전효과를 얻을 수 있게된다. 그리고 조도도 대단히 높아 형광등이 기준조도 이상으로 높일 수 있으며 방전횟수(속도)가 빠르므로 푸리카 현상이 거의 없어 눈의 피로를 덜어주게 된다.The present invention not only obtains high efficiency because the high frequency switch regulating method is applied, and the number of discharges (speed) of the fluorescent lamp by the high frequency (ultrasound) voltage is higher than the number of discharges (speed) by the low frequency (60 Hz) voltage. Due to a hundred times faster (for example,

Luminous efficiency (illuminance) of the fluorescent lamp is significantly increased. Therefore, the fluorescent lighting device of the present invention can obtain a large power saving effect. In addition, the intensity of illumination is very high, the fluorescent lamp can be raised above the standard illumination, and the number of discharges (speed) is fast, so there is almost no Purica phenomenon, which reduces eye fatigue.

Claims (1)

The oscillation circuit is connected (twice-corrected) with an inductor T ₁ interposed in a known inverter circuit, and the transistors TR ₁ and TR ₂ are connected to both ends 2 and 4 of the coil Lo of the transformer T ₂ . The (R ₁ , R ₂ , R ₃ ) diode (ZD ₁ ) and the coil (LF) form an oscillation protection circuit, and the coil (Lo) of the transformer (T ₂ ) extends on the extension lines of both ends (2, 4). A booster circuit is formed by connecting coils (L ₁ , L ₂ ), and an inductor (T ₃ ) connected in series to the tip (1) of the coil (L ₁ ) of the transformer (T ₂ ) to the electronic fluorescent lamp lighting device.

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