KR100551442B1 - Reflective LCD Module - Google Patents

Abstract

The present invention relates to a reflective LCD module, the light assembly is installed along the side of the reflective LCD panel to irradiate light in the direction of the reflective LCD panel, so that a separate light guide member is not provided to face the reflective LCD panel. Therefore, the weight of the product is reduced and the efficiency of light reflected from the reflective LCD panel is improved.

Description

Reflective LCD Module

The present invention relates to a reflective LCD module, and more particularly, to a reflective LCD module, in which a front light assembly is installed along an end of the reflective LCD panel to directly irradiate light to the reflective LCD panel to increase light efficiency. It is about.

In general, the liquid crystal display device is classified into a transmissive liquid crystal display device and a reflective liquid crystal display field depending on the light source.

In the transmissive liquid crystal display, a backlight assembly positioned at the rear of the LCD panel is configured to display data by projecting light onto the LCD panel.

The reflective liquid crystal display device can display data using only an external light source without a backlight assembly. However, in a dark place without external light sources, data cannot be viewed due to the characteristics of the reflective LCD.

To solve this problem, a front light assembly for an external light source is installed in front of the reflective LCD panel.

As the front light assembly is installed on the front of the reflective LCD panel, when the reflective liquid crystal display is used in a dark place, the front light assembly is driven to serve as an external light source.

However, since the light guide plate, which is one of the components of the front light assembly, is disposed opposite to the reflective LCD panel, the light guided by the light guide plate is reflected from the reflective LCD panel and passes through the light guide plate, thereby lowering light efficiency.

In addition, there is a problem in that the overall weight of the product increases due to the light guide plate having a predetermined thickness opposed to the reflective LCD panel.

Therefore, an object of the present invention is to improve the light efficiency and to reduce the weight of the product.

Other objects of the present invention will become more apparent from the following detailed description and the accompanying drawings.

In order to achieve the above object, the present invention provides a case and a space for accommodating a reflective LCD panel, a predetermined space is formed along an edge of the reflective LCD panel, and a gap is formed in communication with the surface of the reflective LCD panel. And a light assembly for irradiating light to the surface of the reflective LCD panel through the gap.

At this time, the case covers the upper part of the space by combining the lower case and the lower case in which the rib covering the lower part of the space is integrally upwardly bent over the entire side and the sidewalls accommodating the reflective LCD panel are integrally protruded from the rib. It may be made of an upper case formed with a pressing portion facing the surface edge of the LCD panel, the pressing portion may be an elastic member.

The front light assembly may also consist of a lamp, such as an LED, and first optical fibers whose ends are installed close to the lamp, wherein the first optical fibers are wrapped by a second optical fiber, wherein the second optical fibers are spaced apart from each other by a predetermined distance. It can be spaced apart, and the ends of these optical fibers can be held by a holder.

A reflective film may be formed on the inner surface of the case.

Hereinafter, the reflective LCD module according to an embodiment of the present disclosure will be described in detail with reference to the accompanying drawings.

1 to 3, the reflective LCD module 10 accommodates the reflective LCD panel 12, the reflective LCD panel 12, which displays data, and along the edge of the reflective LCD panel 12. The case 14 is formed in a predetermined space and a gap is formed in communication with the space along the surface of the reflective LCD panel 12, and is installed in the space to irradiate light to the surface of the reflective LCD panel 12 through the gap. The front light assembly 16 is made to include.

At this time, the light reflection on the inner surface of the case 14 facing the space in which the light assembly 16 is accommodated to prevent the light from the light assembly 16 from being lost, as shown in FIG. 2 or 3. Reflective film 22 is formed.

The case 14 is composed of an upper case 18 and a lower case 20 coupled to the upper case 18.

The lower case 20 has ribs covering the lower part of the space integrally bent upwardly over the entire side to cover the outer part of the space, and an accommodating part accommodating the reflective LCD panel 12 inside the lower case 20 ( 24 is formed, and the side walls 25 forming the accommodating portion 24 protrude integrally from the rib to cover the inner portion of the space.

The upper case 18 covering the upper portion of the space has a pressing portion 26 formed in a lower surface area respectively facing the surface edges of the reflective LCD panel 12 in a diagonal direction.

The pressing unit 26 forms a predetermined gap for light irradiation between the upper surface of the reflective LCD panel 12 and the lower surface of the upper case 18 and simultaneously fixes the reflective LCD panel 12.

At this time, the pressing unit 26 is preferably made of an elastic member such as rubber to prevent cracking of the reflective LCD panel 12.

The light assembly 16 includes lamps 28 disposed adjacent to the mutually opposite outer edge regions of the reflective LCD panel 12 in a diagonal direction, and an optical fiber having an end extending along the space near the lamp 28. Field 30.

Here, the optical fibers 30 cross the optical fibers 32 while covering the outer circumferential surface of the plurality of optical fibers 32 and the optical fibers 32 installed along the side of the reflective LCD panel 12. )

As the optical fibers 32 and the optical fiber 34 are installed in this way, the light leaked from the optical fibers 32 and the light leaked from the optical fiber 34 collide in the region where the optical fibers 32 and the optical fiber 34 cross. As a result, diffuse reflection occurs and luminance is improved. At this time, the optical fibers 34 are preferably spaced apart from each other for a better brightness improvement.

In addition, a holder 36 for holding the optical fibers 30 to improve the fixing force of the optical fiber 30 is installed at the end of the optical fibers 30 adjacent to the lamp 28, the lamp 28 has a long life LED (Light Emitting Diode; LED) is used.

Here, look at the operation of the light assembly in more detail as follows.

First, light is emitted from the lamp 28 and reflected along the inside of the optical fibers 30 through the ends of the optical fibers 30.

Looking more closely at this, one end of the optical fibers 30 is composed of a high refractive index core (not shown) and a low refractive index clad (not shown) surrounding the outer circumferential surface of the core. Incident through them. Then, due to the repetition of total reflection at the interface between the core and the clad, light is confined in the core and propagates to the other ends of the optical fibers 30.

At this time, the light propagating along the optical fibers 30 does not generally achieve total reflection, but leaks a predetermined amount through the clad to come out.

The light leaked from the optical fibers 32 and the optical fibers 34 is again scattered at the intersections, whereby the brightness of the light is further improved.

The light generated through this process irradiates the entire surface of the reflective LCD panel 12 through a gap generated between the upper case 18 and the reflective LCD panel 12.

Of course, the light irradiated in the opposite direction of the gap is reflected by the reflective film 22 and irradiated again toward the reflective LCD panel 12.

As described above, the light efficiency of the light assembly is decreased by the light emitted from the reflective LCD panel and then reflected again through the light guide plate. However, in the present invention, the light of the light assembly is directly irradiated toward the reflective LCD panel, and then a separate light such as the light guide plate Since the light is reflected from the reflective LCD panel without passing through the guide member, the light efficiency is improved.

In addition, in the related art, a light guide member such as a light guide plate is installed to face the front of the LCD panel, thereby increasing the weight of the product. The weight of the is lowered.

In addition, by installing the light assembly on the side of the reflective LCD panel, the thickness of the reflective LCD module is reduced.

Of course, in the present invention, the light is irradiated to the front of the reflective LCD panel using a lamp such as an LED (LED) and the optical fiber, but by installing lamps such as a cold cathode tube along the edge of the reflective LCD panel, the light is You can also do a front survey.

As such, various types of lamps may be applied to the lamp of the light assembly.

Such light assemblies are generally applied to small panels, such as 5.8 inches, but may also be applied to larger panels by adjusting the brightness and uniformity of the light by appropriately adjusting the number of crossings and the number of intersections of the optical fibers.

In addition, it is preferable to apply the light assembly in consideration of various variables such as the intensity of light according to the size change of the panel.

In addition, although two lamps are used in the present embodiment, lamps may be installed in the outer region of each corner of the reflective LCD panel in another modification, and the pressing parts are formed in pairs, but this is also reflected to form two pairs. The pressing portion may be formed in the upper case so as to face each of the upper edge portions of the LCD panel.

As described above, in the present invention, the light assembly is installed along the side of the reflective LCD panel to irradiate light toward the reflective LCD panel, so that a separate optical guide member is not provided to face the reflective LCD panel. At the same time as the weight of the product is reduced, the efficiency of the light reflected from the reflective LCD panel is improved.

1 is an exploded perspective view showing a reflective LCD module according to an embodiment of the present invention.

FIG. 2 is a cross-sectional view illustrating II-II of FIG. 1. FIG.

3 is a cross-sectional view illustrating III-III of FIG. 1.

Claims (8)

Reflective LCD panels; A case accommodating the reflective LCD panel, a predetermined space is formed along an edge of the reflective LCD panel, and a gap is formed in communication with the space and the surface of the reflective LCD panel; And a light assembly installed in the space and irradiating light to the surface of the reflective LCD panel through the gap. The method of claim 1, wherein the case A rib covering the lower part of the space is integrally bent upwardly over the entire side to cover the outer portion of the space, and the lower sidewalls accommodating the reflective LCD panel protrude integrally from the rib to cover the inner part of the space. case; And Reflective LCD module comprising an upper case is coupled to the lower case to cover the upper portion of the space, the pressing portion is formed to face the surface edge of the reflective LCD panel to form the gap. The reflective LCD module of claim 2, wherein the pressing unit is an elastic member. The method of claim 1, wherein the light assembly is At least one lamp for generating light; And Reflective LCD module, characterized in that the end is installed in close proximity to the lamp, the first optical fibers extending along the space to surround the reflective LCD panel. The reflective LCD module of claim 4, wherein the light assembly further comprises a second optical fiber that crosses the first optical fibers while surrounding the outer circumferential surface of the first optical fibers. The reflective LCD module of claim 4, wherein the ends of the first optical fibers are fixed by a holder. The reflective LCD module of claim 4, wherein the lamp is a light emitting diode (LED). The reflective LCD module of claim 1, wherein a reflective film is formed on an inner surface of the case facing the space.