JP2016024994A - Surface light source device and display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a surface light source device showing a superior utilization efficiency of light source light.SOLUTION: This invention relates to a luminance angle distribution in each of the directions in a plane in parallel with both a normal direction (nd) of a light guide plate and the first direction on an emitted light surface 31 of the light guide plate 30 caused by light from a light source 24 in which a peak luminance lx(cd/m), an angle θx(°) in which a direction where the peak luminance can be attained is inclined to the other side in the first direction from the normal direction of the light guide plate, a luminance ly(cd/m) in a direction inclined from the normal direction of the light guide plate to the other side in the first direction only by an angle of a half of the angle θx satisfy the following conditions (a) and (b). 65°<θx...(a) and 50<lx/ly...(b)SELECTED DRAWING: Figure 1

Description

  The present invention relates to a surface light source device having a quantum dot sheet containing quantum dots, and more particularly to a surface light source device having excellent light source light utilization efficiency. The present invention also relates to a display device having a surface light source device excellent in light utilization efficiency.

  A surface light source device that emits light in a planar shape is widely used as a backlight that is incorporated in, for example, a liquid crystal display device and illuminates a liquid crystal display panel from the back side (for example, Patent Document 1). Surface light source devices for liquid crystal display devices can be broadly classified into a direct type in which a light source is arranged directly under an optical member and an edge light type in which a light source is arranged on a side of the optical member (also referred to as a side light type). being classified. The edge light type surface light source device is superior to the direct type surface light source device in that the thickness can be reduced.

  Recently, it has been studied to incorporate a quantum dot sheet containing quantum dots into a surface light source device or a display device. The quantum dots function as phosphors and can absorb light and emit light of different wavelengths. The wavelength of the light emitted from the quantum dot mainly depends on the particle size of the quantum dot. Therefore, in a surface light source device incorporating a quantum dot sheet, various colors can be reproduced while using a light source that projects light in a single wavelength region. For example, the light source can project blue light, and the quantum dot sheet can absorb blue light and emit red light and green light. Since such a surface light source device is excellent in color purity, a display device using this surface light source device has excellent color reproducibility.

Special table 2013-539170 gazette

  By the way, when the present inventors have repeated intensive studies on the edge light type surface light source device including the quantum dot sheet, the luminance angle distribution on the light exit surface of the light guide plate is the use efficiency of the light source light in the surface light source device. It has been found that it can have a big impact on Specifically, the present inventors have confirmed that when the luminance angle distribution on the light exit surface of the light guide plate satisfies a predetermined condition, the use efficiency of the light source light in the surface light source device can be remarkably increased. The present invention is based on such knowledge of the inventors of the present invention, and an object of the present invention is to provide a surface light source device excellent in utilization efficiency of light source light and a display device having the surface light source device.

A surface light source device according to the present invention comprises:
A light guide plate having a light exit surface and a pair of side surfaces facing in the first direction;
A light source that projects light onto a side surface located on one side of the light guide plate in the first direction;
A quantum dot sheet that is disposed to face the light exit surface of the light guide plate and includes quantum dots, and
In the luminance angle distribution in each direction in a plane parallel to both the normal direction of the light guide plate and the first direction, regarding the luminance on the light exit surface of the light guide plate due to the light from the light source, The peak luminance lx [cd / m ² ], the angle θx [°] in which the direction in which the peak luminance is obtained is inclined from the normal direction of the light guide plate to the other side in the first direction, and only half the angle θx The luminance ly [cd / m ² ] in the direction inclined from the normal direction of the light guide plate to the other side in the first direction satisfies both of the following conditions (a) and (b).
65 ° <θx (a)
50 <lx / ly (b)

In the surface light source device according to the present invention,
A prism sheet disposed on the opposite side of the light guide plate of the quantum dot sheet, further comprising:
The prism sheet has a sheet-like main body, and a plurality of unit prisms provided on the opposite side of the main body from the quantum dot sheet,
The plurality of unit prisms may be arranged in the first direction, and each unit prism may extend linearly in a direction non-parallel to the first direction.

In the surface light source device according to the present invention,
A first prism sheet and a second prism sheet disposed on the opposite side of the quantum dot sheet from the light guide plate;
The first prism sheet and the second prism sheet each have a sheet-like main body portion and a plurality of unit prisms provided on the opposite side of the main body portion from the quantum dot sheet,
The plurality of unit prisms of the first prism sheet are arranged in the first direction, and each unit prism extends linearly in a direction non-parallel to the first direction,
The plurality of unit prisms of the second prism sheet may be arranged in an arrangement direction not parallel to the first direction, and each unit prism may extend linearly in a direction non-parallel to the arrangement direction.

In the surface light source device according to the present invention, in the luminance angle distribution, a peak luminance is obtained in a direction in which half the peak luminance located between the normal direction of the light guide plate and the direction in which the peak luminance is obtained is obtained. The angle θα inclined to the one side along the first direction from the given direction may satisfy the following condition (c).
0 ° ≦ θα ≦ 15 ° (c)

A display device according to the present invention comprises:
Any of the surface light source devices according to the present invention described above;
A display panel disposed to face the surface light source device.

  ADVANTAGE OF THE INVENTION According to this invention, the utilization efficiency of the light source light of the surface light source device in which the quantum dot sheet was incorporated can be improved effectively.

FIG. 1 is a cross-sectional view illustrating a schematic configuration of a display device and a surface light source device for explaining an embodiment according to the present invention. FIG. 2 is a diagram for explaining the operation of the surface light source device of FIG. FIG. 3 is a perspective view showing the light guide plate incorporated in the surface light source device of FIG. 1 from the light exit surface side. FIG. 4 is a perspective view showing the light guide plate incorporated in the surface light source device of FIG. 1 from the back side. FIG. 5 is a diagram for explaining the operation of the light guide plate, and is a view showing the light guide plate in a cross section taken along the line V-V in FIG. 3. FIG. 6 is a perspective view showing a prism sheet incorporated in the surface light source device of FIG. FIG. 7 is a partial cross-sectional view showing the prism sheet of FIG. 6 at its main cut surface (cross section taken along line VII-VII of FIG. 6). FIG. 8 is a graph showing the luminance angle distribution on the light exit surface of the light guide plate in a plane parallel to both the front direction and the first direction. FIG. 9 is a graph showing the luminance angle distribution on the light emission side surface of the quantum dot sheet in a plane parallel to both the front direction and the first direction and in a plane parallel to both the front direction and the second direction. . FIG. 10 is a graph showing the luminance angle distribution on the light emitting surface of the surface light source device. FIG. 11 is a diagram corresponding to FIG. 1 and illustrating a modification of the surface light source device.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. In the drawings attached to the present specification, for the sake of illustration and ease of understanding, the scale, the vertical / horizontal dimension ratio, and the like are appropriately changed and exaggerated from those of the actual product.

  FIGS. 1-10 is a figure for demonstrating one Embodiment by this invention. Among these, FIG. 1 is a perspective view showing a schematic configuration of a liquid crystal display device and a surface light source device, and FIG. 2 is a cross-sectional view for explaining the operation of the surface light source device. 3 and 4 are perspective views showing a light guide plate included in the surface light source device, and FIG. 5 is a cross-sectional view showing the light guide plate in the main cut surface of the light guide plate. 6 and 7 are perspective views or cross-sectional views showing a prism sheet included in the surface light source device. FIG. 8 to FIG. 10 are cross-sectional views that are graphs showing an example of the luminance angle distribution related to the surface light source device.

  As shown in FIG. 1, the display device 10 includes a liquid crystal display panel 15 and a surface light source device 20 that is disposed on the back side of the liquid crystal display panel 15 and illuminates the liquid crystal display panel 15 in a planar shape from the back side. . The display device 10 has a display surface 11 for displaying an image. The liquid crystal display panel 15 functions as a shutter that controls transmission or blocking of light from the surface light source device 20 for each pixel, and is configured to display an image on the display surface 11.

  The illustrated liquid crystal display panel 15 is disposed between the upper polarizing plate 13 disposed on the light output side, the lower polarizing plate 14 disposed on the light incident side, and the upper polarizing plate 13 and the lower polarizing plate 14. And a liquid crystal layer cell 12. The polarizing plates 14 and 13 decompose the incident light into two orthogonally polarized components (P wave and S wave) and oscillate in one direction (direction parallel to the transmission axis) (for example, P wave). ) And absorbs a linearly polarized light component (for example, S wave) that vibrates in the other direction (direction parallel to the absorption axis) perpendicular to the one direction.

  An electric field can be applied to the liquid crystal layer 12 for each region where one pixel is formed. Then, the alignment direction of the liquid crystal molecules in the liquid crystal layer 12 changes depending on whether or not an electric field is applied. As an example, a polarization component in a specific direction that has passed through the lower polarizing plate 14 disposed on the light incident side rotates the polarization direction by 90 ° when passing through the liquid crystal layer 12 to which an electric field is applied. When passing through the liquid crystal layer 12 that is not applied, the polarization direction is maintained. In this case, depending on whether or not an electric field is applied to the liquid crystal layer 12, does the polarized light component that vibrates in a specific direction transmitted through the lower polarizing plate 14 further pass through the upper polarizing plate 13 disposed on the light output side of the lower polarizing plate 14? Alternatively, it is possible to control whether the light is absorbed and blocked by the upper polarizing plate 13.

  In this manner, the liquid crystal panel (liquid crystal display unit) 15 can control transmission or blocking of light from the surface light source device 20 for each pixel. The details of the liquid crystal display panel 15 are described in various publicly known documents (for example, “Flat Panel Display Dictionary (supervised by Tatsuo Uchida, Hiraki Uchiike)” published in 2001 by the Industrial Research Council). The detailed description above is omitted.

  Next, the surface light source device 20 will be described. The surface light source device 20 has a light emitting surface 21 that emits light in a planar shape, and is used as a device that illuminates the liquid crystal display panel 15 from the back side in the present embodiment.

  As shown in FIG. 2, the surface light source device 20 is configured as an edge light type surface light source device, and is disposed on the side of the light guide plate 30 and one side (left side in FIG. 1) of the light guide plate 30. The light source 24, the quantum dot sheet 60, the two prism sheets 71 and 72, and the reflection sheet 28, which are disposed so as to face the light guide plate 30, respectively. In the illustrated example, the second prism sheet 72 is arranged facing the liquid crystal display panel 15. The light-emitting surface 21 of the surface light source device 20 is defined by the light-emitting side surface 70a of the second prism sheet 72 disposed on the light-emitting side of the two prism sheets 71 and 72.

  In the illustrated example, the light exit surface 31 of the light guide plate 30 has a planar view shape (in FIG. 1, looking down from above), like the display surface 11 of the liquid crystal display device 10 and the light emitting surface 21 of the surface light source device 20. (Viewed shape) is formed in a square shape. As a result, the light guide plate 30 is generally configured as a rectangular parallelepiped member having a pair of main surfaces (the light exit surface 31 and the back surface 32) in which the sides in the thickness direction are smaller than the other sides. A side surface defined between the pair of main surfaces includes four surfaces. Similarly, the quantum dot sheet 60, the prism sheets 71 and 72, and the reflection sheet 28 are generally configured as rectangular parallelepiped members having relatively thin sides in the thickness direction than other sides.

The light guide plate 30 includes a light output surface 31 constituted by one main surface on the liquid crystal display panel 15 side, a back surface 32 formed of the other main surface facing the light output surface 31, and a space between the light output surface 31 and the back surface 32. And a side surface extending. One side surface of the two surfaces facing the first direction d <b> 1 of the side surfaces forms the light incident surface 33. As shown in FIG. 1, a light source 24 is provided facing the light incident surface 33. Light incident from the light incident surface 33 into the light guide plate 30, toward the opposite surface 34 facing the first direction (light guide direction) d light incident surface 33 along _a generally first direction (light guide direction) The light guide plate 30 is guided along d ₁ . As shown in FIGS. 1 and 2, the quantum dot sheet 60 is disposed so as to face the light exit surface 31 of the light guide plate 30, and the reflection sheet 28 is disposed so as to face the back surface 32 of the light guide plate 30. Has been. In addition, a first prism sheet 71 and a second prism sheet 72 are sequentially arranged on the opposite side of the quantum dot sheet 60 from the side facing the light guide plate 30.

  The light source may be configured in various modes such as a fluorescent lamp such as a linear cold cathode tube, a point LED (light emitting diode), an incandescent lamp, and the like. In the present embodiment, the light source 24 has a large number of dots arranged side by side along the longitudinal direction of the light incident surface 33 (in FIG. 1, the direction orthogonal to the paper surface, that is, the front and back direction of the paper surface). The light emitter 25, specifically, a plurality of light emitting diodes (LEDs). Note that the light guide plate 30 shown in FIGS. 3 and 4 shows the arrangement positions of a large number of point-like light emitters 25 forming the light source 24. In the surface light source device 20 described here, the light source 24 can include only the light emitter 25 that emits light in a single wavelength region, in association with the later-described quantum dot sheet 60. For example, the light emitter 25 can include only a light emitting diode that emits blue light with high color purity as the light emitter 25.

  The reflection sheet 28 is a member for reflecting the light leaking from the back surface 32 of the light guide plate 30 so as to enter the light guide plate 30 again. The reflection sheet 28 is composed of a white scattering reflection sheet, a sheet made of a material having a high reflectance such as metal, a sheet containing a thin film (for example, a metal thin film) made of a material having a high reflectance as a surface layer, and the like. obtain. The reflection on the reflection sheet 28 may be regular reflection (specular reflection) or diffuse reflection. When the reflection on the reflection sheet 28 is diffuse reflection, the diffuse reflection may be isotropic diffuse reflection or anisotropic diffuse reflection.

  By the way, in this specification, the “light exit side” means the light source 24, the light guide plate 30, the quantum dot sheet 60, the first prism sheet 71, the second prism sheet 72, the liquid crystal display panel 15, and the components of the display device 10. It is the downstream side (observer side, for example, the upper side of the paper surface in FIG. 1) in the traveling direction of the light that travels without going back and goes out from the display device 10 and travels toward the viewer. Means that the light source 24, the light guide plate 30, the quantum dot sheet 60, the first prism sheet 71, the second prism sheet 72, the liquid crystal display panel 15 and the liquid crystal display panel 15 and the display device 10 are moved back without going back. It is the upstream side in the traveling direction of the light emitted from 10 and traveling toward the observer.

  Further, in the present specification, terms such as “sheet”, “film”, and “plate” are not distinguished from each other only based on the difference in names. Therefore, for example, a “sheet” is a concept including a member that can also be called a film or a plate.

  Further, in this specification, the “sheet surface (plate surface, film surface)” corresponds to the planar direction of the target sheet-like member when the target sheet-like member is viewed as a whole and globally. Refers to the surface. In the present embodiment, the plate surface of the light guide plate 30, the sheet surface (plate surface) of the base 40 described later of the light guide plate 30, the sheet surface of the quantum dot sheet 60, the sheet surface of the first prism sheet 71, The sheet surface of the two prism sheet 72, the sheet surface of the reflection sheet 28, the panel surface of the liquid crystal display panel, the display surface 11 of the display device 10, and the light emitting surface 21 of the surface light source device 20 are parallel to each other.

  Furthermore, in this specification, the normal line direction of a sheet-like member refers to the normal line direction to the sheet | seat surface of the sheet-like member used as object. Further, in the present specification, the “front direction” is a normal direction to the light emitting surface 21 of the surface light source device 20, and in this embodiment, the normal to the light emitting surface 21 of the surface light source device 20. Direction, normal direction to the plate surface of the light guide plate 30, normal direction to the sheet surface of the quantum dot sheet 60, normal direction to the sheet surface of the first prism sheet 71, to the sheet surface of the second prism sheet 72 And the normal direction to the display surface 11 of the display device 10 and the like (for example, see FIG. 2).

  Next, the light guide plate 30 will be described in detail with reference mainly to FIGS. 2 to 5, the light guide plate 30 has a base 40 formed in a plate shape and a surface on one side of the base 40 (a surface facing the observer side, a light exiting side) 40a. A plurality of unit optical elements 50 formed. The base 40 is configured as a flat member having a pair of parallel main surfaces. And the back surface 32 of the light-guide plate 30 is comprised by the back side surface 40b of the base 40 located in the side facing the reflective sheet 28. FIG.

  The “unit prism”, “unit shape element”, “unit optical element”, and “unit lens” in the present specification refer to the optical action such as refraction and reflection on the light, and indicate the traveling direction of the light. It refers to an element having a function to be changed, and is not distinguished from each other based only on a difference in designation.

  As shown well in FIG. 4, the back side surface 40 b of the base 40 that forms the back surface 32 of the light guide plate 30 is formed as an uneven surface. As a specific configuration, the back surface 32 has an inclined surface 37, a step surface 38 extending in the normal direction nd of the light guide plate 30, and a connection extending in the plate surface direction of the light guide plate 30 due to the unevenness of the back side surface 40 b of the base 40. And a surface 39. The light guide in the light guide plate 30 is based on the total reflection action on the pair of main surfaces 31 and 32 of the light guide plate 30. On the other hand, the inclined surface 37 is inclined with respect to the plate surface of the light guide plate 30 so as to approach the light exit surface 31 from the light incident surface 33 side toward the opposite surface 34 side. Therefore, the incident angle when the light reflected by the inclined surface 37 enters the pair of main surfaces 31 and 32 becomes small. When the incident angle on the pair of main surfaces 31 and 32 is less than the total reflection critical angle by reflecting on the inclined surface 37, the light is emitted from the light guide plate 30. That is, the inclined surface 37 functions as an element for extracting light from the light guide plate 30.

The distribution of the inclined surface 37 along the first direction d ₁ is a light guiding direction by adjusting in the back surface 32, to adjust the first distribution along the direction d ₁ of the amount of light emitted from the light guide plate 30 it can. In the example shown in FIGS. 2 to 5, the proportion of the inclined surface 37 in the back surface 32 increases as the distance from the incident surface 33 approaches the opposite surface 34 along the light guide direction. According to such a configuration, emission of light from the light guide plate 30 in a region separated from the incident surface 33 along the light guide direction is promoted, and the amount of emitted light decreases as the distance from the incident surface 33 increases. Can be effectively prevented.

Next, the unit optical element 50 provided on the light emission side surface 40a of the base 40 will be described. As seen in FIG. 3, a plurality of unit optical elements 50 has a first cross in the direction d ₁ and the light exit side 40a parallel to the array direction of the base 40 (the left-right direction at Figure 3) They are lined up and arranged on the light output side surface 40 a of the base 40. Each unit optical element 50 extends linearly on the light exit side surface 40a of the base 40 in a direction intersecting with the arrangement direction.

In particular, in the present embodiment, as shown in FIGS. 3 and 5, the plurality of unit optical elements 50 are arranged on the light exit side surface 40 a of the base 40 in the second direction (arrangement direction) d orthogonal to the first direction d _{1. 2} are arranged side by side with no gap. Therefore, the light exit surface 31 of the light guide plate 30 is configured as inclined surfaces 35 and 36 formed by the surface of the unit optical element 50. Each unit optical element 50 extends linearly along a first direction d ₁ orthogonal to the arrangement direction. Further, each unit optical element 50 is formed in a column shape and has the same cross-sectional shape along the longitudinal direction thereof. In the present embodiment, the plurality of unit optical elements 50 are configured identically. As a result, the light guide plate 30 in the present embodiment, at each position along the first direction d _1, which is to have a constant cross-sectional shape.

Then, cross-section shown in FIG. 5, i.e., in both the normal direction nd of the arrangement direction of the unit optical element (second direction) d ₂ and the base 40 Idemitsu side 40a (the plate surface of the light guide plate 30) A cross-sectional shape of each unit optical element 50 in a parallel cross section (hereinafter, also simply referred to as a main cut surface of the light guide plate) will be described. As shown in FIG. 5, in the illustrated example, the cross-sectional shape of each unit optical element 50 on the main cut surface of the light guide plate is a shape that tapers toward the light output side. That is, in the main cut surface of the light guide plate, the width of the unit optical element 50 parallel to the plate surface of the light guide plate 30 decreases as the distance from the base 40 increases along the normal direction nd of the light guide plate 30.

In the present embodiment, the outer contour (corresponding to the light-emitting side surface 31) 51 on the main cutting surface of the unit optical element 50 is a light-emitting surface angle that is an angle formed by the outer contour with respect to the light-emitting side surface 40a of the base 40. theta _a is, to be larger toward the base portion 40 to the farthest unit optical from the tip portion 52a of the outer contour 51 of the element 50 on the outer contour 51 of the unit optical elements 50 closest to the base portion 40 of the base end portion 52b Is changing. About this light emission surface angle (theta) _a , it can set as disclosed by Unexamined-Japanese-Patent No. 2013-51149, for example.

The angle the light exit surface an angle theta _a, as described above, in the main cutting face of the light guide plate, the light exit side (outer profile) 51 of the unit optical element 50 which forms with respect to the light exit side 40a of the base portion 40 here It is. As in the example shown in FIG. 5, when the outer contour (light-emitting side surface) 51 in the main cut surface of the unit optical element 50 is formed in a polygonal line shape, each linear part constituting the polygonal line and the light-emitting side surface of the base 40. It is the angle (in a strict sense, the smaller the angle of the ones of the two angles formed (angle of minor angle)) formed between the 40a is the light exit surface an angle theta _a. On the other hand, when the outer contour (light-emitting side surface) 51 on the main cutting surface of the unit optical element 50 is configured by a curved surface, an angle formed between the tangent to the outer contour and the light-emitting side surface 40a of the base 40 ( strictly speaking, the smaller the angle of the ones of the two angles formed (angle of minor angle)), and be identified as the light exit surface an angle theta _a.

The unit optical element 50 as one specific example shown in FIG. 5 has one side located on the light output side surface 40a of the base 40 on the main cut surface of the light guide plate 30, and the front end 52a on the outer contour 51 and each base. It is a pentagonal shape in which two sides are located between the end 52b or a shape formed by chamfering one or more corners of this pentagonal shape. Further, in the illustrated example, raising the front direction luminance effectively, and, for the purpose of imparting symmetry angular distribution of luminance in a plane along the second direction d _2, unit optical The cross-sectional shape of the main cutting surface of the element 50 is symmetric with respect to the front direction nd. That is, as well shown in FIG. 5, the light exit side surface 51 of each unit optical element 50 is configured by a pair of bent surfaces 35 and 36 that are configured symmetrically about the front direction. The pair of bent surfaces 35 and 36 are connected to each other to define a tip portion 52a. Each folding surface 35, 36 has a first surface 35a, 36a that defines a tip 52a, and a second surface 35b, 36b that connects to the first surface 35a, 36a from the base 40 side. . The pair of first inclined surfaces 35a and 36a have a symmetric configuration with respect to the front direction nd, and the pair of second inclined surfaces 35b and 36b also have a symmetric configuration with the front direction nd as the center.

As an overall configuration of the unit optical element 50, the width from the base cutting surface of the light guide plate 30 to the width W _{a in} the arrangement direction of the unit optical elements 50 on the main cutting surface of the light guide plate 30 from the base 40 of the unit optical element 50. the ratio of protrusion height _{H a} along the front direction _(H a / _{W a)} are preferably has a 0.3 to 0.45. According to such a unit optical element 50, an excellent light condensing function is exhibited with respect to light components along the arrangement direction (second direction) of the unit optical elements 50 due to refraction and reflection at the light exit side surface 51. And generation of side lobes can be effectively suppressed.

  In addition, the “pentagonal shape” in the present specification includes not only a pentagonal shape in a strict sense but also a substantially pentagonal shape including limitations in manufacturing technology, errors in molding, and the like. Similarly, terms used in the present specification to specify other shapes and geometric conditions, for example, terms such as “parallel”, “orthogonal”, and “symmetric” are not limited to strict meanings. Interpretation will be made including such an error that a similar optical function can be expected.

Here, the dimension of the light guide plate 30 may be set as follows as an example. First, as a specific example of the unit optical element 50, the width W _a (see FIG. 5) can be set to 10 μm or more and 500 μm or less. On the other hand, the thickness of the base 40 can be 0.2 mm to 6 mm.

  The light guide plate 30 having the above-described configuration can be produced by molding the unit optical element 50 on a base material or by extrusion molding. Various materials can be used as the material forming the base portion 40 and the unit optical element 50 of the light guide plate 30. However, it is widely used as a material for an optical sheet incorporated in a display device, and has excellent mechanical properties, optical properties, stability, workability, etc., and can be obtained at low cost, such as acrylic resin, polystyrene, polycarbonate, etc. Transparent resins mainly composed of one or more of polyethylene terephthalate, polyacrylonitrile, etc., and epoxy acrylate and urethane acrylate-based reactive resins (ionizing radiation curable resins, etc.) can be suitably used. If necessary, a diffusive component having a function of diffusing light can be added into the light guide plate 30. As an example, the diffusion component uses particles made of a transparent material such as silica (silicon dioxide), alumina (aluminum oxide), acrylic resin, polycarbonate resin, silicone resin and the like having an average particle size of about 0.5 to 100 μm. Can do.

  When the light guide plate 30 is produced by curing the ionizing radiation curable resin on the base material, the sheet-shaped land portion that is positioned between the unit optical element 50 and the base material is provided together with the unit optical element 50. It may be formed on a substrate. In this case, the base 40 is composed of a base material and a land portion formed of an ionizing radiation curable resin. Moreover, the board | plate material which consists of a resin material extrusion-molded with the light-diffusion particle as a base material can be used. On the other hand, in the light guide plate 30 manufactured by extrusion molding, the base 40 and the plurality of unit optical elements 50 on the light output side surface 40a of the base 40 can be integrally formed.

  The quantum dot sheet 60 functions as a layer that converts the wavelength of transmitted light. That is, the quantum dot sheet 60 converts the wavelength of light from the light emitter 25 to a different wavelength even when the light source 24 has only the light emitter 25 that emits light in a single wavelength region. Therefore, the surface light source device 20 can emit light in a color different from the light emitted from the light emitter 25 of the light source 24.

  The quantum dot sheet 60 described here includes a binder resin 62 and quantum dots 61 dispersed in the binder resin 62. The quantum dot 61 is a semiconductor particle of a predetermined size having a quantum confinement effect. When the quantum dot 61 absorbs light from the excitation source and reaches an energy excitation state, the quantum dot 61 releases energy corresponding to the energy band gap of the quantum dot 61. Therefore, by adjusting the size of the quantum dots 61 or the composition of the substance, the energy band gap can be adjusted, and energy in various levels of wavelength bands can be obtained. In particular, the quantum dot 61 can generate strong fluorescence in a narrow wavelength band.

  Therefore, even when the light source 24 has only the light emitter 25 that emits light in a single wavelength region, the use of the quantum dots 61 allows various types including red, green, and blue due to the quantum size effect. Can be easily obtained. For example, when the size of the quantum dot is 5.5 to 6.5 nm (nanometer), a red color is emitted. When the size of the quantum dot is 4.0 to 5.0 nm, a green color is emitted. When the size of the quantum dot is 2.0 to 3.5 nm, a blue color is emitted, and yellow has an intermediate size between a quantum dot emitting red and a quantum dot emitting green.

  When the light projected from the light emitter 25 is blue light, the quantum dot sheet 60 can include red quantum dots and green quantum dots. The red quantum dots in the quantum dot sheet 60 convert a part of blue light into red light having a wavelength range of 620 to 750 nm, and the green quantum dots have a part of blue light having a wavelength range of 495 to 570 nm. Convert to green light. And the blue light which is not converted into red light and green light permeate | transmits the quantum dot sheet 60 as it is. According to this example, illumination with white light using the surface light source device 20 can be realized by mixing blue light, red light, and green light. In particular, the quantum dot 61 can generate strong fluorescence in a desired narrow wavelength region. For this reason, the surface light source device 20 can illuminate the liquid crystal display panel 15 with light of three primary colors having excellent color purity. In this case, the liquid crystal display panel 15 has excellent color reproducibility.

  The quantum dot 61 can be composed of a central body having a size of about 2 to 10 nm and a shell made of ZnS (zinc sulfide). Usually, since the polymer coating is applied to the outer surface of the shell, the quantum dots 61 are nanoparticles having a size of 10 to 15 nm. As the central body of the quantum dot 61, CdSe (cadmium selenide), CdTe (cadmium telluride), CdS (cadmium sulfide) can be used. On the other hand, the binder resin 62 may be composed of a silicon resin, an epoxy resin, and an acrylic resin, either singly or in combination.

  Next, the first prism sheet 71 and the second prism sheet 72 will be described. The first prism sheet 71 and the second prism sheet 72 have a function of adjusting the luminance distribution by changing the traveling direction of the transmitted light. The illustrated first prism sheet 71 and second prism sheet 72 change the traveling direction of the light incident from the light incident side and emit the light from the light output side so as to intensively improve the luminance in the front direction (condensing function). )have. The first prism sheet 71 and the second prism sheet 72 are different in arrangement and can have the same configuration. Therefore, the description common to the first prism sheet 71 and the second prism sheet 72 will be described using the reference numerals “71, 72” without distinguishing between “first” and “second”. Hereinafter, the configuration of each component will be described.

  The prism sheets 71 and 72 are a sheet-shaped main body 73 and a large number of unit prisms arranged in a direction (arrangement direction) parallel to the sheet surface of the main body 73 and arranged on the light output side surface 73 a of the main body 73. 75. As described above, the second prism sheet 72 is disposed on the most light output side of the surface light source device 20 and forms the light emitting surface 21.

  The main body 73 functions as a sheet-like member that supports the unit prism 75. As shown in FIG. 6, in the present embodiment, unit prisms 75 are arranged on the light output side surface 73 a of the main body portion 73 without leaving a gap. Therefore, the light exit side surface 70 a of the prism sheets 71 and 72 is formed by the prism surface 76 of the unit prism 75. On the other hand, as shown in FIG. 6, in the present embodiment, the main body 73 has a smooth surface that forms the light incident side surface 70b of the prism sheets 71 and 72 as the light incident side surface 73b that faces the light outgoing side surface 73a. Have.

Next, the unit prism 75 will be described. As described above, the unit prisms 75 are arranged side by side on the light exit side surface 73 a of the main body 73. As shown in FIG. 6, the unit prisms 75 is linear in a direction crossing the arrangement direction d _a of the unit prisms 75, especially linearly in this embodiment, extends. In the present embodiment, a large number of unit prisms 75 included in one prism sheet 71 and 72 extend in parallel to each other. Further, the longitudinal direction _{d b} of the unit prisms 75 of the prism sheet 71, 72 is perpendicular to the arrangement direction _{d a} of the unit prisms 75 in the prism sheet.

As can be understood from FIGS. 1 and 2, the arrangement direction of the first prism sheet 71 and the arrangement direction of the unit prisms 45 of the second prism sheet 72 intersect, and more specifically, are orthogonal to each other. When observing the prism sheet 71, 72 from the normal direction nd of the seat surface of the main body portion 73, the longitudinal direction _{d b} of the unit prisms 75 of the first prism sheet 71, are parallel to the second direction _{d 2,} longitudinal _{d b} of the unit prisms 75 of the second prism sheet 72 is parallel to the first direction _{d 1.}

Figure 7, in both parallel to the cross section of the arrangement direction d _b in the normal direction nd and the unit prisms 75 of the seat surface of the main body portion 73 (also referred to as a main cutting face of the prism sheet) shows a prism sheet 71, 72 Yes. In the present embodiment, the cross-sectional shape of each unit prism 75 at the main cutting surface is substantially constant along the longitudinal direction of the unit prism 75. That is, each unit prism 75 is generally constituted by a column.

  As shown in FIG. 7, the cross-sectional shape of the main cutting surface of each unit prism 75 in the present embodiment is a substantially triangular shape protruding to the light output side. In particular, from the viewpoint of intensively improving the luminance in the front direction, the cross-sectional shape of the unit prism 75 in the main cut surface is an isosceles triangle shape, and the apex angle located between the equilateral sides is the light exit side surface 73a of the main body 73. Each unit prism 75 is configured to project from the light to the light exit side. Typically, the cross-sectional shape of the unit prism 75 in the main cut surface is a right isosceles triangular shape in which a right angle apex protrudes from the main body 75 and is symmetrically arranged with respect to the front direction.

Moreover, the dimension of the prism sheets 71 and 72 can be set as follows as an example. First, as a specific example of the unit prism 75 configured as described above, the arrangement pitch of the unit prisms 75 (corresponding to the width W _b of the unit prism 75 in the illustrated example) can be set to 10 μm or more and 200 μm or less. . However, in recent years, the arrangement of the unit prisms 70 has been rapidly refined, and the arrangement pitch of the unit prisms 75 is preferably 10 μm or more and 50 μm or less. Further, the protruding height _Hb of the unit prism 75 from the main body portion 73 along the normal direction nd to the sheet surfaces of the prism sheets 71 and 72 can be set to 5 μm or more and 100 μm or less. Furthermore, the apex angle theta _b of the unit prisms 75 may be 60 ° or more less than 120 °.

  The prism sheets 71 and 72 having the above-described configuration can be manufactured by molding the unit prism 75 on a base material or by extrusion molding. Various materials can be used as the material forming the main body 73 and the unit prism 75 of the unit prism 75. However, it is widely used as a material for an optical sheet incorporated in a display device, and has excellent mechanical properties, optical properties, stability, workability, etc., and can be obtained at low cost, such as acrylic resin, polystyrene, polycarbonate, etc. Transparent resins mainly composed of one or more of polyethylene terephthalate, polyacrylonitrile, etc., and epoxy acrylate and urethane acrylate-based reactive resins (ionizing radiation curable resins, etc.) can be suitably used.

  When the prism sheets 71 and 72 are produced by curing the ionizing radiation curable resin on the base material, the sheet-like land portion that is positioned between the unit prism 75 and the base material is formed together with the unit prism 75. It may be formed on a substrate. In this case, the main body portion 73 is composed of a base material and a land portion formed of an ionizing radiation curable resin. On the other hand, in the prism sheets 71 and 72 manufactured by extrusion molding, the main body portion 73 and the plurality of unit prisms 75 on the light output side surface 73a of the main body portion 73 can be integrally formed.

  Next, the operation of the display device 10 and the surface light source device 20 configured as described above will be described.

First, as shown in FIGS. 1 and 2, the light emitter 25 that forms the light source 24 emits light. In the present embodiment, corresponding to the provision of the quantum dot sheet 60, the light emitter 25 emits only light in the blue wavelength region. The light emitted from the light emitter 25 enters the light guide plate 30 through the light incident surface 33. As shown in FIG. 2, the light L21 and L22 incident on the light guide plate 30 is reflected on the light output surface 31 and the back surface 32 of the light guide plate 30, particularly due to a difference in refractive index between the material forming the light guide plate 30 and air. The total reflection is repeated, and the light advances to the first direction (light guide direction) d ₁ connecting the light incident surface 33 and the opposite surface 34 of the light guide plate 30.

  The back surface 32 of the light guide plate 30 has an inclined surface 37 that is inclined so as to approach the light exit surface 31 from the light incident surface 33 toward the opposite surface 34. The inclined surface 37 is connected via a step surface 38 and a connection surface 39. Among these, the step surface 38 extends in the normal direction nd of the plate surface of the light guide plate 30. Therefore, most of the light traveling in the light guide plate 30 from the light incident surface 33 side to the opposite surface 34 side does not enter the step surface 38 of the back surface 32, and is incident on the inclined surface 37 or the connection surface 39. Reflected. Then, when reflected by the inclined surface 37 of the back surface 32, the traveling direction of the light in the cross section shown in FIG. 2 increases the inclination angle with respect to the plate surface of the light guide plate 30. That is, when the light is reflected by the inclined surface 37 of the back surface 32, the incident angle of the light on the light output surface 31 and the back surface 32 in the following becomes small. Therefore, the incident angle of the light traveling in the light guide plate 30 to the light exit surface 31 and the back surface 32 is gradually reduced by one or more reflections on the inclined surface 37 of the back surface 32 and is less than the total reflection critical angle. It becomes. In this case, the light can be emitted from the light exit surface 31 and the back surface 32 of the light guide plate 30. Lights L21 and L22 emitted from the light exit surface 31 travel toward the quantum dot sheet 60 disposed on the light exit side of the light guide plate 30. On the other hand, the light emitted from the back surface 32 is reflected by the reflection sheet 28 disposed on the back surface of the light guide plate 30, enters the light guide plate 30 again, and travels through the light guide plate 30.

  In particular, in the illustrated example, the proportion of the inclined surface 37 in the back surface 32 increases as the distance from the incident surface 33 approaches the opposite surface 34 along the light guide direction. This ensures a sufficient amount of light emitted from the light exit surface 31 of the light guide plate 30 in a region separated from the light incident surface 33 where the amount of emitted light tends to decrease, and the amount of emitted light uniform along the light guide direction. Can be achieved.

  By the way, the light exit surface 31 of the illustrated light guide plate 30 is constituted by a plurality of unit optical elements 50, and the cross-sectional shape of the main cut surface of each unit optical element 50 is a pentagonal shape arranged symmetrically about the front direction or The shape is formed by chamfering one or more corners of the pentagonal shape. More specifically, as described above, the light exit surface 31 of the light guide plate 30 is configured as a bent surface inclined with respect to the back surface 32 of the light guide plate 30 (see FIG. 5). The bent surfaces are inclined surfaces 35 and 36 which are inclined to the opposite sides with respect to the normal direction nd to the light output side surface 40a of the base 40. The light that is totally reflected by the inclined surfaces 35 and 36 and travels through the light guide plate 30 and the light that passes through the inclined surfaces 35 and 36 and is emitted from the light guide plate 30 are transmitted from the inclined surfaces 35 and 36 to the following. It comes to have an effect to explain. First, the effect exerted on the light traveling through the light guide plate 30 after being totally reflected by the inclined surfaces 35 and 36 will be described.

In FIG. 5, the optical paths of the lights L51 and L52 traveling through the light guide plate 30 while repeating total reflection on the light exit surface 31 and the back surface 32 are shown in the main cut surface of the light guide plate. As described above, the inclined surfaces 35 and 36 forming the light exit surface 31 of the light guide plate 30 include two types of surfaces inclined opposite to each other across the normal direction nd to the light exit side surface 40a of the base 40. . Further, the two types of inclined surfaces 35 and 36 inclined in opposite sides to each other, along the second direction d _2, are arranged alternately. As shown in FIG. 5, the light L51 and L52 that travel in the light guide plate 30 toward the light exit surface 31 and enter the light exit surface 31 are often guided out of the two kinds of inclined surfaces 35 and 36. In the main cutting plane of the optical plate, the light enters the inclined surface inclined to the opposite side to the traveling direction of the light with reference to the normal direction nd to the light exit side surface 40a of the base 40.

As a result, as shown in FIG. 5, the light L51, L52 traveling in the light guide plate 30 are often totally reflected by the inclined surfaces 35 and 36 of the light exit surface 31, reduces the component along the second direction _{d 2} Further, the traveling direction of the main cut surface is directed to the opposite side with respect to the front direction nd. In this way, the inclined surfaces 35, 36 forming the exit surface 31 of the light guide plate 30, light emitted radially emitting point there is, it is restricted to continue spreading it in the second direction d _2. That is, light emitted from the light emitter 25 of the light source 24 in a direction greatly inclined with respect to the first direction d ₁ and entering the light guide plate 30 is also mainly controlled in the first direction while being restricted from moving in the second direction d ₂ . so advance in the direction _{d 1.} Thus, the light intensity distribution along the second direction d ₂ of the light emitted from the light exit surface 31 of the light guide plate 30, the configuration of a light source 24 (e.g., the sequence of emitters 25) and, by the output of the light emitter 25, adjusted It becomes possible to do.

Next, the effect exerted on the light that passes through the light exit surface 31 and exits from the light guide plate 30 will be described. As shown in FIG. 5, the lights L51 and L52 emitted from the light guide plate 30 through the light output surface 31 are refracted on the light output side surface of the unit optical element 50 that forms the light output surface 31 of the light guide plate 30. Due to this refraction, the traveling direction (outgoing direction) of the lights L51 and L52 traveling in the direction inclined from the front direction nd on the main cut surface is mainly compared with the traveling direction of the light passing through the light guide plate 30. Thus, it is bent so that the angle formed with respect to the front direction nd is small. Such action unit optical element 50, the component of light along the second direction d ₂ perpendicular to the light guiding direction, the traveling direction of the transmitted light can be narrowed down in the front direction nd side. In other words, the unit optical element 50, the component of light along the second direction d ₂ perpendicular to the light guiding direction, so exert a light condensing effect. In this way, the emission angle of the light emitted from the light guide plate 30 is narrowed down to a narrow angle range centering on the front direction in a plane parallel to the arrangement direction of the unit optical elements 50 of the light guide plate 30.

As described above, the emission angle of the light emitted from the light guide plate 30 is narrowed down to a narrow angle range centering on the front direction on a plane parallel to the arrangement direction of the unit optical elements 50 of the light guide plate 30. On the other hand, the emission angle of the light emitted from the light guide plate 30 has so far progressed mainly in the first direction d ₁ in the light guide plate 30 until the first direction as shown in FIG. in (light guiding direction) d ₁ parallel to the plane, a relatively large emission angle theta _k was relatively large inclination from the front direction nd. That is, the outgoing angle of the first direction component d ₁ of the light emitted from the light guide plate 30 (the angle θ _k formed by the first direction component of the outgoing light and the normal direction nd to the plate surface of the light guide plate 30 (see FIG. 2). )) Tends to be biased within a narrow angle range with a relatively large angle.

FIG. 8 shows an example of the angular distribution of luminance measured on the light exit surface 31 of the light guide plate 30. The luminance distribution shown in FIG. 8 is a result of actually examining the luminance from each direction in a plane parallel to both the normal direction nd and the first direction d ₁ of the light guide plate 30. In the graph shown in FIG. 8, and an angle value which is inclined to the other side along the first direction d ₁ from the front direction is positive. The luminance angle distribution indicated by the solid line as the sample 1 in FIG. 8 is a measurement result of the light guide plate having the same configuration as that of the present embodiment described above. On the other hand, the luminance angle distribution indicated by a dotted line as the sample 2 is a result of a light guide plate in which a large number of diffusion recesses are formed on one surface of a transparent resin plate having a pair of parallel main surfaces.

  The light emitted from the light guide plate 30 then enters the quantum dot sheet 60. The quantum dot sheet 60 includes quantum dots 61 that can function as a fluorescent material. Therefore, the quantum dot sheet 60 functions as a color conversion layer that converts the wavelength of light from the light source 24. Specifically, the light source 24 has only the light emitter 25 that emits light in the blue wavelength region. Corresponding to such a light source 24, the quantum dot sheet 60 includes a red quantum dot that converts part of blue light into red light having a wavelength range of 620 to 750 nm, and a part of blue light of 495 to 570 nm. And green quantum dots that convert to green light having a wavelength range. Therefore, part of the blue light transmitted through the quantum dot sheet 60 is converted to green light, and the other part of the blue light is converted to red light, while the quantum dots 61 convert red light and green light. Blue light that is not converted passes through the quantum dot sheet 60 as it is.

  The quantum dot sheet 60 has a light diffusing function, for example, by mixing light diffusing particles. Incidence probability of the light transmitted through the quantum dot sheet 60 to the quantum dots 61 is significantly increased by being diffused inside the quantum dot sheet 60.

  As described above, the blue, green, and red light transmitted through the quantum dot sheet 60 travels to the prism sheets 71 and 72 arranged on the light output side of the quantum dot sheet 60. As shown in FIG. 7, the light beams L <b> 71 and L <b> 72 that pass through the prism sheets 71 and 72 are refracted on the prism surface 76 of the unit prism (unit shape element) 75. Due to this refraction, the traveling direction (outgoing direction) of the lights L71 and L72 traveling in the direction inclined from the front direction nd is mainly compared to the traveling direction of the light when entering the prism sheets 71 and 72. 71 and 72 are bent toward the side where the angle with respect to the normal direction nd to the sheet surface becomes smaller. By such an action, the unit prism 75 can narrow the traveling direction of the transmitted light to the front direction nd side. That is, the unit prism 75 has a condensing effect on the transmitted light. This condensing function can effectively improve the luminance in the front direction.

Incidentally, the condensing function of the unit prisms 75 is exerted primarily in d _a (left-right direction in terms of the FIG. 7) the arrangement direction of the unit prisms 75. The arrangement direction of the unit prisms 75 of the first prism sheet 71 is non-parallel to the arrangement direction of the unit prisms 75 of the second prism sheet 72, and in particular, is orthogonal to the arrangement direction of the unit prisms 75 of the second prism sheet 72. is there. Therefore, the emission direction of the light transmitted through the two prism sheets 71 and 72 is narrowed down within a narrow angle range centering on the front direction in two different directions.

  On the other hand, the light L73 having a small inclination angle in the traveling direction with respect to the front direction nd repeats total reflection on the prism surface 76 of the unit prism 75, and changes the traveling direction to the light incident side (light source side). In particular, when the apex angle (in the main cutting plane) of the unit prism 75 is 90 ° or in the vicinity thereof, retroreflection is performed as illustrated. The light L73 that has turned the optical path travels again toward the light exit side due to reflection by one or more of the quantum dot sheet 60, the light guide plate 30, and the reflection sheet 28. That is, such light L73 can be reused.

  The light L73 whose optical path is inverted by the prism sheets 71 and 72 is incident on the quantum dot sheet 60 again and is subjected to wavelength conversion action by the quantum dots 61. That is, by arranging the prism sheets 71 and 72 on the light output side of the quantum dot sheet 60, the quantum dots 61 included in the quantum dot sheet 60 can be effectively used, and the color conversion efficiency can be greatly improved. As a result, it is possible to reduce the filling amount of the quantum dots 61 and reduce the thickness of the quantum dot sheet 60.

  As described above, the light emitted from the light guide plate 30 travels in a direction greatly inclined from the front direction nd. However, since the quantum dot sheet 60 has a light diffusing function, there is a certain amount of light L73 that can be totally reflected by the unit prism 75, in other words, light L73 that travels in a direction that is not significantly inclined with respect to the front direction. The amount of light is secured stably. For this reason, the color conversion function of the quantum dot sheet 60 is more efficiently exhibited by the optical path folding at the prism sheets 71 and 72.

  The light emitted from the second prism sheet 72 forming the light emitting surface 21 of the surface light source device 20 is then incident on the liquid crystal display panel 15 and is transmitted through the lower polarizing plate 14. The light transmitted through the lower polarizing plate 14 selectively passes through the upper polarizing plate 13 according to the state of electric field application to each pixel. In this manner, the liquid crystal display panel 15 selectively transmits light from the surface light source device 20 for each pixel, so that an observer of the liquid crystal display device 10 can observe an image.

  In the surface light source device 20 as described above, the quantum dot sheet 60 including the quantum dots 61 is provided. The quantum dots 61 can generate strong fluorescence in a desired narrow wavelength region. For this reason, the surface light source device 20 can illuminate the liquid crystal display panel 15 with light of three primary colors having excellent color purity. As a result, the liquid crystal display panel 15 can display an image with excellent color reproducibility.

By the way, the inventors of the present invention repeated earnest studies on the surface light source device including the quantum dot sheet, and the luminance angle distribution on the light exit surface of the light guide plate affects the light source light utilization efficiency in the surface light source device. Found to get. As a result of confirmation by the present inventors, when a large amount of light is emitted from the light exit surface 31 of the light guide plate 30 in a narrow angle range direction greatly inclined with respect to the normal direction nd of the light guide plate 30, a surface light source The utilization efficiency of the light source light in the apparatus 20 could be remarkably increased. In particular, to luminance on the light exit surface 31 of the light guide plate 30 due to the light from the light source 24 facing the light incident surface 33 located in the first direction d ₁ one side, the normal of the light guide plate 30 In the luminance angle distribution in each direction in a plane parallel to both the direction nd and the first direction d ₁ , the peak luminance lx [cd / m ² ], and the direction in which the peak luminance is obtained is the normal direction nd of the light guide plate 30. From the normal direction nd of the light guide plate 30 to the other side in the first direction d ₁ by an angle θx [°] inclined to the other side in the first direction d ₁ from the normal direction nd of the light guide plate 30 by an angle θy [°] half of the angle θx. When the luminance ly [cd / m ² ] is adjusted so as to satisfy both of the following conditions (a) and (b), the use efficiency of the light source light in the surface light source device 20 may be significantly increased. did it.
65 ° <θx <90 (a)
50 <lx / ly (b)

In addition, in this luminance angle distribution, the direction in which half the peak luminance located between the normal direction nd of the light guide plate 30 and the direction in which the peak luminance is obtained is obtained from the direction in which the peak luminance is obtained. When the angle θα inclined to one side along the one direction d ₁ satisfies the following condition (c), the light source light utilization efficiency in the surface light source device 20 can be significantly increased.
0 ° ≦ θα ≦ 15 ° (c)

  In addition to FIG. 8 mentioned above here, FIG. 9 and FIG. 10 show the surface light source device according to the sample 1 and the surface according to the sample 2 using the components of the commercially available surface light source device. It is a graph which shows the result of having produced the light source device and having evaluated the luminance characteristic of each produced surface light source device.

  Sample 2 was produced using components of a display device that is actually commercially available. The surface light source device of Sample 2 includes a light guide plate, a quantum dot sheet, a first prism sheet, a second prism sheet, an LED light source, and a reflective sheet including a silver deposited film, as in the above-described embodiment. It was. Both the first and second prism sheets are sheet-like members in which unit prisms having a cross-sectional shape of an isosceles right triangle are arranged on the light output side without any gap. The LED light source is a light emitting diode that emits blue light. This LED light source was disposed facing one side surface in the first direction d1 of the light guide plate 30, and no light source was disposed at a position facing the other side surface in the first direction d1 of the light guide plate 30. As the light guide plate, a light guide plate incorporated in a commercially available display device was used. This light guide plate has a pair of parallel main surfaces, and a large number of diffusion recesses are formed on one main surface. The arrangement density of the concave portions for diffusion increased as the distance from the light source increased.

  On the other hand, Sample 1 was configured in the same manner as Sample 2 except for the light guide plate. The light guide plate of Sample 1 has the same configuration as that of the above-described embodiment. That is, the back surface 32 of the light guide plate 30 is formed by the inclined surface 37, the step surface 38, and the connection surface 39. The light exit surface 31 of the light guide plate 30 is formed by the inclined surface 35 and the inclined surface 36 of the unit optical element 50.

In the luminance angle distribution on the light exit surface of the light guide plate of Sample 1, the peak luminance lx is 2030 [cd / m ² ], and the direction in which the peak luminance is obtained is the first direction d ₁ from the normal direction nd of the light guide plate 30. The angle θx inclined to the other side in FIG. 8 becomes 81.5 [°], and the luminance ly in the direction inclined to the other side in the first direction d ₁ from the normal direction nd of the light guide plate 30 by an angle θy that is half of the angle θx. Is 15.0 [cd / m ² ], and the angle θα at which the direction in which half the peak luminance is obtained is inclined to the one side along the first direction d ₁ from the direction in which the peak luminance is obtained is 13.5 [cd]. °]. Therefore, in the surface light source device of Sample 1, all of the above conditions (a), (b), and (c) were satisfied.

On the other hand, in the luminance angle distribution on the light exit surface of the light guide plate of Sample 2, the peak luminance lx is 391 [cd / m ² ], the angle θx is 80.5 [°], and the luminance ly is 69.8 [cd]. / M ² ], and the angle θα was 18.5 [°]. Therefore, in the surface light source device of Sample 2, all of the above conditions (a), (b), and (c) were not satisfied.

FIG. 9 shows the luminance angle distribution measured on the light exit surface of the quantum dot sheet for the surface light source devices of Sample 1 and Sample 2. “Sample 1 (first direction)” in FIG. 9 relates to the surface light source device of sample 1, and the luminance in each direction in the plane parallel to both the normal direction nd and the first direction d ₁ of the quantum dot sheet. 9 shows an angular distribution, and “Sample 1 (second direction)” in FIG. 9 relates to the surface light source device of Sample 1 and is in a plane parallel to both the normal direction nd and the second direction d ₂ of the quantum dot sheet. The angular distribution of brightness in each direction is shown. Similarly, “sample 2 (first direction)” in FIG. 9 relates to the surface light source device of sample 2 in each direction in the plane parallel to both the normal direction nd and the first direction d ₁ of the quantum dot sheet. of shows the angular distribution of luminance, "sample 2 (second direction)" in FIG. 9 relates to a surface light source device of sample 2, parallel to both the normal direction nd and the second direction d ₂ of the quantum dots sheet The angular distribution of luminance in each direction within a simple plane is shown. According to the results shown in FIG. 9, the brightness of the sample 1 on the quantum dot sheet is about 15 to 20% brighter in any direction than the brightness of the sample 2 on the quantum dot sheet. .

FIG. 10 shows the luminance angle distribution measured on the light emitting surface for the surface light source devices of Sample 1 and Sample 2. “Sample 1 (first direction)” in FIG. 10 relates to the surface light source device of sample 1, and the luminance angle in each direction within the plane parallel to both the normal direction nd and the first direction d ₁ of the light emitting surface. shows a distribution, "sample 1 (second direction)" in FIG. 10 relates to a surface light source device of the samples 1, each in a plane parallel to both the normal direction nd and the second direction d ₂ of the light emitting surface The angular distribution of luminance in the direction is shown. Similarly, “sample 2 (first direction)” in FIG. 10 relates to the surface light source device of sample 2 in each direction in a plane parallel to both the normal direction nd and the first direction d ₁ of the light emitting surface. FIG. 10 shows a luminance angle distribution, and “Sample 2 (second direction)” in FIG. 10 relates to the surface light source device of Sample 2 and is a surface parallel to both the normal direction nd and the second direction d ₂ of the light emitting surface. The angular distribution of the brightness | luminance in each direction is shown. In FIG. 10, the vertical axis represents the luminance ratio of each luminance angle distribution to the peak luminance so that the profiles of the luminance angle distributions can be compared. As the result of FIG. 10 shows, the luminance angle distribution has the same tendency between the surface light source device of sample 1 and the surface light source device of sample 2. In other words, the surface light source device of sample 1 and the surface light source device of sample 2 have the same light distribution characteristics.

On the other hand, when the luminance in the front direction, that is, the luminance in the normal direction to the light emitting surface was measured on the light emitting surface, the luminance in the front direction of sample 1 was 3290 [cd / m ² ], and the luminance in the front direction of sample 2 was Was 2890 [cd / m ² ]. That is, the front luminance of Sample 1 was 114% with respect to the front luminance of Sample 2. Further, when the x and y color coordinates of the xyY color system are measured on the light emitting surface, the color coordinates of sample 1 are (x: 0.2439, y: 0.2200), and the color coordinates of sample 2 are ( x: 0.2423, y: 0.2174).

  Based on the above results, the surface light source device of sample 1 was able to achieve much brighter illumination with the same light distribution characteristics and the same whiteness as compared with the surface light source device of sample 2. Such an operational effect is an effect that exceeds the range that can be predicted from the prior art where no mention is made of the relationship between the light distribution characteristics in the light guide plate and the color conversion efficiency in the quantum dot sheet, and It is also a noticeable or extraordinary effect.

  Although the details of the reason why such an effect is exhibited are unknown, it is presumed that there is the following reason. First, the outgoing light from the light exit surface 31 of the light guide plate 30 that satisfies the above-described conditions proceeds in a direction that is largely inclined with respect to the normal direction to the light exit surface 31. Therefore, the light can secure a relatively long optical path length in the quantum dot sheet 60. For this reason, in the quantum dot sheet 60, the color conversion function by the quantum dot 61 comes to be exhibited very efficiently. This is presumed to be one of the reasons that the light source light utilization efficiency of the surface light source device 20 incorporating the quantum dot sheet can be greatly improved, but the present invention is not limited to this estimation.

  In the present embodiment, since the optical path length in the quantum dot sheet 60 can be secured long, the thickness of the quantum dot sheet 60 can be reduced. This is advantageous in reducing the manufacturing cost of the surface light source device 20 and reducing the thickness and weight of the surface light source device 20.

As described above, according to this embodiment, the brightness of the on light exit surface 31 of the light guide plate 30 due to the light from the light source 24 disposed on one side in the first direction d ₁ of the light guide plate 30 In the luminance angle distribution in each direction in a plane parallel to both the normal direction nd and the first direction d ₁ of the light guide plate 30, the peak luminance lx [cd / m ² ] and the direction in which the peak luminance is obtained from the normal direction nd of the light guide plate 30 is inclined to the other side in the first direction d ₁ angle θx [°], the other at half the angle by a first direction from the normal direction nd of the light guide plate 30 d ₁ of the angle θx side The luminance ly [cd / m ² ] in the direction inclined in the direction satisfies both the following conditions (a) and (b).
65 ° <θx <90 ° (a)
50 <lx / ly (b)
According to such a surface light source device 20, it is possible to effectively improve the light source light utilization efficiency of the surface light source device 20 in which the quantum dot sheet 60 is incorporated.

  Note that various modifications can be made to the above-described embodiment. Hereinafter, an example of modification will be described with reference to the drawings. In the following description and the drawings used in the following description, the same reference numerals as those used for the corresponding parts in the above-described embodiment are used for parts that can be configured in the same manner as in the above-described embodiment, and overlapping Description to be omitted is omitted.

  First, in the above-described embodiment, an example of the light guide plate 30 has been described. However, the present invention is not limited to this example, and various modifications can be made. For example, the plurality of unit optical elements 50 included in the light guide plate 30 may have different configurations. In addition, the cross-sectional shape of the unit optical element 50 at the main cut surface is not limited to the specific example shown in FIG.

  As shown in FIG. 11, the first light source 24 a is provided at a position facing the light incident surface 33 of the light guide plate 30, and the second light source 24 b is provided at a position facing the opposite surface 34 of the light guide plate 30. You may do it. Both the first light source 24a and the second light source 24b have a light emitter 25 and can be configured in the same manner as the light source 24 of the above-described embodiment.

In such instances, relating to the luminance of the over light exit surface 31 of the light guide plate 30 due to the light from the first light source 24a disposed in the first direction d ₁ in one side of the light guide plate 30, the light guide plate 30 In the luminance angle distribution in each direction in a plane parallel to both the normal direction nd and the first direction d ₁ , the peak luminance lx1 [cd / m ² ] and the direction in which the peak luminance is obtained is the normal line of the light guide plate 30. from the direction nd angles θx1 inclined to the other side in the first direction d ₁ [°], the half angle θx1 angle only of the light guide plate 30 from the normal direction nd in a direction inclined to the other side in the first direction d ₁ When the luminance ly1 [cd / m ² ] satisfies both of the following conditions (a1) and (b1), the light source light utilization efficiency of the surface light source device 20 incorporating the quantum dot sheet 60 is effectively improved. be able to. In addition, in this luminance angle distribution, the direction in which half the peak luminance located between the normal direction nd of the light guide plate 30 and the direction in which the peak luminance is obtained is obtained from the direction in which the peak luminance is obtained. When the angle θα1 inclined to one side along the one direction d ₁ satisfies the following condition (c1), the use efficiency of the light source light in the surface light source device 20 can be significantly increased.
65 ° <θx1 <90 ° (a1)
50 <lx1 / ly1 (b1)
0 ° ≦ θα1 ≦ 15 ° (c1)

Similarly, in the first direction d ₁ of the light guide plate 30 relating to the luminance of the over light exit surface 31 of the light guide plate 30 due to the light from the second light source 24b disposed on the other side, the normal direction nd of the light guide plate 30 In the luminance angle distribution in each direction in a plane parallel to both the first direction d ₁ and the first direction d ₁ , the peak luminance lx2 [cd / m ² ], and the direction in which the peak luminance is obtained is from the normal direction nd of the light guide plate 30. 1 angle inclined to one side in the direction d ₁ Shitaekkusu2 [°], the brightness in the direction inclined to one side in the normal direction nd half of the angle only the light guide plate 30 of the angle Shitaekkusu2 in the first direction d ₁ ly2 [cd / M ² ] effectively improves the light source light utilization efficiency of the surface light source device 20 in which the quantum dot sheet 60 is incorporated even when both of the following conditions (a2) and (b2) are satisfied. it can. In addition, in this luminance angle distribution, the direction in which half the peak luminance located between the normal direction nd of the light guide plate 30 and the direction in which the peak luminance is obtained is obtained from the direction in which the peak luminance is obtained. When the angle θα2 inclined to the other side along the one direction d ₁ satisfies the following condition (c2), the light source light utilization efficiency in the surface light source device 20 can be significantly increased.
65 ° <θx2 <90 ° (a2)
50 <lx2 / ly2 (b2)
0 ° ≦ θα2 ≦ 15 ° (c2)

  In addition, it is preferable that the conditions (a2) and (b2) are satisfied together with the conditions (a1) and (b1), and it is more preferable that the conditions (a2) to (c2) are satisfied together with the conditions (a1) to (c1). .

  In addition, the brightness | luminance on the light emission surface 31 of the light-guide plate 30 resulting from the light from the 1st light source 24a can be measured in the state which turned on the 1st light source 24a and turned off the 2nd light source 24b. Similarly, the luminance on the light exit surface 31 of the light guide plate 30 due to the light from the second light source 24b can be measured with the second light source 24b turned on and the first light source 24a turned off. .

  Further, although not shown, the surface light source device 20 or the display device 10 has a known reflective polarizer (also referred to as a polarization separation film) at a position on the light incident side of the liquid crystal display panel 15. Also good. The reflective polarizer transmits only the specific polarization component of the light emitted from the second prism sheet 72 and reflects the polarization component orthogonal to the specific polarization component without absorbing it. The polarized light component reflected from the reflective polarizer is reflected by the reflective sheet 28 and the like to depolarize (including both the specific polarized light component and the polarized light component orthogonal to the specific polarized light component), and then reflected again. Is incident on the polarizer. Therefore, the polarization component that has been converted into the specific polarization component in the light incident again passes through the reflective polarizer, and the polarization component orthogonal to the specific polarization component is reflected again. Hereinafter, by repeating the above process, about 70 to 80% of the light emitted from the second prism sheet 72 is emitted as the light source light that has become the specific polarization component. Therefore, by making the polarization direction of the specific polarization component (transmission axis component) of the reflective polarizer coincide with the transmission axis direction of the lower polarizing plate 14 of the liquid crystal display panel 15, all the emitted light from the surface light source device 20 is emitted. The liquid crystal display panel 15 can be used for image formation. Therefore, even when the light energy input from the light source 24 is the same, it is possible to form an image with higher brightness than in the case where the reflective polarizer is not arranged, and the light source 24 (and more The energy use efficiency (of the power source) is also improved. In particular, the light reflected by the reflective polarizer can exhibit a color conversion function from the quantum dots 61 of the quantum dot sheet 60. That is, according to this modification, the color conversion efficiency of the quantum dot sheet 60 can be further increased. Therefore, further improvement in the utilization efficiency of the light source light can be expected.

  In addition, although the some modification with respect to embodiment mentioned above was demonstrated above, naturally, it is also possible to apply combining several modifications suitably.

DESCRIPTION OF SYMBOLS 10 Display apparatus 11 Display surface 12 Liquid crystal layer 13 Upper polarizing plate 14 Lower polarizing plate 15 Liquid crystal display panel 20 Surface light source device 21 Light emitting surface 24 Light source 24a First light source 24b Second light source 25 Light emitter 28 Reflective sheet 30 Light guide plate 31 Light exit surface 32 Back surface 33 Incident surface 34 Opposite surface 35 Inclined surface 35a First surface 35b Second surface 36 Inclined surface 36a First surface 36b Second surface 37 Inclined surface 38 Step surface 39 Connecting surface 40 Base 40a Emitting side surface 40b Back side surface 50 Unit Optical element 51 Outer contour 52a Front end portion 52b Base end portion 60 Quantum dot sheet 61 Quantum dot 62 Binder resin 70a Light exit side surface 70b Light incident side surface 71 First prism sheet 72 Second prism sheet 73 Main body portion 73a Light exit side surface 73b Light incident side surface 75 Unit prism 76 Prism surface

Claims (5)

A light guide plate having a light exit surface and a pair of side surfaces facing in the first direction;
A light source that projects light onto a side surface located on one side of the light guide plate in the first direction;
A quantum dot sheet that is disposed to face the light exit surface of the light guide plate and includes quantum dots, and
In the luminance angle distribution in each direction in a plane parallel to both the normal direction of the light guide plate and the first direction, regarding the luminance on the light exit surface of the light guide plate due to the light from the light source, The peak luminance lx [cd / m ² ], the angle θx [°] in which the direction in which the peak luminance is obtained is inclined from the normal direction of the light guide plate to the other side in the first direction, and only half the angle θx A surface light source device in which a luminance ly [cd / m ² ] in a direction inclined from the normal direction of the light guide plate to the other side in the first direction satisfies both of the following conditions (a) and (b).
65 ° <θx (a)
50 <lx / ly (b) A prism sheet disposed on the opposite side of the light guide plate of the quantum dot sheet, further comprising:
The prism sheet has a sheet-like main body, and a plurality of unit prisms provided on the opposite side of the main body from the quantum dot sheet,
The surface light source device according to claim 1, wherein the plurality of unit prisms are arranged in the first direction, and each unit prism extends linearly in a direction non-parallel to the first direction. A first prism sheet and a second prism sheet disposed on the opposite side of the quantum dot sheet from the light guide plate;
The first prism sheet and the second prism sheet each have a sheet-like main body portion and a plurality of unit prisms provided on the opposite side of the main body portion from the quantum dot sheet,
The plurality of unit prisms of the first prism sheet are arranged in the first direction, and each unit prism extends linearly in a direction non-parallel to the first direction,
The plurality of unit prisms of the second prism sheet are arranged in an arrangement direction non-parallel to the first direction, and each unit prism extends linearly in a direction non-parallel to the arrangement direction. 2. The surface light source device according to 1. In the luminance angle distribution, the direction in which half the peak luminance is located between the normal direction of the light guide plate and the direction in which the peak luminance is obtained is along the first direction from the direction in which the peak luminance is obtained. The surface light source device according to claim 1, wherein the angle θα inclined to one side satisfies the following condition (c).
0 ° ≦ θα ≦ 15 ° (c) A surface light source device according to any one of claims 1 to 4,
A display panel disposed to face the surface light source device.

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