KR100497956B1 - Double-face liquid crystal display - Google Patents

Abstract

The present invention relates to a double-sided liquid crystal display, and more particularly, the double-sided liquid crystal display of the present invention is disposed between one photoconductive substrate, two liquid crystal display modules, and two exit surfaces of the liquid crystal module and the photoconductive substrate, respectively. It has two scattering films.

A plurality of recesses are formed and distributed in one of the two exit surfaces. Light rays enter the photoconductive substrate at the incidence surface, are reflected and refracted by the recesses, and exit from the two exit surfaces of the photoconductive substrate. The light source is evenly projected onto the liquid crystal display module by scattering film diffusing light rays emitted from the exit surface.

Description

Duplex Liquid Crystal Display {DOUBLE-FACE LIQUID CRYSTAL DISPLAY}

FIELD OF THE INVENTION The present invention relates to double sided liquid crystal displays, and more particularly to one photoconductive substrate having two outgoing faces to provide the necessary light rays for the two liquid crystal display modules.

Figure 4 shows a conventional double sided liquid crystal display in which the display has two thin layered light emitting cells 71, 72 which provide the necessary light for the two liquid crystal modules 73, 74.

By the above method, the cover substrate or other electronic products of the mobile phone may have two liquid crystal display panels on both the inner surface and the outer surface.

The liquid crystal display panels on the inner surface and the outer surface of the cover substrate have the same size. This structure requires two light emitting cells 71 and 72 having the same size as the liquid crystal display panel.

Therefore, the price of the double-sided liquid crystal display was very high. In addition, the light emitting cells 71 and 72 have a problem of causing vibration and noise.

In order to lower the cost, two photoconductive substrates may be used instead of the light emitting cells 71 and 72. However, in this case, since the liquid crystal display is thickened, it is not suitable to be applied to the liquid crystal display used for the cover substrate of a mobile phone or a personal digital assistant (PDA). In addition, the light emitting cells 71 and 72 and the photoconductive substrate both have power consumption problems.

5 shows another embodiment of a conventional double-sided liquid crystal display, in which two reflective substrates 82 and 83 are disposed on different sides of the front and rear portions of the photoconductive substrate 81, respectively.

The other sides of the photoconductive substrate 81 opposite the reflective substrates 82 and 83 are provided in two liquid crystal display modules 84 and 85, respectively. Two light sources 86 are provided at both ends of the photoconductive substrate 81. Light rays emitted from the light source 86 to the photoconductive substrate 81 are reflected by the reflective substrates 82 and 83 to provide the necessary light emission to the liquid crystal display modules 84 and 85.

In the above structure only one photoconductive substrate is used to reduce the manufacturing cost. However, in order to provide light to the liquid crystal display modules 84 and 85, the reflective substrates 82 and 83 are disposed on different surfaces of the front and rear portions of the photoconductive substrate 81, respectively. Thus, the liquid crystal display modules 84 and 85 do not stick together and do not overlap. Therefore, the liquid crystal display modules 84 and 85 cannot be arranged in the same position, thereby making the volume of the double-sided liquid crystal display larger. In order to reduce the overall size, the area of the liquid crystal display modules 84 and 85 must be reduced. This reduces the number of lines of characters displayed.

Therefore, there is a need to provide an improved double-sided liquid crystal display that eliminates the above problem.

A first object of the present invention is to provide a double-sided liquid crystal display in which a plurality of recesses are formed and distributed on one of the exit surfaces of the photoconductive substrate.

Light rays entering the photoconductive substrate at the incidence plane are reflected and refracted in the concave portions and exit from the two exit surfaces of the photoconductive substrate. And projected onto two liquid crystal display modules, respectively.

Thus, one photoconductive substrate provides the necessary light rays for the two liquid crystal display modules.

It is still another object of the present invention to provide the double-sided liquid crystal display provided with two scattering films respectively disposed between the liquid crystal modules and the two exit surfaces of the photoconductive substrate. The scattering film serves to diffuse light rays exiting from the exit surface so that light rays are uniformly projected on two liquid crystal display modules without generating mesh points.

A double-sided liquid crystal display according to the present invention for achieving the object as described above is provided with at least one light source, at least one incident surface adjacent to the light source and two parallel exit surfaces adjacent to the incident surface, the exit A photoconductive substrate having a plurality of concave portions formed on one of the surfaces thereof and distributed therein, and two liquid crystal display modules respectively provided on two emission surfaces of the photoconductive substrate.

As shown in FIGS. 1 to 3, the double-sided liquid crystal display of the present invention includes a plurality of light sources 10, a photoconductive substrate 1, and two liquid crystal display modules 2.

One side of the photoconductive substrate 1 adjacent to the light source 10 is the incident surface 11, and two parallel surfaces of the photoconductive substrate 1 adjacent to the incident surface 11 are formed of the first exit surface 12 and the first exit surface 12. It is a 2 exit surface 13.

A plurality of recesses 14 are formed and distributed in the second exit surface 13.

In the present invention, the recesses 14 are concave surfaces and the diameter of the recess 14 is less than 50 μm.

Two liquid crystal display modules 2 are disposed on the first emission surface 12 and the second emission surface 13 of the photoconductive substrate 1, respectively.

The scattering film 15 is disposed between the first and second emission surfaces 12 and 13 and each of the liquid crystal display modules 2.

Referring to FIG. 3, the light beam L emitted from the light source 10 is incident on the photoconductive substrate 1 at the incident surface 11, and a part of the light beam L is a concave portion of the second exit surface 13. 14) is projected on.

Since the recess 14 is concave, the reflected light beam L1 is reflected toward the first exit surface 12 and the refracted light beam L2 is refracted toward the second exit surface 13.

The light beam is projected back toward the concave portions 14 so that a part of the refracted ray L2 is reflected between the concave portions 14 and the scattering film 15 to further generate the reflected light and the refracted ray. The reflected light and the refracted light are eventually emitted from the first emission surface 12 or the second emission surface 13.

Some of the light rays L directed to the photoconductive substrate 1 are directly projected onto the first exit surface 12 or the second exit surface 13. Wherever the light beam L is projected to the first exit surface 12 or the second exit surface 13, the reflected light and the refracted light are generated.

The reflected light and the refracted light are continuously reflected and refracted between the photoconductive substrates 1 so that the light rays of the photoconductive substrate 1 become more uniform even if they are not focused on the entire surface. As a result, the reflected light and the refracted light are emitted from the first emission surface 12 or the second emission surface 13.

When the light rays are emitted from the first emission surface 12 or the second emission surface 13, the light rays are formed by the scattering film 15 between the emission surfaces 12 and 13 and the liquid crystal display module 2. Diffuse toward 2).

Thus, the liquid crystal display modules 2 all have the same backlight.

In the double-sided liquid crystal display of the present invention, the light beams are both reflected for exiting the first exit surface 12 and the second exit surface 13 of the photoconductor substrate 1.

Therefore, when applied to a mobile phone or other electronic products, two liquid crystal display panels of the same size may be formed on the inner surface and the outer surface of the cover substrate at the same position.

In addition, since only one photoconductive substrate is used in the present invention, the cost is lower, power consumption is reduced, and the overall thickness of the liquid crystal display is not increased.

In other words, the concave portions 14 distributed on the second emission surface 13 of the photoconductive substrate 1 come from the incidence surface 11 toward the first emission surface 12 and the second emission surface 13. Reflect and refract In turn, the light rays exit the two liquid crystal display modules 2 at the first exit surface 12 and the second exit surface 13. Thus, one photoconductive substrate can provide the necessary light rays for the two liquid crystal display modules. In addition, the scattering film 15 disposed between the first and second exit surfaces 12 and 13 and the liquid crystal display module 2 diffuses light rays exiting from the first exit surface 12 and the second exit surface 13. Let's do it. Thus, no mesh point is generated and light rays are uniformly projected onto the liquid crystal display module 2.

The above embodiments are intended to explain the technical idea of the present invention and do not limit the technical scope of the present invention, and many modifications of the above embodiments can be made without departing from the gist of the present invention.

For example, the concave portion may be embodied in a conical or trapezoid structure which can achieve the same effect as the above embodiment.

As described above, when the double-sided liquid crystal display according to the present invention is applied to a mobile phone or other electronic products, two liquid crystal display panels of the same size may be formed on the inner surface and the outer surface of the cover substrate at the same position, The substrate provides the necessary light rays for the two liquid crystal display modules, resulting in lower cost and lower power consumption without increasing the overall thickness of the liquid crystal display.

In addition, in the present invention, the light beam is uniformly projected onto the liquid crystal display module without generating mesh points.

1 is a cross-sectional view showing a structure of the present invention,

2 is a structural diagram of a photoconductive substrate having a plurality of recesses according to the present invention;

3 is an enlarged view of a plurality of recesses provided in the photoconductive substrate of the present invention showing the reflection, refraction and diffusion of light,

4 is a structural diagram of a conventional double-sided liquid crystal display,

5 is a structural diagram of another form of a conventional double-sided liquid crystal display.

<Description of the code | symbol about the principal part of drawing>

1: photoconductive substrate 10: light source

11: entrance plane 12: first exit plane

13: 2nd exit surface 14: recessed part

15: scattering film 2: liquid crystal display module

Claims (2)

At least one light source 10; A photoconductive substrate (1) having an incident surface (11) adjacent to said light source (10) and two parallel emitting surfaces (12, 13) adjacent to said incident surface (11); In the two-sided liquid crystal display consisting of; two liquid crystal display modules (2) provided on the two exit surfaces (12, 13) of the photoconductive substrate (1), A plurality of recesses 14 are formed and distributed on one of the emission surfaces 12 and 13 of the photoconductive substrate 1, And two scattering films (15) between the two exit surfaces (12,13) of the photoconductive substrate (1) and the two liquid crystal display modules (2). delete