JP2016191870A - Liquid crystal display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce blackness and external light reflection of a display surface during non-display.SOLUTION: A liquid crystal display device (100) includes a liquid crystal cell part (3), a light control plate (17), a reflection type polarizing plate (10b), a light absorption plate (24) and a backlight part (2). The liquid crystal cell part (3) includes a polarizing plate (11b). The light control plate (17) changes light transmittance by using a voltage. The reflection type polarizing plate (10b) transmits specific polarized light and reflects the other polarized light. The light absorption plate (24) absorbs, by using a voltage, light with a specific wavelength. Light incident on the reflection type polarizing plate (10b) has the same polarization direction as the polarization direction of light transmitted by the reflection type polarizing plate (10b). A voltage is applied to the light control plate (17) so that light transmittance when the backlight part (2) is on is higher than light transmittance when the backlight part (2) is off. A voltage is applied to the light absorption plate (24) so that a light absorption rate when the backlight part (2) is on is lower than a light absorption rate when the backlight part (2) is off.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a structure of a liquid crystal display device.

  A conventional liquid crystal display device has a liquid crystal cell portion and a backlight portion. The backlight unit is a surface light source device that provides planar light to the liquid crystal cell unit. The liquid crystal cell part is formed of layered components. The components of the liquid crystal cell unit are arranged in the order of a polarizing plate, a glass substrate, a color filter, a liquid crystal layer, a glass substrate, and a polarizing plate from the display surface side (for example, Patent Document 1).

JP2004-117562 (paragraph 0011, paragraph 0012, FIG. 1)

  A polarizing plate in a conventional liquid crystal display device transmits only light having an amplitude component in a specific direction. The remaining light is absorbed by internal iodine or the like. Therefore, when the backlight unit is not lit in the conventional liquid crystal display device, the display surface looks black because external light is absorbed by iodine or the like inside the polarizing plate.

  However, as a result of an increase in the screen size of liquid crystal display devices in recent years, a black display surface when no image is displayed tends to be undesirable from the viewpoint of interior design.

  The present invention has been made in view of the above, and a liquid crystal display device in which the display surface does not look black when an image is not displayed, and the degree to which the display surface looks bright due to reflection of external light is suppressed. The purpose is to obtain.

  A liquid crystal display device according to the present invention includes a liquid crystal cell unit that includes a liquid crystal layer that changes the orientation of liquid crystal molecules when a first voltage is applied, and a polarizing plate that is disposed on a light emission surface. A light control plate that is disposed on the front surface side and changes the light transmittance by applying a second voltage, and is disposed between the light control plate and the liquid crystal cell unit, and transmits specific polarized light. And a reflective polarizing plate that reflects other light, and is disposed between the light control plate and the reflective polarizing plate, and absorbs light of a specific wavelength by applying a third voltage. A light absorption plate and a backlight unit that is disposed on the back side of the liquid crystal cell unit and irradiates light to the liquid crystal cell unit, and the polarization direction of light incident on the reflective polarizing plate from the liquid crystal layer is: The direction of polarization of light transmitted by the reflective polarizing plate is the same, and the backlight plate is provided with the backlight. The second voltage is applied so that the light transmittance when the part is turned on is higher than the light transmittance when the backlight part is turned off, The third voltage is applied such that the light absorptance when the backlight portion is turned on is lower than the light absorptance when the backlight portion is turned off. And

  According to the present invention, when an image is not displayed on a liquid crystal display device, a liquid crystal display device is obtained that reduces the degree that the display surface looks black and suppresses the degree that the display surface appears bright due to reflection of external light. Can do.

1 is a configuration diagram illustrating a liquid crystal display device according to a first embodiment. FIG. 3 is a configuration diagram illustrating a liquid crystal cell unit according to the first embodiment. 3 is a configuration diagram illustrating a guest-host type liquid crystal layer according to Embodiment 1. FIG. 3 is a configuration diagram illustrating a guest-host type liquid crystal layer according to Embodiment 1. FIG. 3 is a diagram illustrating a relationship between a wavelength and an absorptance of a guest-host type liquid crystal layer according to Embodiment 1. FIG. 3 is a diagram illustrating a relationship between a wavelength and an absorptance of a guest-host type liquid crystal layer according to Embodiment 1. FIG. 1 is a configuration diagram illustrating a light control film of Embodiment 1. FIG. 1 is a configuration diagram illustrating a light control film of Embodiment 1. FIG.

Embodiment 1 FIG.
In the following, description will be made using XYZ coordinates in order to facilitate explanation of the drawings. The surface 17a of the liquid crystal display device 100 has, for example, a rectangular shape. In Embodiment 1, the surface on the + Z-axis direction side of the light control film 17 is the surface 17a. The short side direction of the surface 17a is the X-axis direction, the long side direction is the Y-axis direction, and the direction perpendicular to the XY plane is the Z-axis direction. The surface 17a side of the liquid crystal display device 100 is defined as the + Z-axis direction. The upward direction of the liquid crystal display device 100 is defined as the + X axis direction. The right side when viewed from the surface 17a side of the liquid crystal display device 100 is defined as the + Y-axis direction. “Looking from the surface 17a side” means viewing the surface 17a opposite to the surface 17a of the liquid crystal display device 100. Hereinafter, the surface 17a of the liquid crystal display device 100 is simply referred to as a “display surface”. The + Z-axis direction is called “front”. -The Z-axis direction is called "rear face".

  “Film” generally refers to a thin film, and “plate” refers to a flat shape that is thicker than a film. However, in the following, “film” and “plate” are used as an example, and the thicknesses are not limited to each other. For this reason, “film” and “plate” both indicate flat shapes.

<Liquid crystal display device 100>
FIG. 1 is a configuration diagram schematically showing a cross section of the liquid crystal display device 100 according to the first embodiment of the present invention. The liquid crystal display device 100 includes a backlight unit 2, a liquid crystal cell unit 3, and a light control unit 4. The liquid crystal display device 100 can include a housing 1. The light control unit 4 includes a reflective polarizing film 10 b, a light absorption film 24, and a light control film 17.

  The housing 1 includes a backlight unit 2, a liquid crystal cell unit 3, and a light control unit 4 inside. The backlight unit 2 is inside the housing 1 and is located on the back side (−Z axis direction side) of the liquid crystal cell unit 3. The liquid crystal cell unit 3 is located on the surface 17a side (+ Z-axis direction side) with respect to the backlight unit 2. The light control part 4 is located on the surface 17a side (+ Z-axis direction side) from the liquid crystal cell part 3. That is, the backlight unit 2, the liquid crystal cell unit 3, and the light control unit 4 are arranged in this order from the back side (−Z axis direction side) to the surface 17 a side (+ Z axis direction side).

  In each of the following embodiments, the “surface” is the outermost surface of the liquid crystal display device in the direction in which an image is displayed. That is, the surface on the most + Z-axis direction side of the liquid crystal display device 100. “Front side” means “front side”.

<Backlight part 2>
The backlight unit 2 includes a light source 5. Moreover, the backlight part 2 can be equipped with the light-guide plate 7 or the reflective polarizing film 10a. Moreover, the backlight part 2 can be provided with the reflective sheet 6, the diffusion film 8, or the brightness enhancement film 9.

  “Polarized light” is a property in which light vibrates only in a specific direction. “Polarized light” is light having polarization characteristics. The direction of vibration of the polarized light is regular.

  Various methods for disposing the light source have been disclosed. Here, the side edge method will be described as an example.

  The “side edge method” is a method in which a light source is disposed on the side surface of a transparent light guide plate, and a light beam emitted from the light source proceeds while repeating reflection inside the light guide plate and is emitted from the surface of the light guide plate. The side edge method is also called an edge light method, a side light method, or a light guide plate method. Further, a direct type can be adopted as another method.

  The light source 5 emits illumination light that illuminates the liquid crystal cell unit 3. The light source 5 emits light toward the light guide plate 7. The position of the light source 5 will be described later. “To emit light” means to emit light.

  In recent years, the performance of blue light-emitting diodes (hereinafter referred to as LEDs (Light Emitting Diodes)) has been dramatically improved. In connection with this, the backlight part has employ | adopted white LED widely as a light source. The white LED is an LED using a blue LED element and a phosphor.

  The white LED includes a blue LED element and a yellow phosphor. The yellow phosphor absorbs blue light emitted by the blue LED element and emits yellow light. Yellow is a color including green and red, and is a complementary color of blue. For this reason, white LED emits white light.

  Hereinafter, the light source 5 will be described as an LED.

  The light guide plate 7 has a rectangular shape. For example, the light source 5 is disposed to face the side surface on the short side of the light guide plate 7.

  The light guide plate 7 receives light beams emitted from the plurality of light sources 5. The light guide plate 7 converts the incident light beam into uniform planar light. That is, the light guide plate 7 emits planar light as a surface light source. The “surface light source” is a light source that emits light from a surface.

  The reflective polarizing film 10a is located on the surface 17a side (+ Z-axis direction) from the brightness enhancement film 9. The reflective polarizing film 10a is located on the surface 17a side (+ Z axis direction) from the light guide plate 7. That is, the reflective polarizing film 10a is disposed at a position where planar light is incident.

  The reflective polarizing film 10a has a function of transmitting only light that vibrates in one direction and reflects light that vibrates in the other direction.

  A general polarizing plate transmits only light that vibrates in one direction and absorbs light that vibrates in another direction. As the reflective polarizing film, for example, a 3M multilayer film of the United States is known.

  However, recently, those using metal nanowire grids have been newly developed. A wire grid polarizing plate is a non-absorbing polarizing plate in which a metal material is deposited on a substrate and a wire-like grid is formed by fine etching at a nanometer level. Since no organic material is used, it has excellent heat resistance and light resistance.

  The reflection sheet 6 is located on the most back side (−Z axis direction) in the backlight unit 2. The light guide plate 7 is located on the surface 17a side (+ Z-axis direction) from the reflection sheet 6. Part of the light emitted from the light guide plate 7 is emitted to the back side. The reflection sheet 6 has a function of reflecting the light emitted from the light guide plate 7 to the back side to the surface 17a side. That is, the reflection sheet 6 has a function of collecting light on the surface 17a side.

  The diffusion film 8 is located on the surface 17a side (+ Z axis direction) from the light guide plate 7. The diffusion film 8 has a function of diffusing transmitted light and improving the uniformity of the light. That is, the diffusion film 8 improves the uniformity of planar light.

  The brightness enhancement film 9 is located on the surface 17a side (+ Z axis direction) from the diffusion film 8. The brightness enhancement film 9 is disposed on the liquid crystal cell unit 3 side (+ Z axis direction) of the light guide plate 7.

  The brightness enhancement film 9 has a function of collecting the light emitted from the light source 5 and increasing the brightness on the front side of the surface 17a. “Front” is the + Z-axis direction side of the liquid crystal display device 100.

  Thereby, the brightness | luminance in the front side of the surface 17a can be improved. “Increasing the luminance on the front side of the surface 17 a” means directing the traveling direction of the light diffused by the diffusion film 8 in a direction perpendicular to the exit surface of the luminance increasing film 9 (+ Z axis direction). That is, the brightness enhancement film 9 improves the brightness of an image when the image is viewed at a position facing the surface 17a of the liquid crystal display device 100.

<Liquid crystal cell part 3>
FIG. 2 is a configuration diagram of the liquid crystal cell unit 3.

  The liquid crystal cell unit 3 includes, for example, polarizing plates 11a and 11b, glass plates 12a and 12b, alignment films 16a and 16b, a transparent electrode 13, a liquid crystal layer 14, and a color filter 15. The transparent electrode 13 includes a transparent electrode 13a and a transparent electrode 13b.

  “Orientation” means arranging in a certain direction. In the first embodiment, the alignment is alignment of liquid crystal molecules in a certain direction. Further, “array” means arranging.

  The polarizing plate 11 a is located on the backmost side (−Z axis direction) in the liquid crystal cell unit 3. The glass plate 12a is located on the surface 17a side (+ Z axis direction) from the polarizing plate 11a. The alignment film 16a is located closer to the surface 17a (+ Z axis direction) than the glass plate 12a. The transparent electrode 13a is located in the layer of the alignment film 16a. The liquid crystal layer 14 is located on the surface 17a side (+ Z axis direction) from the alignment film 16a. The liquid crystal layer 14 is located on the surface 17a side (+ Z axis direction) from the transparent electrode 13a. The alignment film 16b is located closer to the surface 17a (+ Z axis direction) than the liquid crystal layer. The transparent electrode 13b is located closer to the surface 17a (+ Z axis direction) than the alignment film 16b. The color filter 15 is located on the surface 17a side (+ Z axis direction) from the transparent electrode 13b. The glass plate 12b is located on the surface 17a side (+ Z axis direction) from the color filter 15. The polarizing plate 11b is located closer to the surface 17a (+ Z axis direction) than the glass plate 12b. The polarizing plate 11b is positioned closest to the surface 17a (+ Z axis direction) in the liquid crystal cell unit 3.

  That is, from the −Z direction to the + Z direction, the polarizing plate 11a, the glass plate 12a, the transparent electrode 13a, the alignment film 16a, the liquid crystal layer 14, the alignment film 16b, the transparent electrode 13b, the color filter 15, the glass plate 12b, and the polarizing plate It is arranged in the order of 11b.

  The alignment film 16 a is located in the same layer as the transparent electrode 13.

  The alignment film 16 is a film having grooves. The alignment film 16a and the alignment film 16b will be collectively described as the alignment film 16.

  When the liquid crystal molecules of the liquid crystal layer 14 are brought into contact with the alignment film 16, the liquid crystal molecules change their arrangement along the grooves. When the alignment film 16a and the alignment film 16b are arranged so that the groove directions are different by 90 degrees and the liquid crystal layer 14 is sandwiched, the liquid crystal molecules of the liquid crystal layer 14 are twisted by 90 degrees and arranged.

  In FIG. 2, the direction of the grooves of the alignment film 16a and the direction of the grooves of the alignment film 16b are rotated 90 degrees on the XY plane.

  The transparent electrode 13 applies a voltage to the liquid crystal layer 14. The transparent electrode 13 applies a voltage between the transparent electrode 13a and the transparent electrode 13b. The transparent electrode 13a and the transparent electrode 13b are collectively described as the transparent electrode 13.

  The transparent electrode 13 is made of a transparent material. Therefore, the transparent electrode 13 allows light from the light source 5 to pass through. It should be noted that the transparent electrode 13 includes a case where the transparent electrode 13 is not transparent, for example, because the width of the electrode is very thin, so that the transparent electrode 13 cannot be seen by a viewer viewing the liquid crystal display device 100.

  As described above, the polarizing plate 11 transmits only light that vibrates in one direction and absorbs light that vibrates in the other direction.

  The polarization direction of the polarizing plate 11a is rotated 90 degrees on the XY plane with respect to the polarization direction of the polarizing plate 11b.

  Specifically, for example, when the polarization direction of the polarizing plate 11a is polarized in the X-axis direction, the polarization direction of the polarizing plate 11b is polarized in the Y-axis direction.

  The “polarizing plate” is a plate that transmits only light polarized in a specific direction.

  In the first embodiment, for example, “polarized light in the X-axis direction” is vertical polarized light. “Polarized in the Y-axis direction” is horizontal polarized light.

  In the following description, as an example, the polarization direction of the polarizing plate 11a is the X-axis direction (vertical polarization), and the polarization direction of the polarizing plate 11b is the Y-axis direction (horizontal polarization).

  The polarizing plate 11a is disposed on the surface 17a side (+ Z-axis direction side) of the reflective polarizing film 10a.

  The polarizing plate 11a transmits light having the same polarization direction as that of the reflective polarizing film 10a. That is, the polarization direction of the polarizing plate 11a is the same as the polarization direction of the reflective polarizing film 10a.

  If the polarizing plate 11a is vertically polarized light, the reflective polarizing film 10a is also vertically polarized light. For this reason, the polarization direction of the reflective polarizing film 10a will be described as the X-axis direction (vertical polarization). The description will be made assuming that the polarizing plate 11a is also vertically polarized light.

<Light control part 4>
The light control unit 4 includes a reflective polarizing film 10 b, a light absorption film 24, and a light control film 17.

  The light control unit 4 has a function of transmitting image light generated by the liquid crystal cell unit 3, a function of reducing light, or a function of shielding light.

  “Image light” refers to light having image information. “Image light” is also called “video light”. In Embodiment 1, an image and a video are used in the same meaning. In Embodiment 1, it is not necessary to distinguish between a still image and a moving image.

  The image light is produced by the liquid crystal cell unit 3. Therefore, the surface on the + Z-axis direction side of the liquid crystal cell unit 3 is an image display surface. However, since the light control film 17 is disposed on the + Z axis direction side of the liquid crystal cell unit 3, the display surface of the liquid crystal display device 100 is the surface 17a.

  “Dimming” means reducing the intensity of light. In other words, the image displayed on the liquid crystal display device is darkened.

  The reflective polarizing film 10b has a function of transmitting only light oscillating in one direction and reflecting light oscillating in the other direction.

  The reflective polarizing film 10b is the same as the reflective polarizing film 10a.

  The reflective polarizing film 10 a is disposed inside the backlight unit 2. On the other hand, the reflective polarizing film 10 b is disposed inside the light control unit 4.

  The reflective polarizing film 10b is located on the surface 17a side (+ Z axis direction) from the liquid crystal cell unit 3. In addition, the reflective polarizing film 10 b is located on the back side (−Z axis direction) from the light absorbing film 24.

  The light absorption film 24 is located on the surface 17a side (+ Z-axis direction) from the reflective polarizing film 10b. That is, the light reflective polarizing film 10 b is located on the back side (−Z axis direction) from the absorbing layer 24.

  The light absorption film 24 absorbs light of a specific wavelength by applying a voltage. That is, the light absorbing film 24 can color (color) the transmitted light.

  3 and 4 are diagrams showing an example of the structure of the light absorption film 24. FIG.

  FIG. 3 shows a case where a voltage is applied between the transparent electrode 28a and the transparent electrode 28b. FIG. 4 shows a case where no voltage is applied between the transparent electrode 28a and the transparent electrode 28b.

  3 and 4 show an example in which a guest-host type liquid crystal using a dichroic dye is used as the light absorbing film 24. FIG.

In Figure 3, the switch _{S 1,} the power supply _{V 1} and the transparent electrode 28a, and connecting the 28b. In Figure 4, the switch _{S 1,} the power supply _{V 1} and the transparent electrode 28a, are cutting links with 28b.

  The light absorption film 24 includes, for example, liquid crystal molecules 25 (host), a dichroic dye 26 (guest), alignment films 27a and 27b, transparent electrodes 28a and 28b, and protective films 29a and 29b.

  The dichroic dye 26 (guest) is dissolved in the liquid crystal molecules 25 (host). That is, the liquid crystal molecules 25 and the dichroic dye 26 are the liquid crystal composition 250. In the liquid crystal composition 250, a pleochroic dye (dichroic dye 26), which is a guest substance, is dissolved in a host liquid crystal (liquid crystal molecule 25) serving as a base material.

  The liquid crystal composition 250 is sandwiched between the alignment film 27a and the alignment film 27b.

  The liquid crystal composition 250 is sandwiched between the transparent electrode 28a and the transparent electrode 28b.

  The dichroic dye 26 is an azo dye, anthraquinone dye, quinophthalone dye or perylene dye. Depending on the chemical nature of the dye, the absorption peak wavelength varies.

  The alignment films 27a and 27b have a function of aligning the alignment of the liquid crystal molecules 25. That is, it has the same function as the alignment films 16a and 16b of the liquid crystal cell unit 3.

  The transparent electrode 28 a is disposed on the back side (−Z axis direction side) of the liquid crystal composition 250. The transparent electrode 28b is disposed on the surface 17a side (+ Z-axis direction side) of the liquid crystal composition 250.

  An alignment film 27a is provided on the surface 17a side of the transparent electrode 28a. An alignment film 27b is provided on the back side of the transparent electrode 28b. That is, the alignment films 27a and 27b are disposed on the liquid crystal composition 250 side of the transparent electrodes 28a and 28b.

  The transparent electrodes 28 a and 28 b apply a voltage to the liquid crystal composition 250.

  The transparent electrodes 28a and 28b are made of a transparent material. Therefore, the transparent electrodes 28a and 28b allow light from the light source 5 to pass through.

  The transparent electrodes 28a and 28b do not have to be transparent themselves. For example, the case where the width of the electrode is so thin that it cannot be seen by a viewer who views the liquid crystal display device 100 is also included.

  The protective film 29a is disposed on the back side (−Z-axis direction side) of the transparent electrode 28a. The protective film 29b is disposed on the surface 17a side (+ Z-axis direction side) of the transparent electrode 28b.

  The protective films 29a and 29b electrically protect the inside of the light absorbing film 24. As an electrical protection, for example, the protective films 29a and 29b are formed of a transparent and insulating resin or the like.

  The protective films 29a and 29b physically protect the inside of the light absorbing film 24. As physical protection, the resin has a role of protecting against external pressure or preventing moisture from entering.

  The control unit 30 controls application and non-application of a voltage to the transparent electrodes 28a and 28b. “No application” means that no voltage is applied.

  The light absorbing film 24 can change the molecular orientation of the dichroic dye 26 by applying or not applying a voltage. The light absorption film 24 can change the color absorption rate by changing the orientation of the molecules of the dichroic dye 26.

  FIG. 3 shows a case where a voltage is applied between the transparent electrode 28a and the transparent electrode 28b.

  In the case of FIG. 3, the liquid crystal molecules 25 are aligned in a direction perpendicular to the surfaces of the transparent electrodes 28a and 28b by Fredericks transition due to an electric field. That is, by applying a voltage, the liquid crystal molecules 25 are oriented in a direction perpendicular to the surfaces of the transparent electrodes 28a and 28b.

  Further, as shown in FIG. 3, the dichroic dye 26 also changes the alignment direction along the liquid crystal molecules 25 in accordance with the Fredericks transition of the liquid crystal molecules 25. That is, the dichroic dye 26 also faces in a direction perpendicular to the surfaces of the transparent electrodes 28a and 28b.

  When a voltage is applied, the projected area of the dichroic dye 26 onto the alignment film 27a is small. The area occupied by the dichroic dye 26 with respect to the region where the light travels is reduced. That is, the area of the dichroic dye 26 is reduced as viewed from the light incident surface side. For this reason, when a voltage is applied, the absorption of light of a specific wavelength by the dichroic dye 26 is small.

  FIG. 4 shows a case where no voltage is applied between the transparent electrode 28a and the transparent electrode 28b.

  In the case of FIG. 4, the liquid crystal molecules 25 and the dichroic dye 26 are arranged in a direction parallel to the alignment films 27a and 27b according to the state of the alignment films 27a and 27b. That is, when no voltage is applied, the liquid crystal molecules 25 and the dichroic dye 26 face in a direction parallel to the alignment films 27a and 27b.

  As shown in FIG. 4, when no voltage is applied, the projected area of the dichroic dye 26 onto the alignment film 27a increases. The area occupied by the dichroic dye 26 with respect to the region where light travels increases. That is, the area of the dichroic dye 26 is increased when viewed from the light incident surface side. For this reason, in the state which does not apply a voltage, absorption of the light of a specific wavelength by the dichroic dye 26 becomes large.

  FIG. 5 is a diagram showing the relationship between the wavelength W [nm] and the light absorption rate A [%] when no voltage is applied.

  The wavelength Wp is a wavelength (absorption peak wavelength) at which the light absorption rate (light absorption rate) is highest. Among the light incident on the light absorption film 24, the absorption rate of the light having the absorption peak wavelength Wp is maximized.

  FIG. 6 is a diagram showing the relationship between the wavelength W [nm] and the absorption rate A [%] when a voltage is applied. The wavelength Wp is an absorption peak wavelength.

  The light absorption rate at the absorption peak wavelength Wp shown in FIG. 6 is lower than the light absorption rate at the absorption peak wavelength Wp shown in FIG. That is, since the absorption of the light having the absorption peak wavelength Wp is small, the degree of coloring of the light emitted from the light absorption film 24 is low.

  As described above, the light absorbing film 24 can color the light transmitted through the light absorbing film 24 by switching between application and non-application of voltage. As shown in FIG. 5, the light absorption film 24 colors light to be transmitted by absorbing light having a part of the wavelength of the transmitted light.

  3 and 4 show examples of the dichroic dye 26 having one absorption peak wavelength Wp. However, any color can be obtained by using a plurality of dichroic dyes 26 having different absorption peak wavelengths Wp. That is, by combining a plurality of light absorption films 24, light having different absorption peak wavelengths Wp can be selectively absorbed. Different colors can be obtained by selecting the dichroic dye 26 depending on the color to be colored.

  In addition, the light absorption film 24 showed the example using the guest host type liquid crystal using the dichroic dye 26 in this Embodiment 1. FIG. However, a material other than the dichroic dye 26 may be used as long as it has a characteristic of changing the absorption rate of light of a specific wavelength W by applying a voltage.

  The light control film 17 is located on the surface 17a side (+ Z-axis direction) from the light absorption film 24. That is, the light absorption film 24 is located on the back side (−Z axis direction) with respect to the light control film 17.

  The light control film 17 is located closest to the surface 17a (+ Z axis direction) in the light control unit 4.

  The light control film 17 has a function of changing the amount of transmitted light by controlling the electric field inside the light control film 17. That is, the light control film 17 can change the light transmission amount by applying a voltage.

  For example, the light control film 17 can employ a liquid crystal capsule method.

  A “liquid crystal capsule” is a liquid crystal in a capsule.

  7 and 8 are views showing an example of the structure of the liquid crystal capsule type light control film 17.

  FIG. 7 is a diagram when no voltage is applied. FIG. 8 is a diagram when a voltage is applied.

In Figure 7, the switch _{S 2,} the power supply _{V 2} and the transparent electrode 20a, are cutting links with 20b. In Figure 8, the switch _{S 2,} the power supply _{V 2} and the transparent electrode 20a, and connecting the 20b.

  The liquid crystal capsule type light control film 17 has a structure in which a polymer film 19 is sandwiched between a transparent electrode 20a and a transparent electrode 20b.

  The polymer film 19 includes a liquid crystal capsule 18. The liquid crystal capsule 18 is obtained by placing liquid crystal molecules in a microcapsule such as a resin.

  The transparent electrode 20a is located on the back side (−Z axis direction). The transparent electrode 20b is located on the surface 17a side (+ Z axis direction).

  The transparent electrode 20a and the transparent electrode 20b are sandwiched between a protective film 21a on the back side (−Z axis direction) and a protective film 21b on the surface 17a side (+ Z axis direction). That is, the protective film 21a is located on the back side (−Z axis direction) of the transparent electrode 20a. Moreover, the protective film 21b is located in the surface 17a side (+ Z-axis direction) of the transparent electrode 20b.

  The transparent electrode 20 applies a voltage to the liquid crystal capsule 18. The transparent electrode 20a and the transparent electrode 20b are collectively described as the transparent electrode 20. That is, a voltage is applied between the transparent electrode 20a and the transparent electrode 20b.

  The transparent electrode 20 is made of a transparent material. Therefore, the transparent electrode 20 allows light from the light source 5 to pass through.

  It should be noted that the transparent electrode 20 includes a case where the transparent electrode 20 is not transparent, but is not visible to a viewer who views the liquid crystal display device 100 because, for example, the width of the electrode is very thin.

  The protective films 21a and 21b are for the purpose of electrically protecting the inside of the light control film 17. As the electrical protection, for example, the protective films 21a and 21b are made of a transparent and insulating resin.

  The protective films 21a and 21b are for the purpose of physically protecting the inside of the light control film 17. As physical protection, the resin has a role of protecting against external pressure or preventing moisture from entering.

  FIG. 7 shows a case where no voltage is applied between the transparent electrode 20a and the transparent electrode 20b.

  In the case of FIG. 7, that is, when no voltage is applied, the direction of the liquid crystal molecules in the liquid crystal capsule 18 is not determined, and the liquid crystal molecules are randomly arranged. Therefore, most of the light rays cannot be straight and scatter due to the difference in refractive index between the polymer film 19 and the liquid crystal molecules in the liquid crystal capsule 18 or the birefringence of the liquid crystal molecules in the liquid crystal capsule 18. “Birefringence” refers to the property of having a different refractive index depending on the direction of incident light.

  In FIG. 7, external light 22 is shown as a light beam incident on the light control film 17.

  FIG. 8 shows a case where a voltage is applied between the transparent electrode 20a and the transparent electrode 20b.

  When a potential is applied between the transparent electrode 20a and the transparent electrode 20b, the liquid crystal molecules in the liquid crystal capsule 18 are aligned perpendicular to the transparent electrode 20a. For this reason, the light beam can go straight without being scattered. That is, the light control film 17 becomes transparent.

  Thereby, the light beam incident on the light control film 17 goes straight. Rays can go straight without scattering. That is, the external light 22 can go straight without being scattered.

  In FIG. 8, external light 22 is shown as a light beam incident on the light control film 17.

  In addition, the control part 23 can change the state of the electric field in the light control film 17 in the state which applied the voltage between the transparent electrode 20a and the transparent electrode 20b. That is, the control unit 23 continuously changes the voltage application state between the transparent electrode 20a and the transparent electrode 20b.

<Case 1>
The housing 1 has a rectangular shape when viewed from the + Z-axis direction.

  In the case of the side edge method, for example, a plurality of light sources 5 are arranged on the short side of the housing 1. In the side edge method, for example, a plurality of light sources 5 are arranged to face the side surface on the short side of the light guide plate 7.

  Although not shown here, the light source 5 is fixed to the housing 1 with a metal support member having a thermal diffusion action. “Thermal diffusion” refers to a phenomenon in which heat diffuses from a high temperature region to a low temperature region. By fixing the light source 5 to the housing 1 using a metal support member, the liquid crystal display device 100 can efficiently dissipate the heat generated by the light source 5.

<Generation of planar light in the backlight unit 2>
The light guide plate 7 makes the light emitted from the light source 5 incident from the side surface on the short side of the light guide plate 7. In addition, when the surface facing the surface 17a is a back surface, the side surface is a surface connecting the surface 17a and the back surface. That is, in FIG. 1, a plane parallel to the YZ plane and a plane parallel to the ZX plane.

  The light guide plate 7 converts “linear light” incident from the side surface into “planar light” using a prism structure disposed on the back surface side.

  For example, the light guide plate 7 emits light mainly to the surface 17a side (+ Z-axis direction) as a surface light source.

  In general, light rays are reflected, refracted, scattered or absorbed at the interface. The reflection of light at the interface is called “interface reflection”.

  Some light beams are emitted from the light guide plate 7 to the back side (−Z-axis direction) due to interface reflection or the like. The reflection sheet 6 reflects the light beam emitted toward the back side (−Z axis direction), and redirects the traveling direction of the light toward the surface 17a side (+ Z axis direction). The reflection sheet 6 has a function of reflecting light and collecting it on the surface 17a side. That is, the reflection sheet 6 has a function of reflecting light and collecting it on the front side.

  The light emitted from the light guide plate 7 toward the surface 17a (+ Z axis direction) passes through the diffusion film 8, the brightness enhancement film 9, and the reflective polarizing film 10a and enters the liquid crystal cell unit 3.

  The light beam that has passed through the brightness enhancement film 9 enters the reflective polarizing film 10a.

  The reflective polarizing film 10a transmits only light that vibrates in one direction and reflects light that vibrates in the other direction.

  The light beam reflected by the reflective polarizing film 10 a is repeatedly reflected inside the backlight unit 2. The light beam reflected by the reflective polarizing film 10a due to reflection inside the backlight unit 2 changes its polarization direction and passes through the reflective polarizing film 10a.

<Behavior of light rays through the liquid crystal cell part 3>
The light beam that has passed through the reflective polarizing film 10 a inside the backlight unit 2 also passes through the polarizing plate 11 a of the liquid crystal cell unit 3. This is because the polarization direction (vertical polarization) is the same.

  The light beam transmitted through the polarizing plate 11a travels along the alignment of the liquid crystal molecules of the liquid crystal layer 14.

  First, the case where the liquid crystal cell unit 3 is a TN type (twisted nematic mode) liquid crystal will be described.

  In the TN type liquid crystal, liquid crystal molecules are aligned so that the alignment of the liquid crystal molecules is twisted 90 degrees on the XY plane in the state where no voltage is applied. That is, the orientation of the liquid crystal molecules is, for example, the Y-axis direction on the −Z-axis direction side of the liquid crystal cell unit 3 and the X-axis direction on the + Z-axis direction side of the liquid crystal cell unit 3.

  Vertically polarized light can pass through a horizontally aligned liquid crystal layer. Also, horizontally polarized light can be transmitted through the vertically aligned liquid crystal layer.

  First, a case where no voltage is applied to the transparent electrode 13 will be described.

  When no voltage is applied to the transparent electrode 13, the orientation of the liquid crystal molecules on the −Z axis direction side of the liquid crystal layer 14 is on the XY plane with respect to the polarization direction (X axis polarization) of the polarizing plate 11a. It is in a state rotated by 90 degrees (Y-axis direction). Further, the orientation of the liquid crystal molecules on the + Z-axis direction side of the liquid crystal layer 14 is in a state (X-axis direction) rotated 90 degrees on the XY plane with respect to the polarization direction (Y-axis polarization) of the polarizing plate 11b. .

  That is, in the liquid crystal layer 14, the alignment of the liquid crystal molecules is in a state of being rotated 90 degrees on the XY plane from the horizontal direction (Y-axis direction) to the vertical direction (X-axis direction).

  The polarization direction of the light beam traveling along the alignment of the liquid crystal molecules of the liquid crystal layer 14 from the −Z axis direction side to the + Z axis direction side rotates 90 degrees on the XY plane as it travels through the liquid crystal layer 14. That is, the X-axis polarized light incident on the liquid crystal layer 14 from the −Z-axis direction side becomes a Y-axis polarized light when exiting from the + Z-axis direction side of the liquid crystal layer 14.

  As described above, the polarization direction of the polarizing plate 11b is the Y-axis direction (horizontal polarization). The polarization direction of the light beam that has traveled along the alignment of the liquid crystal layer 14 is the Y-axis direction. For this reason, the light beam that has traveled along the alignment of the liquid crystal layer 14 can pass through the polarizing plate 11b on the light control unit 4 side.

  Next, a case where a voltage is applied to the transparent electrode 13 will be described.

  When a voltage is applied to the transparent electrode 13, the twist between the liquid crystal molecules of the liquid crystal layer 14 and the light can be taken. That is, the liquid crystal molecules in the liquid crystal layer 14 are not in a state of being rotated 90 degrees on the XY plane.

  The alignment of the liquid crystal molecules in the liquid crystal layer 14 changes in the Z-axis direction. That is, the projected area of the liquid crystal molecules is small as viewed from the protective film 21a. The area occupied by liquid crystal molecules with respect to the region where light travels is reduced.

  For this reason, since the light beam incident on the liquid crystal layer 14 from the −Z-axis direction side only hits a small area portion of the liquid crystal molecules, the vibration direction of the light hardly changes. That is, the light beam incident on the liquid crystal layer 14 from the −Z-axis direction side does not rotate in the polarization direction even though traveling in the liquid crystal layer 14.

  For this reason, the light beam cannot pass through the polarizing plate 11b (polarized light in the Y-axis direction). The polarizing plate 11b is rotated 90 degrees on the XY plane with respect to the polarizing plate 11a (polarized light in the X-axis direction).

  Next, for example, a case where the liquid crystal cell portion is a VA type (Vertical Alignment Mode, vertical alignment type) liquid crystal will be described.

  The VA type liquid crystal is a combination of a liquid crystal molecule having a negative dielectric constant and a vertical alignment film. Thus, in a state where no voltage is applied, the liquid crystal molecules are arranged perpendicularly (Z-axis direction) to the polarizing plates 11a and 11b.

  First, a case where no voltage is applied to the transparent electrode 13 will be described.

  When no voltage is applied to the transparent electrode 13, the liquid crystal molecules of the liquid crystal layer 14 are aligned perpendicular to the alignment films 16a and 16b. That is, the liquid crystal molecules are oriented in the direction perpendicular to the polarizing plates 11a and 11b (Z-axis direction). The area occupied by liquid crystal molecules with respect to the region where light travels is reduced.

  At this time, since the light beam incident on the alignment films 16a and 16b hits only a small area portion of the liquid crystal molecules, the vibration direction of the light hardly changes. For this reason, the light travels through the liquid crystal layer 14 as it is and cannot pass through the polarizing plate 11b located on the light control unit 4 side.

  That is, the light beam travels in the liquid crystal layer 14 without changing the vibration direction and reaches the polarizing plate 11b. For this reason, a light ray cannot permeate | transmit the polarizing plate 11b.

  Next, a case where a voltage is applied to the transparent electrode 13 will be described.

  When a voltage is applied to the transparent electrode 13, the liquid crystal molecules of the liquid crystal layer 14 are arranged in parallel to the alignment films 16a and 16b. That is, the liquid crystal molecules lie on the alignment films 16a and 16b. Note that “sleeping” means lying down.

  As a result, the area occupied by liquid crystal molecules with respect to the region where light travels increases. Then, the vibration direction of light changes due to the influence of the birefringence of the liquid crystal. For this reason, a light ray permeate | transmits the polarizing plate 11b. The polarization direction of the polarizing plate 11b differs from that of the polarizing plate 11a by 90 degrees on the XY plane.

  Note that an IPS liquid crystal or OCB liquid crystal may be used for the liquid crystal cell portion 3 shown in FIG. The IPS type liquid crystal is characterized in that the transparent electrode 13 is disposed only on one side of the liquid crystal layer 14 and the alignment of the liquid crystal molecules rotates parallel to the surface 17a depending on whether or not a voltage is applied. The OCB type liquid crystal is characterized in that the liquid crystal is arranged in a bow shape when no voltage is applied.

<Behavior of light when displaying image in light control unit 4>
First, a light beam (image light) transmitted through the liquid crystal cell unit 3 will be described. That is, this is a case where the observer is watching the video on the liquid crystal display device 100.

  When an image formed by the liquid crystal cell unit 3 is presented to an observer, a voltage is applied to the light control film 17. A voltage is also applied to the light absorbing film 24.

  As described above, of the image light emitted from the liquid crystal cell unit 3, the light beam passing through the polarizing plate 11b on the surface 17a side (+ Z axis direction side) of the liquid crystal cell unit 3 is, for example, the Y axis direction (horizontal polarization). Is vibrating.

  The light beam transmitted through the liquid crystal cell unit 3 enters the light control unit 4.

  The reflective polarizing films 10a and 10b have a characteristic of reflecting without absorbing light rays whose polarization directions do not match.

  The polarizing plate 11 b is located on the light control unit 4 side of the liquid crystal cell unit 3.

  The polarization direction of the reflective polarizing film 10b matches the polarization direction of the polarizing plate 11b. The polarization direction of the polarizing plate 11b is the horizontal direction (Y-axis direction). The polarization direction of the reflective polarizing film 10b is the horizontal direction (Y-axis direction).

  The light beam transmitted through the polarizing plate 11b is a horizontally polarized light beam. That is, the light beam that has passed through the liquid crystal cell unit 3 and entered the reflective polarizing film 10b is polarized in the horizontal direction (Y-axis direction).

  Light rays that have passed through the liquid crystal cell unit 3 and entered the reflective polarizing film 10b are transmitted without being reflected by the reflective polarizing film 10b. Since the polarization direction of the reflective polarizing film 10b is the same as that of the polarizing plate 11b, the light emitted from the liquid crystal cell unit 3 is transmitted through the reflective polarizing film 10b without loss.

  In order to explain the behavior of light in a simple manner, “no loss” is shown, but in reality, “loss is low (low loss)”. The same applies to the following.

  The light beam that has passed through the reflective polarizing film 10 b passes through the light absorbing film 24.

  In the light-absorbing film 24, the dichroic dye is aligned in the direction perpendicular to the alignment film by applying a voltage. For this reason, the light absorption film 24 transmits light without coloring the light.

  Further, the light beam that has passed through the light absorbing film 24 passes through the light control film 17.

  The light control film 17 arranges the liquid crystal molecules in the liquid crystal capsule 18 perpendicularly to the transparent electrode 20a by applying a voltage. For this reason, the light control film 17 will be in a transparent state.

  And the light ray which permeate | transmitted the light control film 17 is shown as an image | video to an observer.

  That is, the image light emitted from the liquid crystal cell unit 3 can reach the observer as it is.

  The image light emitted from the liquid crystal cell unit 3 reaches the viewer without receiving light loss by the reflective polarizing film 10b, the light absorption film 24, and the light control film 17. “Loss of light” is a loss of light positively generated by each component. In the following, it is called “light loss”.

  In addition, in order to explain the behavior of light in a simple manner, “without loss of light” is shown, but in reality, “loss is low (low loss)”. The same applies to the following.

  As shown in FIG. 8, when a voltage is applied between the transparent electrode 20 a and the transparent electrode 20 b of the light control film 17, much light is transmitted through the light control film 17 in the light control unit 4. it can. Usually, the transmittance for transmitting parallel light rays through the light control film 17 is 70% or more.

  This transmittance is sufficiently larger than the transmittance of a half mirror described later. The transmittance of the half mirror is about 50%. The “half mirror” refers to a mirror that reflects a part of incident light and transmits a part of the incident light, and has substantially the same amount of reflected light and transmitted light.

  For this reason, it is possible to minimize a decrease in luminance in the light control unit 4.

  Next, the external light 22 when the observer is watching the liquid crystal display device 100 will be described.

  First, a case where a voltage is applied to the liquid crystal capsule 18 of the light control film 17 will be described. That is, it is a case where an image is presented to an observer. For example, this is a case where the observer is watching the liquid crystal display device 100.

  The external light 22 can go straight without being scattered. The light control film 17 is in a transparent state. Thereby, the external light 22 can go straight without being scattered. That is, the external light 22 incident on the liquid crystal display device 100 passes through the light control film 17 as it is.

  The light beam that has passed through the light control film 17 then reaches the light absorption film 24. The light absorbing film 24 also transmits light without coloring the light. For this reason, the external light 22 reaches | attains the reflective polarizing film 10b, without receiving an optical loss.

  The reflective polarizing films 10a and 10b transmit light that vibrates in one direction and reflect light that vibrates in the other direction. For this reason, a part of the external light 22 that has reached the reflective polarizing film 10 b is reflected, passes through the light absorption film 24 and the light control film 17 again, and reaches the observer.

  As described above, when the image formed in the liquid crystal cell unit 3 is presented to the observer by the configuration of the light control film 17, the light absorption film 24, and the reflective polarizing film 10b, the external light that has reached the light control film 17 22 reflection can be reduced.

<Behavior of light when no image is displayed in the light control unit 4>
Next, a case where no voltage is applied to the liquid crystal capsule 18 of the light control film 17 will be described. For example, this is a case where the observer is not watching an image on the liquid crystal display device 100.

  When the observer is not watching the video on the liquid crystal display device 100, the light source 5 is not lit. That is, the light source 5 is not turned on.

  For this reason, there is no light passing through the liquid crystal cell unit 3 and transmitted to the surface 17a side.

  Hereinafter, the external light 22 will be described.

  In this case, no voltage is applied to the light control film 17. Further, no voltage is applied to the light absorbing film 24. That is, no voltage is applied to both the light control film 17 and the light absorption film 24.

  The light control film 17 scatters most of the external light 22 in a state where no voltage is applied, as illustrated in FIG. 7.

  However, part of the external light 22 passes through the light control film 17. The light beam that has passed through the light control film 17 reaches the light absorption film 24.

  No voltage is applied to the light absorbing film 24 as well.

  As shown in FIG. 5, when no voltage is applied, the light absorption film 24 absorbs light having an absorption peak wavelength Wp.

  For this reason, light having a specific wavelength (absorption peak wavelength Wp) among the light incident on the light absorption film 24 is absorbed by the light absorption film 24. Light having a wavelength that is not absorbed by the light absorption film 24 passes through the light absorption film 24. That is, light is colored when passing through the light absorbing film 24.

  The “specific wavelength” can be set by selecting the dichroic dye 26 (guest).

  The light rays colored when passing through the light absorbing film 24 reach the reflective polarizing film 10b.

  The reflective polarizing film 10b transmits light that vibrates in the horizontal direction (horizontal polarized light), for example. The reflective polarizing film 10b reflects light that vibrates in a direction other than the horizontal direction.

  The colored outside light 22 that has reached the reflective polarizing film 10b has no fixed polarization direction. For this reason, a part of the colored outside light 22 reaching the reflective polarizing film 10b is reflected. Then, the colored outside light 22 that has reached the reflective polarizing film 10b passes through the light absorption film 24 and the light control film 17 again and reaches the observer.

  Generally, when a video is not being viewed, the display surface of the liquid crystal display device is black. That is, the color of the surface 17a of the liquid crystal cell unit 3 is generally black.

  This is because the polarizing element of the polarizing plate 11b arranged on the surface 17a side absorbs light other than a specific polarization direction. The polarizing element is, for example, iodine molecules.

  Therefore, when the light control film 17 is disposed on the surface 17 a side of the liquid crystal cell unit 3 without disposing the light absorbing film 24, a part of the external light 22 transmitted through the light control film 17 is part of the surface of the liquid crystal cell unit 3. Is absorbed by the polarizing plate 11b. For this reason, the light control film 17 looks dark milky white.

  For example, the polarizing plate 11b transmits only light that vibrates in the Y-axis direction (horizontal direction) and absorbs light that vibrates in other directions. On the other hand, the reflective polarizing film 10b transmits only light that vibrates in the Y-axis direction (horizontal direction) and reflects light that vibrates in other directions.

  That is, when viewed from the front side of the liquid crystal display device 100, the polarizing plate 11b looks black, while the reflective polarizing film 10b looks white.

  Between the light control film 17 and the liquid crystal cell part 3, the light absorption film 24 and the reflective polarizing film 10b are disposed.

  In this configuration, part of the external light 22 is scattered due to the characteristics of the light control film 17. That is, a part of the external light 22 cannot go straight through the light control film 17.

  Further, a part of the external light 22 that has passed through the light control film 17 becomes colored light by passing through the light absorption film 24.

  A part of the light beam transmitted through the light absorbing film 24 is reflected by the reflective polarizing film 10b.

  Due to these scattering and reflection, the display screen (surface 17 a) of the liquid crystal display device 100 looks a color corresponding to the absorption peak wavelength Wp of the light absorption film 24.

  As described above, when displaying an image on the liquid crystal cell unit 3, it is possible to display an image as usual by applying a voltage to the light control film 17 to make it transparent.

  On the other hand, when an image is not displayed on the liquid crystal cell portion, the surface 17 a can be colored by not applying a voltage to the light control film 17 and the light absorption film 24.

  The color of the surface 17 a is determined by the properties of the dichroic dye (guest) 26 used for the light absorbing film 24. “The case where no image is displayed on the liquid crystal cell unit” is a case where the liquid crystal display device 100 is not used, for example.

  As a result of the above, in the case where the liquid crystal display device 100 having a large display screen (surface 17a) is arranged in a room, it is possible to reduce the presence when the liquid crystal display device 100 is not used and to harmonize with the interior. become.

  Moreover, since the light loss in the light control part 4 is small, the light quantity of the backlight part 2 can be restrained compared with the past.

  For example, there is a liquid crystal display device in which a half mirror or the like is arranged in front of the liquid crystal display device, and a mirror is used when the liquid crystal display device is not displayed to avoid a black display screen when no image is displayed. Has been developed.

  However, in this case, since the transmittance of the half mirror is low, it is necessary to increase the amount of light of the backlight in order to obtain a desired luminance. Here, the “desired luminance” is a luminance necessary for viewing an image.

  In the present invention, the light control film 17 appears as a colored surface under the condition that the liquid crystal display device 100 is not displayed. Moreover, the light control film 17 looks transparent under the conditions for displaying the liquid crystal display device 100.

  From the viewpoint of power saving, the liquid crystal display device 100 of the present invention that suppresses an increase in the amount of light of the backlight unit 2 is superior.

  In addition, in the case of a system that is a mirror when the liquid crystal display device is not used, when the liquid crystal display device has a large screen, it becomes a large mirror, so that the installation location is limited. Also from the viewpoint of interior design, when the liquid crystal display device is not used, the liquid crystal display device 100 that can make the display screen the same color as the wall color, for example, is preferable to the liquid crystal display device in which the half mirror is arranged.

  In the first embodiment, the configuration using the polarizing plate 11b and the reflective polarizing film 10b has been described. This is because the liquid crystal cell unit 3 is often handled as one component, and a configuration in which a reflective polarizing film 10b is newly added is relatively easy to realize.

  However, instead of using the polarizing plate 11b, the reflective polarizing film 10b may be disposed on the surface 17a side (+ Z axis direction) of the glass plate 12b instead.

  In this case, the polarization direction of the reflective polarizing film 10b is determined by the alignment direction of the liquid crystal molecules of the liquid crystal layer 14 and the polarization direction of the polarizing plate 11a. For example, in the case of VA liquid crystal, the polarization direction of the reflective polarizing film 10b may be perpendicular to the polarization direction of the polarizing plate 11a on the XY plane.

  That is, when displaying an image, the polarization direction of the light emitted from the liquid crystal layer 14 toward the reflective polarizing film 10b may be the same as the polarizing direction of the reflective polarizing film 10b. Thereby, the light at the time of displaying an image can be transmitted through the reflective polarizing film 10b without loss. If the polarization directions do not match, a part of light (image light) for displaying an image cannot pass through the reflective polarizing film 10b, and the image becomes dark.

  By using the reflective polarizing film 10b instead of the polarizing plate 11b, the number of parts can be reduced. And assembly property can be improved. And manufacturing cost can be reduced. In addition, since optical components are reduced, light loss due to light absorption or light scattering is reduced. And the effect of energy saving is acquired. When a liquid crystal display device with a large screen is arranged in a room, it is possible to reduce the presence when the liquid crystal display device is not used and to achieve harmony with the interior.

  In the first embodiment, the liquid crystal cell member 3 has been described as the liquid crystal cell portion 3.

  In the first embodiment, the light control member 17 has been described as the light control film 17. However, the light control member 17 does not necessarily need to be a film. The light control member 17 may be a plate-shaped member, for example.

  Moreover, in Embodiment 1, the reflective polarizing member 10b was demonstrated as the reflective polarizing film 10b. However, the reflective polarizing member 10b is not necessarily a film. The reflective polarizing member 10b may be a plate-like member, for example.

  The liquid crystal display device 100 includes a liquid crystal cell unit 3, a light control plate 17, a reflective polarizing plate 10 b, a light absorption plate 24, and a backlight unit 2.

  The liquid crystal cell unit 3 includes a liquid crystal layer 14 that changes the orientation of liquid crystal molecules when a first voltage is applied, and a polarizing plate 11b that is disposed on the light exit surface.

  The light control plate 17 is disposed on the surface 17a side of the liquid crystal cell unit 3, and changes the light transmittance by applying a second voltage.

  The reflective polarizing plate 10b is disposed between the light control plate 17 and the liquid crystal cell unit 3, and transmits specific polarized light and reflects other light.

  The light absorption plate 24 is disposed between the light control plate 17 and the reflective polarizing plate 10b, and absorbs light of a specific wavelength when a third voltage is applied.

  The backlight unit 2 is disposed on the back side of the liquid crystal cell unit 3 and irradiates the liquid crystal cell unit 3 with light.

  The polarization direction of light incident on the reflective polarizing plate 10b from the liquid crystal layer 14 is the same as the polarization direction of light transmitted through the reflective polarizing plate 10b.

  A second voltage is applied to the light control plate 17 so that the light transmittance when the backlight unit 2 is turned on is higher than the light transmittance when the backlight unit 2 is turned off. Is done.

  A third voltage is applied to the light absorbing plate 24 so that the light absorption rate when the backlight unit 2 is turned on is lower than the light absorption rate when the backlight unit 2 is turned off. Applied.

  The light absorbing plate 24 includes a guest-host type liquid crystal 250 using a dichroic dye.

  When the backlight unit 2 is lit, the light transmittance of the light control plate 17 is increased, and the light absorption rate of the guest-host type liquid crystal layer 250 is decreased.

  When the backlight unit 2 is turned off, the light transmittance of the light control plate 17 is reduced, and the light absorption rate of the guest-host type liquid crystal layer 250 is increased.

  The light control plate 17 has a configuration in which a capsule containing liquid crystal is sandwiched between electrodes.

  In addition, although embodiment of this invention was described as mentioned above, this invention is not limited to these embodiment.

DESCRIPTION OF SYMBOLS 1 Housing | casing, 2 Backlight part, 3 Liquid crystal cell part, 4 Light control part, 5 Light source, 6 Reflective sheet, 7 Light guide plate, 8 Diffusion film, 9 Brightness enhancement film, 10 Reflective polarizing film, 11 Polarizing plate, 12 Glass plate, 13 transparent electrode, 14 liquid crystal layer, 15 color filter, 16, 27 alignment film, 17 light control film, 17a surface, 18 liquid crystal capsule, 19 polymer film, 20, 28 transparent electrode, 21, 29 protective film, 22 external light 23, 30 control unit, 24 light absorbing layer, 25 liquid crystal molecules 26 dichroic dye 250 liquid crystal composition, _S 1, _{S 2} switch, _V 1, _{V 2} power, A light absorptance, W wavelength , Wp absorption peak wavelength.

Claims (4)

A liquid crystal cell unit comprising a liquid crystal layer that changes the orientation of liquid crystal molecules by applying a first voltage and a polarizing plate disposed on a light exit surface;
A light control plate that is disposed on the surface side of the liquid crystal cell unit and changes a light transmittance by applying a second voltage;
A reflective polarizing plate that is disposed between the light control plate and the liquid crystal cell unit, transmits specific polarized light, and reflects other light;
A light absorbing plate that is disposed between the light control plate and the reflective polarizing plate and absorbs light of a specific wavelength by applying a third voltage;
A backlight unit disposed on the back side of the liquid crystal cell unit and irradiating the liquid crystal cell unit with light;
The polarization direction of light incident on the reflective polarizing plate from the liquid crystal layer is the same as the polarization direction of light transmitted through the reflective polarizing plate,
The dimming plate has the second voltage so that the light transmittance when the backlight portion is turned on is higher than the light transmittance when the backlight portion is turned off. Applied,
The light absorption plate has the third voltage so that the light absorption rate when the backlight unit is turned on is lower than the light absorption rate when the backlight unit is turned off. A liquid crystal display device to which is applied.   The liquid crystal display device according to claim 1, wherein the light absorbing plate includes a guest-host type liquid crystal using a dichroic dye. When the backlight portion is lit, increase the light transmittance of the light control plate, reduce the light absorption rate of the guest-host type liquid crystal layer,
3. The liquid crystal according to claim 1, wherein when the backlight unit is turned off, the light transmittance of the light control plate is lowered and the light absorptance of the guest-host type liquid crystal layer is increased. Display device.   4. The liquid crystal display device according to claim 1, wherein the light control plate has a configuration in which a capsule containing liquid crystal is sandwiched between electrodes. 5.

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