KR20050098140A - Back-light inverter with stabilization function of lamp current - Google Patents

Abstract

The present invention is applied to LCD backlights, such as LCD (hereinafter referred to as "LCD")-TV, LCD-monitor, and the object is to provide a backlight inverter that can stabilize the lamp current early.

According to an aspect of the present invention, a backlight inverter having an early stabilizing lamp current may include a driver configured to generate a square wave signal for adjusting a lamp current based on a feedback signal corresponding to a magnitude of lamp current; A transformer for boosting a square wave signal from the driving unit to a winding ratio of a primary coil and a secondary coil and outputting an alternating current to the lamp; A resonance capacitor connected in parallel to the secondary coil of the transformer; And a voltage corresponding to the current of the lamp is detected through a voltage detecting resistor grounded at the connection node and connected to the ground-side connection node between the secondary coil of the transformer and the resonance capacitor. And a lamp current detector configured to output a feedback signal corresponding to a comparison result with a preset reference voltage to the driver.

According to the present invention, by realizing to accurately detect the lamp current using the resonant capacitor in the backlight inverter, it is possible to stabilize the lamp current early, and to control the lamp current constantly, accordingly the lamp current The phenomena of increasing gradually can be eliminated, so that the luminance can be kept constant.

Description

BACK-LIGHT INVERTER WITH STABILIZATION FUNCTION OF LAMP CURRENT}

The present invention relates to a backlight inverter applied to LCD backlights, such as LCD (hereinafter referred to as "LCD")-TV, LCD-monitor, in particular, so that the lamp current can be accurately detected by using a resonant capacitor in the backlight inverter. By realizing the lamp, the lamp current can be stabilized early, the lamp current can be controlled constantly, and the lamp current can be eliminated gradually, thereby keeping the brightness constant. A backlight inverter having a current early stabilization function.

In general, as the LCD-TV and LCD-monitor market gradually enlarges, the number of lamps mounted on the back light unit gradually increases, and as the tube shape of the lamp and the tube length of the lamp gradually increase, The manner in which the lamp is driven is also changing.

1 is a configuration diagram of a backlight inverter for a conventional small LCD.

Referring to FIG. 1, a conventional backlight backlight inverter for a small LCD includes a driver 11 generating a square wave signal based on the detected lamp current, and boosting the square wave signal from the driver 11 to convert an AC signal. The voltage corresponding to the current flowing in the lamp 13 is connected by connecting a feedback node to a transformer 12 for outputting an alternating current necessary for lamp operation to the lamp 13 and a cold end of the lamp 13. It comprises a lamp current detection unit 14 for detecting and outputting to the drive unit (11).

Here, an input terminal of a lamp to which a high current is supplied is called a hot end, and an output terminal of a lamp through which a low current flows is called a cold end.

In addition, in FIG. 1, 'C' is provided for resonance with the parasitic inductance of the secondary coil of the transformer 12, and 'R' is a voltage detection resistor for detecting a lamp current as a voltage.

Such a conventional backlight inverter for a small LCD can be applied to a small LCD of approximately 17 or so, and can generate approximately 500-800 Vrms lamp driving voltage. Further, in the conventional backlight backlight inverter for small LCDs, a feedback node for detecting the lamp current and stabilizing the lamp current is formed at the cold end of the lamp.

Referring to the operation of the backlight inverter for a small LCD, when the inverter is operated, a high voltage is induced at the output terminal of the transformer 12, and the lamp 13 emits light at the induced voltage. At this time, if the current flowing through the lamp is sensed and controlled to control the current of the lamp to be constant, the leakage caused by parasitic components is not reflected in the feedback, but accurately detects the current flowing through the lamp, ideally the lamp Current can be controlled.

However, as the LCD is gradually enlarged to 17 inches or more, a backlight inverter applied to a large LCD is relatively larger than a lamp applied to a conventional small LCD backlight inverter such as a long straight lamp or a "U" shaped lamp. Longer ramps are applied.

Since such a long lamp requires a driving voltage of about 1 KVrms, there are technical problems to be solved even when driving such a long lamp, and one of them is how to control the current flowing through the lamp in the constant current mode. .

In particular, a large LCD backlight inverter drives two lamps using two transformers, and since the distinction between a hot end and a cold end is ambiguous, unlike a small LCD inverter shown in FIG. Since it is not desirable to sense current at the stage, a method of controlling the lamp current through another root has been adopted. One of such conventional backlight inverters is as shown in FIG.

2 is a configuration diagram of a conventional backlight inverter for a large LCD.

Referring to FIG. 2, a conventional backlight inverter for a large LCD includes two first and second transformers 22A and 22B for driving a lamp 23 requiring a high driving voltage of about 1 KVrms. Each of the first and second transformers 22A and 22B boosts square wave signals by the corresponding driving units 21A and 21B and converts them into alternating current signals so that the first and second transformers 22A and 22B each have an inverse phase relationship necessary for the operation of the lamp 23. The second AC driving current is supplied to one side and the other side of the lamp 23.

In order to constantly control the current flowing through the lamp 23, the backlight inverter may include first and second feedback nodes connected to a ground node of each secondary coil of the first and second transformers 22A and 22B. Lamp current detection units 24A and 24B. The first and second lamp current detectors 24A and 24B detect a voltage due to the current flowing in the secondary of the transformer and output a feedback signal to the corresponding driver 21A and 21B.

Here, 'C1' and 'C2' are installed for resonance with the parasitic inductance of the secondary coil of each transformer, and 'R1' and 'R2' are voltage detection resistors.

However, in such a conventional large LCD backlight inverter, the transformer output is sent as the sum of the current flowing through the resonant capacitors C1 and C2 and the current flowing through the lamp 23, but measured at the input side of the lamp 23. Since the current does not include the value of the current flowing through the resonant capacitors C1 and C2, the current flowing through the lamp cannot be controlled at an early stage.

In particular, since the impedance of the lamp is considerably high in the initial stage of driving and the impedance of the lamp after stabilization after driving is considerably low, the current flowing through the lamp changes due to the impedance change of the initial stage of the driving and subsequent stages of the lamp. There is a problem that it is not possible to control the current flowing in the constant.

That is, the capacitance of the capacitor varies depending on the temperature, frequency, and capacitance values. Since the capacitance is in parallel with the lamp impedance, as the lamp impedance decreases, the current flowing through the lamp increases, and the current flowing through the capacitor decreases. For this reason, when the lamp is initially turned on, the current flowing to the lamp flows less than the set value, and then becomes the set value over time.

In addition, in the case where the lamp tube is long and differential driving or floating driving is performed, the current control of the lamp is controlled by the information of the transformer, and in this case, the leakage current is reflected and reflected to the feedback stage. Therefore, there is a problem in that the current of the lamp continues to increase even when the impedance of the lamp is reduced.

The present invention has been proposed to solve the above problems, the object of which is to realize the lamp current can be accurately detected by using a resonant capacitor in the backlight inverter, it is possible to stabilize the lamp current early, The present invention provides a backlight inverter having a lamp current early stabilization function which can be controlled constantly, thereby eliminating a phenomenon in which the lamp current gradually increases, thereby maintaining a constant luminance.

In order to achieve the above object of the present invention, a backlight inverter having a lamp current early stabilization function of the present invention

A driving unit generating a square wave signal for adjusting the lamp current based on a feedback signal corresponding to the magnitude of the lamp current;

A transformer for boosting a square wave signal from the driving unit to a winding ratio of a primary coil and a secondary coil and outputting an alternating current to the lamp;

A resonance capacitor connected in parallel to the secondary coil of the transformer; And

The voltage corresponding to the current of the lamp is detected through a voltage detecting resistor grounded at the connection node and connected to the ground-side connection node between the secondary coil of the transformer and the resonance capacitor. Lamp current detection unit for outputting a feedback signal corresponding to the comparison result with the reference voltage set in the drive unit

Characterized in that comprises a.

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

In the drawings referred to in the present invention, components having substantially the same configuration and function will use the same reference numerals.

3 is a block diagram of a backlight inverter according to the present invention.

Referring to FIG. 3, the backlight inverter of the present invention includes a first driver 31A for generating a first square wave signal for adjusting lamp current based on a first feedback signal corresponding to the current magnitude of the lamp 33, and the first inverter 31A. A first transformer 32A for boosting the first square wave signal from the first driving unit 31A to the turns ratio of the primary coil and the secondary coil therein and outputting a first AC current to one end of the lamp 33; Ground-side connection node between the first resonance capacitor CA connected in parallel to the secondary coil of the first transformer 32A, and the secondary coil of the first transformer 32A and the first resonance capacitor CA. The voltage corresponding to the current flowing through the lamp 33 is detected through the voltage detecting resistor RA connected to N1 and grounded at the connection node N1 to detect the voltage and the preset first voltage. Outputs the first feedback signal corresponding to the comparison result with the reference voltage to the first driver 31A. Includes a first lamp current detecting unit (34A).

In addition, the backlight inverter of the present invention includes a second driver 31B for generating a second square wave signal for adjusting lamp current based on a second feedback signal corresponding to the current magnitude of the lamp 33, and the second driver 31B. A second transformer 32B for boosting the second square wave signal from the circuit to a winding ratio of an internal primary coil and a secondary coil and outputting a second alternating current to the other end of the lamp 33; A second resonance capacitor CB connected in parallel to the secondary coil of 32B, and a ground-side connection node N2 between the secondary coil of the second transformer 32B and the first resonance capacitor CB. The voltage corresponding to the current flowing through the lamp 33 is detected through the voltage detection resistor RB grounded at the connection node N2, and the detected voltage is compared with a preset second reference voltage. A second RAM outputting a second feedback signal corresponding to a comparison result to the second driver 31A And a current detector (34A).

The first AC signal of the first transformer 32A is made to have a phase inverse to that of the second AC signal of the second transformer 32B.

The first reference voltage of the first lamp current detector 34A is set to a voltage substantially the same as the second reference voltage of the second lamp current detector 34B.

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

The backlight inverter having the early stabilization of the lamp current of the present invention may be applied to a backlight inverter for a small LCD or a backlight inverter for a large LCD, and embodiments of the present invention describe a backlight inverter for a large LCD.

Referring to FIG. 3, the first driver 31A of the present invention generates a first square wave signal for adjusting the lamp current based on a first feedback signal corresponding to the current magnitude of the lamp 33. The second driver 31B generates a second square wave signal for adjusting the lamp current based on the second feedback signal corresponding to the current magnitude of the lamp 33.

Here, the first driver 31A and the second driver 31B operate in synchronization with each other, and the first square wave signal and the second square wave signal are in phase inverted relationship with each other.

Next, the first transformer 32A of the present invention boosts the first square wave signal from the first driver 31A to the winding ratios of the primary coil and the secondary coil therein so that one end of the lamp 33 is provided with a first transformer 32A. An alternating current is output, and the second transformer 32B of the present invention boosts the second square wave signal from the second driving part 31B to the ratio of the turns of the primary coil and the secondary coil in the lamp 33. Outputs a second AC current at the other end of

Here, the first alternating current signal of the first transformer 32A has a phase inverse to that of the second alternating current signal of the second transformer 32B.

On the other hand, in each transformer of the backlight backlight inverter of the present invention, it is preferable to output an AC signal of a sine wave required for lamp operation. In order to make an AC signal having such distortion into an AC signal having almost no distortion, a first resonance capacitor CA is connected in parallel to the secondary coil of the first transformer 32A, and the second transformer ( A second resonance capacitor CB is connected in parallel to the secondary coil of 32B).

Accordingly, the AC signal output from the first transformer 32A is distorted by using resonance caused by the parasitic inductance of the secondary coil of the first transformer 32A and the capacitance of the first resonance capacitor CA. It is made of almost sine wave. In addition, the AC signal output from the second transformer 32B is almost distorted by using resonance caused by the parasitic inductance of the secondary coil of the second transformer 32B and the capacitance of the second resonance capacitor CB. Make sinusoidal.

For this operation, the first AC signal flows through one end of the lamp 33 and the second AC signal flows through the other end of the lamp 33, so that the lamp 33 operates.

Then, the first lamp current detection unit 34A of the present invention is connected to the ground side connection node N1 of the secondary coil of the first transformer 32A and the first resonance capacitor CA, and this connection is made. The voltage corresponding to the current flowing through the lamp 33 is detected through the voltage detecting resistor RA grounded at the node N1 and corresponds to a result of comparing the detected voltage with a preset first reference voltage. The first feedback signal is output to the first driver 31A.

Here, since the first lamp current detector 34A also detects the influence of the current flowing through the first resonance capacitor CA, the current flowing through the lamp 33 can be accurately detected.

In addition, the second lamp current detection unit 34A of the present invention is connected to the ground side connection node N2 between the secondary coil of the second transformer 32B and the second resonance capacitor CB, and this connection node The voltage corresponding to the current flowing through the lamp 33 is detected through the voltage detecting resistor RB grounded at N2, and the second voltage corresponding to the comparison result between the detected voltage and the second preset reference voltage is set. 2, a feedback signal is output to the second driver 31B.

Here, the second lamp current detector 34B also detects the influence of the current flowing through the second resonance capacitor CB, so that the current flowing through the lamp 33 can be accurately detected.

In addition, the first reference voltage of the first lamp current detector 34A is set to a voltage substantially the same as the second reference voltage of the second lamp current detector 34B.

As described above, if the trans output load is purely composed of a lamp and the current flowing through the capacitor is reflected in the feedback sensing stage, the current value fed into the feedback includes the current flowing through the capacitor, so that the current value changes as the lamp impedance changes. The phenomenon can be improved. That is, the current flowing through the resonant capacitor C is reflected as a feedback, and the current flowing through the lamp is purely measured as the lamp current value, so that the current may be kept constant even when time is initially started.

According to the present invention as described above, in the backlight inverter applied to the LCD backlight, such as LCD-TV, LCD-monitor, by implementing the resonant capacitor to accurately detect the lamp current, stabilizing the lamp current early It is possible to control the lamp current constantly, thereby eliminating a phenomenon in which the lamp current gradually increases, thereby maintaining a constant luminance.

Since the above description is only a description of specific embodiments of the present invention, the present invention is not limited to these specific embodiments, and various changes and modifications of the configuration are possible from the above-described specific embodiments of the present invention. It will be apparent to those skilled in the art to which the present invention pertains.

1 is a configuration diagram of a backlight inverter for a conventional small LCD.

2 is a configuration diagram of a conventional backlight inverter for a large LCD.

3 is a block diagram of a backlight inverter according to the present invention.

Explanation of symbols on main parts of drawing

31A: first driver 31B: second driver

32A: 1st transformer 32B: 2nd transformer

33: lamp 34A: first lamp current detection unit

34B: second lamp current detector CA: first resonance capacitor

CB: Second Resonant Capacitor

Claims (4)

A driving unit generating a square wave signal for adjusting the lamp current based on a feedback signal corresponding to the magnitude of the lamp current; A transformer for boosting a square wave signal from the driving unit to a winding ratio of a primary coil and a secondary coil and outputting an alternating current to the lamp; A resonance capacitor connected in parallel to the secondary coil of the transformer; And The voltage corresponding to the current of the lamp is detected through a voltage detecting resistor grounded at the connection node and connected to the ground-side connection node between the secondary coil of the transformer and the resonance capacitor. Lamp current detection unit for outputting a feedback signal corresponding to the comparison result with the reference voltage set in the drive unit Backlight inverter having a lamp current early stabilization function comprising a. A first driver configured to generate a first square wave signal for adjusting lamp current based on a first feedback signal corresponding to a lamp current magnitude; A first transformer for boosting a first square wave signal from the first driver to a winding ratio of an internal primary coil and a secondary coil to output a first AC current to one end of the lamp; A first resonance capacitor connected in parallel to the secondary coil of the first transformer; A voltage corresponding to a current flowing through the lamp is detected through a voltage detecting resistor connected to a ground-side connection node between the secondary coil of the first transformer and the first resonance capacitor and grounded at the connection node. A first lamp current detector for outputting a first feedback signal corresponding to a result of comparing the detected voltage with a preset first reference voltage to the first driver; A second driver configured to generate a second square wave signal for adjusting a lamp current based on a second feedback signal corresponding to a lamp current magnitude; A second transformer for boosting a second square wave signal from the second driver to a winding ratio of an internal primary coil and a secondary coil to output a second AC current to the other end of the lamp; A second resonance capacitor connected in parallel to the secondary coil of the second transformer; And A voltage corresponding to a current flowing through the lamp is detected through a voltage detecting resistor grounded at the connection node of the second coil of the second transformer and the first resonance capacitor. A second lamp current detector for outputting a second feedback signal corresponding to a result of comparing the detected voltage with a preset second reference voltage to the second driver; Backlight inverter having a lamp current early stabilization function comprising a. The method of claim 2, wherein the first AC signal of the first transformer is The backlight inverter having the early stabilization lamp current characterized in that the phase and the reverse phase of the second AC signal of the second transformer. The method of claim 2, wherein the first reference voltage of the first lamp current detection unit And a lamp current early stabilizing function, wherein the voltage is substantially equal to a second reference voltage of the second lamp current detector.