JP2004151337A - Liquid crystal display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a both-surface display type liquid crystal display device that performs both-surface display by using one liquid crystal display element and reduces the occupation area, and displays an image observed on one surface side and an image observed on the other surface side by using illumination light from a surface light source or displays them by using external light as light in outer environment. <P>SOLUTION: On the front side and rear side of the liquid crystal display element 1 provided with a reflecting/transmitting means 10 of reflecting a portion of light incident on a plurality of pixels from the front side of a liquid crystal cell 2 and reflecting the remaining light behind a liquid crystal layer 5 of the liquid crystal cell 2, a front-side surface light source 25a and a rear-side surface light source 25b are arranged which project illumination light to the entire display area where the plurality of pixels A of the liquid crystal display element are arrayed and transmit the light incident from the front and rear sides. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a double-sided display type liquid crystal display device.
[0002]
[Prior art]
For example, as a double-sided display type liquid crystal display device used for a portable device having a double-sided display function such as a mobile phone, two liquid crystal display elements are arranged in a back-to-back state with their respective display surfaces facing in opposite directions, and between them. There is a configuration in which a surface light source that emits illumination light toward both liquid crystal display elements is arranged (see Patent Documents 1 and 2).
[0003]
However, using two liquid crystal display elements in this way increases the cost, and therefore it is desired to perform double-sided display using one liquid crystal display element.
[0004]
2. Description of the Related Art Conventionally, as a liquid crystal display device that performs double-sided display using one liquid crystal display element, a screen area of the liquid crystal display element is divided into a first screen section and a second screen section, and the first screen section is used for one side. (See Patent Documents 3 and 4) in which an image observed from the surface side is displayed and an image observed from the other surface side is displayed on the second screen portion.
[0005]
[Patent Document 1]
JP-A-10-90678
[0006]
[Patent Document 2]
JP 2001-290445 A
[0007]
[Patent Document 3]
JP 2000-193946 A
[0008]
[Patent Document 4]
JP 2001-305525 A
[0009]
[Problems to be solved by the invention]
However, in the double-sided display type liquid crystal display device in which the screen area of the liquid crystal display element is divided into the first and second screen parts, the display area of the liquid crystal display element has a display screen on one surface side and a display screen on the other surface side. Since the display screen and the display screen are arranged side by side, the occupied area of the liquid crystal display device is much larger than that of the double-sided display screen. Can not be used.
[0010]
According to the present invention, both sides can be displayed using one liquid crystal display element, and the occupied area can be reduced, and an image viewed from one side and an image viewed from the other side can be displayed. It is an object of the present invention to provide a liquid crystal display device capable of performing display using illumination light from a surface light source and display using external light that is light of an external environment.
[0011]
[Means for Solving the Problems]
The liquid crystal display device of the present invention comprises:
A liquid crystal layer is provided between the front substrate and the rear substrate that are disposed to face each other, and at least one electrode is provided on one of the opposed inner surfaces of the front substrate and the rear substrate, and the at least one electrode is provided on the other inner surface. A liquid crystal cell provided with a plurality of electrodes forming a plurality of pixels arranged in a matrix by opposing regions; and a liquid crystal cell provided on the rear side of the liquid crystal layer and incident on the plurality of pixels from the front side of the liquid crystal cell. A liquid crystal display element having a reflection / transmission means for reflecting a part of the reflected light and transmitting other light;
Arranged on the front side and the rear side of the liquid crystal display element, respectively, emits illumination light toward the entire display area where the plurality of pixels of the liquid crystal display element are arranged, and light incident from the front side and the rear side. And two surface light sources for transmitting light.
[0012]
This liquid crystal display device is configured such that, of the two surface light sources, a front side light source arranged on the front side of the liquid crystal display element (opposite to the side on which the reflection / transmission means is provided) changes the display area of the liquid crystal display element. The illumination light is emitted toward the whole area, and a part of the light emitted from the front side light source and incident on the plurality of pixels of the liquid crystal display element is reflected by the reflection / transmission means, and the front light is reflected. By emitting the light to the front side of the side light source, an image viewed from the front side is displayed, and other light is transmitted through the reflection / transmission means, and the rear side of the rear side light source arranged behind the liquid crystal display element. By emitting an image to be observed from the rear side, the illumination light is emitted from the rear side light source toward the entire display area of the liquid crystal display element, and emitted from the rear side light source. Liquid crystal display element reflection By emitting the light incident to each of the plurality of pixels on the front side of the front side light source is transmitted through the transmission means, for displaying the image viewed from the front side.
[0013]
That is, the liquid crystal display device emits illumination light from the front side light source toward the entire display area of the liquid crystal display element, thereby displaying an image observed from the front side by reflection display using the illumination light. Then, while displaying an image observed from the rear side by the transmissive display using the illumination light, the illumination light is emitted from the rear side light source toward the entire display area of the liquid crystal display element to emit the illumination light. An image viewed from the front side is displayed by transmissive display using light.
[0014]
According to this liquid crystal display device, both an image observed from the front side, which is one surface side, and an image observed from the rear side, which is the other surface side, are displayed on the entire display area of the liquid crystal display element. Therefore, the display area of the liquid crystal display element may have a size corresponding to one of the front and rear display screens.
[0015]
Therefore, according to this liquid crystal display device, both sides can be displayed using one liquid crystal display element, and the occupied area can be reduced.
[0016]
In addition, in this liquid crystal display device, since the front side light source and the rear side light source transmit light incident from the front side and the rear side, respectively, external light (light in an external environment) incident from the front side passes through the front side light source. Then, the light reflected by the reflection / transmission means out of the light respectively incident on the plurality of pixels of the liquid crystal display element is emitted to the front side of the front side light source, and The light transmitted through the transmission unit is emitted to the rear side of the rear side light source, and external light incident from the rear side is transmitted through the rear side light source and is incident on the liquid crystal display element. Light that has passed through the reflection / transmission unit and has entered each of the plurality of pixels can be emitted to the front side of the front side light source.
[0017]
Therefore, according to this liquid crystal display device, an image observed from the front side is reflected by the illumination light from the front side light source and external light incident from the front side, and the illumination light from the rear side light source and the rear display. In addition to displaying by transmissive display using external light incident from the side, an image observed from the rear side is displayed by illumination light from the front side light source and transmissive display using external light incident from the front side. be able to.
[0018]
As described above, the liquid crystal display device of the present invention reflects a part of light incident on each of the plurality of pixels from the front side of the liquid crystal cell behind the liquid crystal layer of the liquid crystal cell, and transmits other light. On the front side and the rear side of the liquid crystal display element provided with the reflection / transmission means, respectively, the illumination light is emitted toward the entire display area where the plurality of pixels of the liquid crystal display element are arranged, and from the front side and the rear side. By arranging a front side light source and a rear side light source that transmit incident light, a single liquid crystal display element can be used to display images on both sides, reduce the occupied area, and be observed from one side (front side). And an image observed from the other surface side (rear side) can be displayed by a display using illumination light from the surface light source and a display using external light that is light of an external environment. That we can do. .
[0019]
In the liquid crystal display device according to the present invention, the reflection / transmission means of the liquid crystal display element has a plurality of reflection films respectively corresponding to predetermined regions in a plurality of pixels of the liquid crystal cell, It is preferable that the light-reflecting layer be formed of a partial reflection / transmission layer that reflects the light incident on the reflective film among the incident lights and transmits the light incident on the portion without the reflective film.
[0020]
Further, the liquid crystal display device includes front and rear polarizers disposed with the liquid crystal cell interposed therebetween, and the reflection / transmission unit is provided between the rear polarizer and a liquid crystal layer. Is desirable.
[0021]
BEST MODE FOR CARRYING OUT THE INVENTION
1 to 5 show one embodiment of the present invention. FIG. 1 is an exploded perspective view of a liquid crystal display device, and FIG. 2 is a sectional view of a part of the liquid crystal display device.
[0022]
As shown in FIG. 1 and FIG. 2, the liquid crystal display device of this embodiment has one liquid crystal display element 1 and two surface light sources 25a arranged on the front side and the rear side of the liquid crystal display element 1, respectively. 25b.
[0023]
The liquid crystal display element 1 includes a liquid crystal cell 2, a reflection / transmission unit 10 provided behind the liquid crystal layer 5 of the liquid crystal cell 2, and front and rear sides of the liquid crystal cell 2. And a rear-side polarizing plate 16 provided.
[0024]
In the liquid crystal cell 2, as shown in FIG. 2, a liquid crystal layer 5 is provided between a front (upper side in the figure) transparent substrate 3 and a rear side (lower side in the figure) transparent substrate 4 which are opposed to each other. At least one transparent electrode 6 is arranged on one of the opposing inner surfaces of the front substrate 3 and the rear substrate 4, and a plurality of pixels A are arranged in a matrix on the other inner surface by a region opposing the at least one electrode 6. A plurality of transparent electrodes 7 to be formed are provided.
[0025]
The liquid crystal cell 2 is of an active matrix type. The electrode 6 provided on the inner surface of the front substrate 3 is a single film counter electrode, and the electrode 7 provided on the inner surface of the rear substrate 4 is It is a plurality of pixel electrodes arranged and formed in a matrix in a row direction and a column direction.
[0026]
The plurality of pixel electrodes 7 are respectively connected to a plurality of TFTs (thin film transistors) 8 provided on the inner surface of the rear substrate 4 so as to correspond to the pixel electrodes 7, respectively. It is connected to a gate wiring and a data wiring (not shown) provided on the inner surface of the rear substrate 4.
[0027]
The liquid crystal cell 2 includes a plurality of color filters 9R, 9G, 9B of a plurality of colors corresponding to the plurality of pixels A, for example, three colors of red, green, and blue, respectively. , 9B are formed on one of the substrates, for example, on the inner surface of the front substrate 3 so as to correspond to the entire area of each pixel A, and the counter electrode 6 is formed on the color filters 9R, 9G, 9B. ing.
[0028]
On the other hand, the reflection / transmission means 10 provided behind the liquid crystal layer 5 of the liquid crystal cell 2 includes a plurality of reflection films 10a corresponding to predetermined regions in a plurality of pixels A of the liquid crystal cell 1, respectively. And a partial reflection / transmission layer that reflects the light incident on the reflective film 10a among the light incident on the plurality of pixels A and transmits the light incident on the portion without the reflective film 10a. I have. Hereinafter, the reflection / transmission unit 10 is referred to as a partial reflection / transmission layer.
[0029]
The plurality of reflection films 10a of the partial reflection / transmission layer 10 are subjected to low-reflection processing on the surface opposite to the surface facing the liquid crystal layer 5, and the surface facing the liquid crystal layer 5 is subjected to a single-side reflection. These reflective films 10a are formed on the inner surface of the rear substrate 4 of the liquid crystal cell 2 so as to correspond to approximately half the area of all the pixels A arranged in a matrix. Each of the pixel electrodes 7 is formed by directly overlapping a part thereof (substantially a half of the pixel electrode 7) on the reflective film 10a, or by covering the reflective film 10a with a transparent insulating film. Formed on it.
[0030]
Further, alignment films 12 and 13 are provided on the inner surfaces of the front substrate 3 and the rear substrate 4 of the liquid crystal cell 2 so as to cover the electrodes 6 and 7, respectively.
[0031]
The front substrate 3 and the rear substrate 4 are joined via a frame-shaped sealing material 14 (see FIG. 1) surrounding a display area in which the plurality of pixels A are arranged in a matrix. A liquid crystal layer 5 is provided in a region between the rear substrate 4 and the frame-shaped sealing material 14.
[0032]
The liquid crystal molecules of the liquid crystal layer 5 are oriented by the alignment films 12 and 13 in the vicinity of the front and rear substrates 2 and 3 and are oriented in a predetermined initial alignment state between the substrates 2 and 3. .
[0033]
The polarizing plates 15 and 16 disposed on the front side and the rear side of the liquid crystal cell 2, respectively, have an absorption axis (not shown) and transmission axes 15a and 16a in directions orthogonal to each other. Absorbing polarized light that absorbs one of the two linearly polarized light components having a vibration plane parallel to the absorption axis and transmits the other polarization component with a vibration plane parallel to the transmission axes 15a and 16a. It is a board.
[0034]
The liquid crystal display element 1 of this embodiment is a normally white mode TN (twisted nematic) liquid crystal display element, and the liquid crystal molecules of the liquid crystal layer 5 of the liquid crystal cell 2 are disposed between the front and rear substrates 3 and 4. The absorption polarizers 15 and 16 on the front side are arranged so that their transmission axes 15a and 16a are substantially perpendicular to each other.
[0035]
Further, the liquid crystal display element 1 is disposed between the liquid crystal cell 2 and the front polarizer 15 and between the liquid crystal cell 2 and the rear polarizer 16 to improve display contrast and viewing angle. Phase difference plates 17 and 18 and a light scattering layer (hereinafter referred to as a scattering layer) 19 disposed between the liquid crystal cell 2 and the phase difference plate 17 on the front side thereof.
[0036]
On the other hand, the surface light sources 25a and 25b disposed on the front side (the front side of the front polarizer 15) and the rear side (the rear side of the rear polarizer 16) of the liquid crystal display element 1 are respectively provided by a plurality of the liquid crystal display elements 1. The illumination light is emitted toward the entire display area in which the pixels A are arranged, and the light incident from the front side and the rear side is transmitted.
[0037]
3 and 4 are a plan view and a side view of the surface light sources 25a and 25b, and FIG. 5 is a schematic diagram showing a light guide member, a retardation plate, and a linear polarization component of light emitted from the light guide plate of the surface light sources 25a and 25b. FIG.
[0038]
As shown in FIGS. 3 and 4, the surface light sources 25a and 25b include a light guide plate 26, a light guide member 31 disposed on the side of the light guide plate 26, the light guide plate 26 and the light guide member 31. And a light emitting element 38 disposed on the side of the light guide member 31.
[0039]
The light guide plate 26 is made of a transparent plate such as an acrylic resin plate having an area facing the entire display area of the liquid crystal display element 1, and one end surface of the light guide plate 26 forms an incident end surface 27 on which light is incident. One of the two plate surfaces of the transparent plate emits light guided to the transparent plate by a flat exit surface 28, and the other plate surface reflects the light incident from the incident end surface 27 by internal reflection. A reflection surface 29 for emitting light from the emission surface 28 is formed.
[0040]
The reflection surface 29 of the light guide plate 26 is densely arranged over the entire area of the other plate surface of the light guide plate 26 and formed parallel to each other. It is made up of a plurality of prism portions 30 that internally reflect in a direction in which the angle with respect to the line becomes smaller.
[0041]
The plurality of prism portions 30 are elongated prism portions having a trapezoidal cross-sectional shape having a length parallel to the incident end face 27 of the light guide plate 26 and having a length over the entire width of the light guide plate 26. Of the two side surfaces, the side surface on the side of the incident end surface 27 is formed at a steep angle surface substantially perpendicular to the exit surface 28, and the other side surface faces the outer surface side of the reflection surface 29 in the direction of the incident end surface 27. The output surface 28 is formed on an inclined surface inclined at an angle of 30 to 60 degrees (preferably approximately 45 degrees) with respect to the emission surface 28, and a top surface portion between these side surfaces (a steep angle surface and an inclined surface) is formed. It is formed on a flat surface parallel to the surface 28.
[0042]
In FIG. 4, the plurality of prism portions 30 are greatly exaggerated, but these prism portions 30 are formed at a pitch smaller than the pixel pitch of the liquid crystal cell 2.
[0043]
That is, the light guide plate 26 guides light incident from the incident end surface 27 and emits the light from the exit surface 28. Light incident on the light guide plate 26 from the incident end surface 27 is indicated by an arrow in FIG. As shown, one of the plurality of elongated prism portions 30 of the reflection surface 29 either goes straight in the light guide plate 26 or is internally reflected by the total reflection at the interface with the outside air (air) at the emission surface 28. And the light is internally reflected by the total reflection at the interface with the outside air in a direction in which the angle with respect to the normal line of the emission surface 28 becomes smaller, and exits from the emission surface 28.
[0044]
On the other hand, the light guide member 31 arranged on the side of the light guide plate 26 is made of a rectangular rod-shaped elongated transparent material (for example, an acrylic resin material) having a length corresponding to the incident end face 27 of the light guide plate 26. One of the side surfaces forms an elongated emission surface 33 from which light is emitted, and one of two end surfaces of the elongated transparent material that intersects the elongated emission surface 33 defines the incident end surface 32 on which light is incident, the elongated end surface being the elongated shape. The other side surface facing the emission surface 33 forms a reflection surface 34 for internally reflecting light incident from the incident end surface 32 and emitting the light from the elongated emission surface 33.
[0045]
The reflection surface 34 on the other side of the light guide member 31 is densely arranged in parallel with each other over the entire area of the other side surface, and the light incident from the incident end surface 32 of the light guide member 31 is It is composed of a plurality of prism portions 35 that internally reflect toward a direction in which the angle of the side surface with respect to the normal of the elongated emission surface 33 becomes smaller.
[0046]
The plurality of prism portions 35 are elongated prism portions having a triangular cross-sectional shape having a length parallel to the incident end face 32 of the light guide member 31 and having a length that covers the entire width of the other side surface of the light guide member 31. Of the two side surfaces of the prism portion 35, the side surface on the incident end surface 32 side is formed at a steep angle surface substantially perpendicular to the elongated emission surface 33, and the other side surface is on the outer surface side of the reflection surface 34. It is formed on an inclined surface inclined at an angle of 30 to 60 degrees (preferably approximately 45 degrees) with respect to the elongated exit surface 33 in the direction of the incident end face 32 toward the entrance end face 32.
[0047]
In FIG. 3, the plurality of prism portions 35 are greatly exaggerated, but these prism portions 35 are formed at a pitch substantially equal to the pitch of the elongated prism portions 30 of the reflection surface 29 of the light guide plate 26. Have been.
[0048]
That is, the light guide member 31 guides light incident from the incident end surface 32 and emits the light from the elongated exit surface 33 on one side surface, and light incident on the light guide member 31 from the incident end surface 32 is: As shown by arrows in FIG. 4, the plurality of elongated prisms of the reflecting surface 34 which travel straight in the light guide member 31 or are internally reflected by the elongated emitting surface 33 by total reflection at an interface with the outside air. The light is incident on one of the inclined surfaces of the portion 35, and is internally reflected by the total reflection at the interface with the outside air in a direction in which the angle with respect to the normal line of the elongated emission surface 33 becomes smaller. Light is emitted from the entire region 33 with a uniform intensity distribution.
[0049]
The light guide member 31 has its elongated exit surface 33 opposed to the incident end surface 27 of the light guide plate 26 and the elongated exit surface 33 of the light guide member 31 and the incident end surface 27 of the light guide plate 26 are mutually connected. They are arranged in parallel.
[0050]
Note that, in this embodiment, on the rear side of the reflection surface 34 of the light guide member 31, the light transmitted through the reflection surface 34 and leaked to the rear side of the light guide member 31 is returned to the light guide member 31. A reflector 37 is provided.
[0051]
The phase difference plate 36 disposed between the light guide plate 26 and the light guide member 31 is a λ / 2 phase difference plate that gives a phase difference of 波長 wavelength between the ordinary light and the extraordinary light of the transmitted light. The polarization plane of the linearly polarized light component of the light emitted from the elongated exit surface 33 of the light guide member 31 is rotated by substantially 90 degrees to be incident on the entrance end surface 27 of the light guide plate 26.
[0052]
The λ / 2 retardation plate 36 has an elongated shape corresponding to the entire area of the entrance end face 27 of the light guide plate 26 and the elongated exit surface 33 of the light guide member 31. One surface is adhered to the incident end surface 27 of the light guide plate 26 with a transparent adhesive between the light emitting member 33 and the elongated emission surface 33 of the light guide member 31, and the other surface is the elongated emission surface of the light guide member 31. 33 is attached by a transparent adhesive.
[0053]
The light emitting element 38 disposed opposite to the incident end face 32 of the light guide member 31 is a solid light emitting element such as an LED (light emitting diode) that emits white light, and includes, for example, a red LED and a green LED. A blue LED is molded with a transparent resin, and white light obtained by mixing red, green, and blue light emitted from these LEDs is emitted.
[0054]
The surface light sources 25a and 25b cause the light emitted from the solid state light emitting element 38 to enter the light guide member 31 from the incident end face 32 thereof, and to transmit the light to the opposite side of the elongated light emission surface 33 of the light guide member 31. The light is internally reflected by the reflection surface 34 and emitted from the entire elongated emission surface 33 of the light guide member 31 toward the incident end surface 27 of the light guide plate 26 with a uniform intensity distribution. 27, light having a uniform intensity distribution is made incident from the entire area of the light guide plate 26, and the light is internally reflected by the reflection surface 29 of the light guide plate 26 and emitted from the entire area of the emission surface 28 of the light guide plate 26; According to the surface light sources 25a and 25b, light having a uniform intensity distribution can be emitted from the entire area of the emission surface 28 of the light guide plate 26 with a small number of light emitting elements.
[0055]
Moreover, the surface light sources 25a and 25b arrange the light emitted from the elongated emission surface 33 of the light guide member 31 between the incident end surface 27 of the light guide plate 26 and the elongated emission surface 33 of the light guide member 31. Since the polarization plane of the linearly polarized light component of the light is rotated by substantially 90 degrees by the λ / 2 phase difference plate 36 to be incident on the incident end face 27 of the light guide plate 26, the light guide member is provided. The light guide member 31 is incident on the incident end face 32, is internally reflected by the reflection surface 34 on the other side of the light guide member 31, exits from the elongated exit surface 33 of the light guide member 31, and is incident on the light guide plate 26 at the entrance end face 27. Of the high-intensity linearly polarized light component of the light incident from the light guide plate 26 is reflected internally by the reflection surface 29 of the light guide plate 26 with high reflection intensity, and light of sufficient intensity is emitted from the emission surface 28 of the light guide plate 26. Can be.
[0056]
That is, as described above, the light guide plate 26 enters the light from the incident end face 27 and travels straight through the light guide plate 26, or reflects the light that is internally reflected by the emission surface 28 and enters the reflection surface 29. The light is internally reflected by the surface 29 and is emitted from the emission surface 28. Since the reflection intensity of the reflection surface 29 differs depending on the linearly polarized light component included in the light, the light beam incident on the reflection surface 34 and the reflected light beam are separated. The linearly polarized light component oscillating in a direction perpendicular to the plane (hereinafter, referred to as S wave) is internally reflected at a higher intensity than the linearly polarized light component oscillating in the plane (hereinafter, referred to as P wave).
[0057]
Further, as described above, the light guide member 31 enters from the incident end face 32 and goes straight in the light guide member 31 or is internally reflected by the elongated emission surface 33 on one side and is reflected on the other side by the reflection surface. The light incident on the reflecting surface 34 is internally reflected by the reflecting surface 34 and emitted from the elongated emission surface 33. The reflection intensity of the reflecting surface 34 also varies depending on the linearly polarized light component included in the light. The S-wave of the linearly polarized light component oscillating in the direction perpendicular to the plane containing the incident light ray and the reflected light ray is internally reflected with higher intensity than the P-wave of the linearly polarized light component oscillating in the plane.
[0058]
Therefore, the light emitted from the elongated emission surface 33 of the light guide member 31 has a higher intensity of the polarization component of the S-wave than the polarization component of the P-wave.
[0059]
Since the reflection surface 29 of the light guide plate 26 and the reflection surface 34 of the light guide member 31 intersect at 90 degrees with each other, the light emitted from the elongated emission surface 33 of the light guide member 31. Is incident on the light guide plate 26 as it is, of the light, the P wave of low reflection intensity reflected on the reflection surface 34 of the light guide member 31 is reflected on the reflection surface 29 of the light guide plate 26. Since the S-wave having high intensity is incident as an S-wave, and the S-wave having high reflection intensity reflected on the reflection surface 34 of the light guide member 31 is incident on the reflection surface 29 of the light guide plate 26 as a P-wave having low reflection intensity. In addition, the intensity of light emitted from the emission surface 28 of the light guide plate 26 is low.
[0060]
On the other hand, in the surface light sources 25a and 25b, since the λ / 2 phase difference plate 36 is disposed between the incident end surface 27 of the light guide plate 26 and the elongated emission surface 33 of the light guide member 31, FIG. As shown in (2), the S-wave S1 and the P-wave P1 emitted from the elongated emission surface 33 of the light guide member 31 have their polarization planes rotated by 90 degrees by the λ / 2 phase difference plate 36, and The light enters from the incident end face 27.
[0061]
Therefore, of the light emitted from the elongated emission surface 33 of the light guide member 31, the S wave S 1 having high intensity is reflected on the reflection surface 29 of the light guide plate 26 by the S wave S 2 having high reflection intensity by the reflection surface 29. The P wave having a low intensity is incident on the reflection surface 29 of the light guide plate 26 as a P wave having a low reflection intensity by the reflection surface 29.
[0062]
Therefore, according to the surface light sources 25 a and 25 b, the light of the polarization component with high intensity emitted from the elongated emission surface 33 of the light guide member 31 is reflected by the reflection surface 29 of the light guide plate 26 with high reflection intensity. The light can be reflected internally, so that light with sufficient intensity can be emitted from the emission surface 28 of the light guide plate 26.
[0063]
As described above, in the surface light sources 25a and 25b, one end surface of the transparent plate forms the incident end surface 27 on which light is incident, and one of the two plate surfaces of the transparent plate is the light guided inside the transparent plate. A light guide plate that forms a reflection surface 29 that internally reflects the light incident from the incident end surface 27 and emits the light from the emission surface 28, and one side surface of the elongated transparent material. An elongated exit surface 33 that emits light is formed, and one of two end surfaces of the elongated transparent material that intersects the elongated exit surface 33 faces the incident end surface 32 on which light is incident. A side surface forms a reflection surface that internally reflects light incident from the incident end surface 32 and emits the light from the elongated exit surface 33, and the elongated exit surface 33 faces the incident end surface 27 of the light guide plate 26. The light guide member 31 disposed and the light guide plate 6 is disposed between the entrance end face 27 of the light guide member 31 and the elongated exit surface 33 of the light guide member 31, and the polarization plane of the linear polarization component of the light emitted from the elongated exit surface 33 of the light guide member 31 is substantially 90 degrees. Since there are provided a phase difference plate 36 that is rotated to be incident on the incident end face 27 of the light guide plate 26 and a solid light emitting element 38 that is disposed to face the incident end face 32 of the light guide member 31, the number is small. With the number of light emitting elements, light having a uniform intensity distribution and sufficient intensity can be emitted from the entire area of the emission surface 28 of the light guide plate 26.
[0064]
Since the surface light sources 25a and 25b of this embodiment include one solid-state light-emitting element 38 such as an LED as a light-emitting element, the cost can be reduced and the number of electrodes consumed can be reduced.
[0065]
In addition, since the solid-state light emitting element 38 can change the light emission intensity by controlling the driving voltage, the light intensity emitted from the light emission surface 28 of the light guide plate 26 can be adjusted arbitrarily.
[0066]
In addition, the surface light sources 25a and 25b use the reflection surface 34 on the other side surface of the light guide member 31 to apply light incident from the incident end face 32 of the light guide member 31 to the elongated emission surface 33 of the light guide member 31. Since the light guide member 26 is formed by the plurality of prism portions 35 that internally reflect in the direction in which the angle with respect to the line becomes smaller, the light emitted from the elongated emission surface 33 of the light guide member 31 is incident on the light guide plate 26 at the incident end surface 27 thereof. From the vicinity of the direction perpendicular to the light guide plate 26, the light is evenly spread over the entire area of the light guide plate 26, and light with a more uniform intensity distribution is emitted from the entire area of the emission surface 28 of the light guide plate 26. it can.
[0067]
Further, the surface light sources 25a and 25b have a small reflection surface 29 on the rear surface of the light guide plate 26 and a small angle of the light incident from the incident end surface 27 of the light guide plate 26 with respect to the normal line of the emission surface 28 of the light guide plate 26. Since it is formed by a plurality of prism portions 30 that internally reflect in a certain direction, the front luminance (light emitted in a direction near the normal to the emission surface 28 of the light guide plate 26) from the emission surface 28 of the light guide plate 26 is used. High luminance) can be emitted.
[0068]
The front surface light source 25a causes the light exit surface 28 of the light guide plate 26 to face the front surface of the liquid crystal display element 1 (the front surface of the front polarizer 15) and emits light from the light exit surface 28 of the light guide plate 26. The direction parallel to the polarization plane of the high intensity S-wave S2, that is, the length direction of the plurality of elongated prism portions 30 of the reflection surface 29 of the light guide plate 26, is transmitted through the front polarization plate 15 of the liquid crystal display element 1. The rear surface light source 25b is disposed substantially parallel to the axis 15a, and the rear surface light source 25b causes the light exit surface 28 of the light guide plate 26 to face the rear surface of the liquid crystal display element 1 (the rear surface of the rear polarizer 16). At the same time, of the light emitted from the emission surface 28 of the light guide plate 26, a direction parallel to the polarization plane of the high intensity S-wave S2 (the length direction of the plurality of elongated prism portions 30 of the reflection surface 29 of the light guide plate 26). To the rear side of the liquid crystal display element 1. Are arranged substantially parallel to the transmission axis 16a of the plate 16.
[0069]
In this liquid crystal display device, of the two surface light sources 25a and 25b, the front surface light source 10a disposed on the front side of the liquid crystal display element 1 (the side opposite to the side on which the partial reflection / transmission layer 10 is provided). Illumination light is emitted toward the entire display area of the liquid crystal display element 1, and a part of the light emitted from the front side light source 10 a and incident on each of the plurality of pixels A of the liquid crystal display element 1 is reduced. By reflecting the light by the partial reflection / transmission layer 10 and emitting the light to the front side of the front side light source 10a, an image viewed from the front side is displayed, and other light is transmitted through the partial reflection / transmission layer 10 and By emitting the light to the rear side of the rear side light source 10b disposed on the rear side of the liquid crystal display element 1, an image viewed from the rear side is displayed, and the display area of the liquid crystal display element 1 from the rear side light source 10a is displayed. Whole area of The light emitted from the rear side light source 10b is transmitted through the partial reflection / transmission layer 10 of the liquid crystal display element 1, and is incident on the plurality of pixels A. By emitting light to the front side, an image observed from the front side is displayed.
[0070]
The light emitted from the emission surface 28 of the light guide plate 26 of each of the surface light sources 25a and 25b has a polarization plane parallel to the length direction of the plurality of elongated prism portions 30 of the reflection surface 29 of the light guide plate 26. Although the polarization intensity of the S-wave S2 is high and the polarization intensity of the P-wave P2 orthogonal to the S-wave S2 is low, in this liquid crystal display device, the front side light source 25a emits the light emitted from the emission surface 28 of the light guide plate 26. Among them, the direction parallel to the polarization plane of the high intensity S-wave S2 is arranged substantially parallel to the transmission axis 15a of the front polarizer 15 of the liquid crystal display element 1, and the rear light source 25b is connected to the light guide plate 26 thereof. Out of the light exiting from the exit surface 28 of the liquid crystal display element 1, the direction parallel to the polarization plane of the high intensity S-wave S2 is substantially parallel to the transmission axis 16a of the rear polarizing plate 16 of the liquid crystal display element 1. The light from the front side light source 25a. The high-intensity S-wave S2 emitted from the light exit surface 28 of the liquid crystal display element 1 is transmitted through the front polarizer 15 of the liquid crystal display element 1 and is incident on the liquid crystal cell 2, and the light guide plate 26 of the rear side light source 25b is The S-wave S2 having a high intensity of light emitted from the emission surface 28 can be transmitted through the rear polarizing plate 16 of the liquid crystal display element 1 and can be incident on the liquid crystal cell 2.
[0071]
First, a display using illumination light from the front side light source 25a will be described. Illumination light emitted from the front side light source 25a toward the entire display area of the liquid crystal display element 1 is indicated by an arrow in FIG. As described above, the front polarizer 15 of the liquid crystal display element 1 converts the polarized light into linearly polarized light parallel to the transmission axis 15 a, transmits the front retardation plate 17, and is further scattered by the scattering layer 19 to form a plurality of liquid crystal cells 2. To the pixel A from the front side.
[0072]
The light incident on the plurality of pixels A of the liquid crystal cell 2 from the front side is colored by the color filters 9R, 9G, 9B corresponding to the respective pixels A, enters the liquid crystal layer 5, and passes through the liquid crystal layer 5. The liquid crystal cell 2 is subjected to a birefringent action according to the orientation state of the liquid crystal molecules, which is changed by the electric field applied between the electrodes 6 and 7 of each pixel A, and the partial reflection provided on the inner surface of the rear substrate 4 of the liquid crystal cell 2 And a part of the light, that is, the light incident on the area A1 corresponding to the reflective film 10a of the partial reflection / transmission layer 10 in the pixel A is directed forward by the partial reflection / transmission layer 10. The other light that is reflected and enters the area A2 corresponding to the portion of the partial reflection / transmission layer 10 in the pixel A where the reflection film 10a is not provided passes through the partial reflection / transmission layer 10.
[0073]
The light reflected by the partial reflection / transmission layer 10 passes through the liquid crystal layer 5 and the color filters 9R, 9G, 9B again, exits to the front side of the liquid crystal cell 2, and is scattered by the scattering layer 19. The polarized light component transmitted through the front-side retardation plate 17 and incident on the front-side polarizing plate 15, and the polarized light component of the light, which is parallel to the transmission axis 15 a of the front-side polarizing plate 15, passes through the front-side polarizing plate 15 and the front surface. The light passes through the light guide plate 26 of the light source 25a and is emitted to the front side, and the polarized component parallel to the absorption axis of the front side polarizing plate 15 is absorbed by the front side polarizing plate 15 to display an image observed from the front side.
[0074]
On the other hand, of the light incident on the plurality of pixels A of the liquid crystal cell 2 from the front side thereof, the light transmitted through the partial reflection / transmission layer 10 is emitted to the rear side of the liquid crystal cell 2.
[0075]
The light emitted to the rear side of the liquid crystal cell 2 passes through the rear retardation plate 18 and enters the rear polarizing plate 16, and of the light, the light is parallel to the transmission axis 16 a of the rear polarizing plate 16. The polarized light component passes through the rear polarizer 16 and passes through the light guide plate 26 of the rear side light source 25b and is emitted to the rear side, and the polarized light component parallel to the absorption axis of the rear polarizer 16 is transmitted to the rear side. An image which is absorbed by the polarizing plate 16 and observed from the rear side is displayed.
[0076]
Next, a display using illumination light from the rear side light source 25b will be described. Illumination light emitted from the rear side light source 25b toward the entire display area of the liquid crystal display element 1 is indicated by an arrow in FIG. As shown, the rear polarizing plate 16 of the liquid crystal display element 1 converts the light into linearly polarized light parallel to the transmission axis 16a, passes through the rear retardation plate 18, and enters the partial reflection / transmission layer 10, Of the light, the light incident on the area A2 corresponding to the portion of the partial reflection / transmission layer 10 that does not have the reflection film 10a transmits through the partial reflection / transmission layer 10 and a plurality of pixels A of the liquid crystal cell 2. At the rear side.
[0077]
The light incident on the plurality of pixels A of the liquid crystal cell 2 from the rear side respectively changes the alignment state of the liquid crystal molecules by the electric field applied between the electrodes 6 and 7 of each pixel A while passing through the liquid crystal layer 5. And is colored by the color filters 9R, 9G, 9B corresponding to the respective pixels A, and is emitted to the front side of the liquid crystal cell 2.
[0078]
The light emitted to the front side of the liquid crystal cell 2 is scattered by the scattering layer 19, passes through the front phase difference plate 17 and is incident on the front polarizing plate 15. A polarization component parallel to the transmission axis 15a transmits through the front-side polarizing plate 15 and passes through the light guide plate 26 of the front-side light source 25a and is emitted to the front side. The image absorbed by the front polarizing plate 15 and observed from the front side is displayed.
[0079]
In this embodiment, since the liquid crystal display element 1 is in the normally white mode, neither the image observed from the front side nor the image observed from the rear side includes the plurality of pixels A of the liquid crystal cell 2. Light emitted from an electric field-free pixel (a pixel in which liquid crystal molecules are in an initial alignment state) in which an electric field is not applied between the electrodes 6 and 7 is transmitted through the front and rear polarizers 15 and 16 and is emitted to be red and green. , Blue light, and light emitted from an electric field applied pixel to which an electric field is applied between the electrodes 6 and 7 so that liquid crystal molecules rise substantially vertically to the substrates 3 and 4 and are aligned. Is a color image which is absorbed by the polarizing plates 15 and 16 to form a black dark display.
[0080]
That is, the liquid crystal display device emits illumination light from the front side light source 25a toward the entire display area of the liquid crystal display element 1, thereby displaying an image observed from the front side by reflection display using the illumination light. By displaying an image observed from the rear side by the transmissive display using the illumination light, and emitting the illumination light from the rear side light source 25b toward the entire display area of the liquid crystal display element 1, An image viewed from the front side is displayed by a transmissive display using illumination light.
[0081]
According to this liquid crystal display device, both the image observed from the front side which is one surface side and the image observed from the rear side which is the other surface side are displayed on the entire display area of the liquid crystal display element 1. Therefore, the display area of the liquid crystal display element 1 may have a size corresponding to one of the front and rear display screens.
[0082]
Therefore, according to this liquid crystal display device, double-sided display can be performed using one liquid crystal display element 1, and the occupied area can be reduced.
[0083]
Further, the liquid crystal display device includes front and rear light sources 25a and 25b that emit light having a uniform intensity distribution and sufficient intensity from the entire exit surface 28 of the light guide plate 26 as described above. The direction parallel to the vibration plane of the high intensity S wave S2 of the light emitted from the emission surface 28 of the light guide plate 26 is substantially the same as the transmission axis 15a of the front polarizing plate 15 of the liquid crystal display element 1. The liquid crystal display element 1 is arranged in parallel with the rear side light source 26a. The light emitted from the light exit surface 28 of the light guide plate 26 is directed to the direction parallel to the vibrating surface of the high intensity S wave S2. The S-wave S2 having a high intensity of light emitted from the emission surface 28 of the light guide plate 26 of each of the surface light sources 25a and 25b is disposed in the liquid crystal display element because the S-axis S2 is disposed substantially parallel to the transmission axis 16a of the plate 16. 1 front polarizer 15 and rear polarizer By transmitting plate 16 is incident on the liquid crystal cell 2, the liquid crystal display device 1, bright, yet it is possible to display a high quality image without uneven brightness.
[0084]
Moreover, in this liquid crystal display device, since the front side light source 25a and the rear side light source 25b transmit light incident from the front side and the rear side, respectively, as shown by broken lines in FIG. Light (light of the external environment) is transmitted through the front side light source 25a and is incident on the liquid crystal display element 1. Of the light incident on the plurality of pixels A of the liquid crystal display element 1, the partial reflection / transmission layer is included. The light reflected by the light source 10 is emitted to the front side of the front side light source 25a, the light transmitted through the partial reflection / transmission layer 10 is emitted to the rear side of the rear surface light source 25b, and external light incident from the rear side. Is transmitted through the rear side light source 25b and is incident on the liquid crystal display element 1. Of the light, the light transmitted through the partial reflection / transmission layer 10 and incident on each of the plurality of pixels A is referred to as the front side. Of the light source 25a It can be emitted to the side.
[0085]
Therefore, according to this liquid crystal display device, an image viewed from the front side is reflected by the illumination display from the front side light source 25a and the external light incident from the front side, and the illumination light from the rear side light source 25b. And a transmissive display using external light incident from the rear side, and an image observed from the rear side is displayed by an illumination light from the front side light source 25a and a transmissive display using external light incident from the front side. Can be displayed.
[0086]
In the case of the display using the external light, the image observed from the front side is an environment where external light is incident from both the front side and the rear side of the liquid crystal display device, and the reflection of the external light incident from the front side, The display is performed by both the transmission of the external light incident from the rear side, and in an environment where the external light does not enter from the rear side of the liquid crystal display device, the display is performed by the reflection of the external light incident from the front side.
[0087]
Further, in the case of the display using the external light, when the intensity of the incident external light is insufficient and a display of sufficient brightness cannot be obtained, an image observed from the front side is displayed on the front and rear surface light sources. The display is performed by emitting illumination light having an intensity that compensates for the lack of the intensity of the external light from one or both of the light sources 25a and 25b, and an image observed from the rear side is compensated for the lack of the intensity of the external light from the front side light source 25a. The display may be performed by emitting high-intensity illumination light. In this way, by using the surface light sources 25a and 25b as auxiliary light sources during display using external light, a display with sufficient brightness can be obtained. Can be.
[0088]
As described above, the liquid crystal display device reflects a part of the light incident on each of the plurality of pixels A from the front side of the liquid crystal cell 2 behind the liquid crystal layer 5 of the liquid crystal cell 2 and reflects the other light. A display area in which a plurality of pixels A of the liquid crystal display element 1 are arranged on the front side and the rear side of the liquid crystal display element 1 provided with a reflection / transmission means (partial reflection / transmission layer in the above embodiment) 10 for transmitting light. Since two surface light sources 25a and 25b that emit illumination light toward the whole area and transmit light incident from the front side and the rear side are arranged, two-sided display is performed using one liquid crystal display element 1, Moreover, the occupied area is reduced, and an image observed from one surface side (front side) and an image observed from the other surface side (rear side) are used with illumination light from the surface light sources 25a and 25b, respectively. Display and the light of the external environment It can be displayed by a display utilizing light.
[0089]
In the above embodiment, the liquid crystal cell 2 of the liquid crystal display element 1 is provided on the rear side of the liquid crystal layer 5 with a predetermined area in the plurality of pixels A of the liquid crystal cell 2 as the reflection / transmission means. It has a plurality of corresponding reflective films 10a, and among the light incident on the plurality of pixels A, reflects the light incident on the reflective film 10a and transmits the light incident on a portion without the reflective film 10a. Since the partial reflection / transmission layer 10 is provided, the liquid crystal cell 2 is provided with a plurality of liquid crystal cells 2 both when displaying using illumination light from the front and rear surface light sources 25a and 25b and when displaying using external light. The image to be observed from the front side is displayed by emitting light to the front side from the predetermined area in the pixel A, and the light is emitted to the rear side from the other area in the plurality of pixels A from the rear side. The image to be observed can be displayed.
[0090]
Further, in the above embodiment, the liquid crystal display element 1 is provided with front and rear polarizers (absorption polarizers) 15 and 16 arranged with the liquid crystal cell 2 interposed therebetween, and the reflection / transmission means (partial reflection / transmission (Transmissive layer) 10 is provided between the rear polarizer 16 and the liquid crystal layer 5, so that an image observed from the front side can be illuminated with illumination light from the front side light source 25a and external light incident from the front side. The light absorption by the polarizing plate when displaying by the reflection display to be used is made only the absorption at the time of incidence and at the time of emission by the front-side polarizing plate 15, and a bright display can be obtained.
[0091]
In the above embodiment, the plurality of reflection films 10a of the partial reflection / transmission layer 10 are formed so as to correspond to approximately 1/2 regions in the plurality of pixels A of the liquid crystal cell 2, respectively. The shape and the area ratio of the reflection part corresponding to the reflection film 10a of the partial reflection / transmission layer 10 and the transmission part without the reflection film 10a may be arbitrarily determined. May be formed plurally.
[0092]
Further, the reflection / transmission means is not limited to the partial reflection / transmission layer 10 of the above-described embodiment. For example, a transflective film that reflects and transmits incident light at a predetermined reflectance and transmittance, or an incident light Out of the two polarized light components different from each other, a polarized light separating element that reflects one polarized light component and transmits the other polarized light component may be used, and the reflection / transmission means may be the transflective film or the polarized light separating element. Accordingly, both when displaying using the illumination light from the surface light sources 25a and 25b and when displaying using external light, light is emitted from the entire area of the plurality of pixels A of the liquid crystal cell 2 to the front side and the rear side. Is emitted, and both the image observed from the front side and the image observed from the rear side can be displayed using the entire area of the plurality of pixels A of the liquid crystal cell 2.
[0093]
Further, in the liquid crystal display device of the above embodiment, the display contrast and the viewing angle between the liquid crystal cell 2 of the liquid crystal display element 1 and the front polarizer 15 and between the liquid crystal cell 2 and the rear polarizer 16 are respectively reduced. Since the retardation plates 17 and 18 for improving the brightness are arranged and the scattering layer 19 is arranged between the liquid crystal cell 2 and the retardation plate 17 on the front side thereof, the scattering is provided on the front side and the rear side, respectively. Light scattered by the layer 19 and having a uniform luminance distribution can be emitted, and therefore, both the image viewed from the front side and the image viewed from the rear side have sufficient contrast and viewing angle, and A high quality image without uneven brightness can be obtained.
[0094]
In the above embodiment, the scattering layer 19 is disposed between the liquid crystal cell 2 and the front retardation plate 17. However, the scattering layer 19 is provided between the front polarizing plate 15 and the front retardation plate 17. It may be arranged between them.
[0095]
FIG. 6 is a cross-sectional view of a part of another liquid crystal display device. In this liquid crystal display device, a liquid crystal cell 2 of a liquid crystal display element 1 has a plurality of pixels A on the inner surface of a rear substrate 4 as reflection / transmission means. A partial reflection / transmission layer (hereinafter, referred to as a rear partial reflection / transmission layer) 10 having a plurality of reflection films 10a respectively corresponding to predetermined regions in the front substrate 3 is provided on the inner surface of the front substrate 3. A second partial reflection / transmission having a plurality of reflection films 11a respectively corresponding to predetermined regions among regions other than the portion corresponding to the reflection film 10a of the rear partial reflection / transmission layer 10 in the pixel A. A layer (hereinafter referred to as a front partial reflection / transmission layer) 11 is provided, the phase difference plate 18 on the rear side of the liquid crystal cell 2 in the above embodiment is omitted, and the rear polarization in the above embodiment is further omitted. Plate (absorption polarizing plate) 1 Has a reflection axis and a transmission axis in directions orthogonal to each other, and absorbs one polarized component having a vibration plane parallel to the reflection axis among two linearly polarized lights of the incident light orthogonal to each other, and In this embodiment, a reflection polarizing plate 20 having a vibration plane parallel to the axis and transmitting the other polarization component is used, and a second scattering layer 21 is disposed between the reflection polarizing plate 20 and the liquid crystal cell 2. The other configuration is the same as that of the liquid crystal display of the above embodiment.
[0096]
That is, in this liquid crystal display device, the rear partial reflection / transmission layer 10 and the front partial reflection / transmission layer 11 are provided on the inner surface of the rear substrate 4 and the inner surface of the front substrate 3 of the liquid crystal display element 1. A portion corresponding to the reflection film 10a of the rear partial reflection / transmission layer 10 in each pixel A of the liquid crystal cell 2 is a front reflection portion Aa for reflecting light incident from the front side to the front side by the reflection film 10a, A portion corresponding to the reflection film 11a of the front partial reflection / transmission layer 11 in each of the pixels A is defined as a rear reflection portion Ab that reflects light incident from the rear side to the rear side by the reflection film 11a. Areas other than the portions corresponding to the reflective films 10a and 11a of the rear and front partial reflection / transmission layers 10 and 11 in A are defined as transmission portions Ac that transmit light incident from the front and rear sides, respectively. liquid On the rear side of the cell 2, the reflective polarizer 20 is disposed as a rear-side polarizing plate, between the reflective polarizer 20 and the liquid crystal cell 2 is obtained by the second scattering layer 21 is disposed.
[0097]
In this liquid crystal display device, a plurality of reflective films 10a of the rear partial reflection / transmission layer 10 are provided corresponding to approximately one third of one side of each pixel A, respectively, and the front partial reflection / transmission layer 10 is provided. By providing a plurality of reflective films 11a of the transmission layer 11 corresponding to approximately one-third of the other side of each pixel A, approximately one-third of one side of each pixel A is reflected forward. The portion Aa, approximately one-third of the region on the other side is defined as a rear reflection portion Ab, and the remaining region of each pixel A, that is, approximately one-third of the center of each pixel A, is incident from the front side and the rear side. The light-transmitting portion Ac transmits light.
[0098]
Further, the liquid crystal display element 1 is a TN type liquid crystal display device in which the display viewed from the front side is a normally white mode, and the reflective polarizing plate 20 has a transmission axis whose front side is disposed on the front side of the liquid crystal cell 2. The transmission axis 15a of the polarizing plate (absorption polarizing plate) 15 is substantially parallel to the transmission axis 15a of the front-side polarizing plate 15, and the reflection axis is substantially orthogonal to the transmission axis 15a.
[0099]
This liquid crystal display device converts an image observed from the front side into light (illumination light from the front side light source 25a or external light incident from the front side) among the light incident on the plurality of pixels A from the front side of the liquid crystal display element 1. A reflective display in which light incident on the front reflective portion Aa and reflected by the reflective film 10a of the rear partial reflection / transmission layer 10 is emitted to the front side; and the plurality of pixels A from the rear side of the liquid crystal display element 1. (Illumination light from the rear side light source 25b or external light incident from the rear side) of the light incident on the transmission part Ac, and the light transmitted through the transmission part Ac is emitted to the front side. The liquid crystal display device 1 performs an image viewed from the rear side of the light (illumination light from the rear side light source 25b or external light incident from the rear side) on the plurality of pixels A from the rear side of the liquid crystal display element 1. Before entering the rear reflector Ab A reflection display in which light reflected by the reflection film 11a of the front partial reflection / transmission layer 11 is emitted to the rear side; and light incident on the plurality of pixels A from the front side of the liquid crystal display element 1 (from the front side light source 25a). (Illumination light or external light incident from the front side), the light is incident on the transmissive portion Ac, and the light transmitted through the transmissive portion Ac is transmitted to the rear side. According to the apparatus, an image observed from the front side and an image observed from the rear side can be displayed by both the reflection display and the transmission display.
[0100]
Note that the liquid crystal display device shown in FIGS. 1 and 2 and the liquid crystal display device shown in FIG. 6 each include a TN type liquid crystal display element 1, but the liquid crystal display element has a TN type. The present invention is not limited to this, and may be an STN (super twisted nematic) type, a non-twist homogeneous alignment type, a ferroelectric or antiferroelectric liquid crystal display device, or the like.
[0101]
Further, the liquid crystal display element is not limited to a normally white mode, and may be a normally black mode. The liquid crystal cell is not limited to an active matrix type and may be a simple matrix type.
[0102]
Further, the front and rear side light sources 25a and 25b of the liquid crystal display device use the reflection surface 34 on the other side of the light guide member 31 to change the light incident from the incident end face 32 of the light guide member 31 to the light guide member 31. It is formed by a plurality of prism portions 35 that internally reflect in a direction in which the angle of the elongated emission surface 33 on one side with respect to the normal line becomes smaller, and the reflection surface on the other side of the light guide member 31 is, for example, The light guide member 31 may have a continuous inclined surface that is inclined from the incident end surface 32 side to the other end side in a direction closer to the elongated emission surface 33.
[0103]
Further, the surface light sources 25a and 25b are arranged so that the reflection surface 29 of the light guide plate 26 is oriented such that the light incident from the incident end face 27 of the light guide plate 26 has a smaller angle with respect to the normal to the exit surface 28 of the light guide plate 26. The reflection surface 29 of the light guide plate 26 is, for example, formed on the emission surface 28 from the incident end surface 27 side of the light guide plate 26 toward the other end side. It may be a continuous inclined surface that is inclined in the direction of becoming closer.
[0104]
Further, in the surface light sources 25a and 25b, one solid-state light-emitting element 38 is disposed so as to face the incident end face 32 of the light guide member 31, and the area of the incident end face 32 of the light guide member 31 is the same as that described above. If it is larger than the solid state light emitting elements 38, a plurality of solid state light emitting elements 38 may be arranged to face the incident end face 32 of the light guide member 31.
[0105]
In the surface light sources 25a and 25b, one end face of the light guide plate 26 is formed on the incident end face 27, and the light guide member 31 having one end face formed on the incident end face 32 is arranged to face the incident end face 27, and The solid-state light-emitting element 38 is disposed so as to face the incident end face 32 of the light guide member 31. Both end faces of the light guide member 31 are formed on the incident end faces 32, respectively, and both of the incident end faces 32 are provided. The solid-state light-emitting elements 38 may be arranged so as to face each other. Also, both end faces of the light guide plate 26 are formed on the incident end faces 27, respectively, and the λ / 2 phase difference plates In addition to disposing the light guide member 31 and the light guide member 31, the solid state light emitting element 38 may be disposed so as to face the incident end surfaces 32 of these light guide members 31 respectively.
[0106]
Further, the surface light sources 25a and 25b emit illumination light toward the entire display area where the plurality of pixels A of the liquid crystal display element 1 are arranged, and transmit light incident from the front side and the rear side. For example, the light guide member 31 may be omitted, and a light emitting element such as a straight-tube cold-cathode tube may be disposed so as to face the incident end surface 27 of the light guide plate 26.
[0107]
The liquid crystal display device is used for a double-sided display type portable device. Note that the liquid crystal display device of the embodiment shown in FIGS. 1 and 2 converts an image observed from the front side into a reflective display using illumination light from the front side light source 25a and external light incident from the front side, and An image viewed from the rear side is displayed by illuminating light from the side light source 25b and transmissive display using external light incident from the rear side, and illumination light from the front side light source 25a and external light incident from the front side are displayed. Both the front side and the rear side are used for displaying the image viewed from the rear side with the transmission display using the illumination light from the front side light source 25a and the external light incident from the front side. By emitting illumination light from the surface light sources 25a and 26b, the image observed from the front side can be made brighter than the image observed from the rear side, and external light can be emitted from both the front side and the rear side. Under the incident environment Even when using crystal display device, brighter than the image which the image observed from the front side is observed from the rear side.
[0108]
Therefore, in the liquid crystal display device of the embodiment, the front surface, that is, the outer surface (reflection surface 29) of the light guide plate 26 of the front side light source 25a is used as the main display surface, and the rear surface, that is, the outer surface of the light guide plate 26 of the rear side light source 25b ( It is preferable to use the reflection surface 29) as a sub display surface.
[0109]
7 to 10 are perspective views of a double-sided display type mobile device on which the liquid crystal display device of the above embodiment is mounted.
[0110]
The mobile device shown in FIG. 7 is a foldable mobile phone 40, which has a main body 41 having a keyboard 42 on the upper surface and display portions 44a and 44b on two outer surfaces which are opposite to each other. And a lid 43 that is pivotally opened and closed with respect to.
[0111]
The portable telephone 40 has a main display of an inner surface of the lid 43 (a surface facing the user of the telephone when the lid 43 is opened) with the lid 43 opened as shown in FIG. 7A. The main information such as destination data and transmitted / received mail is displayed on the section 44a, and a clock is displayed on the sub-display section 44b on the outer surface of the lid 43 with the lid 43 closed as shown in FIG. And display sub-information such as transmission source data. The display units 44a and 44b on both sides are provided with display windows 45a and 45b on the inner surface and the outer surface of the lid 43, respectively. The liquid crystal display device is configured by mounting the liquid crystal display device with its front surface (main display surface) facing the display window 45a on the inner surface of the lid and its rear surface (sub display surface) facing the display window 45b on the outer surface of the lid. ing.
[0112]
In addition, the mobile phone 40 drives the liquid crystal display element 1 of the liquid crystal display device so as to display an image in which the left and right are reversed when the lid 43 is opened and closed. Since a display drive unit is provided, a correct image without left-right inversion can be displayed on the main display portion 44a on the inner surface of the lid portion 43 and the sub-display portion 44b on the outer surface.
[0113]
The portable device shown in FIG. 8 is a thin digital camera 50, and two outer surfaces of a camera body 51 provided with an imaging lens 52, a finder 53, and the like, which are opposite to each other, that is, the rear surface shown in FIG. Display portions 44a and 44b are respectively provided at positions corresponding to the back of the (photographer-side surface) and the front surface (subject-side surface) shown in FIG. 8B.
[0114]
The digital camera 50 displays an image being captured or a stored image that has been captured on a main display unit 54a on the rear side and a sub display unit 54b on the front side, and the display units 54a and 54b on both sides are provided with the camera. Display windows 55a and 55b are provided on the rear surface and the front surface of the main body 51, respectively. The liquid crystal display device is provided inside the camera main body 51, and the front surface (main display surface) is provided on the display window 55a on the rear surface of the camera main body 51. The camera is mounted such that the rear surface (sub display surface) faces the display window 55b on the front surface of the camera body 51.
[0115]
Note that the digital camera 50 can display an image being captured or a stored image by selecting one of the main display unit 54a and the sub-display unit 54b, and also displays the image on the main display unit 54a. The display can be simultaneously performed on both of the sub-display units 54b. When either the main display unit 54a or the sub-display unit 54b is selected for display, the liquid crystal display element 1 of the liquid crystal display device is turned on. By driving the display so that the left and right images are inverted between when the image is displayed on the main display unit 54a and when the image is displayed on the sub display unit 54b, there is no right and left inversion in any of the display units 54a and 54b. When an image is displayed and displayed simultaneously on both the main display unit 54a and the sub display unit 54b, the image is displayed on one of the both 54a and 54b, for example, on the sub display unit 54b. Image display image of the main display section 54a is horizontally reversed can be displayed.
[0116]
The portable device shown in FIG. 9 is a notebook computer 60, which has a main body 61 having a keyboard 62 on the upper surface and display portions 64a and 64b on two outer surfaces opposite to each other. And a lid 63 that is pivotally opened and closed.
[0117]
As shown in FIG. 9A, the notebook personal computer 60 has a main part on an inner surface of the lid 63 (a surface facing the user of the personal computer when the lid 63 is opened) with the lid 63 opened. The main information is displayed on the display unit 64a, and the sub-information is displayed on the sub-display unit 64b on the outer surface of the lid 63 with the lid 63 closed as shown in FIG. 9B. The display portions 64a and 64b are provided with display windows 65a and 65b on the inner surface and the outer surface of the lid portion 63, respectively. The liquid crystal display device is provided inside the lid portion 63, and the front surface (main display surface) is covered. It is configured such that it is mounted so as to face the display window 65a on the inner surface of the unit and the rear surface (sub-display surface) faces the display window 65b on the outer surface of the lid.
[0118]
Even when the lid 63 is closed, the notebook computer 60 partially displays a clock or an illustration on a part of the sub-display 64b on the outer surface thereof, or displays a television image on the entire sub-display 64b. The liquid crystal display element 1 of the liquid crystal display device displays an image in which the left and right are inverted when the lid 63 is opened and closed. By driving as described above, a correct image without left-right inversion can be displayed on the main display portion 64a on the inner surface of the lid portion 63 and the sub-display portion 64b on the outer surface.
[0119]
Note that the notebook personal computer 60 may have a configuration in which a transparent touch input panel is arranged on the sub display portion 64b on the outer surface of the lid portion 63 so as to overlap the rear surface of the liquid crystal display device. Even when the lid 63 is closed, the information can be input from the touch input panel and information can be displayed on the sub-display 64b to be used.
[0120]
The portable device shown in FIG. 10 is a video camera 70, which is provided with an imaging lens 72, a finder 73, and the like, and has a monitor body 74 formed on one side and a camera main body 71 formed on two opposite outer surfaces. Each has display sections 76a and 76b, and includes a monitor section 75 which is used by being raised from a monitor storage section 74 of the camera body 71.
[0121]
The video camera 70 displays an image being picked up or a stored image that has been picked up by a main display portion 76a on the rear surface of the monitor portion shown in FIG. 10B and a sub display on the front surface of the monitor portion shown in FIG. The display section 76b on both sides of the monitor section 75 is provided with display windows 77a and 77b on the rear and front sides of the monitor section 75, respectively. The liquid crystal display device has a front surface (main display surface) facing the display window 77a on the rear surface of the monitor unit 75 and a rear surface (sub display surface) facing the display window 77b on the front surface of the monitor unit 75. It is configured by implementing.
[0122]
The video camera 70 can display an image being captured or a stored image by selecting one of the main display unit 76a and the sub-display unit 76b on both sides of the monitor unit 75, and It is also possible to simultaneously display both the main display section 76a and the sub-display section 76b, and to select and display one of the main display section 76a and the sub-display section 76b, By driving the liquid crystal display element 1 so as to display an image in which the left and right are inverted when displaying on the main display section 76a and when displaying on the sub display section 76b, both the display sections 76a and 76b are displayed. When displaying a correct image without horizontal reversal and displaying it simultaneously on both the main display section 76a and the sub-display section 76b, one of the two 76a and 76b, for example, On the display unit 76 b, it is possible to display an image display image of the main display section 76a is horizontally reversed.
[0123]
Each of the portable devices 40, 50, 60, and 70 shown in FIGS. 7 to 10 is a device in which the liquid crystal display device mounted inside thereof performs one-sided display using one liquid crystal display element 1. The area occupied by the liquid crystal display device in the inside is sufficient for approximately one liquid crystal display element 1, so that the size of the device can be reduced, and both sides can be displayed with a sufficiently large screen size. It can be manufactured at a lower cost as compared with a device equipped with a double-sided display type liquid crystal display device having two liquid crystal display elements.
[0124]
In addition, the portable devices 40, 50, 60, and 70 display the images viewed from the front and rear sides of the liquid crystal display device using the illumination light from the surface light sources 25a and 25b and the display using the external light, respectively. Therefore, both of the displays on both sides can be displayed by a display using illumination light from the surface light sources 25a and 25b of the liquid crystal display device and a display using external light.
[0125]
The liquid crystal display device of the present invention can be used not only for the above-described mobile phone 40, digital camera 50, notebook computer 60, and video camera 70 but also for other double-sided display type mobile devices. Display windows are respectively provided on two external surfaces of the device opposite to each other, and inside the liquid crystal display device, the front surface is opposed to one display window of the two external devices, and the rear surface is opposed to the other display window. And implement it.
[0126]
【The invention's effect】
According to the liquid crystal display device of the present invention, a reflection / transmission means for reflecting a part of light incident on each of a plurality of pixels from the front side of the liquid crystal cell behind the liquid crystal layer of the liquid crystal cell and transmitting other light. On the front side and the rear side of the liquid crystal display element provided with, the illumination light is emitted toward the entire display area where the plurality of pixels of the liquid crystal display element are arranged, and the light incident from the front side and the rear side is emitted. Since the front side light source and the rear side light source to be transmitted are arranged, both sides are displayed using one liquid crystal display element, the occupied area is reduced, and an image observed from one surface side (front side). And an image viewed from the other surface side (rear side) can be displayed by a display using illumination light from the surface light source and a display using external light that is light of an external environment.
[0127]
In the liquid crystal display device according to the present invention, the reflection / transmission means of the liquid crystal display element has a plurality of reflection films respectively corresponding to predetermined regions in a plurality of pixels of the liquid crystal cell, and the plurality of reflection films are provided on the plurality of pixels. It is preferable that the light-reflecting layer be formed of a partial reflection / transmission layer that reflects the light incident on the reflection film and transmits the light incident on the portion without the reflection film. When displaying using illumination light from the front and rear surface light sources, even when displaying using external light, light is emitted forward from a predetermined region in a plurality of pixels of the liquid crystal cell. Thus, an image observed from the front side can be displayed, and light can be emitted from another region in the plurality of pixels to the rear side to display an image observed from the rear side.
[0128]
Further, the liquid crystal display device includes front and rear polarizers disposed with the liquid crystal cell interposed therebetween, and the reflection / transmission unit is provided between the rear polarizer and a liquid crystal layer. In this way, light absorption by the polarizing plate when displaying an image observed from the front side by reflection display using illumination light from the front side light source 25a and external light incident from the front side can be reduced. By using the front polarizer, only absorption at the time of incidence and at the time of emission can be performed, and a bright display can be obtained.
[Brief description of the drawings]
FIG. 1 is an exploded perspective view of a liquid crystal display device according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view of a part of the liquid crystal display device.
FIG. 3 is a plan view of a surface light source before and after the liquid crystal display device.
FIG. 4 is a side view of the surface light source.
FIG. 5 is a schematic view showing a linear polarization component of light emitted from the light guide member, the phase difference plate, and the light guide plate of the surface light source.
FIG. 6 is a cross-sectional view of a part of another liquid crystal display device.
FIG. 7 is a perspective view of a mobile phone on which the liquid crystal display device of the present invention is mounted.
FIG. 8 is a perspective view of a digital camera on which the liquid crystal display device of the present invention is mounted.
FIG. 9 is a perspective view of a notebook computer on which the liquid crystal display device of the present invention is mounted.
FIG. 10 is a perspective view of a video camera on which the liquid crystal display device of the present invention is mounted.
[Explanation of symbols]
1: Liquid crystal display element
2: Liquid crystal cell
3,4 ... substrate
5 ... Liquid crystal layer
6,7 ... electrode
8 ... TFT
9R, 9G, 9B ... Color filter
10. Partial reflection / transmission layer (reflection / transmission means)
10a ... reflective film
A: Pixel
15, 16 ... absorption polarizer
17, 18… Phase plate
19: Light scattering layer
25a, 25b ... surface light source

Claims (3)

A liquid crystal layer is provided between the front substrate and the rear substrate that are disposed to face each other, and at least one electrode is provided on one of the opposed inner surfaces of the front substrate and the rear substrate, and the at least one electrode is provided on the other inner surface. A liquid crystal cell provided with a plurality of electrodes forming a plurality of pixels arranged in a matrix by opposing regions; and a liquid crystal cell provided on the rear side of the liquid crystal layer and incident on the plurality of pixels from the front side of the liquid crystal cell. A liquid crystal display element having a reflection / transmission means for reflecting a part of the reflected light and transmitting other light;
Arranged on the front side and the rear side of the liquid crystal display element, respectively, emits illumination light toward the entire display area where the plurality of pixels of the liquid crystal display element are arranged, and light incident from the front side and the rear side. Two surface light sources to be transmitted;
A liquid crystal display device comprising: The reflection / transmission means of the liquid crystal display element has a plurality of reflection films respectively corresponding to predetermined regions in a plurality of pixels of the liquid crystal cell, and includes a reflection film of light incident on each of the plurality of pixels. 2. The liquid crystal display device according to claim 1, further comprising a partial reflection / transmission layer that reflects light incident on said portion and transmits light incident on a portion having no reflection film. The liquid crystal display element includes front and rear polarizers disposed with a liquid crystal cell interposed therebetween, and the reflection / transmission means is provided between the rear polarizer and the liquid crystal layer. The liquid crystal display device according to claim 1.

Images