KR200326800Y1 - double-sided light emitting backlight module - Google Patents

Abstract

The present invention is provided between two liquid crystal display modules (21, 22) and includes a double-sided light emitting backlight including at least one light source 10, an illumination photoconductive substrate (1), at least one luminance-enhanced film (14, 15) It is about a module.

In other words, the P-light passes through the luminance-enhanced films 14 and 15, and the S-light is reflected by the luminance-enhanced films 14 and 15 and transformed into mixed light of P- and S-lights. Accordingly, the backlight module can prevent the lower polarizing plates 211 and 221 of the liquid crystal display module from absorbing S light among all light rays of the light source, thereby increasing the usage of the light source relatively and increasing the brightness of the liquid crystal display module. Let's do it.

Description

Double-sided light emitting backlight module

The present invention relates to a double-sided light emitting backlight module, and more particularly to a double-sided light emitting backlight module that can produce a double-sided light emission effect and to increase the brightness of the liquid crystal display module.

According to the prior art illustrated in FIG. 6, the conventional liquid crystal display module 3 includes a light source 30, a lower polarizing plate 11 ′, an upper polarizing plate 12 ′, and the lower polarizing plate 11 ′ and an upper polarizing plate 12 ′. It consists of a liquid crystal layer 13 'positioned between (). The light source 30 includes a P light 31 directed toward the P axis direction of the optical image and an S light 32 directed toward the S axis direction of the optical image, wherein the P light 31 is perpendicular to the S light 32. . In addition, the lower polarizing plate 11 ′ allows only the passage of the P light 31 and the upper polarizing plate 12 ′ only permits the passage of the S light 32. Therefore, after the light rays of the light source 30 pass through the lower polarizing plate 11 ′, the S light 32 included in the light source 30 is absorbed by the lower polarizing plate 11 ′, and the light source ( Only the P light 31 included in 30 passes through the lower polarizing plate 11 ′. After the P-light 31 passes through the liquid crystal layer 13 ', the P-light 31 is transformed into an S-light 32 that can pass through the upper polarizing plate 12', so that the optical of the light source 30 Only half of the optical strength is available for the liquid crystal display module 3.

According to the prior art illustrated in FIG. 7, the conventional double-sided light emitting backlight module 4 includes two light source substrates for supplying the light source 40 and the light source 40 to the two liquid crystal display modules 43 and 44. 41,42). The two illumination photoconductive substrates 41 and 42 have a first side surface having the light emitting surfaces 411 and 421 and the semi-transparent reflective films 45 and 46, respectively, and a second side surface having the reflecting plates 47 and 48. Lower polarizing plates 431 and 441 are provided in each of the two liquid crystal display modules 43 and 44. After the light of the light source 40 enters the two illumination light conducting substrates 41 and 42, the light is emitted from the light exit surfaces 411 and 421 of each of the illumination light conducting substrates 41 and 42, and then the translucent reflective film 45 46, and then enters the two liquid crystal display modules 43,44. Only the P light included in the light source 40 can pass through the lower polarizing plates 431 and 441 of the two liquid crystal display modules 43 and 44, so that the backlight module 4 has only P light which is an effective light source. Thus, the backlight module 4 requires two illumination photoconductive substrates 41 and 42 in order to achieve a double-sided light emission effect, whereby the thickness is increased.

According to the prior art illustrated in FIG. 8, another conventional double-sided light emitting backlight module 5 is a light source 50 and an illumination light conducting substrate 51 for supplying the light source to the two liquid crystal display modules 54 and 55. It is composed. The illumination photoconductive substrate 51 includes two light exit surfaces 52 and 53 and two translucent reflective films 56 and 57. Each of the two liquid crystal display modules 54 and 55 includes lower polarizers 541 and 551. After the light of the light source 50 enters the illumination photoconductive substrate 51, the light is emitted from the light exit surfaces 52, 53 of the illumination photoconductive substrate 51 and then passes through the translucent reflecting films 56, 57. Then, the two liquid crystal display modules 54 and 55 enter the light source to supply the liquid crystal display modules 54 and 55. Thus, the thickness is reduced. However, only half of the light of the light source 50 is supplied to the respective light exit surfaces 52 and 53. In addition, only the P light included in the light source 50 can pass through the lower polarizing plates 541 and 551 of the two liquid crystal display modules 54 and 55, so that the backlight module 5 is one of the effective lights of the light source 50. Only / 4 is obtained, and as a result, the luminance of the liquid crystal display module is lowered.

The main object of the present invention is to provide a double-sided light emitting backlight module that can achieve a double-sided light emitting effect by a single illumination photoconductive substrate.

Another object of the present invention is to provide a double-sided light emitting backlight module that can reduce the thickness of the backlight module.

Another object of the present invention is to provide a double-sided light emitting backlight module that can enhance the brightness of the liquid crystal display module.

1 is a structural diagram of a double-sided light emitting backlight module according to a first embodiment of the present invention,

2 is a light path diagram of a double-sided light emitting backlight module according to a first embodiment of the present invention,

3 is a schematic view of a luminance-enhanced film of the double-sided light emitting backlight module according to the first embodiment of the present invention,

4 is a structural diagram of a double-sided light emitting backlight module according to a second embodiment of the present invention,

5 is an optical path diagram of a double-sided light emitting backlight module according to a second embodiment of the present invention,

6 is a perspective view of a conventional liquid crystal display module according to the prior art,

7 is a schematic diagram of a conventional double-sided light emitting backlight module according to the prior art,

8 is a schematic view of another conventional double sided light emitting backlight module according to the prior art;

[Explanation of symbols on the main parts of the drawings]

1: lighting photoconductive board

10: light source

11: light entrance face

12: first light outlet face

13: second light outlet face

14,15: brightness enhancement film

L1,102,103: incident light

L2,105,107,109: permeable light

L3,104,106,108: reflective light

21,22: liquid crystal display module

101 light beam

211,221: lower polarized plate

In order to achieve the above object, a double-sided light emitting backlight module positioned between two liquid crystal display modules of the present invention includes at least one light source; one side consisting of a light incident surface adjacent to the light source, and two liquid crystal display modules. An illumination photoconductive substrate having two parallel planes each comprising a first light exit surface and a second light exit surface adjacent to the light incident surface to provide a light source required for each; and a single mandrel-shaped light that can be separated and separated The mandrel-shaped light passes through the luminance-enhanced film and another mandrel-shaped light is reflected by the luminance-enhanced film, and is installed on one of the first and second emission surfaces of the illumination photoconductive substrate, and its characteristics It consists of; at least one brightness enhancing film for enhancing the brightness of the liquid crystal display module.

According to the double-sided light emitting backlight module of the present invention, the luminance-enhanced film is characterized in that the PCF or DBEF.

In addition, the double-sided light emitting backlight module of the present invention is provided with a brightness enhancing film on the other of the first light emitting surface and the second light emitting surface of the illumination photoconductive substrate, after the light is reflected between the two brightness enhancing film, All light sources are characterized in that the axial direction of the optical image is transformed into light that satisfies the two liquid crystal display modules, thereby enhancing the brightness of the liquid crystal display modules.

According to the double-sided light emitting backlight module of the present invention, the luminance-enhanced film is characterized in that the PCF or DBEF.

Further advantages and advantages of the present invention can be better understood through the following detailed description and the accompanying drawings.

1 is a structural diagram of a double-sided light emitting backlight module according to a first embodiment of the present invention, Figure 2 is a light path diagram of a double-sided light emitting backlight module according to a first embodiment of the present invention, Figure 3 is 4 is a schematic diagram of a luminance-enhanced film of a double-sided light emitting backlight module according to the first embodiment, Figure 4 is a structural diagram of a double-sided light emitting backlight module according to a second embodiment of the present invention, Figure 5 is a second embodiment of the present invention The optical path diagram of the double-sided light emitting backlight module according to the present invention.

1 to 3, the double-sided light emitting backlight module according to the first embodiment of the present invention is composed of at least one light source 10, an illumination photoconductive substrate 1 and the brightness enhancement film (14).

According to the first embodiment of the present invention, the double-sided light emitting backlight module uses one light source 10.

The illumination photoconductive substrate 1 has one side formed by a light incident surface 11 adjacent to the light source 10, and a first light emitting surface 12 and a second light emitting surface 13 adjacent to the light incident surface 11, respectively. Two parallel planes each consisting of

The brightness enhancing film 14 is installed on one side of the first light emitting surface 12. It is preferable that the luminance-enhanced film 14 adopt PCF or DBEF (double luminance-enhanced film).

Referring to FIG. 3, the light intensity of the light source is represented by the width of the line sign. The incident light L1 (P light and S light) calculates the transmitted light L2 (P light) and the reflected light L3 (P light and S light). The brightness enhancing film 14 separates P light from S light, the P light passes through the brightness enhancing film 14 and the S light is reflected by the brightness enhancing film 14. Therefore, in the light source 10, P light passes and S light is reflected, while S light after reflection is transformed into mixed light of P light and S light.

Referring to FIG. 2, the backlight module has two side surfaces on which the liquid crystal display modules 21 and 22 on which the lower polarizing plates 211 and 221 are installed, respectively. For explanation, the light intensity of the light source is represented by the width of the line sign and only the path of a single light is displayed. In practice, the light ray 101 of the light source 10 includes P light and S light. The light beam 101 enters the illumination light conducting substrate 1 through the light incident surface 11, and then incident light 102 and 103 of the light beam 101 is directed to the first light emitting surface 12 and the second light emitting surface 13. Each projected. The first light emitting surface 12 is provided with a brightness enhancing film 14, the incident light 102 projected on the first light emitting surface 12 is directed toward the second light emitting surface 13 and the first reflected light (104) The first transmitted light 105 directed toward the first light exit surface 12 will be calculated. In this manner, the first reflected light 104 becomes a mixed light of P light and S light, and the first transmitted light 105 becomes P light. The optical image axis of the first transmitted light 105 has the same direction as the lower polarizing plate 211, so that the first transmitted light 105 may pass through the lower polarizing plate 211 without loss. In addition, the first reflected light 104 is directed toward the second light emitting surface 13, so that the light emitted from the second light emitting surface 13 includes the incident light 103 and the first reflected light 104. The luminance of the liquid crystal display module 22 is enhanced.

In conclusion, due to the optical characteristics of the luminance-enhanced film 14, the light absorption action of the lower polarizing plate 211 of the liquid crystal display module 21 is provided to the luminance-enhanced film 14, the light absorbed is the liquid crystal of the opposite side Reflected by the display module 22, the brightness of the liquid crystal display module 22 is thereby enhanced. Thus, the luminance of the liquid crystal display module 22 is enhanced without reducing the luminance of the liquid crystal display module 21.

In addition, the lower polarizing plate of each of the two liquid crystal display modules allows only P light to pass, so that the backlight module can transform all the light rays of the light source into the P light, and the lower polarizing plate of each of the two liquid crystal display modules is a light source. It is possible to prevent the absorption of the S light of all the light rays of the, so that the amount of use of the light source is relatively increased and the brightness of the liquid crystal display module is increased.

4 and 5, the double-sided light emitting backlight module according to the second embodiment of the present invention includes at least one light source 10, an illumination photoconductive substrate 1, a first luminance-enhanced film 14, and a second The brightness enhancement film 15 is comprised.

In the second embodiment of the present invention, the double-sided light emitting backlight module uses one light source 10.

The illumination photoconductive substrate 1 has one side formed by a light incident surface 11 adjacent to the light source 10, and a first light emitting surface 12 and a second light emitting surface 13 adjacent to the light incident surface 11, respectively. Two parallel planes each consisting of

The first brightness enhancing film 14 and the second brightness enhancing film 15 are respectively provided on one side of the first light emitting surface 12 and the second light emitting surface 13. Accordingly, the light rays are continuously reflected between the first luminance enhanced film 14 and the second luminance enhanced film 15, so that all the rays of the light source satisfy two liquid crystal display modules 21 and 22 in the optical axis direction. The brightness of the liquid crystal display module is increased as a result.

Referring to FIG. 5, the backlight module includes liquid crystal display modules 21 and 22 having lower polarizing plates 211 and 221 adjacent to the first luminance enhanced film 14 and the second luminance enhanced film 15, respectively. It has two sides. In addition, the lower polarizing plates 211 and 221 only allow P light to pass therethrough.

For the sake of explanation, the light intensity of the light source is represented by the width of the line sign, and only a single light path is displayed. In practice, the light ray 101 of the light source 10 includes P light and S light. After the light beam 101 enters the illumination photoconductive substrate 1 from the light incident surface 11, incident light 102 and 103 of the light beam 101 is directed to the first light emitting surface 12 and the second light emitting surface 13, respectively. Projected. The second luminance enhancing film 15 is installed on the second light emitting surface 13 so that the incident light 102 projected on the second light emitting surface 13 is directed toward the first light emitting surface 12. ) And the first transmitted light 105 directed toward the second light exit surface 13. In this manner, the first reflected light 104 becomes a mixed light of P light and S light, and the first transmitted light 105 becomes P light. In addition, the first luminance-enhanced film 14 is provided on the first light emitting surface 12, so that the first reflected light 104 projected on the first light emitting surface 12 is directed toward the second light emitting surface 13; The second transmitted light 107 directed toward the second reflected light 106 and the first exit surface 12 will be calculated. In addition, the second reflected light 106 projected onto the second light emitting surface 13 is the third reflected light 108 directed toward the first light emitting surface 12 and the third transmitted light 109 directed toward the second light emitting surface 13. Will yield

In this manner, the incident light 102 continuously calculates reflected light and transmitted light between the first luminance enhanced film 14 and the second luminance enhanced film 15. Similarly, the incident light 103 also continuously calculates reflected light and transmitted light between the first luminance enhanced film 14 and the second luminance enhanced film 15. As a result, the reflected light and the transmitted light are evenly emitted toward the two liquid crystal display modules 21 and 22, and all the emitted light rays are transformed into P light.

Thus, the light rays are continuously reflected between the first luminance-enhanced film 14 and the second luminance-enhanced film 15 so that all the rays of the light source pass through the lower polarizing plates 211 and 221 without loss by the backlight module. The axial direction of the image is deformed to P-light satisfying the lower polarizing plates 211 and 221 of the two liquid crystal display modules 21 and 22, thereby enhancing the luminance of the liquid crystal display module.

In conclusion, the first photoluminescence enhancing film 14 and the second luminance enhancing film 15 are installed in the illumination photoconductive substrate 1, so that all light rays of the light source are transformed into P light. In addition, the lower polarizing plates 211 and 221 of the two liquid crystal display modules 21 and 22 allow only the passage of the P light so as not to absorb the S light in the light source, thereby preventing the optical loss from occurring, thereby preventing the two liquid crystal display modules ( 21,22) can achieve the optimal optical effect.

Although the present invention has been described with reference to the above-described embodiments, it is understood that many other possible changes and modifications can be made without departing from the spirit of the present invention. Therefore, it is anticipated that the appended claims shall apply to modifications and variations that fall within the true scope of the present invention.

As described above, the double-sided light emitting backlight module according to the present invention can achieve the double-sided light emitting effect by a single illumination photoconductive substrate, can not only reduce the thickness of the backlight module but also enhance the brightness of the liquid crystal display module. It can be effective.

Claims (6)

At least one light source 10; and One side surface comprising the light incident surface 11 adjacent to the light source 10 and the first light emitting surface adjacent to the light incident surface 11 so as to provide necessary light sources to the two liquid crystal display modules 21 and 22, respectively. 12) and an illumination photoconductive substrate 1 having two parallel planes each consisting of a second light exit surface 13; and Two mandrel-shaped light can be separated so that the separated mandrel-shaped light passes through the luminance-enhanced film 14 and the other mandrel-shaped light is reflected by the luminance-enhanced film 14, At least one luminance provided on one of the first light emitting surface 12 and the second light emitting surface 13 of the illumination photoconductive substrate 1 to enhance the brightness of the liquid crystal display modules 21 and 22 by its characteristics Reinforcement film 14; Double-sided light emitting backlight module installed between the two liquid crystal display module, characterized in that consisting of. The double-sided light emitting backlight module of claim 1, wherein the brightness enhancing film (14) is a PCF. 2. A double-sided light emitting backlight module according to claim 1, wherein said luminance-enhanced film (14) is DBEF. 2. The brightness enhancing film 15 is installed on the other of the first light emitting surface 12 and the second light emitting surface 13 of the illumination photoconductive substrate 1, and the light is emitted from the two brightness enhancing films. After being reflected between (14, 15), all the light sources are transformed into light whose optical axial direction satisfies the two liquid crystal display modules 21, 22, thereby enhancing the brightness of the liquid crystal display modules. Double-sided light emitting backlight module, characterized in that. 5. A double-sided light emitting backlight module according to claim 4, wherein said brightness enhancing film (15) is PCF. 5. A double-sided light emitting backlight module according to claim 4, wherein said brightness enhancing film (15) is DBEF.