JPH02251882A - Cold cathode-ray tube backlighting device - Google Patents

Abstract

PURPOSE:To obtain uniform brightness and chromaticity between devices by using diffusion plates which have transmissivity set so that the highest brightness is obtained within a range wherein there is no brightness variance and are set to the chromaticity, etc., matching the mean chromaticity of chromaticity variance between respective cold cathode-ray tube most. CONSTITUTION:The diffusion plates 4 and 5 as a diffusing means are provided on the front side of a lighting curtain 3 and a liquid crystal panel 6 which makes a display by interrupting or transmitting the light from the diffusion plate 5 having uniform brightness is provided on the front side of the diffusion plate 5. Further, the diffusion plate 4 uses a diffusion plate which has its transmissitivity so that the highest brightness is obtained within the range wherein there is no brightness variance on the surface and is set to the chromaticity matching the mean chromaticity as the mean value of the chromaticity variance between the cold cathode-ray tubes 2 most. Consequently, no variance in brightness and chromaticity between mass-manufactured devices is realized.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a cold cathode tube backlight device used in liquid crystal displays and the like.

[Conventional technology]

In general, cold cathode tube backlight devices are classified into direct type and edge light type depending on where the cold cathode tubes serving as the backlight are arranged.

In the direct type, cold cathode tubes 12 are interposed between a lighting curtain 13 and a reflecting plate 11, as shown in FIG. The reflecting plate 11 is configured to reflect the light emitted by the cold cathode tubes 12 toward the lighting curtain 13 . In addition, the above lighting curtain 1
A diffuser plate 14 is provided on the front side of 3 and supported by a reflector plate 11. Furthermore, a liquid crystal panel 15, for example, is provided on the front side of the diffuser plate 14.

When the cold cathode tube 12 emits light, the second light is reflected by the reflecting plate 11 toward the lighting curtain 13, so that uniform brightness can be obtained on the surface of the lighting curtain 13. It has become. Thereby, when the liquid crystal panel 15 is driven, characters, symbols, etc. having uniform brightness can be visually recognized on the surface of the liquid crystal panel 15.

Next, as shown in FIG. 3, the edge light type has a cold cathode tube 22 provided at one end of a light guide plate 23 that equalizes brightness. A reflector plate 21 is provided on the back surface of the light guide plate 23 to reflect the light emitted from the cold cathode tubes 22 toward the diffuser plate 24 . Further, a diffusion plate 24 is provided on the front surface of the light guide plate 23. Furthermore, the diffusion plate 24
For example, a liquid crystal panel 25 is provided on the front side.

When the cold cathode tube 22 emits light, this light passes through the light guide plate 23, and uniform brightness can be obtained on the surface of the light guide plate 23. Thereby, when the liquid crystal panel 25 is driven, characters, symbols, etc. having uniform brightness can be visually recognized on the surface of the liquid crystal panel 25.

Therefore, when the conventional cold cathode tube backlight device is assembled into, for example, a liquid crystal panel, the brightness on the surfaces of the diffusion plates 14 and 24 becomes uniform, making the display easy to see.

[Problem to be solved by the invention]

However, in the above-mentioned conventional cold cathode tube backlight device, the brightness on the surface of each reflecting plate 14, 24 is made uniform for each device, but when mass-produced, the brightness and chromaticity between each device are Regarding this, there are variations.

Therefore, an object of the present invention is to make the brightness and chromaticity uniform among mass-produced cold cathode tube backlight devices without variation.

[Means to solve the problem]

In order to solve the above-mentioned problems, a cold cathode tube backlight device according to the present invention includes a cold cathode tube serving as a backlight, and a brightness equalizing member that obtains uniform brightness on a surface using light emitted from the cold cathode tube. A diffusing means is provided on the front side of the brightness equalizing member, and a reflecting plate is provided on the back side of the brightness equalizing member for reflecting the light emitted from the cold cathode tube toward the diffusing means. In cold-cathode tube backlight devices, the above-mentioned diffusion means has a transmittance that provides the highest brightness within a range with no brightness variations on the surface, compared to the lowest brightness of the brightness variations among mass-produced cold-cathode tubes. and a diffuser plate set to a chromaticity that best matches the average chromaticity of the chromaticity variations among the cold cathode tubes above, and a diffuser plate that is set to a chromaticity that best matches the average chromaticity of the chromaticity variations among the above cold cathode tubes, and , and a diffuser plate with uniform brightness and chromaticity on each surface.

[For production]

According to the above configuration, the light emitted from the cold cathode tube is reflected by the reflection plate toward the diffusion means. Then, the brightness becomes uniform on the surface of the brightness equalizing member. At this time, the luminance uniformity member among the mass-produced devices has variations in luminance and chromaticity among the cold cathode tubes.

On the other hand, a diffusion plate is provided on the front side of the brightness uniformizing member, which is a diffusion means to deal with variations in brightness and chromaticity among the cold cathode tubes. Uniform brightness and chromaticity is obtained between light devices.

That is, the diffusion means is set to the lowest luminance of the luminance variation among mass-produced cold cathode tubes, and the transmittance that provides the highest luminance within a range with no luminance variation on the surface, and The diffuser plate has a chromaticity set to the most suitable chromaticity to the average chromaticity of the chromaticity variations. As a result, on the surface of this diffuser plate, the luminance and chromaticity have variations that deviate from the minimum luminance and average chromaticity.

Further, the diffusion means has a diffusion plate that makes the brightness and chromaticity uniform on each surface in response to each of the above-mentioned variations, thereby making the chromaticity and brightness between each cold cathode tube uniform. Variations become uniform.

〔Example〕

An embodiment of the present invention will be described below based on FIG.

The cold cathode tube backlight device according to this embodiment is a direct type, as shown in FIG. In this direct type, a cold cathode tube 2 serving as a backlight is interposed between a lighting curtain 3 serving as a brightness uniformizing member and a reflecting plate 1.

The reflecting plate 1 is configured to reflect the light emitted by the cold cathode tubes 2 toward the lighting curtain 3.

Further, the above-mentioned lighting curtain 3 is supported by a reflection plate 1. The lighting curtain 3 is formed by, for example, depositing aluminum on a polyester film while patterning it in order to make the brightness uniform.

On the front side of the lighting curtain 3, diffusion plates 4 and 5 serving as diffusion means are provided in this order. Further, on the front side of the above-mentioned diffuser plate 5, a diffuser plate 5 having uniform brightness is provided.
A liquid crystal panel 6 is provided which performs display by blocking or transmitting light from the screen.

Among the above-mentioned diffusion plates 4 and 5, the diffusion plate 4 on the lighting curtain 3 side has luminance variations (3000 cd/m" to 6000 cd/m") between the mass-produced cold cathode tubes 2.
It has a transmittance that provides the highest brightness within a range that does not cause brightness variations on the surface with respect to the lowest brightness among, and
The chromaticity that best matches the average chromaticity, which is the average value of the chromaticity variations among the cold cathode tubes 2, is used.

On the other hand, the diffusion plate 5 provided on the front side of the diffusion plate 4 suppresses variations in brightness and chromaticity that deviate from the minimum brightness and average chromaticity between each cold cathode tube 2, and The transmittance and chromaticity set above are used to provide uniform brightness and chromaticity.

In the above configuration, when the cold cathode tube 2 starts emitting light,
The light from the cold cathode tubes 2 is reflected by the reflecting plate 1 toward the lighting curtain 3. This light passes through the lighting curtain 3 and the diffusion plates 4 and 5 (.

At this time, the surface of the diffuser plate 4 has brightness and chromaticity that are different from the lowest brightness and average chromaticity among the mass-produced cold cathode tubes 2. On the other hand, on the surface of the diffuser plate 5, since the diffuser plate 5 has transmittance and chromaticity set to suppress the above-mentioned variations in luminance and chromaticity, there is a difference between each diffuser plate 5. It will have no uniform brightness and chromaticity.

〔Effect of the invention〕

As described above, the cold cathode tube backlight device according to the present invention includes a cold cathode tube serving as a backlight and a brightness equalizing member that obtains uniform brightness on a surface using light emitted from the cold cathode tube. However, a diffuser is provided on the front side of the brightness equalizing member, and a reflecting plate is provided on the back side of the brightness equalizing member to reflect the light emitted from the cold cathode tube toward the diffuser. In the cathode tube backlight device, the above-mentioned diffusion means is set to a transmittance that provides the highest brightness within a range without brightness variations on the surface, with respect to the lowest brightness of the brightness variations among mass-produced cold cathode tubes. , and a diffuser plate set to a chromaticity that best matches the average chromaticity of the chromaticity variations among the above cold cathode tubes, and This configuration includes a diffuser plate that has uniform brightness and chromaticity across the top.

As a result, it is possible to obtain uniform brightness and chromaticity without variation among mass-produced cold cathode tube backlight devices.

[Brief explanation of drawings]

FIG. 1 shows an embodiment of the present invention, in which a schematic configuration diagram of a cold cathode tube backlight device is shown, FIGS. 2 and 3 show a conventional example, and FIG. 2 shows a direct type cold cathode backlight device. FIG. 3 is a schematic diagram of an edge light type cold cathode tube backlight device. 1 is a reflecting plate, 2 is a cold cathode tube, 3 is a lighting curtain (luminance equalizing member), and 4 and 5 are diffuser plates (diffusion means).

Claims (1)

[Claims] 1. It has a cold cathode tube serving as a backlight and a brightness equalizing member that obtains uniform brightness on a surface by the light emitted from the cold cathode tube, and the front surface of this brightness equalizing member In a cold cathode tube backlight device, a diffusion means is provided on the side, and a reflector plate is provided on the back side of the brightness equalization member to reflect the light emitted from the cold cathode tube toward the diffusion means. The diffusion means is set at a transmittance that provides the highest brightness within a range with no brightness variation on the surface, with respect to the lowest brightness of the brightness variation among mass-produced cold cathode tubes, and The diffuser plate is set to the chromaticity that best matches the average chromaticity of the chromaticity variation, and the luminance variation described above,
and a diffuser plate that makes brightness and chromaticity uniform on each surface in response to variations in chromaticity.