KR101034705B1 - Backlight assembly and operating method thereof - Google Patents

Abstract

The backlight assembly according to the present invention includes a plurality of external electrode fluorescent lamps manufactured in a U shape and arranged side by side; A first inverter for applying power in parallel to the odd-numbered electrodes of the U-shaped external electrode fluorescent lamps; A second inverter for applying power in parallel to even-numbered electrodes of the U-shaped external electrode fluorescent lamps; It includes.

In addition, the method of driving a backlight assembly according to the present invention comprises a plurality of external electrode fluorescent lamps manufactured in a U shape and arranged side by side; A first inverter for applying power in parallel to the odd-numbered electrodes of the U-shaped external electrode fluorescent lamps; A second inverter for applying power in parallel to even-numbered electrodes of the U-shaped external electrode fluorescent lamps; And a voltage applied from the first inverter and a voltage applied from the second inverter are equal in magnitude to each other, and a voltage is applied to each electrode so that the phases are 180 degrees apart.

In addition, the backlight assembly according to the present invention includes a plurality of external electrode fluorescent lamps manufactured in a U shape and arranged side by side; A first inverter for applying power in parallel to the straight tube electrode of the U-shaped external electrode fluorescent lamp; A second inverter for applying power in parallel to the bending part electrode of the U-shaped external electrode fluorescent lamp; It includes.

Description

Backlight assembly and operating method thereof

1 is a view for explaining a method of driving a backlight assembly employing a conventional external electrode fluorescent lamp.

2 is a view for explaining another driving method of a backlight assembly employing a conventional external electrode fluorescent lamp.

3 is a view for explaining a method of driving a backlight assembly employing an external electrode fluorescent lamp according to the present invention.

4 is a view for explaining another driving method of a backlight assembly employing an external electrode fluorescent lamp according to the present invention.

<Explanation of symbols for the main parts of the drawings>

21, 22, 41, 42 ... Inverter

The present invention relates to a backlight assembly and a driving method thereof.

Today, the image display device is changing from the CRT method to the liquid crystal display device, the plasma display panel, etc. In particular, the liquid crystal display device has lower power consumption than the CRT method, can be lighter and thinner, and emits harmful electromagnetic waves. Due to its advantages, it is attracting attention as the next generation of advanced image display device.

A general liquid crystal display device includes a lower substrate on which a thin film transistor (TFT) is formed, an upper substrate on which color filters are arranged, and a liquid crystal layer injected between the lower substrate and the upper substrate. It is configured to include.

Here, the TFT formed on the lower substrate serves to transmit and control the electrical signal, and the liquid crystal controls the degree of light transmission by changing the molecular structure according to the applied voltage. The light controlled through the above process passes through the upper substrate and appears in a desired color and image.

On the other hand, since the liquid crystal display is a light receiving device that displays an image by controlling the amount of light coming from the outside, a separate light source for illuminating the liquid crystal panel, that is, a backlight assembly is required.

Such a backlight assembly is classified into an edge type and a direct type according to the position of the light source with respect to the display surface. Among these, the direct type backlight assembly is widely used in large liquid crystal display devices because of high light utilization, simple handling, and no limitation on the size of the display surface.

The external light source applied to the direct backlight assembly is appropriately selected according to the size and purpose of use of the liquid crystal display device. The external light source can be divided into types of point light sources such as incandescent lamps and white halogen lamps, and fluorescent lamps (hot cathode, cold cathode, external). Linear light sources such as electrodes), EL (Electroluminescent), and planar light sources using matrix light emitting diodes (LEDs).

Currently, Cold Cathode Fluorescent Lamps (CCFLs) are mainly used, but are gradually replaced with External Electrode Fluorescent Lamps (EEFLs). In the case of using an external electrode fluorescent lamp, the number of inverters can be reduced since the multi-drive is possible, and thus, there is an advantage in that the cost can be reduced and the weight of the liquid crystal display can be greatly reduced due to the reduction in the number of components.

Conventional CCFLs have a current difference when they are connected in parallel, and a lamp with relatively low resistance is applied to all the lamps so that only a few lamps are driven and the others do not turn on.

However, the EEFL adopts an external electrode and applies a high voltage between the two electrodes to generate plasma and emit light by an electric field so that the external electrode acts as a capacitor to control the generation of current difference, thereby enabling parallel operation. It has less merit than CCFL, so it has long life expectancy.

On the other hand, as shown in Figure 1, in the conventional medium / small model (32 inches or less), whether the CCFL or EEFL supply voltage to only one side and the other side is enough to drive the lamp in a grounded 'High-Low' method Could. 1 is a view for explaining a method of driving a backlight assembly employing a conventional external electrode fluorescent lamp.

However, in large models (32 inches or more), if the lamp is lengthened and voltage is applied only on one side, it may not be possible to apply enough voltage to turn on the entire lamp, which may result in poor lighting.

In order to solve this problem, as shown in FIG. 2, in a large model, an inverter is installed at both ends of the lamp, and a high voltage is applied to the lamp by dividing a high voltage. You can solve the problem. 2 is a view for explaining another driving method of a backlight assembly employing a conventional external electrode fluorescent lamp. At this time, one side is to apply the voltage of the waveform having a normal phase, the other side is to apply a voltage having a waveform of the reverse phase.

Meanwhile, various studies have been conducted on a backlight assembly and a driving method thereof capable of reducing the number of lamps and reducing driving voltage while providing the same brightness.

It is an object of the present invention to provide a backlight assembly and a method of driving the same, which can reduce the number of lamps and reduce the driving voltage while providing the same brightness.

In order to achieve the above object, the backlight assembly includes a plurality of external electrode fluorescent lamps manufactured in a U shape and arranged side by side; A first inverter for applying power in parallel to odd-numbered electrodes of the U-shaped external electrode fluorescent lamp; A second inverter for applying power in parallel to even-numbered electrodes of the U-shaped external electrode fluorescent lamp; Its features are to include.

In addition, the backlight assembly driving method according to the present invention in order to achieve the above object, a plurality of external electrode fluorescent lamps manufactured in a U-shape and arranged side by side; A first inverter for applying power in parallel to odd-numbered electrodes of the U-shaped external electrode fluorescent lamp; A second inverter for applying power in parallel to even-numbered electrodes of the U-shaped external electrode fluorescent lamp; In the backlight assembly comprising a,

The voltage applied from the first inverter and the voltage applied from the second inverter are equal in magnitude to each other, and a phase is applied to each electrode so that the phase is 180 degrees apart.

In addition, the backlight assembly according to the present invention in order to achieve the above object, a plurality of external electrode fluorescent lamps manufactured in a U-shape and arranged side by side; A first inverter configured to apply power in parallel to the straight tube electrode of the U-shaped external electrode fluorescent lamp; A second inverter for applying power in parallel to the bending part electrode of the U-shaped external electrode fluorescent lamp; Its features are to include.

In addition, the backlight assembly driving method according to the present invention in order to achieve the above object, a plurality of external electrode fluorescent lamps are manufactured in a U-shape and arranged side by side; A first inverter configured to apply power in parallel to the straight tube electrode of the U-shaped external electrode fluorescent lamp; A second inverter for applying power in parallel to the bending part electrode of the U-shaped external electrode fluorescent lamp; In the backlight assembly comprising a,

The voltage applied from the first inverter is 1/2 of the magnitude of the voltage applied from the second inverter, and the characteristic is that the voltage is applied to each electrode so that the phase is 180 degrees apart.                     

According to the present invention as described above, while providing the same brightness, there is an advantage that can reduce the number of lamps and reduce the driving voltage.

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

The present invention proposes a method for constructing a backlight assembly using a U-shaped external electrode fluorescent lamp and efficiently driving the configured backlight assembly.

First, referring to FIG. 3, a driving method of a backlight assembly employing an external electrode fluorescent lamp according to the present invention applied to a medium / small model will be described.

In the medium / small size model, the conventional external type external electrode fluorescent lamp supplied the voltage in a 'high-low' manner. When the U-shaped external electrode fluorescent lamp is applied to the small and medium models, the inverter is installed at one end of the lamp, the A ₁ part of the first lamp 10_1 and the A ₂ part of the second lamp 10_2,. .., A _N of _N- th lamp 10_N is connected to first inverter 21, B ₁ part of first lamp 10_1 and B ₂ part of second lamp 10_2,. B _N of the N lamps 10_N are connected to the second inverters 22 in parallel, respectively.

Since the U-shaped lamp is about 30 inches in length, the unfolded length from A ₁ to B ₁ corresponds to a 55-inch straight lamp length, so that the first inverter 21 and the second inverter 22 are driven to drive the lamp. The high voltage should be applied.

This is the same concept as the 'High-High' method in which straight tube lamps apply high voltage at both ends of the lamp. In this case, when applying a voltage to the first inverter 21 and the second inverter 22, the waveform of the positive phase to the first inverter 21, and the waveform of the antiphase to the second inverter 22 must be applied. Should apply voltage. Of course, a voltage having a waveform of reverse phase may be applied to the first inverter 21 and a voltage having a waveform of positive phase may be applied to the second inverter 22. However, if the voltage of the in-phase waveform is applied at both ends, the voltages cancel each other out.

Currently, the external electrode fluorescent lamp adopts an opaque electrode (Tube + Dipping type, Dipping type), and is mainly applied to a backlight assembly of 30 inches or less. In the case of small and small liquid crystal display devices, it is possible to supply enough voltage for driving the lamp without difficulty, and to ensure uniformity in the effective emission area, and to achieve the same brightness as the CCFL. Can be.

Next, a case of applying to a large model will be described. The electrode length of an external electrode fluorescent lamp used for 30 inches or less will be described based on a case of applying the same to a large model of 30 inches or more.

In the case of external electrode fluorescent lamp used for 30-inch or larger liquid crystal display device, the electric field becomes longer, so if the voltage is applied only in one direction like the medium / small size, the lighting failure and the center part of the lamp do not light up due to the lack of power as in the case of a straight lamp. This may occur. It is possible to supply the required power by increasing the voltage applied to the lamp, but ozone may be generated due to the high voltage applied.

In order to solve this problem, as shown in FIG. 4, the straight portion A between the lamps is connected to the third inverter 41, and the U-shaped banding part B of the lamp is connected to the fourth inverter 42 in parallel. Install the power supply.

The straight portion A between the lamps applies a voltage of the same high voltage to each lamp in the third inverter 41. The U-shaped bending portion B of the lamp is supplied with a high voltage having a reverse phase waveform different from that of the portion (A) through a power supply. A ₁ = a ₂ = ,,,, = a _n is applied equally, and the voltage applied to b ₁ must be applied to be twice the voltage applied to a ₁ , that is, b ₁ = b _n = 2a _1. The same voltage is applied across the lamp.

In this way, a U-shaped lamp is used to construct a backlight assembly corresponding to a large model, and drive the configured backlight assembly to supply a voltage at an appropriate input voltage level required for the straight lamp of the large model, thereby achieving high brightness. It becomes possible.

As described above, the backlight assembly and the driving method thereof according to the present invention have the advantage of reducing the number of lamps and reducing the driving voltage while providing the same brightness.

Claims (8)

delete delete delete delete A plurality of external electrode fluorescent lamps manufactured in a U shape and arranged side by side; A first inverter configured to apply power in parallel to the straight tube electrode of the U-shaped external electrode fluorescent lamp; A second inverter for applying power in parallel to the bending part electrode of the U-shaped external electrode fluorescent lamp, The magnitude of the voltage applied from the first inverter is 1/2 of the magnitude of the voltage applied from the second inverter. delete The method of claim 5, The phase of the voltage applied from the first inverter and the phase of the voltage applied from the second inverter, the backlight assembly, characterized in that there is a difference of 180 degrees. A plurality of external electrode fluorescent lamps manufactured in a U shape and arranged side by side; A first inverter configured to apply power in parallel to the straight tube electrode of the U-shaped external electrode fluorescent lamp; A second inverter for applying power in parallel to the bending part electrode of the U-shaped external electrode fluorescent lamp; In the driving method of the backlight assembly comprising a, The voltage applied from the first inverter is 1/2 of the magnitude of the voltage applied from the second inverter, the phase of the backlight assembly driving method characterized in that the voltage is applied to each electrode to be 180 degrees apart.

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