KR20040032453A - The dimming device - Google Patents

Abstract

PURPOSE: An apparatus for controlling brightness is provided to increase the adjustment width of brightness by controlling an amount of a current that flows in a lighting apparatus. CONSTITUTION: One power line of a fluorescent lamp(10) is connected to a secondary coil of a step-up transformer(13). A current sensing circuit(21) senses an amount of a current of the fluorescent lamp(10) to convert the amount of a current sensed into a corresponding voltage signal. The voltage signal is inputted to a comparator(22). The comparator(22) compares the voltage signal with a brightness adjusting voltage to generate a pulse width adjusting signal. The pulse width adjusting signal is inputted to a PWM(Pulse Width Modulation) signal generating circuit(24). The PWM signal generating circuit(24) generates a PWM signal to output to a switching circuit(25). The switching circuit(25), in response to the PWM signal, controls an amount of a current that flows in the fluorescent lamp(10).

Description

Brightness Control Unit {THE DIMMING DEVICE}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a brightness control apparatus for lighting equipment employing light sources such as a backlight for LCDs employing fluorescent lamps and various discharge tubes. The luminance adjusting device of the present invention mainly applies an AC type high voltage, and corresponds to a mechanism employing a fluorescent lamp and various discharge tubes driven at a frequency of several kHz to several MHz. The backlight and the luminaire require a function that the user can arbitrarily adjust the brightness.

The brightness control function of the conventional backlight adopts a method of sensing the amount of current flowing through the fluorescent lamp and controlling the amount of current flowing through the fluorescent lamp by adjusting the input of the power supply device through a feedback circuit. The adjustment of the input of the power supply is mainly due to the change in voltage, driving frequency, and duty ratio of the driving voltage wave.

However, the method of adjusting the input of the power supply is not an effective method in a large area backlight power supply driven by a large power. That is, the conventional small backlight has a small power supply, and the small power is easily controlled at the input terminal of the inverter.

3 is a conceptual diagram of a luminance control circuit of a conventional backlight driving inverter.

The high voltage is applied through the inverter 12 to drive the fluorescent lamp 10, the current flowing through the lamp is detected 21, and the sensed signal is inputted through the feedback circuit (input voltage, input frequency, The duty cycle of the input waveform, etc.), and the lamp is driven with the new input condition. When the user adjusts the brightness adjusting terminal 23 in the circuit, the driving conditions of the inverter change to change the brightness of the backlight 11. In the circuit, the input condition of the input stage 14 is determined according to the manner of the inverter. By changing the input condition through the feedback circuit, a constant amount of current is maintained at the same time as brightness adjustment.

However, a backlight requiring high current and high power driven by a single inverter by connecting a plurality of fluorescent lamps in parallel has the following problems when employing the feedback circuit as described above.

In the case of adjusting the input voltage, a switching power supply device and a constant voltage adjusting device are used, and power consumption occurs in the voltage control circuit itself, and the power consumption is proportional to the driving power of the inverter (proportional to the number of lamps). In addition, the power consumption is converted to the heat of the circuit is difficult to control stable.

In addition, in the case of adopting a current control method by chopping the input current, power consumption in the switching element, mechanical noise of the transformer due to the chopping frequency, and corona discharge due to the initial high voltage of the high voltage switching are caused. do.

In addition, in the case of controlling the input current by changing the driving frequency or duty ratio, the problem of heat generation in the circuit element due to the low efficiency and the adjustment range of the luminance are small due to the change of the efficiency of the inverter according to the frequency. Not desirable

Changes in input conditions due to feedback circuits are considered to be more difficult for large-area backlights or high-power luminaires employing fluorescent lamps, and the luminance adjustment is extremely small, even if possible. It can be seen that the luminance control method according to the present invention can be applied only when a small backlight or a fluorescent lamp is driven by an individual inverter.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is an automatic circuit device for a brightness control function and a constant current driving function of a backlight employing a fluorescent lamp, the power loss of the circuit is small and the It is to provide a brightness control and a constant current driving method that does not generate vibration or noise.

1A is a conceptual diagram of a luminance control circuit of a backlight in which a plurality of fluorescent lamps is disposed according to a first embodiment of the present invention;

1B is a conceptual diagram of a circuit for controlling brightness by controlling current by switching in both directions at both ends of a fluorescent lamp of a backlight according to a second embodiment of the present invention;

FIG. 1C is a conceptual diagram of a circuit for controlling luminance by controlling current in both directions at both ends of a fluorescent lamp of a backlight according to a third embodiment of the present invention; FIG.

2 is a conceptual diagram of a current sensing circuit and a switching circuit according to another embodiment of the present invention.

3 is a conceptual diagram of a luminance control circuit of a conventional backlight;

Brief description of symbols for the main parts of the drawings

10 fluorescent lamp 11: backlight

12: inverter (power supply unit) 13: step-up transformer

14 input terminal 21 current sensing circuit

22: comparator 23: constant current and brightness control terminal

24 pulse width modulation signal generator 25 switching circuit

Rt: switching element parallel resistor Rb, R1, R2, R3: bias resistor

In order to achieve the above object, the present invention adopts a method of directly controlling the current flowing in the fluorescent lamp in the backlight is driven by connecting a plurality of fluorescent lamps in parallel.

In general, in a power supply device employing a boost transformer, when a fluorescent lamp is connected across the transformer secondary coil, the amount of current flowing through the primary coil increases in proportion to the amount of current flowing through the lamp. That is, when the power supply line connected to the fluorescent lamp of the secondary side is cut off, the present invention focuses on the amount of input current and input power of the primary side also greatly reduced, and there is no problem such as vibration and noise of the transformer.

Another concept of the present invention is that the ratio of the amount of current flowing through the primary coil and the secondary coil of the boost transformer is inversely proportional to the number of turns of each coil. That is, since the amount of current flowing through the secondary side coil is smaller than the amount of current flowing through the primary side coil, it is possible to easily control the flow of current by directly switching the low current on the secondary side rather than controlling the high current on the primary side.

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

FIG. 1A is a conceptual diagram of a circuit having a function of adjusting brightness and a constant current of a backlight in which a plurality of fluorescent lamps are disposed, and one power line of the fluorescent lamp 10 is connected to a secondary coil of the boost transformer 13 and connected to the secondary coil of the fluorescent lamp. The other power line is a circuit for controlling the amount of current by a switching method.

On either side of the fluorescent lamp, the current sensing circuit 21 senses the amount of current in the fluorescent lamp and exchanges it with the voltage signal, which is input to the comparator 22, and the luminance input from the brightness adjusting terminal 23 at the comparator. The pulse width control signal is input to the PWM (Pulse Width Modulation) signal generating circuit 24 in comparison with the adjustment voltage, and the switching time is adjusted in the switching circuit 25 through the duty signal change signal to flow to the lamp. Adjust the amount of current. When the brightness is adjusted by the brightness adjusting terminal, the current amount is kept constant at the adjusted brightness.

1B and 1C are conceptual views of a bidirectional switching circuit 25 having a brightness control and a constant current function by switching current flowing in both directions flowing in the fluorescent lamp.

FIG. 1B is characterized by using one boost transformer and two power lines electrically separated from the secondary coil interrupt of the boost transformer in order to control the current in both directions flowing through the fluorescent lamp. Both ends of the secondary coil of the boost transformer are connected to both ends of the fluorescent lamp, and the two separate power lines of the secondary coil interrupt each control the current in both directions by switching to adjust the brightness.

FIG. 1C is characterized by using two identical boost transformers to control the current in both directions flowing in the fluorescent lamp. One of the secondary coils of each of the two transformers is connected to a fluorescent lamp, and the other of the secondary coils attaches a switching element to control current in both directions.

In the bidirectional switching method of FIGS. 1B and 1C, a larger current is controlled than the current control method of the one-way switching method of FIG.

2 is a conceptual diagram of the current sensing circuit 21 and the switching circuit 25. Various switching schemes are possible as shown in FIGS. 2A-2C.

2A shows an example using an NPN switching transistor. In the circuit, Rt is a resistor for lowering the breakdown voltage applied to the switching element.

2B shows an example using a PNP switching transistor. In the circuit, R1 and R2 are bias resistors, and Rt is a resistor for lowering the breakdown voltage applied to the switching element. If the withstand voltage of the switching element is sufficient, Rt may be omitted.

2C shows an example in which NPN and PNP transistors are used together. R1, R2, and R3 are bias resistors, and Rt is a resistor for lowering the voltage applied to the switching element.

In addition to the transistor device in FIG. 2, semiconductor switching devices such as FETs, SCRs, and GTOs may be used.

According to the experiments of the present inventors employing the above brightness adjustment function, in a diagonal 17-inch backlight produced by connecting 12 fluorescent lamps in parallel, a wide brightness adjustment function of the highest surface luminance of the backlight from 12,000 nit to the lowest luminance of 3,000 nit In this case, the input current amount at the input voltage of 14V of the inverter controlled the change of the current amount from 3A to 2A or less.

Although the present invention has been described in detail above, those skilled in the art to which the present invention pertains may variously modify the present invention without departing from the spirit and scope of the present invention as defined in the appended claims. It is apparent that the present invention may be modified or modified. Therefore, a simple change according to an embodiment of the present invention will not be possible without departing from the technology of the present invention.

According to the present invention of the above configuration, it is easy to adjust the brightness and maintain the constant current of the large current backlight, there is little power loss due to the brightness adjustment and current control, there is no problem such as noise. The present invention, unlike the conventional method of controlling the amount of current by changing the input condition by the feedback circuit, ensures a high-efficiency power supply device driven at the input condition having the optimum efficiency without changing the input condition.

Since the present invention directly controls the current flowing in the fluorescent lamp irrespective of the input terminal, the present invention is applied regardless of the type or type of inverter. In particular, the present invention can be conveniently applied to a driving device of a backlight which directly uses a general power supply (for example, 110V and 220V AC power).

The present invention can be usefully used for a lighting device having a very wide adjustment range of luminance and having a blinking function.

Claims (7)

An AC high voltage is applied by connecting a light source to the secondary coil of the boost transformer, and attaching a switching element between the secondary coil and the light source, and controlling the amount of current flowing through the light source in the ON-OFF manner of the switching element to reduce luminance. The brightness control device, characterized in that for adjusting. The brightness adjusting device of claim 1, wherein the switching element is any one of a transistor, a FET, an SCR, and a GTO. According to claim 1, further comprising a brightness control terminal, a current sensor flowing to the light source, a comparator, a pulse width modulation generator, a specific voltage is output from the brightness control terminal, a specific voltage is output from the current sensor flowing to the fluorescent lamp The output voltage of the brightness control terminal and the output voltage of the current detector are input to a comparator, an output signal from the comparator is input to a pulse width modulation generator, a signal output from the pulse width modulation generator is input to a switching element, And the switching time of the switching element is adjusted to control the amount of current flowing through the fluorescent lamp, the luminance is controlled by the control of the amount of current, and a constant current flows at the predetermined luminance. The transformer of claim 1, wherein the boost transformer is provided with two power lines electrically separated from the interruption of the transformer secondary coil, and both ends of the transformer secondary coil are connected to electrodes at both ends of the fluorescent lamp. And a switching circuit is provided in each of the two power lines of the interruption to control the current across the fluorescent lamp. 2. The transformer of claim 1, wherein the boost transformer uses a pair of transformers, one of the secondary coils of each of the pair of transformers is connected to electrodes on both ends of the fluorescent lamp, and the other of the transformer secondary coils of the pair of transformers. Are respectively provided with a switching circuit to control the current across the fluorescent lamp. The luminance control device of claim 1, wherein the light source is configured by connecting a plurality of external electrode fluorescent lamps in parallel. The brightness control apparatus of claim 1, wherein the light source is configured by connecting a plurality of cold cathode fluorescent lamps each having a capacitor having the same capacitance at both ends thereof in parallel.