JP2002132189A - Both side liquid crystal display device and assembling method of the device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To cope with both simplification and uniform illumination of an illumination device, to reduce the cost as a result and to effectively utilize external light beams. SOLUTION: A light guiding layer 11 is arranged in the rear surface side of a liquid crystal panel 4. A first reflection plate 7 is arranged in a first one side portion region of the front surface side of the panel 4. A second reflection plate 8 is arranged in a front other side portion region of the rear surface side of the panel 4. A third reflection plate 18 is arranged in a second other side portion region of the rear surface side of the layer 11. A light emitting source 13 is added to introduce internal light beams 34 and 34' in the layer 11. The plate 8 has a light transmissive portion. The first one side portion region does not visually overlap with the first other side portion region and the second other side portion region. The both side liquid crystal display is realized by the three reflection plates 7, 8 and 18 and the layer 11. The existence of the simplified light source 13 and the layer 11 makes the entire illumination uniform, the cost is reduced as a result and effective utilization of external light beams is made possible.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a double-sided liquid crystal display device and a method for assembling the double-sided liquid crystal display device.
The present invention relates to a double-sided liquid crystal display device that illuminates a liquid crystal panel capable of double-sided display from both sides and a method of assembling the double-sided liquid crystal display device.

[0002]

2. Description of the Related Art A double-sided liquid crystal display device capable of double-sided display is disclosed in JP-A-10-198291 and JP-A-2000-20.
No. 6523. The double-sided liquid crystal display device is used in portable terminals, notebook computers, and the like. The liquid crystal of the liquid crystal display device has no self-luminous property, the liquid crystal cannot be visually recognized, and the liquid crystal has a display performance when illuminated from the outside. The double-sided liquid crystal display device includes an irradiation device that irradiates the liquid crystal panel from both sides. By irradiating the liquid crystal with external light such as sunlight or indoor light, the liquid crystal display can be performed. Alternatively, the liquid crystal can be displayed by irradiating the liquid crystal with a backlight or a front light.
The double-sided liquid crystal display device disclosed in Japanese Patent Application Laid-Open No. 2000-206523 is a technology in which irradiation light is incident on a liquid crystal panel from a side surface thereof.

[0003] It is difficult to uniformly irradiate the entire surface of the liquid crystal panel with the technique of irradiating the irradiation light from the side surface of the liquid crystal panel. In the technology of irradiating the liquid crystal with external light such as sunlight or indoor light, the display performance depends on the weather and indoor environment of the day. The technology of irradiating a liquid crystal with a backlight or a front light has limitations on the space for arranging them, and it is difficult to arrange the liquid crystal display. Therefore, the overall strength of the liquid crystal display device depends on the liquid crystal panel. From the viewpoint of the above, the arrangement is difficult. The use of two sets of backlight and front light requires two sets of parts, increases the number of assembly steps, and increases the cost.

[0004] It is desired to use a single lighting device and uniform lighting.
As a result, cost reduction is required. It is further required that the overall strength of the device does not depend on the strength of the liquid crystal panel. Further, effective use of external light is required. It is important that further structural reinforcement be achieved.

[0005]

SUMMARY OF THE INVENTION It is an object of the present invention to provide a double-sided liquid crystal display and a double-sided liquid crystal display in which a single illumination device and uniform illumination can be achieved at the same time, and as a result, cost can be reduced. Is to provide an assembling method. Another object of the present invention is to provide a double-sided liquid crystal display device in which unitization of a lighting device and uniform illumination are compatible and the overall intensity does not depend on the intensity of a liquid crystal panel, and a method of assembling the double-sided liquid crystal display device. It is in. Still another object of the present invention is to provide a double-sided liquid crystal display device in which unification of illumination devices and uniform illumination are compatible, resulting in cost reduction and effective use of external light, and And a method for assembling a double-sided liquid crystal display device. Still another object of the present invention is to achieve uniformity of illumination devices and uniform illumination at the same time, resulting in cost reduction, effective use of external light, and easy assembly. Another object of the present invention is to provide a double-sided liquid crystal display device in which the structure of the display device is strengthened by the assembly, and a method of assembling the double-sided liquid crystal display device.

[0006]

Means for solving the problem are described as follows. The technical items appearing in the expression are appended with numbers, symbols, and the like in parentheses (). The numbers, symbols, and the like are technical items that constitute at least one embodiment or a plurality of the embodiments of the present invention, in particular, the embodiments or the examples. Corresponds to the reference numerals, reference symbols, and the like assigned to the technical matters expressed in the drawings corresponding to the above. Such reference numbers and reference symbols clarify the correspondence and bridging between the technical matters described in the claims and the technical matters of the embodiments or examples. Such correspondence / bridge does not mean that the technical matters described in the claims are interpreted as being limited to the technical matters of the embodiments or the examples.

A double-sided liquid crystal display device according to the present invention comprises a liquid crystal panel (4), a light guide layer (11) disposed on the back side of the liquid crystal panel (4), and a first liquid crystal panel (4) on the front side of the liquid crystal panel (4). A first reflector (7) arranged in one partial area, a second reflector (8) arranged in a first other partial area on the back side of the liquid crystal panel (4), and a light guide layer (11). ), A third reflector (18) disposed in the second other side partial area on the back surface side, and a light emitting source (13) for introducing internal light (34, 34 ′) into the light guide layer (11). Have been. The second reflector (8) is arranged on the surface side of the light guide layer (11), and the second reflector (8) has a plurality of light transmitting portions (9) and a plurality of light reflecting portions (second
The light-transmitting portion (9) of the reflector (8) is formed with the light-transmitting portion (9), and the light-transmitting portion (9) and the light-reflecting portion are adjacent to each other and have a first one-side portion. The regions do not visually overlap the first other-side partial region and the second other-side partial region, and the internal light (34, 34 ') introduced by the light-emitting source (13) is applied to the liquid crystal panel (4). Are introduced in a crossing direction crossing in the front and back direction.

[0008] The second reflector (8) having a plurality of light-transmitting portions (9) forms internal light (3) introduced into the light guide layer (11).
4, 34 ') can be guided in the direction of the liquid crystal panel (4), and effectively reflects external light (38) incident on the A-plane side (front side) display area (15), thereby reducing external light (38). Can effectively irradiate the liquid crystal portion of the liquid crystal panel (4). The first reflecting plate (7) has a display area (17) on the side B (back side).
The external light (29) incident on the liquid crystal panel (4) can be effectively reflected, the external light (29) can effectively irradiate other liquid crystal portions of the liquid crystal panel (4), and the display area other than the A-side display area (15) Area can be effectively hidden visually. The third reflector (18) effectively reflects external light (41) incident on the A-side display area (15), and the external light (41) effectively irradiates the liquid crystal portion of the liquid crystal panel (4). And an area other than the B-side display area (17) can be effectively hidden. The internal light is introduced into the light guide layer (11) from the side surface thereof, the arrangement of the light guide layer (11) and the light emitting source (13) is simple, and an increase in the overall depth is effectively suppressed. . By arranging the three reflectors (7, 8, 18) and the light guide layer (11) in the front and back directions, the lighting for front and back display can be made uniform and uniform, resulting in cost reduction. It is possible. The front surface and the back surface have a relative surface arrangement relationship, and refer to a relationship between surfaces on opposite sides of each other.

The crossing direction is preferably substantially perpendicular to the front and back surfaces, but is not completely perpendicular. This direction is optimized in relation to the formation of the prism surface described later. The back surface of the light guide layer (11) is formed by a plurality of prism surfaces (28), and the prism surface (28) transmits internal light (34, 34 ') introduced into the light guide layer (11) to the liquid crystal panel (4). Is refracted (reflected) in the direction toward. The inclined internal light reflected by the prism surface (28) effectively irradiates the entire area of the liquid crystal panel (4). It is preferable that the plural or innumerable prism surfaces (28) arranged two-dimensionally cross each other at an appropriate angle. The entire area refers to the effective area.

It is preferable that a light diffusion layer (12) is provided between the second reflector (8) and the light guide layer (11). The light diffusion layer (12) is disposed in the other partial region on the back surface side of the second reflection plate (8). The anti-reflection layer (1) disposed in the second partial area on the back side of the liquid crystal panel (4)
6) is further added. The non-reflective layer (16) effectively guides external light (29) to the first reflector (7), and effectively displays light (33) reflected, refracted and diffracted by the liquid crystal display portion of the liquid crystal panel (4). The display can be led to the B-side display area (17).

The non-reflective layer (16) has excellent optical properties for transmitting internal light (34, 34 ') and external light in the front and back direction of the non-reflective layer (16). The side surface side of the second reflector (8) and the side surface side of the light diffusion layer (12) are joined, and the thickness of the non-reflection layer (16) is the same as the thickness of the second reflection plate (8) and the light diffusion layer (12). ) Is approximately equal to the sum of the thicknesses. Such a thickness relationship can facilitate assembly and enhance overall strength. The addition of the antireflection film (14) bonded to the entire region on the back surface side of the light guide layer (11) further promotes the effective use of the internal light and the external light described above. First polarizing plate (5) bonded to the entire area on the front side of the liquid crystal panel (4)
And a second region joined to the entire region on the back surface side of the liquid crystal panel (4).
The addition of the polarizing plate (6) is a trivial additional device in a liquid crystal display device using the polarizing plate.

The holder (3) is advantageously used for assembly. The holder (3) has a step on the inner surface side, and the step is formed by a first step (21) and a second step (22), and the peripheral area on the rear surface side of the liquid crystal panel (4) is the second step. The third reflector (18) is joined to the first step (21), and the peripheral area on the back side of the third reflector (18) is joined to the second step (22). Such assembling can reduce the assembling cost, and the holder (3) can strengthen the entire structure and effectively protect the internal structure of the liquid crystal panel. It is more preferable that the peripheral region on the back surface side of the antireflection film (14) is joined to the second step (22).

According to the method for assembling a double-sided liquid crystal display device according to the present invention, a first step (22) is formed in a holder (3);
Forming the second step (21) on the holder (3), forming the illuminating section (2), forming the liquid crystal display section (1), and arranging the illuminating section (2) on the first step (22). It is formed from joining and joining the liquid crystal display unit (1) to the second step (21). Forming the illumination part (2) includes forming the light guide layer (11), forming the first reflector (18) in one partial region on the back surface side of the light guide layer (11), Forming a light diffusion layer (12) in one partial region on the surface side of the light layer (11). Joining the illumination unit (2) to the first step (22) means joining the peripheral area on the back surface side of the first reflector (18) to the first step (22). Forming the liquid crystal display section (1) includes forming a liquid crystal panel (4), bonding a second reflector (7) to the other partial area on the front side of the liquid crystal panel (4), (3) bonding a third reflection plate (8) to the one-side partial region on the back surface side. The third reflector has the optical properties described above. Joining the liquid crystal display (1) to the second step (21)
This is to join the peripheral area on the back side of the liquid crystal display panel (4).

The holder (3) used for such a partial assembly and a whole assembly is for the convenience of the assembly and for strengthening the whole structure. Due to the structural reinforcement, the internal structure of the display device of the liquid crystal panel can be effectively protected. Forming the illuminating part (2) comprises forming a light guide layer (11).
The method further comprises forming a non-reflective layer (16) in the other partial region on the front surface side, and further comprising forming an anti-reflection film (14) in the entire region on the back surface side of the light guide layer (11). Forming the illumination section (2) further comprises forming a plurality of prism faces (28) on the back side of the light guide layer (11). Forming the illumination part (2) further comprises arranging the light source (13) on the side of the light guide layer (11).

[0015]

Referring to the drawings, an embodiment of a double-sided liquid crystal display device according to the present invention has a double-sided liquid crystal display section provided with a single illumination section. Double-sided liquid crystal display 1
1 is shown in FIG. 1, and the illumination unit 2 is shown in FIG.
The overall device, which is an assembly of the liquid crystal display unit 1 and the illumination unit 2,
As shown in FIG. 3, the double-sided liquid crystal display unit 1 is mounted on the illumination unit 2 via the holder 3 and assembled. The double-sided liquid crystal display unit 1 technically partially inherits the well-known double-sided liquid crystal display device disclosed in the above-mentioned JP-A-2000-206523 and JP-A-10-298291, and the illuminating unit 2 has a known single-sided display. Technology is partially inherited.

The double-sided liquid crystal display unit 1 includes a liquid crystal panel 4 as shown in FIG. The upper polarizing plate 5 is bonded to the upper surface (front surface or A surface) of the liquid crystal panel 4, and the lower polarizing plate 6 is bonded to the lower surface (back surface or B surface) of the liquid crystal panel 4. A front-side reflector 7 is joined to a partial region on one side on the front side of the upper-side polarizer 5. A central reflector 8 is joined to a partial area on the other side on the back surface of the lower polarizer 6. A light-transmitting region (opening region) 9 is provided in the central reflector 8 with an appropriate area dispersion ratio. The region where the center-side reflector 8 is present substantially coincides in position with the A-side display region 15. Providing openings at a fixed ratio in the center-side reflector 8 is already well known as a technique used in a transflective liquid crystal display device.

As shown in FIG. 2, the illumination section 2 includes a light guide layer 11 having a light transmitting property. A diffusion sheet 12 for diffusely diffusing light is bonded to the surface of the light guide layer 11. The light emitting surface of the LED (light emitting diode) 13 is joined to the side surface of the light guide layer 11. An AR coat (antireflection film) 14 is bonded to the back surface of the light guide layer 11. AR
The coat 14 is an antireflection film that has been subjected to a treatment that does not reflect the light of the surrounding environment.

The area where the diffusion sheet 12 is present is designed to substantially match the display area 15 on the front surface side.
Reference numeral 2 denotes a region corresponding to the existing region, and covers the light guide layer 11 on the upper surface side (front surface side). The diffusion sheet 12 is formed of a translucent plastic material having a physical property of diffusing illumination light incident on the light guide layer 11 toward the liquid crystal panel 4 at various angles.

The anti-reflection film 16 is joined to the diffusion sheet 12 side by side with the diffusion sheet 12, and is joined to one partial region on the upper surface side of the light guide layer 11. Non-reflective film 16
Has the physical property of transmitting and transmitting light incident thereon without reflection without reflecting inside. The existence region of the anti-reflection film 16 substantially corresponds to the existence region of the front-side reflection plate 7 and the back-side display region 17 described above. A rear surface side reflection plate 18 is joined to a part of the other side on the rear surface side of the AR coat 14. The non-reflection film 16 has a function (strength function) of a spacer between the light guide layer 11 and the lower surface side polarizing plate 6 in addition to having a non-reflection light transmitting property, and has a function of the diffusion sheet 12 and the center. It has mechanical and geometric properties for adjusting the total height of the two layers of the side reflector 8.

The illumination section 2 shown in FIG. 2 is assembled by being supported by a holder 3 as shown in FIG. At least two walls (opposite 2 walls) of the rectangular cylindrical holder 3
A first step 21 on both sides and a second step 22 on both sides are formed on both inner peripheral surfaces of the wall). Between the step 22 on one side and the step 22 on the other side, an AR coat 1
A drop (depth) corresponding to the total thickness corresponding to the thickness of No. 4 and the thickness of the back side reflection plate 18 is given. On the upper surface of the second step 22 on both sides, the other end of the back side reflection plate 18 and one end of the AR coat 14 are installed and joined. The entire lighting unit 2 is housed between the first step 21 and the second step 22.

The double-sided liquid crystal display unit 1 shown in FIG.
As shown in (2), it is joined and installed on the upper surface side of the lighting unit 2. The central reflector 8 of the double-sided liquid crystal display unit 1 is provided on the upper surface of the diffusion sheet 12 of the illumination unit 2. When the central reflecting plate 8 is installed on the upper surface of the diffusion sheet 12, the lower surface of a part of the lower polarizing plate 6 matches the upper surface of the anti-reflection film 16, and the lower surface of the liquid crystal panel 4 has the first step. 21. In this state, the other part of the lower surface of the lower polarizing plate 6 is joined to the upper surface of the central reflecting plate 8.

FIGS. 4A and 4B show the area division of the assembled assembly as seen from the front and back sides. FIG. 4A shows the assembled surface viewed from the front side, and FIG. 4B shows the assembled surface viewed from the back side. FIG. 4A shows the surface of the upper-side polarizing plate 5 and the surface of the front-side reflecting plate 7 that covers a partial area of the upper-side polarizing plate 5. FIG. 4B shows the back surface of the back-side reflector 18 covering a part of the AR coat 14 and the exposed back surface of the other part of the AR coat 14 on the other side. 4 (b) (not shown in FIGS. 2 and 3)
Is a member that connects the upper corner frame 25 and the lower corner frame 26 of the holder 19 to strengthen the entire holder 19.

FIGS. 5 and 6 show the formation of the prism surface 27 on the back surface side of the light guide layer 11. The back surface 27 of the light guide layer 11 is formed as a set of a large number of inclined surface elements 28. The prism surface 27 has a reflection function of changing a light path of a light beam emitted from the LED 13 in a direction orthogonal to the surface of the light guide layer 11 on average. A part of the layer of the AR coat 14 enters a shallow depression formed by the inclined surface element 28, thereby improving the reflection function on the prism surface 27. The anti-reflection film may be formed on the diffusion sheet 12 side. The AR coat 14, as shown in FIG.
Of the reflected light portions reflected as dotted-line illustrated lights 31 and 31 ′, the amount of the incident light 32 incident on the light guide layer 11 from the outside and the back side emission outside emitted from the light guide layer 11 to the outside The amount of light 33 is increased.

By such antireflection, external light 29,
The light 29 ′ enters the light guide layer 11 with high efficiency, passes through the anti-reflection film 16, and further passes through the lower polarizing plate 6, the liquid crystal panel 4, and the upper polarizing plate 5, as shown in FIG. The upper surface side polarizing plate 5, the liquid crystal panel 4, the lower surface side polarizing plate 6, the anti-reflection film 16, the light guide layer 11
, The light amount of the back side outgoing external light 33 emitted from the AR coat 14 increases. Due to such an increase, external light can be used more effectively.

As shown in FIG. 8, the cone-shaped light beam emitted from the LED 13 is incident on the light guide layer 11 in the lateral direction (in-plane direction) on average, and a part of the light guide layer 34, 34 'is guided. The light is reflected by the prism action of the prism surface 27 formed as the lower surface of the light layer 11, changes the optical path to the surface side on average, and is diffused by the diffusion sheet 12 to pass and transmit through the light transmitting region 9. The liquid crystal element region (front side display unit) of the liquid crystal panel 4 is uniformly irradiated, and is polarized by the polarizing plates 5 and 6 to be emitted from the upper side polarizing plate 5 as front side emitted light 35 and 35 ′. . The presence / absence of the front side emission light 35, 35 'is visually recognized as an image, a character image, or the like on the A side. The emitted light of the LED 13 used for such visual recognition is used as a backlight.

The other part 36 of the cone-shaped light beam emitted from the LED 13 is reflected by the prism surface 27 and transmitted through the non-reflective film 16 in a non-reflective manner, like the part 34 described above. 4 and is reflected by the front-side reflector 7;
While passing through the upper polarizing plate 5, the liquid crystal panel 4, and the lower polarizing plate 6 again, it is polarized by the upper polarizing plate 5 and the lower polarizing plate 6. The liquid crystal element region (backside display section) is uniformly irradiated, again passes through the non-reflection film 16 and the light guide layer 11, passes through the AR coat 14, and becomes the backside emission light 37 from the AR coat 14. Emit. The presence or absence of the back side outgoing light 37 is visually recognized as an image, a character image, or the like on the B side. The emitted light of the LED 13 used for such visual recognition is used as a front light.

A part 38 of the external light on the front side passes through the upper polarizing plate 5, the liquid crystal panel 4, and the lower polarizing plate 6, is reflected by the central reflecting plate 8, and is again reflected by the lower polarizing plate 6, the liquid crystal. The light passes through the panel 4 and the upper-side polarizing plate 5 to be polarized, and irradiates the liquid crystal display area of the liquid crystal panel 4 while passing through the liquid crystal panel 4, and is emitted to the outside as front-side emitted external light 39. The other part 41 of the external light on the front side passes through the upper polarizer 5, the liquid crystal panel 4, and the lower polarizer 6, passes through and transmits through the light-transmitting region 9 of the central reflector 8, and diffuses. 12. Light guide layer 1
1 and is reflected by the rear-surface-side reflector 18, and again, the light guide layer 11, the diffusion sheet 12, the light-transmitting region 9, the lower-surface-side polarizer 6,
The light passes through the liquid crystal panel 4 and the upper surface side polarizing plate 5 and undergoes a polarization action. The external light on the front side is divided into light passing through the light-transmitting region 9 and light not passing through the light-transmitting region 9. Both light passing through the light-transmitting region 9 and light not passing through the light-transmitting region 9 pass through the liquid crystal panel 4. To irradiate the liquid crystal display area of the liquid crystal panel 4 substantially uniformly. The incidence and emission of the backside external light are as described above.

As described above, the presence of the light guide layer 11 unifies the arrangement of the light sources for uniformly irradiating the front side liquid crystal display section and the back side liquid crystal display section, respectively. The illumination device for a liquid crystal display having such a one-side arrangement structure can be configured such that the backlight and the front light of the double-sided liquid crystal display device are integrated as one irradiation device.

FIG. 9 shows another illumination section 2 '. The illumination unit 2 'of the present embodiment is the same as the illumination unit 2 described above, except that a brightness enhancement film is added to the illumination unit 2'. On the upper surface side of the diffusion sheet 12, one or a plurality of surface-side brightness enhancement films 51 are bonded. Central reflector 8
Is bonded to the upper surface of the surface-side brightness enhancement film 51 of the outermost layer. Since the total thickness of the plurality of front-side brightness enhancement films 51 and the diffusion sheet 12 is the same as the thickness of the diffusion sheet 12 of the illumination unit 2 described above, the dimension of the step structure of the holder 19 is not changed. Alternatively, the thickness of the anti-reflection film 16 is readjusted without changing the thickness of the diffusion sheet 12, and the position of the step 21 is changed, so that the step at the time of assembly can be eliminated. The brightness increasing film is a conventional film having a physical property of condensing light diverging at various angles in a certain direction. In the present embodiment, the amount of light irradiating the liquid crystal display unit of the liquid crystal panel 4 is reduced. Can be increased. The area where the front-side brightness enhancement film 51 is present coincides with the area where the diffusion sheet 12 is present.

It is preferable that a back surface side brightness enhancement film 52 is further added to the back surface side of the AR coat 14 or the light guide layer 11. The back side brightness increasing film 52 can make the back side external light incident on the back side brightness increasing film 52 toward the non-reflection film 16 with high efficiency.

[0031]

The double-sided liquid crystal display device according to the present invention, and
The assembling method of the double-sided liquid crystal display device achieves both unification of the illumination device and uniform illumination. As a result, the cost can be reduced, and the external light can be effectively used.

[Brief description of the drawings]

FIG. 1 is a sectional view showing an embodiment of a liquid crystal display section of a double-sided liquid crystal display device according to the present invention.

FIG. 2 is a cross-sectional view illustrating a lighting unit of the double-sided liquid crystal display device according to the present invention.

FIG. 3 is a cross-sectional view illustrating an assembly of a liquid crystal display unit and a lighting unit.

FIGS. 4A and 4B are a front view and a rear view, respectively, showing the front and back sides of the assembly.

FIG. 5 is a plan view showing a light guide layer.

FIG. 6 is a front view showing a light guide layer.

FIG. 7 is a cross-sectional view showing transmission of external light transmitted through the light guide layer.

FIG. 8 is a cross-sectional view showing light guide for front and back display.

FIG. 9 is a sectional view showing an embodiment of a double-sided liquid crystal display device according to the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Liquid crystal display part 2 ... Illumination part 3 ... Holder 4 ... Liquid crystal panel 5 ... 1st polarizing plate 6 ... 2nd polarizing plate 7 ... 1st reflective plate 8 ... 2nd reflective plate 9 ... Light transmission part 11 ... Light guide Layer 12: Light diffusion layer 13: Light emitting source 14: Anti-reflection film 15: A-side (front side) display area 16: Non-reflective layer 17: B-side (rear side) display area 18: Third reflector 21 ... First step (second step) 22 Second step (first step) 28 Prism surface 29 External light 33 Display light (external light) 34, 34 'Internal light 38 External light 41 External light

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 2H089 KA11 QA12 QA16 2H091 FA14X FA14Z FA16Z FA21Z FA23Z FA31Z FA37Z FA41Z FD04 FD06 LA13 5C094 AA15 AA44 BA43 DA08 EB02 ED11 5G435 AA03 AA18 BB12 FF15

Claims (14)

[Claims] A liquid crystal panel; a light guide layer disposed on a rear surface side of the liquid crystal panel; a first reflector disposed on a first partial region on a front surface side of the liquid crystal panel; A second reflector disposed in a first other side partial area on the back side of the light guide layer; a third reflector disposed in a second other side partial area on the back side of the light guide layer; A light emitting source for introducing light, wherein the second reflector is disposed on a surface side of the light guide layer, and wherein the second reflector is formed of a plurality of light transmitting portions and a plurality of light reflecting portions. The light transmitting portion and the light reflecting portion are adjacent to each other, and the first one side partial region does not visually overlap with the first other side partial region and the second other side partial region. The internal light introduced by the light-emitting source crosses the liquid crystal panel in a direction crossing the front and back surfaces. Double-sided liquid crystal display device introduced in the cross direction. 2. The double-sided liquid crystal display device according to claim 1, wherein said crossing direction is substantially orthogonal to said front and back surfaces. 3. The light guide layer according to claim 1, wherein a back surface of the light guide layer is formed by a plurality of prism faces, and the prism face refracts internal light introduced into the light guide layer in a direction toward the liquid crystal panel. Double-sided liquid crystal display device. 4. A light diffusion layer interposed between the second reflection plate and the light guide layer, wherein the light diffusion layer is provided on the other partial region on the back surface side of the second reflection plate. 2. The double-sided liquid crystal display device according to claim 1, wherein the liquid crystal display device is arranged. 5. The liquid crystal panel further includes a non-reflective layer disposed in a second partial area on the back surface side of the liquid crystal panel, wherein the non-reflective layer includes the internal light and the external light in the front and back directions of the non-reflective layer. The non-reflective layer is bonded to the side surface of the second reflector and the side surface of the light diffusion layer, and the thickness of the non-reflective layer is equal to that of the second reflector. 5. The double-sided liquid crystal display device according to claim 4, wherein the thickness is substantially equal to the sum of the thickness of the light diffusion layer and the thickness of the light diffusion layer. 6. The double-sided liquid crystal display device according to claim 1, further comprising an anti-reflection film bonded to an entire region on the back surface side of said light guide layer. 7. A liquid crystal panel further comprising: a first polarizing plate bonded to an entire region on the front surface side of the liquid crystal panel; and a second polarizing plate bonded to an entire region on the rear surface side of the liquid crystal panel. The double-sided liquid crystal display device according to claim 1, wherein 8. The liquid crystal panel further includes a holder, wherein the holder has a step on an inner surface side, the step is formed of a first step and a second step, and a peripheral area on the back surface side of the liquid crystal panel is the step. 2. The double-sided liquid crystal display device according to claim 1, wherein the liquid crystal display device is joined to a first step, and a peripheral area on the back surface side of the third reflector is joined to the second step. 9. The double-sided liquid crystal display device according to claim 6, further comprising an anti-reflection film bonded to the back surface side of the light guide layer, wherein a peripheral area on the back surface side of the anti-reflection film is bonded to the second step. . 10. forming a first step on the holder, forming a second step on the holder, forming an illuminating section, forming a liquid crystal display section, joining an illuminating section to the first step. Bonding a liquid crystal display unit to the second step, forming the illuminating unit, forming a light guide layer, and forming a light guide layer on one side partial area on the back surface side of the light guide layer. Forming a light-diffusing layer in one partial region on the surface side of the light-guiding layer, and joining an illumination unit to the first step; Joining the peripheral area on the back side of the first step to the first step; forming the liquid crystal display section; forming a liquid crystal panel; and forming a second area on the other side area on the front side of the liquid crystal panel. Joining a reflector, one side of the back side of the liquid crystal panel Bonding a third reflector to the divided area, wherein the third reflector is partially light-transmissive, and bonding a liquid crystal display unit to the second step is a back surface of the liquid crystal display panel. A method of assembling a double-sided liquid crystal display device, which comprises joining peripheral portions on the sides. 11. The method for assembling a double-sided liquid crystal display device according to claim 10, wherein forming the illuminating portion further comprises forming a non-reflection layer in the other partial region on the surface side of the light guide layer. 12. The method for assembling a double-sided liquid crystal display device according to claim 11, wherein forming the illuminating unit further comprises forming an anti-reflection film on an entire region on the back surface side of the light guide layer. 13. The method for assembling a double-sided liquid crystal display device according to claim 10, wherein forming the illuminating section further comprises forming a plurality of prism surfaces on a back surface side of the light guide layer. 14. The method for assembling a double-sided liquid crystal display device according to claim 13, wherein forming the illuminating unit further comprises arranging a light source on a side surface of the light guide layer.