KR20070070745A - Back light unit - Google Patents

Abstract

A back light unit is provided to improve the quality of moving pictures of a liquid crystal display by increasing the effect of scanning driving without lowering the uniformity of brightness by installing reflectors for minimizing light interference between light sources. A plurality of light sources(L1-Ln) are lighted sequentially. A case(101) contains the plurality of light sources. A plurality of reflectors(102) have first planes facing a first light source which is lighted in the first place, wherein the first planes are inclined to a bottom of the case, and have second planes facing a second light source which is lighted next to the first light source, wherein the second planes are vertical to the bottom of the case. The light sources are arranged between the reflectors. The reflectors are protruded from the bottom of the case.

Description

Back Light Unit

1A to 1C show scanning driving of a conventional backlight unit.

FIG. 2 is a diagram illustrating a timing at which lamps illustrated in FIGS. 1A to 1C sequentially flash.

3A and 3B show interference of light between adjacent lamps of the lamps shown in FIGS. 1A-1C.

4 shows a backlight unit according to a first embodiment of the present invention;

FIG. 5 shows another structure of the reflector shown in FIG. 4; FIG.

FIG. 6 shows elements associated with the formation of the reflector shown in FIGS. 4 and 5.

7 illustrates a backlight unit according to a second embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

101: case 102, 202: reflector

103: light diffusing member 104: reflecting plate

L1 to Ln: lamp

The present invention relates to a backlight unit, and more particularly, to a backlight unit capable of improving video quality of a liquid crystal display device.

The LCD displays an image by adjusting the light transmittance of the liquid crystal cells according to an electrical signal. Since the liquid crystal display device is not a display device using a self-light emitting device, a separate light source device such as a back light unit is required.

Recently, in order to reduce motion blurring that an observer feels due to the retention characteristics of liquid crystals when displaying a video through a liquid crystal display device, the light source of the backlight unit blinks sequentially along the scanning direction of the display line. Driving technology is applied to liquid crystal display devices.

1A to 1C illustrate scanning driving of the backlight unit. In the backlight unit including the sixteen lamps L1 to L16, eight neighboring lamps are used as one block. A scanning drive for sequentially flashing B1 to B8) is shown. In this scanning drive, each of the blocks B1 to B8 has a predetermined duty ratio for one frame period and blinks sequentially. For example, as shown in FIG. 2, each block has a 50% duty period for one frame period. In the case of sequentially blinking, the off time of the first block B1 and the on time of the second to fifth blocks B2 to B5 overlap each other. Such optical interference between adjacent blocks reduces the effect of the scanning driving to reduce the motion blur due to the retention characteristics of the liquid crystal by turning off the lamp in the region where the liquid crystal does not respond properly, which is the video quality of the liquid crystal display. Will lower. Meanwhile, in order to prevent optical interference between adjacent blocks, reducing the duty ratio of each block reduces the uniformity of luminance when scanning is performed so that the off time and the on time do not overlap between adjacent blocks. Will occur.

Accordingly, an object of the present invention is to provide a backlight unit capable of improving the moving image quality of a liquid crystal display by increasing the effect of scanning driving without lowering the uniformity of luminance.

In order to achieve the above object, a backlight unit according to an embodiment of the present invention includes a plurality of light sources sequentially turned on; A case accommodating the light sources; A first surface facing the first light source that is first turned on in the light sources is inclined with respect to the bottom surface of the case, and a second surface facing the second light source which is lit after the first light source is in the bottom surface of the case. A reflector perpendicular to the; The light source is disposed between the reflectors and the reflector protrudes from the bottom surface of the case.

A cross section of the reflector is a right angle having a cross section of the first surface as a hypotenuse, a cross section of the second surface as a vertical side, and a cross section of an imaginary flat surface that connects a bottom surface of the first surface to a bottom surface of the second surface as a base. It is formed to form a triangle.

And a flat reflecting surface connecting the lower end of the second surface of the first reflector and the lower end of the first surface of the second reflector.

The reflector further includes a flat surface connecting the lower end of the first surface and the lower end of the second surface, and the cross section of the reflector is a hypotenuse of the cross section of the first surface, and a cross section of the second surface. It is formed as a vertical side, and forms a right triangle with the cross section of the flat surface as the base side.

A reflecting plate is further provided on the bottom surface of the case, and the flat surface is attached to the reflecting plate.

The reflector further includes a flat reflecting surface connecting the upper end of the first surface and the upper end of the second surface, and a cross section of the reflector is a cross section of the first surface and the second surface, respectively, of the flat reflecting surface. The cross section is formed to have a trapezoid having an upper side, a cross section of an imaginary flat surface connecting the lower end of the first surface and the lower end of the second surface.

Other objects and advantages of the present invention in addition to the above object will become apparent from the description of the preferred embodiment of the present invention with reference to the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described with reference to FIGS. 3A to 7.

3A and 3B show a result of measuring light in front of the first lamp L1 flashing first and the sixteenth lamp L16 flashing last in the backlight unit described through the above example. Referring to FIG. 3A, the waveform of the light measured from the front surface of the sections in which the lamps L1 to L16 are turned on is ideally represented by a clean square wave like W1, but in the case of the first lamp L1. It has many inflection points due to the influence of the surrounding lamps and shows a triangular wave shape such as W2. On the other hand, like the first lamp L1, the sixteenth lamp L16 has a plurality of inflection points under the influence of surrounding lamps, but has a waveform similar to that of W3, which is closer to W1, an ideal waveform than the first lamp L1. Shows the result. This result disproves the fact that the interference from the pre-illumination lamp to the pre-illumination lamp has a greater effect than the interference from the pre-illumination lamp.

Accordingly, the backlight unit according to the first exemplary embodiment of the present invention has a plurality of light sources L1 to Ln sequentially lit as shown in FIG. 4, and a case 101 in which the light sources L1 to Ln are stored. And the first surface S1 facing the k-th light source Lk, which is first turned on among the light sources L1 to Ln, is inclined with respect to the bottom surface of the case 101 and is subsequently lit after the k-th light source Lk. The second surface S2 opposite to the k + 1 th light source Lk + 1 diffuses the reflector 102 perpendicular to the bottom surface of the case 101 and the light received from the light sources L1 to Ln. The light-diffusion member 103 is made to make.

The light sources L1 to Ln sequentially flash from the first light source L1 to the nth light source Ln. The light sources L1 to Ln may each include one or more lamps.

The light sources L1 to Ln are stored in the case 101. The light sources L1 to Ln are fixed to the case 101 through a plurality of fastening members formed in the case 101.

The light diffusing member 103 serves to evenly distribute the light received from the light sources L1 to Ln. The light diffusing member 103 is composed of a diffusion plate 121 and a diffusion sheet 122 and the like. The light diffusing member 103 is disposed such that the light receiving surface is parallel to the bottom surface of the case 101 with the light sources L1 to Ln interposed therebetween.

The reflector 102 faces the k-th light source Lk, which is first turned on among the light sources L1 to Ln, and is disposed on the first surface S1 and the k-th light source Lk that are inclined with respect to the bottom surface of the case 101. Subsequently, it has a second surface S2 facing the k + 1 light source Lk + 1 that is turned on and perpendicular to the bottom surface of the case 101. The reflector 102 has a cross section that connects the cross section of the first surface S1 to the hypotenuse, the cross section of the second surface S2 to the vertical side, and connects the bottom of the first surface S1 to the bottom of the second surface S2. It is formed to form a right triangle having a cross section of the virtual flat surface (S3) as the base, and has a shape protruding from the bottom surface of the case (102). The reflector 102 is disposed between the light sources L1 to Ln, and the second surface S2 of the reflector 102 disposed between the k-th light source Lk and the k + 1th light source Lk + 1. ) The bottom of the first surface S1 of the reflector 102 disposed between the bottom and the k + 1 th light source Lk + 1 and the k + 2 th light source Lk + 2 is parallel to the bottom surface of the case 101. It is connected to one flat reflective surface (S5). The second surface S2 of the reflector 102 directly blocks all or part of the light traveling from the k + 1th light source Lk + 1 toward the kth light source Lk. The first surface S1 adjusts the inclination angle in consideration of the reflected light according to the position of the k light source Lk and the first surface S1 to adjust the inclination angle of the k-1th light source Lk-1 of the kth light source Lk. Minimize interference.

As described above, the backlight unit according to the first embodiment of the present invention maintains the duty ratio of the light source as it is and uses the reflector 102 to block the light traveling from the back light source to the pre-light source. It is possible to reduce the interference of light from the backlit light source from the backlit light source without deterioration. At this time, the degree to which the reflector 102 can reduce the interference of the light from the back light source to the pre-light source, that is, the performance of the reflector 102 is the case that the first surface (S1) as shown in FIG. (101) the angle of inclination θ formed with the bottom surface, the distance a between the lower end of the first surface S1 and the lower end of the second surface S2, and the second surface S2 from the bottom surface of the case 101. Distance b to the upper end, distance h between the bottom surface of the case 101 and the light receiving surface of the light diffusing member 103, between the k-th light source Lk and the k + 1th light source Lk + 1 Is influenced by factors such as the distance m, the distance d from the bottom surface of the case 101 to the top of the light sources L1 to Ln, and the like. Therefore, in order to maximize the performance of the reflector 102, the optimum point must be determined through the simulation of the above elements combined within the range in which the above elements satisfy the following Equations 1 to 3 below.

Meanwhile, as illustrated in FIG. 5, the reflector 102 may be formed to have a flat surface S4 connecting the lower end of the first surface S1 and the lower end of the second surface S2. In this case, the cross section of the reflector 102 forms a right triangle with the hypotenuse of the cross section of the first surface S1, the cross section of the second surface S2 of the vertical side, and the cross section of the flat surface S4 of the cross section, and the case 102. ) It protrudes from the bottom surface. In this case, the backlight unit according to the first embodiment of the present invention further includes a reflecting plate 104 stacked on the bottom surface of the case 101, and the flat surface S4 of the reflector 102 is the reflecting plate 104. Is attached to.

7 shows a backlight unit according to a second embodiment of the present invention.

Referring to FIG. 7, the backlight unit according to the second embodiment of the present invention includes a plurality of light sources L1 to Ln sequentially lit, a case 101 in which the light sources L1 to Ln are accommodated, The bottom surface of the case 101 is opposed to the light diffusing member 103 for diffusing the light received from the light sources L1 to Ln and the k-th light source Lk which is first turned on among the light sources L1 to Ln. The first surface S1 inclined with respect to the second surface S2 opposite to the k + 1 light source Lk + 1 which is lit after the k-th light source Lk, and is perpendicular to the bottom surface of the case 101. ), A reflector 202 facing the light receiving surface of the light diffusing member 103 and including a flat reflecting surface S6 connecting the upper end of the first surface S1 and the upper end of the second surface S2.

The light sources L1 to Ln sequentially flash from the first light source L1 to the nth light source Ln. The light sources L1 to Ln may each include one or more lamps.

The light sources L1 to Ln are stored in the case 101. The light sources L1 to Ln are fixed to the case 101 through a plurality of fastening members formed on the case 101.

The light diffusing member 103 serves to evenly distribute the light received from the light sources L1 to Ln. The light diffusing member 103 is composed of a diffusion plate 121 and a diffusion sheet 122. The light diffusing member 103 is disposed such that the light receiving surface is parallel to the bottom surface of the case 101 with the light sources L1 to Ln interposed therebetween.

The reflector 202 faces the k-th light source Lk, which is first turned on among the light sources L1 to Ln, and is inclined with respect to the bottom surface of the case 101. Subsequently, the second surface S2, which is opposite to the k + 1 light source Lk + 1 that is turned on and is perpendicular to the bottom surface of the case 101, faces the light receiving surface of the light diffusing member 103, S1) has a flat reflective surface S6 connecting the upper end with the upper end of the second surface S2. The reflector 202 has a cross section of each of the first and second surfaces S1 and S2 with an angle, a cross section of the flat reflective surface S6 with an upper side, a bottom of the first surface S1 and a second surface ( S2) is formed to form a trapezoid having a cross section of the virtual flat surface S7 connecting the lower end to the lower side, and has a shape protruding from the bottom surface of the case 102. The reflector 202 is disposed between the light sources L1 to Ln, and the second surface S2 of the reflector 202 disposed between the k-th light source Lk and the k + 1th light source Lk + 1. The bottom of the first surface S1 of the reflector 202 disposed between the bottom and the k + 1 th light source Lk + 1 and the k + 2 th light source Lk + 2 is connected. The second surface S2 of the reflector 202 directly blocks all or part of the light traveling from the k + 1 th light source Lk + 1 toward the k th light source Lk. The first surface S1 adjusts the inclination angle in consideration of the reflected light according to the position of the k light source Lk and the first surface S1 to adjust the inclination angle of the k-1th light source Lk-1 of the kth light source Lk. Minimize interference.

As described above, the backlight unit according to the second embodiment of the present invention maintains the duty ratio of the light source as it is and lowers the luminance by blocking the light traveling from the back light source to the pre-light source using the reflector 202. It is possible to reduce the interference of light from the backlit light source from the backlit light source without. At this time, the factors affecting the performance of the reflector 202 should be determined through simulation as in the above description of the backlight unit according to the first embodiment of the present invention.

As described above, the backlight unit according to the present invention includes a reflector for minimizing interference of light between adjacent light sources between sequentially flashing light sources, thereby increasing the effect of scanning driving without deteriorating luminance uniformity. Can improve the video quality.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

Claims (6)

A plurality of light sources sequentially lit; A case accommodating the light sources; A first surface facing the first light source that is first turned on in the light sources is inclined with respect to the bottom surface of the case, and a second surface facing the second light source which is lit after the first light source is in the bottom surface of the case. A reflector perpendicular to the; The light source is disposed between the reflectors and the reflector is characterized in that the projecting from the bottom surface of the case. The method of claim 1, The cross section of the reflector, Formed to form a right triangle with a hypotenuse side of the cross section of the first side, a vertical side of the cross section of the second side, and a cross section of an imaginary flat surface connecting the lower side of the first side and the lower side of the second side as the base side. The backlight unit characterized by the above-mentioned. The method of claim 2, And a flat reflecting surface connecting the lower end of the second surface of the first reflector and the lower end of the first surface of the second reflector. The method of claim 1, The reflector, Further comprising a flat surface connecting the lower end of the first surface and the lower end of the second surface, The cross section of the reflector, And a cross section of the first surface as the hypotenuse, a cross section of the second surface as the vertical side, and a rectangular triangle having the cross section of the flat surface as the bottom side. The method of claim 4, wherein Further provided with a reflecting plate formed on the bottom surface of the case, And the flat surface is attached to the reflecting plate. The method of claim 1, The reflector is And a flat reflection surface connecting the upper end of the first surface and the upper end of the second surface, The cross section of the reflector, Cross sections of the first surface and the second surface are formed to form a trapezoid with a cross section of an imaginary flat surface connecting the upper side of the flat surface and the lower surface of the first surface and the lower surface of the second surface to the lower side of each of the flat surface. Back light unit, characterized in that.

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