JP4062032B2 - Liquid crystal display - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a double-sided display type liquid crystal display device.
[0002]
[Prior art]
The double-sided display type liquid crystal display device is used in electronic devices such as a folding cellular phone in which display units are provided on both sides of a lid body that is pivotally opened and closed with respect to the device body.
[0003]
In the double-sided display type liquid crystal display device, for example, two liquid crystal elements that reflect or transmit light incident from the front side or the rear side and emit the light to the front side are arranged in a back-to-back state with their emission surfaces facing in opposite directions. This can be configured.
[0004]
However, since the use of two liquid crystal elements increases the cost, it is desired to perform double-sided display using one liquid crystal element.
[0005]
Conventionally, as a double-sided display type liquid crystal display device that performs double-sided display using a single liquid crystal element, the display area of the liquid crystal element has a front emission area that emits incident light to the front side, and a rear emission that emits incident light to the rear side. It is divided into areas, and an image observed from the front side by the front emission area is displayed, and an image observed from the rear side by the rear emission area is displayed (Patent Document 1,). Patent Document 2).
[0006]
[Patent Document 1]
JP 2000-193946 A
[0007]
[Patent Document 2]
JP 2001-305525 A
[0008]
[Problems to be solved by the invention]
However, in the conventional double-sided display type liquid crystal display device in which the display area of the liquid crystal element is divided into the front emission area and the rear emission area, the area of the display area of the liquid crystal element is the front display screen and the rear display screen. Since the flat area of the liquid crystal display device is much larger than the front and rear display screens, it should be mounted on a small electronic device such as a mobile phone. I can't.
[0009]
The present invention provides a double-sided display type liquid crystal display device that can perform double-sided display using a single liquid crystal element and can reduce the plane area to the same extent as the display screen on either the front side or the rear side. Is intended to provide.
[0010]
[Means for Solving the Problems]
  In the liquid crystal display device of the present invention, a liquid crystal layer is provided between the front substrate and the rear substrate that are arranged to face each other, and at least one electrode is provided on one of the opposing inner surfaces of the front substrate and the rear substrate. A plurality of electrodes for forming a plurality of pixels by a region facing the at least one electrode are provided on the inner surface, and a predetermined inner surface of the plurality of pixels is provided on the inner surface of the front substrate.In a predetermined second area of the areas excluding the first areaA plurality of front reflective films are provided in correspondence with each other, and the inner surface of the rear substrate is provided on the inner surface of the plurality of pixels.The first region andThe front reflective film correspondsSecond areaOther than predeterminedThird areaA plurality of rear reflection films are provided in correspondence with each of the plurality of pixels, and the rear reflection films of the plurality of pixels are provided.Third areaAs a result, a front reflection portion that reflects light incident from the front side by the rear reflection film and emits the light to the front side is formed, and the front reflection film of the plurality of pixels is provided.Second areaAs a result, a rear reflection part is formed that reflects light incident from the rear side by the front reflection film and emits the light to the rear side.The first region other than the second region and the third region forms a transmission part that transmits light incident from the front side and the rear side and emits the light to the rear side and the front side.And a front polarizing plate and a rear polarizing plate disposed on the front side and the rear side of the liquid crystal device.
[0011]
  That is, this liquid crystal display device reflects the light incident from the front side and emits it to the front side in each of the plurality of pixels of the liquid crystal element, and reflects the light incident from the rear side and emits it to the rear side. With back reflectorA transmission part that transmits light incident from the front side and the rear side and emits the light to the rear side and the front side;And a front polarizing plate and a rear polarizing plate are arranged on the front side and the rear side of the liquid crystal element, and are observed from the front side by the light emitted from the front reflecting portions of the plurality of pixels of the liquid crystal element. An image is displayed, and an image observed from the rear side is displayed by the light emitted from the rear reflecting portions of the plurality of pixels of the liquid crystal element.
[0012]
  The liquid crystal display device displays an image observed from the front side by the light emitted from the front reflecting portions of the plurality of pixels of the liquid crystal element, and the rear side by the light emitted from the rear reflecting portions of the plurality of pixels of the liquid crystal element. Display the image observed fromIn addition, images are displayed by transmitted light incident from the front and rear sides.Therefore, the area of the display area in which the plurality of pixels of the liquid crystal element are arranged may be a size corresponding to one of the front and rear display screens.
[0013]
Therefore, according to this liquid crystal display device, both sides can be displayed using one liquid crystal element, and the plane area can be reduced to the same extent as the display screen on either the front side or the rear side.
[0014]
  As described above, the liquid crystal display device according to the present invention is predetermined in the plurality of pixels on the inner surface of the front substrate.In a predetermined second area of the areas excluding the first areaA plurality of front reflective films are provided in correspondence with each other, and the inner surface of the rear substrate is provided on the inner surface of the plurality of pixels.The first region andThe front reflective film correspondsSecond areaOther than predeterminedThird areaA plurality of rear reflection films are provided in correspondence with each of the plurality of pixels, and the rear reflection films of the plurality of pixels are provided.Third areaAs a result, a front reflection portion that reflects light incident from the front side by the rear reflection film and emits the light to the front side is formed, and the front reflection film of the plurality of pixels is provided.Second areaAs a result, a rear reflection part is formed that reflects light incident from the rear side by the front reflection film and emits the light to the rear side.The first region other than the second region and the third region forms a transmission part that transmits light incident from the front side and the rear side and emits the light to the rear side and the front side.By providing a liquid crystal element and a front polarizing plate and a rear polarizing plate disposed on the front side and the rear side of the liquid crystal element, both sides are displayed using one liquid crystal element, and the plane area is The display screen can be made as small as the display screen on either the front side or the rear side.
[0015]
  In the liquid crystal display device of the present invention, a plurality of pixels of the liquid crystal elementEach of the second region to which the front reflective film corresponds, the third region to which the rear reflective film corresponds, and the first region other than the second region and the third region are substantially each. It is preferable to form the same area.
[0016]
In that case, at least one of the front side of the front polarizing plate and the rear side of the rear polarizing plate is provided with a surface light source that transmits incident light from the front-rear direction and emits illumination light from the surface facing the polarizing plate. It is preferable to do this.
[0017]
  Furthermore, in the liquid crystal display device of the present invention,The electrode formed on the inner surface of the front substrate is divided into the first electrode corresponding to the first region and the second region, and the second electrode corresponding to the third region, and The electrode formed on the inner surface of the side substrate is divided into the first region, the third electrode corresponding to the third region, and the fourth electrode corresponding to the second region. Canpreferable.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
1 and 2 show a first embodiment of the present invention, FIG. 1 is an exploded perspective view of a liquid crystal display device, and FIG. 2 is a display state using external light of the liquid crystal display device and a surface light source It is sectional drawing of a part in the display state using illumination light.
[0019]
As shown in FIGS. 1 and 2, the liquid crystal display device of this embodiment includes one liquid crystal element 1, a front polarizing plate 13 and a rear polarizing plate disposed on the front side and the rear side of the liquid crystal element 1. 14 and a pair of front and rear surface light sources 17 disposed on the front side of the front polarizing plate 13 and the rear side of the rear polarizing plate 14.
[0020]
The liquid crystal element 1 includes a liquid crystal layer 4 provided between a transparent substrate 2 on the front side (upper side in the drawing) and a transparent substrate 3 on the rear side (lower side in the drawing). A plurality of transparent electrodes 5 for forming at least one transparent electrode 5 on one of the opposing inner surfaces of the side substrate 3 and a plurality of pixels A arranged in a matrix in a region facing the at least one electrode 4 on the other inner surface. An electrode 6 is provided, and a plurality of front reflective films 7 are provided on the inner surface of the front substrate 2 so as to correspond to predetermined regions in the pixels A, respectively. A plurality of rear reflection films 8 are provided corresponding to predetermined areas other than the areas corresponding to the front reflection films 7 in the plurality of pixels A, respectively, and the rear reflections of the plurality of pixels A are provided. Region where film 8 is provided Accordingly, a front reflection portion A1 that reflects light incident from the front side by the rear reflection film 8 and emits the light to the front side is formed, and the rear reflection film 7 of the plurality of pixels A is provided on the rear side. The rear reflection part A2 for reflecting the light incident from the front side reflection film 7 and emitting it to the rear side is formed.
[0021]
The liquid crystal element 1 is a simple matrix liquid crystal element, and the electrodes 5 provided on the inner surface of the front substrate 2 have a plurality of scans formed in parallel to each other along the row direction (left-right direction in FIG. 2). The electrodes 6 provided on the inner surface of the rear substrate 3 are a plurality of signal electrodes formed in parallel to each other along the column direction (direction perpendicular to the paper surface in FIG. 2).
[0022]
A plurality of front-side reflection films 7 provided on the inner surface of the front-side substrate 2 and a plurality of rear-side reflection films 8 provided on the inner surface of the rear-side substrate 3 are low-reflective on the surfaces in contact with the substrates 2 and 3, respectively. The front-side reflection film 7 is provided so as to correspond to approximately a half area on one side of all the pixels A arranged in a matrix, and the rear-side reflection film 8. Are provided so as to correspond to approximately ½ regions on the other side of all the pixels A, respectively.
[0023]
In other words, in this embodiment, approximately a half of the area of each pixel A is a front reflecting portion A1 that reflects the light incident from the front side by the rear reflective film 8 and emits the light to the front side. The other half of the area is a rear reflecting portion A2 that reflects light incident from the rear side by the front reflective film 7 and emits it to the rear side.
[0024]
The liquid crystal element 1 includes a plurality of color filters 9R, 9G, and 9B corresponding to the plurality of pixels A, for example, red, green, and blue, and these color filters 9R, 9G. , 9B are formed on one of the substrates, for example, the inner surface of the front substrate 2 so as to correspond to the entire area of each pixel A.
[0025]
The plurality of front reflective films 7 and 8 are respectively formed on the substrate surfaces of the front substrate 2 and the rear substrate 3, and the color filters 9 R, 9 G, and 9 B are formed on the inner surface of the front substrate 2. It is provided so as to cover the front reflective film 7.
[0026]
The plurality of scanning electrodes 5 are formed on the color filters 9R, 9G, and 9B provided on the inner surface of the front substrate 2 so that approximately ½ of the electrode width is opposed to the front reflective film 7. In addition, the plurality of signal electrodes 6 are formed on the inner surface of the rear substrate 2 so that approximately ½ of the electrode width is superimposed on the rear reflective film 8.
[0027]
In addition, alignment films 10 and 11 are provided on the inner surfaces of the front substrate 2 and the rear substrate 3 so as to cover the electrodes 5 and 6, respectively.
[0028]
The front substrate 2 and the rear substrate 3 are joined via a frame-shaped sealing material 12 (see FIG. 1) surrounding a display area in which the plurality of pixels A are arranged in a matrix, and the front substrate 2 A liquid crystal layer 4 is provided in a region surrounded by the frame-shaped sealing material 12 between the rear substrate 3 and the rear substrate 3.
[0029]
The liquid crystal molecules of the liquid crystal layer 4 are defined in the alignment direction in the vicinity of the respective substrates 2 and 3 by the alignment films 10 and 11, and are aligned in a predetermined initial alignment state between the front and rear substrates 2 and 3. Yes.
[0030]
The liquid crystal element 1 may be any of a TN (twisted nematic) type, STN (super twisted nematic) type, non-twisted homogeneous alignment type, ferroelectric or antiferroelectric liquid crystal element, and the like.
[0031]
Further, the liquid crystal display device of this embodiment includes a front retardation plate 15 and a rear retardation plate 16 disposed between the liquid crystal element 1 and the front polarizing plate 13 and the rear polarizing plate 14, respectively. .
[0032]
These retardation plates 15 and 16 are provided to improve the contrast and viewing angle of the display observed from the front side and the rear side. The transmission axes of the front and rear polarizing plates 13 and 14 and the front and rear retardation plates are provided. The directions of the slow axes 15 and 16 are, for example, when no electric field is applied between the electrodes 5 and 6 of each pixel A of the liquid crystal element 1, that is, the liquid crystal molecules of the liquid crystal layer 4 are in the initial alignment state. Sometimes, the display observed from the front side and the rear side is set to a normally white mode in which the brightest display is bright.
[0033]
A pair of front and rear surface light sources 17 disposed on the front side of the front polarizing plate 13 and the rear side of the rear polarizing plate 14 respectively transmit incident light from the front and rear directions and face the polarizing plates 13 and 14. As shown in FIG. 1, one end surface is a light incident end surface, one surface is formed as a flat light exit surface, and the other surface is the incident surface, as shown in FIG. A light guide plate 18 formed on a concavo-convex surface having a serrated cross section in which a minutely inclined surface and a steeply inclined surface along a direction parallel to the end surface are alternately arranged, and opposed to the incident end surface of the light guide plate 18 The light emitting element 19 is provided.
[0034]
In addition, the surface light source 17 used in this embodiment is configured by arranging a plurality of light emitting elements 19 made of LEDs (light emitting diodes) so as to face the incident end face of the light guide plate 18. The light-emitting element arranged to face the incident end face may be a straight tubular cold cathode tube or the like.
[0035]
The surface light source 17 transmits light incident from the uneven surface to the light guide plate 18 and exits from the exit surface of the light guide plate 18, and transmits light incident from the exit surface to the light guide plate 18. Light emitted from the uneven surface of the light guide plate 18 and emitted from the light emitting element 19 and incident on the light guide plate 18 from its end surface is converted into the uneven surface and the output surface of the light guide plate 18 and outside air (air). The light guide plate 18 is guided in the light guide plate 18 while being totally reflected at the interface, and is emitted from the entire area of the emission surface in the front direction (a direction near the normal line of the emission surface of the light guide plate 18). It is turned off when the liquid crystal display device is used in an environment where bright external light is obtained, and is turned on when the liquid crystal display device is used in an environment where sufficient external light cannot be obtained.
[0036]
Of the pair of front and rear surface light sources 17, the front surface light source 17 is disposed on the front side of the front polarizing plate 13, with the emission surface of the light guide plate 18 facing the front polarizing plate 13. The surface light source 17 is disposed on the rear side of the rear polarizing plate 14 with the light exit surface of the light guide plate 18 facing the rear polarizing plate 14.
[0037]
This liquid crystal display device performs both display with the front surface as the display surface and display with the rear surface as the display surface. The liquid crystal display device has a plurality of pixels A of the liquid crystal element 1 from the front reflection portion A1. An image observed from the front side is displayed by the emitted light, and an image observed from the rear side is displayed by the emitted light from the rear reflecting portions A2 of the plurality of pixels A of the liquid crystal element 1.
[0038]
In the liquid crystal display device of this embodiment, the incident light from the front-rear direction is transmitted to the front side of the front polarizing plate 13 and the rear side of the rear polarizing plate 14, and illumination light from the surface facing the polarizing plates 13, 14. Since a pair of front and rear surface light sources 17 that emit light is disposed, even when any one of the front and rear surfaces is used as a display surface, display is performed using external light that is light of the environment in an environment with sufficient brightness. However, in an environment where sufficient external light cannot be obtained, the illumination light can be emitted from the surface light source 17 to display using the illumination light.
[0039]
In addition, the liquid crystal display device of this embodiment uses external light incident from the display surface side as the display surface of the liquid crystal element 1 when using external light, regardless of whether the front surface or the rear surface is the display surface. When the reflective light is reflected by the reflective films 7 and 8 on the side opposite to the side and emitted to the display surface side, and the illumination light from the surface light source 17 is used, the illumination light is emitted from the surface light source 17 on the display surface side. Reflection display is performed in which illumination light that is emitted and incident from the display surface side is reflected by the reflective films 7 and 8 on the opposite side of the display surface side of the liquid crystal element 1 and is emitted to the display surface side.
[0040]
In FIG. 2, (a) shows the display state using the external light of the liquid crystal display device, the arrow line is the emission path of the light incident from the front side when the front surface is the display surface, the broken line is An emission path of light incident from the rear side when the rear surface is used as a display surface is shown.
[0041]
First, external light utilization display using the front surface as the display surface will be described. At this time, as indicated by the arrow in FIG. 2A, the external light incident from the front side which is the display surface side is the front surface. The light passes through the light guide plate 18 of the light source 17 and enters the front polarizing plate 13, is converted into linearly polarized light by the front polarizing plate 13, and further passes through the front retardation plate 15 and enters the liquid crystal element 1.
[0042]
Of the light incident on the liquid crystal element 1 from its front side, the light incident on the rear reflecting portion A2 of each pixel A of the liquid crystal element 1 is a front reflective film in which a surface facing the front substrate 2 is subjected to low reflection processing. The light that is blocked by 7 and incident on the front reflection portion A1 of each pixel A is colored by the color filters 9R, 9G, and 9B corresponding to each pixel A and enters the liquid crystal layer 4.
[0043]
The light incident on the liquid crystal layer 4 is subjected to a birefringence action according to the alignment state of the liquid crystal molecules that changes due to the electric field applied between the electrodes 5 and 6 of each pixel A while passing through the liquid crystal layer 4. The light is reflected by the rear reflective film 8 provided on the inner surface of the rear substrate 3, and is transmitted again through the liquid crystal layer 4 and the color filters 9R, 9G, and 9B. The light is emitted from A1 to the front side of the liquid crystal element 1.
[0044]
Then, the light emitted to the front side of the liquid crystal element 1 is transmitted through the front retardation plate 15 and incident on the front polarizing plate 13 from the rear side. Of the light, polarized light parallel to the transmission axis of the front polarizing plate 13. The component passes through the front polarizing plate 13, further passes through the light guide plate 18 of the front surface light source 17, exits to the front side (display surface side), and a polarization component parallel to the absorption axis of the front polarizing plate 13 is obtained. And is absorbed by the front polarizing plate 13.
[0045]
Since the liquid crystal display device of this embodiment performs display in the normally white mode as described above, among the pixels A of the liquid crystal element 1, no electric field pixel in which an electric field is not applied between the electrodes 5 and 6 is used. (Pixel in which liquid crystal molecules are in the initial alignment state) Electric field application in which light emitted from the front reflection part A1 of A is transmitted through the front polarizing plate 13 and emitted to the front side, and an electric field is applied between the electrodes 5 and 6 Light emitted from the front reflection portion A1 of the pixel A is absorbed by the front polarizing plate 13, and from the front side, a bright display of any one of red, green, and blue corresponding to the non-electric field pixel A of the liquid crystal element 1, A color image due to black dark display corresponding to the electric field application pixel A of the liquid crystal element 1 is observed.
[0046]
Next, the external light utilization display with the rear surface as the display surface will be described.At this time, as indicated by the broken line in FIG. 2A, the external light incident from the rear side which is the display surface side is The light is transmitted through the light guide plate 18 of the surface light source 17 on the rear side and is incident on the rear polarizing plate 14, and is linearly polarized by the rear polarizing plate 14, and further passes through the rear retardation plate 16 and enters the liquid crystal element 1. Incident.
[0047]
Of the light incident on the liquid crystal element 1 from the rear side, the light incident on the front reflection part A1 of each pixel A of the liquid crystal element 1 is subjected to low reflection processing on the surface facing the rear substrate 3. Light that is blocked by the reflective film 8 and incident on the rear reflecting portion A <b> 2 of each pixel A enters the liquid crystal layer 4.
[0048]
The light incident on the liquid crystal layer 4 undergoes a birefringence action according to the alignment state of the liquid crystal molecules while passing through the liquid crystal layer 4, and the light is colored by the color filters 9 R, 9 G, and 9 B. The light is reflected by the front reflective film 7 provided on the inner surface.
[0049]
The light reflected by the front reflective film 7 is transmitted again through the color filters 9R, 9G, and 9B and the liquid crystal layer 4, and is emitted from the rear reflective portion A2 of each pixel A to the rear side of the liquid crystal element 1. .
[0050]
Then, the light emitted to the rear side of the liquid crystal element 1 is transmitted through the rear retardation plate 16 and incident on the rear polarizing plate 14 from the front side, and the transmission axis of the rear polarizing plate 14 out of the light. The polarized light component parallel to the light passes through the rear polarizing plate 14, further passes through the light guide plate 18 of the rear surface light source 17, and exits to the rear side (display surface side). A polarized light component parallel to the absorption axis is absorbed by the rear polarizing plate 14.
[0051]
Also at this time, the light emitted from the rear reflection portion A2 of the non-electric field pixel A of the liquid crystal element 1 is transmitted through the rear polarizing plate 14 and emitted to the rear side, and the rear reflection of the electric field application pixel A of the liquid crystal element 1 is performed. The light emitted from the portion A2 is absorbed by the rear polarizing plate 14, and from the rear side, the bright display of any one of red, green, and blue corresponding to the non-electric field pixel A of the liquid crystal element 1, and the liquid crystal element A color image by black dark display corresponding to one electric field application pixel A is observed.
[0052]
As described above, in the case of display with the front surface as the display surface, among the light incident from the front side which is the display surface side, the light incident on the rear reflecting portion A2 of each pixel A of the liquid crystal element 1 is reflected on the front side. Of the light incident from the rear side which is the display surface side, the light incident on the front reflection portion A1 of each pixel A of the liquid crystal element 1 is blocked by the film 7 and the display surface is the rear surface. Although it is blocked by the rear reflective film 8, the surface facing the front substrate 2 of the front reflective film 7 and the surface facing the rear substrate 3 of the rear reflective film 8 are each subjected to low reflection treatment. Therefore, the reflection of the light incident from the display surface side and blocked by the front reflective film 7 or the rear reflective film 8 to the display surface side is very small. Therefore, the front reflective film 7, The light blocked by 8 hardly affects the contrast of the displayed image. . The same applies to the display using illumination light described later.
[0053]
In FIG. 2, (b) shows the display state using the illumination light of the liquid crystal display device, the arrow line indicates the path of the illumination light when the front surface is the display surface, and the broken line indicates the rear surface. The exit path | route of the incident light from the back side of illumination light when it is set as a display surface is shown.
[0054]
First, the illumination light utilization display using the front surface as the display surface will be described. This display is performed by emitting illumination light from the front surface light source 17 on the display surface side.
[0055]
At this time, as indicated by an arrow in FIG. 2B, the illumination light emitted from the front surface light source 17 is converted into linearly polarized light by the front polarizing plate 13 and further transmitted through the front retardation plate 15. Incident on the liquid crystal element 1.
[0056]
The following is the same as in the above-described display using the external light with the front surface as the display surface, and the light incident on the front reflection portion A1 of each pixel A of the liquid crystal element 1 is the color filters 9R, 9G, 9B and the liquid crystal. The light passes through the layer 4, is reflected by the rear reflective film 8, and exits from the front reflective portion A 1 of each pixel A to the front side of the liquid crystal element 1. The reflected light emitted to the front side of the liquid crystal element 1 passes through the front retardation plate 15 and enters the front polarizing plate 13, and the polarized light component parallel to the transmission axis of the front polarizing plate 13 is included in the light. The polarized light component transmitted through the front polarizing plate 13, further transmitted through the light guide plate 18 of the front surface light source 17 and emitted to the front side (display surface side), and parallel to the absorption axis of the front polarizing plate 13, Absorbed by the front polarizing plate 13.
[0057]
Next, illumination light utilization display using the rear surface as a display surface will be described. This display is performed by emitting illumination light from the rear surface light source 17 on the display surface side.
[0058]
At this time, as indicated by a broken line in FIG. 2B, the illumination light emitted from the rear surface light source 17 is converted into linearly polarized light by the rear polarizing plate 14, and further, the rear retardation plate 16 passes through and enters the liquid crystal element 1.
[0059]
The following is the same as in the case of display using the external light with the rear surface as the display surface described above, and the light incident on the back reflecting portion A2 of each pixel A of the liquid crystal element 1 is the liquid crystal layer 4 and the color filters 9R and 9G. , 9B and reflected by the front reflective film 7 and emitted from the rear reflective portion A2 of each pixel A to the rear side of the liquid crystal element 1. Then, the reflected light emitted to the rear side of the liquid crystal element 1 passes through the rear retardation plate 16 and enters the rear polarizing plate 14, and among the light, it is parallel to the transmission axis of the rear polarizing plate 14. The polarized light component passes through the rear polarizing plate 13, further passes through the light guide plate 18 of the rear surface light source 17, and exits to the rear side (display surface side). The absorption axis of the rear polarizing plate 14 Is polarized by the rear polarizing plate 14.
[0060]
The surface light source 17 can also be used as an auxiliary light source for supplementing the brightness of the display during reflection display using outside light. In this case, the outside light using display using the front surface as the display surface. In this case, the illumination light may be emitted from the front surface light source 17 and the illumination light may be emitted from the rear surface light source 17 in the display using the external light with the rear surface as the display surface.
[0061]
That is, the liquid crystal display device includes a front reflecting portion A1 that reflects light incident from the front side and emits the light to the front side in each of the plurality of pixels A of the liquid crystal element 1, and reflects the light incident from the rear side. When a display is made using outside light by forming the rear reflection part A2 to be emitted to the side and disposing the front polarizing plate 13 and the rear polarizing plate 14 on the front side and the rear side of the liquid crystal element 1, respectively. In addition, when displaying using the illumination light from the surface light source 17, an image observed from the front side is displayed by the light emitted from the front reflection portions A 1 of the plurality of pixels A of the liquid crystal element 1, and the liquid crystal element The image observed from the rear side is displayed by the light emitted from the rear reflecting portion A2 of the plurality of pixels A.
[0062]
The liquid crystal display device displays an image observed from the front side by light emitted from the front reflection portions A1 of the plurality of pixels A of the liquid crystal element 1, and from the rear reflection portions A2 of the plurality of pixels A of the liquid crystal element 1. In order to display an image observed from the rear side by the emitted light, the area of the display area in which the plurality of pixels A of the liquid crystal element 1 are arranged in a matrix is equivalent to the display screen on either the front side or the rear side The size that you want.
[0063]
Therefore, according to this liquid crystal display device, it is possible to perform double-sided display using one liquid crystal element 1, and it is possible to reduce the plane area to the same extent as the display screen on either the front side or the rear side. Therefore, it can be mounted on a small electronic device.
[0064]
Moreover, since the liquid crystal display device has the front reflection part A1 and the rear reflection part A2 formed in all the pixels A of the liquid crystal element 1, the display of the liquid crystal element 1 is provided on the front side and the rear side. An image having the same screen size as the entire area can be displayed.
[0065]
Further, in the above-described embodiment, the front reflective portion A1 is used as the substantially half area of each pixel A of the liquid crystal element 1, and the rear reflective portion A2 is used as the other substantially half area. The aperture ratio can be made substantially the same when the display is displayed and when the display is performed with the rear surface as the display surface.
[0066]
The liquid crystal display device has, for example, display units on both sides of a lid that is pivotally opened and closed with respect to the device main body, and when the lid is closed, the display on the display unit on the outer surface of the lid is displayed. Foldable mobile phone in which the display on the inner surface of the lid (the surface facing the user of the electronic device when the lid is opened) is observed when the lid is opened. And mounted in the lid of the electronic device such that one display surface of the liquid crystal display device is opposed to the display portion on the inner surface of the lid, and the other display surface is opposed to the display portion on the outer surface of the lid. The
[0067]
When the liquid crystal display device is mounted on the lid of an electronic device of this type, when the lid is closed, only the display surface facing the display portion on the outer surface of the lid of the liquid crystal display can be seen. When the lid is opened, both the display surface facing the inner surface of the lid of the liquid crystal display device and the display surface facing the outer surface of the lid are visible.
[0068]
The liquid crystal display device displays an image observed from the front side by light emitted from the front reflecting portions A1 of the plurality of pixels A of the liquid crystal element 1, and displays an image observed from the rear side. In order to display by the light emitted from the back reflecting portion A2 of the plurality of pixels A, the display using the external light can be seen on both the front and rear display surfaces of the liquid crystal display device (the lid of the electronic device). When the display is performed in an environment in which external light with sufficient illuminance is incident from both the front side and the rear side of the liquid crystal display device, the display surface (observed by the user of the electronic device) The same image as the display image on the one display surface can be displayed on the other display surface as well as the display surface facing the display portion on the inner surface of the lid body. Can be observed.
[0069]
Further, since the surface light source 17 is disposed on the front side of the front polarizing plate 13 and the rear side of the rear polarizing plate 14 in the liquid crystal display device, display is performed using illumination light from the surface light source 17. In this case, the same display image can be simultaneously observed from both sides by emitting illumination light from both the front and rear surface light sources 17.
[0070]
In the above-described embodiment, a substantially ½ region on one side of each pixel A of the liquid crystal element 1 is the front reflecting portion A1, and a substantially ½ region on the other side is the back reflecting portion A2. The positional relationship, shape, and area ratio of the front reflection part A1 and the rear reflection part A2 may be arbitrary, and a plurality of front reflection parts A1 and rear reflection parts A2 may be formed in one pixel A.
[0071]
Moreover, in the said Example, although the surface light source 17 is arrange | positioned at the front side of the front side polarizing plate 13 and the rear side of the rear side polarizing plate 14, respectively, either or both of the said surface light sources 17 are abbreviate | omitted, and either The display with the surface or both surfaces as the display surface may be limited to the display using outside light.
Further, in the above embodiment, only the front reflection part A1 and the rear reflection part A2 are formed in each of the plurality of pixels A of the liquid crystal element 1, but each of the plurality of pixels A of the liquid crystal element 1 has the front reflection. You may form part A1 and back reflection part A2, and the permeation | transmission part which permeate | transmits the light which injected from the front side and the back side, and radiate | emits it to the back side and the front side.
[0072]
FIG. 3 is a partial sectional view of a liquid crystal display device according to a second embodiment of the present invention in a display state using external light and a display state using illumination light from a surface light source. In this embodiment, the same components as those in the first embodiment shown in FIGS. 1 and 2 are denoted by the same reference numerals and description thereof is omitted.
[0073]
In the liquid crystal display device of this embodiment, a plurality of front reflection films 7 on the inner surface of the front substrate 2 of the liquid crystal element 1 and a plurality of rear reflection films 8 on the inner surface of the rear substrate 3 are respectively provided in the plurality of pixels A. Transmission that is provided excluding a predetermined region and transmits light incident from the front side and the rear side through the region other than the front reflection part A1 and the rear reflection part A2 of the plurality of pixels A and emits the light to the rear side and the front side. The portion A3 is formed, and the incident light from the front and rear direction is transmitted to the front side of the front polarizing plate 13 and the rear side of the rear polarizing plate 14, and the illumination light is emitted from the surface facing the polarizing plates 13 and 14. A pair of front and rear surface light sources 17 are arranged, and other configurations are the same as those of the first embodiment.
[0074]
In this embodiment, the plurality of front-side reflection films 7 on the inner surface of the front-side substrate 2 of the liquid crystal element 1 are made to correspond to approximately one third of the region on one side of all the pixels A arranged in a matrix. The plurality of rear reflection films 8 on the inner surface of the rear substrate 3 are provided so as to correspond to the substantially one third region on the other side of all the pixels A, respectively. The 1/3 region is a front reflecting portion A1 that reflects light incident from the front side by the rear reflective film 8 and emits the light to the front side, and an approximately 1/3 region on the other side of each pixel A is a rear side. A rear reflecting portion A2 that reflects the light incident from the side by the front reflective film 7 and emits it to the rear side, and the remaining area of each pixel A, that is, the area of about 1/3 of the center of the pixel A, is the front side. And a transmission part A3 that transmits light incident from the rear side and emits the light to the rear side and the front side.
[0075]
In the liquid crystal display device of this embodiment, when using outside light, both the front surface and the rear surface are used as the display surface, and external light incident from the display surface side is transmitted to the display surface side of the liquid crystal element 1. Is reflected by the reflecting films 7 and 8 on the opposite side and emitted to the display surface side, and when the illumination light from the surface light source 17 is used, illumination from the surface light source 17 on the opposite side to the display surface side is performed. Light is emitted, and transmissive display is performed in which illumination light incident from the opposite side is transmitted through the liquid crystal element 1 and emitted to the display surface side.
[0076]
In FIG. 3, (a) shows the display state using the external light of the liquid crystal display device of this embodiment, and the arrow line indicates the path of light incident from the front side when the front surface is used as the display surface. A line indicates a path of light incident from the rear side when the rear surface is the display surface.
[0077]
First, the external light utilization display using the front surface as the display surface will be described. At this time, as indicated by the arrow in FIG. 3A, the external light incident from the front side which is the display surface side is the front surface. The light passes through the light guide plate 18 of the light source 17 and enters the front polarizing plate 13, is converted into linearly polarized light by the front polarizing plate 13, and further passes through the front retardation plate 15 and enters the liquid crystal element 1.
[0078]
Of the light incident on the liquid crystal element 1 from its front side, the light incident on the rear reflecting portion A2 of each pixel A of the liquid crystal element 1 is a front reflective film in which a surface facing the front substrate 2 is subjected to low reflection processing. 7, the light incident on the front reflection part A1 and the transmission part A3 of each pixel A is colored by the color filters 9R, 9G, and 9B and enters the liquid crystal layer 4.
[0079]
Of the light incident on the front reflective portion A1 and the transmissive portion A3 of each pixel A from the front side of the liquid crystal element 1, the light incident on the front reflective portion A1 and transmitted through the liquid crystal layer 4 is the first described above. Similar to the embodiment, the light is reflected by the rear reflective film 8 and emitted to the front side of the liquid crystal element 1. Of the light, the polarization component parallel to the transmission axis of the front polarizing plate 13 is transmitted through the front polarizing plate 13. Further, the polarized light component that is transmitted through the light guide plate 18 of the front surface light source 17 and emitted to the front side (display surface side) and parallel to the absorption axis of the front polarizing plate 13 is absorbed by the front polarizing plate 13. .
[0080]
On the other hand, the light that has entered the transmission part A3 of each pixel A from the front side of the liquid crystal element 1 and has passed through the liquid crystal layer 4 is emitted to the rear side of the liquid crystal element 1, and the rear polarizing plate 14 out of the light. The polarization component parallel to the transmission axis is transmitted through the rear polarizing plate 14, further transmitted through the light guide plate 18 of the rear surface light source 17, and emitted to the rear side (opposite to the display surface). A polarized light component parallel to the absorption axis of the rear polarizing plate 14 is absorbed by the rear polarizing plate 14.
[0081]
Next, the external light utilization display with the rear surface as the display surface will be described.At this time, as indicated by the broken line in FIG. 3A, the external light incident from the rear side which is the display surface side is The light is transmitted through the light guide plate 18 of the surface light source 17 on the rear side and is incident on the rear polarizing plate 14, and is linearly polarized by the rear polarizing plate 14, and further passes through the rear retardation plate 16 and enters the liquid crystal element 1. Incident.
[0082]
Of the light incident on the liquid crystal element 1 from the rear side, the light incident on the front reflection part A1 of each pixel A of the liquid crystal element 1 is subjected to low reflection processing on the surface facing the rear substrate 3. Light that is blocked by the reflective film 8 and incident on the rear reflective portion A2 and the transmissive portion A3 of each pixel A enters the liquid crystal layer 4, passes through the liquid crystal layer 4, and is colored by the color filters 9R, 9G, and 9B. The
[0083]
Of the light incident on the rear reflection part A2 and the transmission part A3 of each pixel A from the rear side of the liquid crystal element 1, the light incident on the rear reflection part A2 and transmitted through the liquid crystal layer 4 is the first mentioned above. As in the first embodiment, the light reflected by the front reflective film 7 is emitted to the rear side of the liquid crystal element 1, and the polarized light component parallel to the transmission axis of the rear polarizing plate 14 is the rear polarizing plate. 14 further passes through the light guide plate 18 of the rear surface light source 17 and exits to the rear side (display surface side), and the polarization component parallel to the absorption axis of the rear polarizing plate 14 Absorbed by the polarizing plate 14.
[0084]
On the other hand, the light that has entered the transmission part A3 of each pixel A from the rear side of the liquid crystal element 1 and has passed through the liquid crystal layer 4 is emitted to the front side of the liquid crystal element 1, and of the light, A polarized light component parallel to the transmission axis passes through the front polarizing plate 13, further passes through the light guide plate 18 of the front surface light source 17, and exits to the front side (opposite to the display surface). The polarized light component parallel to the absorption axis is absorbed by the front polarizing plate 13.
[0085]
In FIG. 3, (b) shows a display state using illumination light of the liquid crystal display device of this embodiment, and an arrow line indicates a path of illumination light when the front surface is the display surface, a broken line. Indicates the exit path of incident light from the rear side of the illumination light when the rear surface is the display surface.
[0086]
First, the illumination light utilization display using the front surface as the display surface will be described. This display is performed by emitting illumination light from the rear surface light source 17 on the opposite side to the display surface (front surface).
[0087]
At this time, as indicated by an arrow in FIG. 3B, the illumination light emitted from the rear surface light source 17 is converted into linearly polarized light by the rear polarizing plate 14, and the rear retardation plate 16. And enters the liquid crystal element 1.
[0088]
Of the light incident on the liquid crystal element 1 from the rear side, the light incident on the front reflection part A1 of each pixel A of the liquid crystal element 1 is subjected to low reflection processing on the surface facing the rear substrate 3. Light that is blocked by the reflective film 8 and incident on the rear reflective portion A2 and the transmissive portion A3 of each pixel A enters the liquid crystal layer 4, passes through the liquid crystal layer 4, and is colored by the color filters 9R, 9G, and 9B. The
[0089]
Of the light incident on the rear reflection part A2 and the transmission part A3 of each pixel A from the rear side of the liquid crystal element 1, the light incident on the transmission part A3 and transmitted through the liquid crystal layer 4 is transmitted through the liquid crystal element 1. Of the light, a polarization component parallel to the transmission axis of the front polarizing plate 13 is transmitted through the front polarizing plate 13 and further transmitted through the light guide plate 18 of the front surface light source 17. The polarized light component emitted to the front surface side and parallel to the absorption axis of the front polarizing plate 13 is absorbed by the front polarizing plate 13.
[0090]
On the other hand, the light that has entered the back reflecting portion A2 of each pixel A from the rear side of the liquid crystal element 1 and transmitted through the liquid crystal layer 4 is reflected by the front reflective film 7 and emitted to the rear side of the liquid crystal element 1. Among the light, a polarized light component parallel to the transmission axis of the rear polarizing plate 14 is transmitted through the rear polarizing plate 14, and further transmitted through the light guide plate 18 of the rear surface light source 17. The polarized light component which is emitted to the opposite side) and parallel to the absorption axis of the rear polarizing plate 14 is absorbed by the rear polarizing plate 14.
[0091]
Next, the illumination light utilization display using the rear surface as the display surface will be described. This display is performed by emitting illumination light from the front surface light source 17 on the side opposite to the display surface (rear surface).
[0092]
At this time, as indicated by the broken line in FIG. 3B, the illumination light emitted from the front surface light source 17 is converted into linearly polarized light by the front polarizing plate 13 and further transmitted through the front retardation plate 15. Then, it enters the liquid crystal element 1.
[0093]
Of the light incident on the liquid crystal element 1 from its front side, the light incident on the rear reflecting portion A2 of each pixel A of the liquid crystal element 1 is a front reflective film in which a surface facing the front substrate 2 is subjected to low reflection processing. 7, the light incident on the front reflection part A1 and the transmission part A3 of each pixel A is colored by the color filters 9R, 9G, and 9B and enters the liquid crystal layer 4.
[0094]
Of the light incident on the front reflection part A1 and the transmission part A3 of each pixel A from the front side of the liquid crystal element 1, the light incident on the transmission part A3 and transmitted through the liquid crystal layer 4 is transmitted to the rear of the liquid crystal element 1. Of the light, the polarized light component parallel to the transmission axis of the rear polarizing plate 14 is transmitted through the rear polarizing plate 14 and further transmitted through the light guide plate 18 of the rear surface light source 17. A polarized light component emitted to the rear side (display surface side) and parallel to the absorption axis of the rear polarizing plate 14 is absorbed by the front polarizing plate 13.
[0095]
On the other hand, the light that has entered the front reflecting portion A1 of each pixel A from the front side of the liquid crystal element 1 and transmitted through the liquid crystal layer 4 is reflected by the rear reflective film 8 and is emitted to the front side of the liquid crystal element 1. Among the light, a polarized light component parallel to the transmission axis of the front polarizing plate 13 is transmitted through the front polarizing plate 13 and further transmitted through the light guide plate 18 of the front surface light source 17 (front side opposite to the display surface). , And the polarized light component parallel to the absorption axis of the front polarizing plate 13 is absorbed by the front polarizing plate 13.
[0096]
In this embodiment as well, the surface light source 17 may be used as an auxiliary light source for supplementing the brightness of the display during reflective display using outside light. In this case, the front surface is the display surface. Illumination light is also emitted from the rear surface light source 17 during external light display, and illumination light is also emitted from the front surface light source 17 during external light display using the rear surface as a display surface. Just do it.
[0097]
That is, the liquid crystal display device of this embodiment reflects the light incident from the front side and the front reflection part A1 that reflects the light incident from the front side and emits the light to the front side in each of the plurality of pixels A of the liquid crystal element 1. A rear reflection portion A2 that emits light to the rear side, and a transmission portion A3 that transmits light incident from the front side and the rear side and emits the light to the rear side and the front side, and the front side and the rear side of the liquid crystal element 1 The front polarizing plate 13 and the rear polarizing plate 14 are disposed on the front side, and incident light from the front and rear directions is transmitted through the front side of the front side polarizing plate 13 and the rear side of the rear side polarizing plate 14, respectively. When a surface light source 17 that emits illumination light from the surfaces facing the plates 13 and 14 is disposed, when displaying using outside light, the liquid crystal element 1 has a plurality of pixels A from the front reflecting portion A1. Image observed from the front side by the emitted light When displaying and displaying an image observed from the rear side by the light emitted from the back reflecting portion A2 of the plurality of pixels A of the liquid crystal element 1, and displaying using the illumination light from the surface light source 17, An image observed from the front side and an image observed from the rear side are displayed by the emitted light from the transmissive portions A3 of the plurality of pixels A of the liquid crystal element 1.
[0098]
Also in the liquid crystal display device of this embodiment, the area of the display area in which the plurality of pixels A of the liquid crystal element 1 are arranged in a matrix may be a size corresponding to one of the front and rear display screens, Therefore, double-sided display can be performed using one liquid crystal element 1, and the plane area can be reduced to the same extent as the display screen on either the front side or the rear side.
[0099]
In addition, since the liquid crystal display device includes the front reflection portion A1, the rear reflection portion A2, and the transmission portion A3 formed in all the pixels A of the liquid crystal element 1, the liquid crystal display device is arranged on the front side and the rear side. An image having the same screen size as the entire display area of the element 1 can be displayed.
[0100]
Further, in this embodiment, an approximately 1/3 region of each pixel A of the liquid crystal element 1 is a front reflecting portion A1, and another approximately 1/3 region is a back reflecting portion A2, and the remaining 1/3 region. Is used as the transmissive portion A3, so that the front and rear display aperture ratios that use external light are substantially the same, and the front and rear display aperture ratios that use illumination light from the surface light source 17 are the same. The aperture ratio of the display using the can be made substantially the same.
[0101]
Even in the liquid crystal display device of this embodiment, when the display using external light is performed in an environment in which external light with sufficient illuminance is incident from both the front side and the rear side, the same display image is simultaneously displayed from both sides. Can be observed.
[0102]
In addition, as described above, the liquid crystal display device according to this embodiment uses the illumination light from the surface light source 17 to display the liquid crystal elements 1 in the illumination light emitted from the rear surface light source 17. The light incident on the rear reflection part A2 of the pixel A is reflected and emitted to the rear side, and the light incident on the front reflection part A1 of each pixel A of the liquid crystal element 1 of the illumination light emitted from the front surface light source 17 is reflected. Since it is reflected and emitted to the front side, when the illumination light is emitted from the rear surface light source 17 and an image observed from the front side is displayed, the same image as the image observed from the front side is displayed from the rear side. In addition to simultaneously observing, when the illumination light is emitted from the front surface light source 17 and an image observed from the rear side is displayed, the same image as that observed from the front side is simultaneously observed from the rear side. Can do.
[0103]
FIG. 4 is a partial sectional view of a liquid crystal display device according to a third embodiment of the present invention in a display state using external light and a display state using illumination light from a surface light source. In this embodiment, the same components as those in the first and second embodiments described above are denoted by the same reference numerals in the drawings, and the description thereof is omitted.
[0104]
In the liquid crystal display device of this embodiment, the liquid crystal element 1 has a configuration in which a front reflection portion A1, a rear reflection portion A2, and a transmission portion A3 are formed in each pixel A, as in the second embodiment, and the front polarization The incident light from the front-rear direction is transmitted to one of the front side of the plate 13 and the rear side of the rear polarizing plate 14, for example, the rear side of the rear polarizing plate 14, and illumination light from the surface facing the polarizing plate 14. One surface light source 17 that emits light is disposed, and the other configuration is the same as that of the first embodiment.
[0105]
When the liquid crystal display device uses external light, the liquid crystal display device displays an image observed from the front side by light emitted from the front reflection portion A1 of each pixel A of the liquid crystal element. When an image observed from the rear side is displayed by the emitted light from the rear reflecting portion A2, and the illumination light is used, the rear polarizing plate 14 is used regardless of whether the front surface is a display surface or the rear surface is a display surface. Illumination light is emitted from the surface light source 17 disposed on the rear side, and an image observed from the front surface is displayed by light emitted from the transmission part A3 of each pixel A of the liquid crystal element, and each pixel A of the liquid crystal element is displayed. The image observed from the rear surface is displayed by the light emitted from the rear reflection part A2.
[0106]
4A shows a display state using the external light of the liquid crystal display device of this embodiment, and FIG. 4B shows a display state using the illumination light of the liquid crystal display device of this embodiment. Yes.
[0107]
In this liquid crystal display device, since one surface light source 17 is disposed only on the rear side of the rear polarizing plate 14, external light from the front side is directly incident on the front polarizing plate 13 and the liquid crystal element 1. The light emitted from the front reflection portion A1 of each pixel A and transmitted through the front polarizing plate 13 and the light emitted from the transmission portion A3 of each pixel A of the liquid crystal element 1 to the front side and transmitted through the front polarizing plate 13 The light is emitted to the front side as it is. Except for this, the emission path of incident light when using external light is the same as that of the liquid crystal display device of the second embodiment shown in FIG. When the illumination light from the surface light source 17 is used, the emission path of the incident light uses the illumination light from the rear surface light source 17 in the liquid crystal display device of the second embodiment shown in FIG. Since the route is the same as the route when the operation is performed, the overlapping description is omitted.
[0108]
That is, in the liquid crystal display device of this embodiment, when using external light, the display with the front surface as the display surface and the display with the rear surface as the display surface are respectively performed by reflection display, and the illumination light from the surface light source 17 is displayed. Is used, display with the front surface as the display surface is performed by transmissive display, and display with the rear surface as the display surface is performed by reflective display.
[0109]
According to this liquid crystal display device, since only one surface light source 17 is required, the cost can be reduced as compared with the liquid crystal display devices of the first and second embodiments having two surface light sources 17.
[0110]
FIG. 5 is a partial sectional view of a liquid crystal display device according to a fourth embodiment of the present invention in a display state using external light and a display state using illumination light from a surface light source. In this embodiment, the same components as those in the first to third embodiments described above are denoted by the same reference numerals in the drawings, and the description thereof is omitted.
[0111]
In the liquid crystal display device of this embodiment, the liquid crystal element 1 is formed with a front reflection portion A1, a rear reflection portion A2, and a transmission portion A3 in each pixel A, and a plurality of inner surfaces of the front substrate 2 of the liquid crystal element 1 are formed. The first scanning electrode 5a corresponding to both the front reflection part A1 and the transmission part A3 of each pixel A, and the second scanning electrode 5b corresponding to the rear reflection part A2 of each pixel A, respectively. The plurality of signal electrodes on the inner surface of the rear substrate 3 of the liquid crystal element 1 are respectively divided into a first signal electrode 6a corresponding to the front reflection portion A1 of each pixel A and the rear of each pixel A. The second signal electrode 6b corresponding to both the reflection part A2 and the transmission part A3 is divided, and either the front side of the front polarizing plate 13 or the rear side of the rear polarizing plate 14, for example, the rear polarizing plate The incident light from the front-rear direction is transmitted to the rear side of 14. Is intended together to place one surface light source 17 for emitting illumination light from the surface facing the polarizing plate 14, other configurations are the same as those of the first embodiment.
[0112]
In this embodiment, the first scan electrode 5a of the liquid crystal element 1 is formed corresponding to both the front reflection portion A1 and the transmission portion A3 for each pixel A, and the second scan electrode 5b is formed for each of the pixels A so as to correspond to the back reflecting portion A3. Among the first and second scanning electrodes 5a and 5b corresponding to the plurality of pixels A in the same row, The scan electrodes 5a are commonly connected to a first scan electrode wiring (not shown) provided along one side of each pixel row, and the second scan electrodes 5b are arranged along the other side of each pixel row. The second scanning electrode wiring (not shown) provided in common is connected in common.
[0113]
The first signal electrode 6a is formed corresponding to the front reflection part A1 for each pixel A, and the second signal electrode 6b is connected to the rear reflection part A2 for each pixel A. Of the first and second signal electrodes 6a and 6b, which are formed to correspond to both of the transmissive portions A3 and respectively correspond to the plurality of pixels A in the same column, the first signal electrodes 6a are connected to each pixel. A second signal electrode (not shown) is connected in common to the first signal electrode wiring (not shown) provided along one side of the column, and the second signal electrodes 6b are provided along the other side of each pixel column. The signal electrode wirings are commonly connected.
[0114]
5A shows a display state using the external light of the liquid crystal display device of this embodiment, and FIG. 5B shows a display state using the illumination light of the liquid crystal display device of this embodiment. Yes.
[0115]
In this liquid crystal display device, one surface light source 17 is disposed on the rear side of the rear polarizing plate 14, and the emission path of incident light when using external light and the illumination light from the surface light source 17. Since the exit path of the incident light when using is the same as that of the liquid crystal display device of the third embodiment described above, redundant description is omitted.
[0116]
In the liquid crystal display device of this embodiment, each of the liquid crystal elements 1 depends on the condition of which one of the front and rear surfaces is used as a display surface, or which display uses external light or illumination light from the surface light source 17. The potentials of signals supplied to the first and second scanning electrodes 5a and 5b in the pixel row are individually controlled, and the potentials of signals supplied to the first and second signal electrodes 6a and 6b in each pixel column are controlled. The display is driven by controlling each individually.
[0117]
That is, this liquid crystal display device supplies a scanning signal to the first scanning electrode 5a of the pixel A for each selection period of the pixel A in each row of the liquid crystal element 1 when the front surface is the display surface, for example. A write signal having a potential difference corresponding to write data is supplied to the scanning signal to the second signal electrodes 6a and 6b, and the write signal or the write signal is supplied to the second signal electrode 5b. By supplying a signal having a potential difference that does not substantially operate the liquid crystal molecules, the rear reflection portion A2 of each pixel A is always substantially in a no electric field state, and the front reflection portion A1 of each pixel A and the transmissive display portion It is driven by applying a write electric field to A3.
[0118]
Therefore, at this time, the voltage of the potential difference corresponding to the write data is applied to the front reflection part A1 and the transmissive display part A3 of each pixel A of the liquid crystal element 1 for each selection period, and the rear reflection part of each pixel A A2 is always in a substantially no electric field state. Therefore, an image is displayed only on the front surface, which is the display surface, by the light emitted from the front reflection portion A1 and the transmission portion A3 of each pixel A, and the entire screen is entirely from the rear surface opposite to the display surface. The non-display state can be made white due to the mixture of red, green, and blue colored light emitted from the rear reflection portion A2 of the pixel A to the rear side.
[0119]
When the rear surface is used as the display surface, the scanning signal is supplied to the first and second scanning electrodes 5a and 5b, the write signal is supplied to the second signal electrode 6b, and the first signal is supplied to the first scanning electrode 5b. By supplying the signal electrode 6a with the write signal or a signal having a potential difference that does not substantially operate the liquid crystal molecules in response to the write signal, the front reflecting portion A1 of each pixel A is always substantially in a no electric field state. Then, a writing electric field is applied to the transmission part A3 and the rear reflection part A2 of each pixel A to drive. By this driving, an image can be displayed by the emitted light only on the rear surface that is the display surface, and the entire rear surface of the rear surface opposite to the display surface can be in a white non-display state.
[0120]
Further, in this embodiment, when the front surface is the display surface, a scanning signal is supplied to the first and second scanning electrodes 5a, 5b and the second signal electrode 6b, and the first signal electrode 6a is supplied with the scanning signal. A write signal may be supplied, and when the rear surface is a display surface, the scan signal is supplied to the first scan electrode 5a and the first and second signal electrodes 6a and 6b, and the first The writing signal may be supplied to the second scanning electrode 5b, and by this driving, the display can be performed only by the reflective display, and the display content cannot be seen at all from the opposite side of the display surface. be able to.
[0121]
Therefore, according to the liquid crystal display device of this embodiment, the display image is displayed on the display surface regardless of which of the front and rear surfaces is used as the display surface, and when any of the external light and the illumination light from the surface light source 17 is used. It is possible to display only on the display surface so that it cannot be seen from the opposite side.
[0122]
In the second to fourth embodiments shown in FIG. 3 to FIG. 5, the front reflection portion A1 and the back reflection are applied to the regions of one side and the other side of each pixel A of the liquid crystal element 1, respectively. The portion A2 is a transmissive portion A3 that is approximately one third of the center of each pixel A. However, the positional relationship and area ratio of the front reflective portion A1, the rear reflective portion A2, and the transmissive portion A3 may be arbitrary. Furthermore, a plurality of front reflection parts A1, rear reflection parts A2, and transmission parts A3 may be formed in one pixel A.
[0123]
Moreover, in the said 3rd and 4th Example, although the surface light source 17 is arrange | positioned on the back side of the rear side polarizing plate 14, the said surface light source 17 is arrange | positioned on the back side of the front side polarizing plate 13, and the said surface When the illumination light from the light source 17 is used, an image observed from the front surface is displayed by light emitted from the front reflecting portion A1 of each pixel A of the liquid crystal element, and an image observed from the rear surface is displayed on the liquid crystal You may make it display by the emitted light from the permeation | transmission part A3 of each pixel A of an element.
[0124]
Further, although the liquid crystal display device of each of the above embodiments includes the simple matrix type liquid crystal element 1, the liquid crystal element may be an active matrix type, and the present invention is not limited to the normally white mode. The present invention can also be applied to a normally black mode liquid crystal display device.
[0125]
【The invention's effect】
  In the liquid crystal display device of the present invention, the inner surface of the front substrate has a predetermined number of pixels.In a predetermined second area of the areas excluding the first areaA plurality of front reflective films are provided in correspondence with each other, and the inner surface of the rear substrate is provided on the inner surface of the plurality of pixels.The first region andThe front reflective film correspondsSecond areaOther than predeterminedThird areaA plurality of rear reflection films are provided in correspondence with each of the plurality of pixels, and the rear reflection films of the plurality of pixels are provided.Third areaAs a result, a front reflection portion that reflects light incident from the front side by the rear reflection film and emits the light to the front side is formed, and the front reflection film of the plurality of pixels is provided.Second areaAs a result, a rear reflection part is formed that reflects light incident from the rear side by the front reflection film and emits the light to the rear side.The first region other than the second region and the third region forms a transmission part that transmits light incident from the front side and the rear side and emits the light to the rear side and the front side.Liquid crystal element, and a front polarizing plate and a rear polarizing plate arranged on the front side and the rear side of the liquid crystal element. The area can be made as small as the display screen on either the front side or the rear side.
[0126]
  In the liquid crystal display device of the present invention, a plurality of pixels of the liquid crystal elementEach of the second region to which the front reflective film corresponds, the third region to which the rear reflective film corresponds, and the first region other than the second region and the third region are substantially each. It is preferable that they are formed in an equal area. In this case, an image observed from the front side and an image observed from the rear side are respectively equal in aperture ratio.Can be displayed.
[0127]
In that case, at least one of the front side of the front polarizing plate and the rear side of the rear polarizing plate is provided with a surface light source that transmits incident light from the front-rear direction and emits illumination light from the surface facing the polarizing plate. It is preferable to do this, and in this way, at least one of the image observed from the front side and the image observed from the rear side is used for the reflective display using external light and the illumination light from the surface light source. It can be displayed by both reflection display.
[0128]
  Furthermore, in the liquid crystal display device of the present invention,The electrode formed on the inner surface of the front substrate is divided into the first electrode corresponding to the first region and the second region, and the second electrode corresponding to the third region, and The electrode formed on the inner surface of the side substrate is divided into the first region, the third electrode corresponding to the third region, and the fourth electrode corresponding to the second region. CanPreferably, by doing so, an image observed from the front side and an image observed from the rear sideCan be different from each other, andIt can be displayed by both reflective display using external light and transmissive display or reflective display using illumination light from the surface light source.
[Brief description of the drawings]
FIG. 1 is an exploded perspective view of a liquid crystal display device according to a first embodiment of the present invention.
FIG. 2 is a partial cross-sectional view of the liquid crystal display device according to the first embodiment in a display state using external light and in a display state using illumination light from a surface light source.
FIG. 3 is a partial cross-sectional view of a liquid crystal display device according to a second embodiment of the present invention in a display state using external light and a display state using illumination light from a surface light source.
FIG. 4 is a partial cross-sectional view of a liquid crystal display device according to a third embodiment of the present invention in a display state using external light and a display state using illumination light from a surface.
FIG. 5 is a partial cross-sectional view of a liquid crystal display device according to a fourth embodiment of the present invention in a display state using external light and a display state using illumination light from a surface light source.
[Explanation of symbols]
1 ... Liquid crystal element
2.3 ... Board
4 ... Liquid crystal layer
5, 6, 5a, 5b, 6a, 6b ... electrodes
7.8 ... Reflective film
9R, 9G, 9B ... Color filters
A ... Pixel
A1 ... Front reflection part
A2 ... Back reflector
A3 ... Transmission part
13, 14 ... Polarizing plate
15, 16 ... retardation plate
17 ... A surface light source

Claims (4)

A liquid crystal layer is provided between the front substrate and the rear substrate disposed to face each other, and at least one electrode is provided on one of the opposing inner surfaces of the front substrate and the rear substrate, and the at least one electrode is provided on the other inner surface. A plurality of electrodes for forming a plurality of pixels are provided by the opposing regions, and a predetermined one of the regions excluding the predetermined first region in the plurality of pixels is provided on the inner surface of the front substrate. A plurality of front reflective films corresponding to the second regions, and a second region corresponding to the first region and the front reflective film in the plurality of pixels on the inner surface of the rear substrate. A plurality of rear reflective films are provided corresponding to predetermined third areas other than the above, and light incident from the front side by the third areas provided with the rear reflective films of the plurality of pixels. Is reflected by the rear reflective film. Front reflector portion to emit the front is formed to emit the by second region front reflection film is provided, after the light incident from the rear and reflected by the front reflecting film side of said plurality of pixels A rear reflection portion is formed , and a transmission portion that transmits light incident from the front side and the rear side and emits the light to the rear side and the front side is formed by the first region other than the second region and the third region. A liquid crystal element
A liquid crystal display device comprising a front polarizing plate and a rear polarizing plate arranged on the front side and the rear side of the liquid crystal element. Each of the plurality of pixels of the liquid crystal element includes a second region corresponding to the front reflective film, a third region corresponding to the rear reflective film, and a first region other than the second region and the third region. The liquid crystal display device according to claim 1, wherein each has a substantially equal area . At least one of the front side of the front polarizing plate and the rear side of the rear polarizing plate is provided with a surface light source that transmits incident light from the front-rear direction and emits illumination light from the surface facing the polarizing plate. The liquid crystal display device according to claim 1, wherein the liquid crystal display device is a liquid crystal display device. The electrode formed on the inner surface of the front substrate is divided into the first electrode corresponding to the first region and the second region, and the second electrode corresponding to the third region, and The electrode formed on the inner surface of the side substrate is divided into the first region, the third electrode corresponding to the third region, and the fourth electrode corresponding to the second region. the liquid crystal display device according to claim 1, wherein, characterized in that.

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