JPH0734416Y2 - Backlight - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Application Field> The present invention relates to a backlight of a liquid crystal television or the like using a transmissive liquid crystal display as an image display element.

<Prior Art> A conventional backlight will be described with reference to FIG.

A liquid crystal television uses a transmissive liquid crystal display as an image display element, and a backlight is generally provided on the back side of the liquid crystal display.

The backlight used in LCD TVs is
It is attached to the back side of a transmissive liquid crystal display and irradiates the liquid crystal display with light. Its purpose is to improve the contrast of an image.

The backlight includes a light source 10 that emits a light source light L, a substrate 40 that is provided with a holder 41 that holds the light source 10, a diffuser plate 30 that diffuses the light source light L and irradiates a liquid crystal display from the backside. A light guide 20 for reflecting the light source light L to the diffuser plate 30 side is provided.

As the light source 10, a straight tube type cold cathode tube is generally used.
The light source 10 is held by a holder 41 and installed in the center of a light guide 20 described later.

The light guide 20 is formed of metal or synthetic resin in a substantially gutter shape, and its surface is subjected to aluminum vapor deposition or the like.

The diffuser plate 30 is a milky white filter that uses incident light as diffused light, and is attached so as to cover the light guide 20. The central portion of the diffusion plate 30, that is, the light source 10
A lens unit 31 is provided directly above. This lens part
Reference numeral 31 is provided in consideration of the fact that more light source light L is incident directly above the light source 10 than in other portions, and the light source light L incident on this lens portion 31 is refracted by the lens portion 31. Is diffused to other parts by.

<Problems to be Solved by the Invention> However, the above-described conventional backlight has the following problems.

That is, the brightness at any point on the diffuser plate 30 is
As the total of the direct light L ₁ emitted directly from the light source 10 and the indirect light L ₂ reflected by the light guide 20, the portion directly above the light source 10 (dots in the graph are shown in FIG. 5). (Indicated by 0) is higher than the surrounding brightness. This is a problem that cannot be solved completely even if the diffusion plate 30 is provided with the lens portion 31. Therefore, the image displayed on the liquid crystal display tends to have high brightness in the central portion. To solve this, it is conceivable to increase the diffusion effect by increasing the thickness of the diffusion plate 30, but this will increase the thickness of the backlight.

The present invention was devised in view of the above circumstances, and an object thereof is to provide a backlight that can be made thin and has uniform brightness.

<Means for Solving the Problems> A backlight according to a first aspect of the present invention is a backlight for irradiating uniform diffused light from the back side of a transmissive liquid crystal display, the light source emitting light source light, and the light source. A diffusion plate that diffuses light and illuminates the liquid crystal display from the back side,
A grooved transparent plate interposed between the diffusion plate and the light source, and a light guide for reflecting the light source light not directly incident on the grooved transparent plate to the grooved transparent plate side, The grooved transparent plate is provided with a groove only in a portion directly above the light source, and the groove refracts the incident light source light to the peripheral portion of the grooved transparent plate, and the diffusion plate is provided directly above the light source. A lens portion is formed to diffuse the light source light incident on the portion corresponding to the upper portion toward the peripheral portion.

A backlight according to a second invention is a backlight for irradiating a diffused light from a back side of a transmissive liquid crystal display, the light source emitting the light source and the liquid crystal display by diffusing the light source. A diffuser that irradiates from the side,
The Fresnel lens plate is provided between the diffuser plate and the light source, and the light guide that reflects the light source light that did not directly enter the Fresnel lens plate toward the Fresnel lens plate side. Has a Fresnel lens formed only in a portion corresponding to directly above the light source. The Fresnel lens refracts the incident light source light to the peripheral portion of the Fresnel lens plate, and the diffusion plate corresponds to immediately above the light source. A lens portion for diffusing the light source light incident on the portion to be diffused toward the peripheral portion is formed.

<Function> The light source light emitted by the light source is roughly divided into direct light that is directly incident on the grooved transparent plate and indirect light that is reflected by the light guide and is incident on the grooved transparent plate. The amount of light at any point is the total of direct light and indirect light. In this case, most of the light source light incident on the portion directly above the grooved transparent plate is direct light, which is significantly larger than the total of direct light and indirect light incident on the peripheral portion of the diffusion plate. However, since the groove is formed at the center of the grooved transparent plate, a part of the direct light incident on the center is refracted by the groove to the peripheral edge of the grooved transparent plate. Therefore, the brightness is made uniform in the central portion and the peripheral portion of the grooved transparent plate as compared with the case where there is no groove.

The light source light L transmitted through the grooved transparent plate is diffused by the diffusion plate, so that the brightness is further uniformized.

Therefore, in the image displayed on the liquid crystal display, the difference in brightness between the central portion and the peripheral portion is reduced.

The same applies when a Fresnel lens plate provided with a Fresnel lens is used.

<Embodiment> An embodiment according to the present invention will be described below with reference to the drawings.

FIG. 1 is a plan view and a sectional view of a backlight according to the first invention, and FIG. 2 is an enlarged sectional view of a portion shown in FIG.
FIG. 3 is an explanatory view for explaining the operation of the backlight, FIG. 4 is an enlarged sectional view of an essential part of the backlight according to the second invention, and FIG. 5 is a backlight according to the first and second inventions. It is a graph which shows the effect of. It should be noted that parts and the like that are substantially the same as the conventional ones will be given the same reference numerals for the description.

The backlight according to the first invention is a backlight that radiates uniform diffused light from the back side of a transmissive liquid crystal display 70, and includes a light source 10 that emits a light source light L and a light source that diffuses the light source light L. A diffuser plate 30 that illuminates the liquid crystal display from the back, a light guide 20 that reflects the light source light L that has not entered the diffuser plate 30 to the diffuser plate 30, the light source 10, and the diffuser plate.
And a grooved transparent plate 50 formed in a portion corresponding to the light source 10 and having a plurality of grooves 51 for refracting the incident light source light L.

As the light source 10, a straight tube type cold cathode tube is generally used.
As the light source 10, a light source having a peak in each of the R, G and B wavelength portions is used.

The light guide 20 is for reflecting the light source light L from the light source 10, and is formed by molding a metal or a synthetic resin into a substantially gutter shape,
Aluminum vapor deposition or the like is applied to the surface thereof. The light source 10 is held by a holder (not shown) at approximately the center of the bottom of the light guide 20. The shape of the light guide 20 is set so that all the incident light source light L is reflected and is incident on the grooved transparent plate 50 described later.

The grooved transparent plate 50 is attached so as to cover the opening of the light guide 20. This grooved transparent plate 50
Is formed of a transparent synthetic resin or glass, and the sawtooth-shaped groove 51 having a substantially saw-tooth cross section is provided only in the substantially central portion of the grooved transparent plate 50, that is, a portion corresponding to just above the light source 10. Are formed along the longitudinal direction.
The groove 51, so to speak, functions as a prism, and changes the traveling direction of the incident light source light L and emits it, that is, transmits it. In this case, the groove 51 is set so that the incident light source light L is emitted from the peripheral portion of the grooved transparent plate 50. The portion where the groove 51 is not formed is the incident light source light L.
Does not change the direction of travel.

The diffusion plate 30 is a milky white filter that diffuses the incident light source light L over the entire surface, and is mounted on the grooved transparent plate 50. It is attached on the diffusion plate 50. A lens portion having a substantially trapezoidal shape is provided at a substantially central portion of the diffuser plate 30, that is, a portion directly above the light source 10.
31 is formed. The lens portion 31 is formed to further diffuse the incident light source light L toward the peripheral portion.

Next, the operation of the backlight according to the first invention will be described with reference to FIG.

The light source light L emitted from the light source 10 is roughly classified into direct light L ₁ which is directly incident on the grooved transparent plate 50 and indirect light L ₂ which is reflected by the light guide 20 and is incident on the grooved transparent plate 50. The amount of light at any point on the grooved transparent plate 50 is the total of the direct light L ₁ and the indirect light L ₂ . In this case, most of the light source light L incident on the portion directly above the grooved transparent plate 50 is the direct light L ₁₁ , and the diffusion plate 30
It is significantly larger than the total of the direct light L ₁₂ and the indirect light L ₂ incident on the peripheral portion of. However, the groove 51 is formed in the center of the grooved transparent plate 50.
Therefore, a part of the direct light L ₁₁ incident on the central portion is refracted by the groove 51 toward the peripheral portion of the grooved transparent plate 50. Therefore, the brightness of the central portion and the peripheral portion of the grooved transparent plate 50 is made uniform as compared with the case where the groove 51 is not provided.

The light source light L that has passed through the grooved transparent plate 50 is diffused by the diffusion plate 50, so that the brightness is further uniformized.

Therefore, in the image displayed on the liquid crystal display 70, the difference in luminance between the central portion and the peripheral portion is reduced (see FIG. 5).

Next, the backlight according to the second invention will be described. The backlight according to the second aspect of the invention will be described only on the points different from the backlight according to the first aspect of the invention.

The backlight according to the second invention is different from the backlight according to the first invention in that the grooved transparent plate 50 is a Fresnel lens plate 60.

The Fresnel lens 61 is formed only in the central portion of the Fresnel lens plate 60, that is, the portion directly above the light source 10. A part of the light source light L that has entered the Fresnel lens 61 is refracted in the peripheral edge direction of the Fresnel lens plate 60, so that the same effect as the backlight according to the first invention is obtained.

The backlight according to the present invention is not limited to the backlight of a liquid crystal television, and can be used in other image display devices using a transmissive liquid crystal display, such as a word processor.

<Effect of the Invention> A backlight according to the present invention is a backlight that irradiates a diffused light uniformly from the back side of a transmissive liquid crystal display, and includes a light source that emits a light source and a liquid crystal that diffuses the light source. A diffuser plate for illuminating the display from the back side, a grooved transparent plate or Fresnel lens plate interposed between the diffuser plate and the light source, and a grooved light source light that did not directly enter the grooved transparent plate. The transparent plate or the Fresnel lens plate is provided with a light guide that reflects, and the grooved transparent plate or Fresnel lens plate is provided with a groove or Fresnel lens only in a portion directly above the light source. The groove or Fresnel lens refracts the incident light source light to the peripheral portion of the grooved transparent plate. Further, a lens portion is formed on the diffusion plate at a portion directly above the light source. Also because of this,
The diffused light emitted to the liquid crystal display can be made more uniform than that of a conventional backlight. Therefore, the image displayed on the liquid crystal display can be made clearer.

In addition, since a grooved transparent plate or a Fresnel lens plate is interposed between the liquid crystal display and the light source, it is possible to reduce adverse effects of heat of the light source on the liquid crystal display (for example, deterioration of liquid crystal due to heat). You can

Furthermore, since the grooved transparent plate or the Fresnel lens plate is plate-shaped, a certain space can be secured between the grooved transparent plate and the Fresnel lens plate. Further, because of this space, the heat of the light source is not trapped in the light guide, and the life of the light source is not adversely affected.

[Brief description of drawings]

FIG. 1 is a plan view and a sectional view of a backlight according to the first invention, and FIG. 2 is an enlarged sectional view of a portion shown in FIG.
FIG. 3 is an explanatory view for explaining the operation of the backlight, FIG. 4 is an enlarged sectional view of an essential part of the backlight according to the second invention, and FIG. 5 is a backlight according to the first and second inventions. FIG. 6 is a graph showing the effect of the above, and FIG. 6 is a schematic diagram showing the structure of a conventional backlight. 10 ... Light source, 20 ... Light guide, 30 ... Diffuser, 50 ...
… Transparent plate with groove, 51 …… Groove, 60 …… Fresnel lens plate, 61
...... Fresnel lens, 70 …… LCD display.

Claims (2)

[Scope of utility model registration request] 1. A backlight for irradiating uniform diffused light from the back side of a transmissive liquid crystal display, and a light source for emitting light source light, and a diffusion plate for diffusing the light source light and irradiating the liquid crystal display from the back side. A grooved transparent plate interposed between the diffuser plate and the light source, and a light guide for reflecting the light source light not directly incident on the grooved transparent plate to the grooved transparent plate side. In the grooved transparent plate, a groove is formed only in a portion directly above the light source, and the groove refracts incident light source light to the peripheral portion of the grooved transparent plate,
The backlight according to claim 1, wherein the diffusion plate is formed with a lens portion for diffusing the light source light incident on a portion directly above the light source in a peripheral direction. 2. A backlight for irradiating uniform diffused light from the back side of a transmissive liquid crystal display, and a light source for emitting light source light, and a diffusion plate for diffusing the light source light and irradiating the liquid crystal display from the back side. A Fresnel lens plate interposed between the diffuser plate and the light source, and a light guide for reflecting the light source light not directly incident on the Fresnel lens plate toward the Fresnel lens plate side. A Fresnel lens is formed on the lens plate only at a portion directly above the light source. The Fresnel lens refracts the incident light source light to the peripheral edge of the Fresnel lens plate, and the diffusion plate is directly above the light source. A backlight having a lens portion for diffusing the light source light incident on a portion corresponding to the above in a peripheral direction.