JP6287550B2 - Display with solar panel - Google Patents

Description

  The present invention includes a light control sheet having a plurality of lens surfaces, a solar cell panel, and an illumination unit that emits light using power generated by the solar cell panel, and further displays a display target. It is invention regarding the display body with a solar cell panel provided with the some display surface.

  Patent Document 1 discloses a display body that displays a specific display object in a predetermined direction. In the display body disclosed in Patent Document 1, the display target can be observed from a predetermined direction by deflecting the light traveling direction from the display surface by the lens surface. However, if the light from the display surface toward the lens surface is not sufficiently secured, the display target cannot be sufficiently observed. Therefore, the display body may not be able to display the display target at night. Further, when the display body is disposed outdoors, there is a possibility that the display target cannot be sufficiently displayed according to the position of the sun, that is, according to the time zone or season.

  On the other hand, the display body disclosed in Patent Document 2 is provided with a light emitting means, and can perform sufficient display regardless of the incident state of external light. In particular, in the display body disclosed in Patent Document 2, the power of the light emitting means is secured using a solar cell panel. The use of a solar cell panel is very useful in that it is not necessary to install wiring for a display body fixed outdoors. However, the light receiving surface of the solar cell panel is black or dark and has poor design, and it is difficult to achieve harmony with the surrounding environment. In particular, when the light receiving surface of the solar cell panel is visually recognized in the vicinity of the area where the display target is displayed, the design of the display body is significantly impaired.

JP 2000-131783 A JP 2000-54325 A

  The present invention has been made in consideration of the above points. Using a solar cell panel, ensuring sufficient visibility of the display object, and using a light control sheet, making the light receiving surface of the solar cell panel less visible from the direction in which the front-to-face object is viewed With the goal.

The display body with a solar cell panel according to the present invention is:
A light control sheet having a plurality of lens surfaces arranged along the sheet surface;
A solar cell panel having a light receiving surface arranged at a position facing the plurality of lens surfaces;
Illuminating means for emitting light using the power generated by the solar cell panel,
A plurality of display surfaces for displaying a display target are provided at positions facing the plurality of lens surfaces,
The display surface is illuminated by light from the illumination means,
The lens surface directs the traveling direction of light incident from a certain direction toward the light receiving surface of the solar cell panel, and the traveling direction of light emitted from the display surface via the lens surface. Point in a different direction from the direction.

  In the display body with a solar cell panel according to the present invention, the display surface may be inclined with respect to the sheet surface of the light control sheet.

  In the display body with a solar cell panel according to the present invention, the display surface faces the inside of the light control sheet, the back surface facing the lens surface of the light control sheet, or the lens surface of the light control sheet. You may provide in the notch formed in the back surface.

  In the display body with a solar cell panel according to the present invention, the display surface is disposed between the light receiving surface of the solar cell panel and the plurality of lens surfaces, and is inclined with respect to the light receiving surface of the solar cell panel. It may be.

In the display body with a solar cell panel according to the present invention,
Each lens surface extends linearly in a direction intersecting with the arrangement direction of the plurality of lens surfaces,
The illuminating unit may include a light emitter that is disposed to face a side end surface of the light control sheet positioned on one side or the other side in a direction parallel to a direction in which the lens surface extends linearly. .

  In the display body with a solar cell panel according to the present invention, at least a part of the illumination means may be disposed between the light control sheet and the solar cell panel so as to have translucency.

  In the display body with a solar cell panel according to the present invention, the illuminating means faces a translucent light guide plate disposed between the light control sheet and the solar cell panel, and a side end surface of the light guide plate. You may make it have the light-emitting body arrange | positioned.

In the display body with a solar cell panel according to the present invention,
In the display surface, an end portion located on one side in the arrangement direction of the lens surfaces is closer to the lens surface in a normal direction of the light control sheet than an end portion located on the other side in the arrangement direction. Inclined with respect to the sheet surface of the light control sheet,
The light emitter may be arranged to face a side end surface of the light guide plate located on the one side in a direction parallel to the arrangement direction of the lens surfaces.

  In the display body with a solar cell panel according to the present invention, the light guide plate may have a diffusion function of diffusing light.

  In the display body with a solar cell panel according to the present invention, the illumination means includes a translucent support disposed between the light control sheet and the solar cell panel, and a plurality of disposed on the support. You may make it have a light emission sheet | seat containing a light-emitting body and the wiring provided on the said support body and connected to the said light-emitting body.

In the display body with a solar cell panel according to the present invention,
A plurality of solar battery panels are provided at positions facing the plurality of lens surfaces,
The light receiving surface of the solar cell panel is alternately arranged with the display surface in the arrangement direction of the lens surface,
The plurality of solar cell panels and the plurality of display surfaces may be disposed between the plurality of lens surfaces of the light control sheet and the illumination unit.

  In the display body with a solar cell panel according to the present invention, the light receiving surface of the solar cell panel may be inclined with respect to the sheet surface of the light control sheet.

  In the display body with a solar cell panel according to the present invention, the light receiving surface of the solar cell panel may be inclined to a side opposite to the display surface with respect to a sheet surface of the light control sheet.

  In the display body with a solar cell panel according to the present invention, the illuminating means includes a light guide plate disposed to face the light control sheet, and a light emitter disposed to face a side end surface of the light guide plate. You may do it.

In the display body with a solar cell panel according to the present invention,
In the display surface, an end portion located on one side in the arrangement direction of the lens surfaces is closer to the lens surface in a normal direction of the light control sheet than an end portion located on the other side in the arrangement direction. Inclined with respect to the sheet surface of the light control sheet,
The light emitter may be arranged to face a side end surface of the light guide plate located on the one side in a direction parallel to the arrangement direction of the lens surfaces.

  In the display body with a solar cell panel according to the present invention, the illuminating means includes a support body disposed to face the light control sheet, a plurality of light emitters disposed on the support body, and the support body. You may make it have a light emission sheet | seat including the wiring provided and connected to the said light-emitting body.

  ADVANTAGE OF THE INVENTION According to this invention, a solar cell panel can be ensured enough visibility of a display object, and a solar cell panel can be ensured from the direction in which a surface pair object is visually recognized using a light control sheet. It is possible to make it difficult to visually recognize the light receiving surface.

FIG. 1 is a diagram for explaining a first embodiment of the present invention, and is a perspective view showing a display body with a solar cell panel. FIG. 2 is a cross-sectional view taken along the line II-II in FIG. FIG. 3 is a plan view of a display body with a solar cell panel. 4 is an enlarged cross-sectional view of the low refractive index portion of the display body with a solar cell panel shown in FIG. FIG. 5 is a diagram for explaining the lens function of the lens surface exerted on the light from the display surface in the same cross section as FIG. FIG. 6 is a diagram for explaining the lens function of the lens surface exerted on the light traveling to the light receiving surface of the solar cell panel in the same cross section as FIG. FIG. 7 is a diagram for explaining a method of manufacturing the light control sheet. FIG. 8 is a diagram for explaining a method of manufacturing the light control sheet. FIG. 9 is a view showing a modification of the light control sheet in a cross section corresponding to FIG. FIG. 10 is a view showing another modification of the light control sheet in the cross section corresponding to FIG. FIG. 11 is a diagram corresponding to FIG. 2 for explaining the second embodiment of the present invention. FIG. 12 is a plan view showing the illumination means of FIG. FIG. 13 is a diagram corresponding to FIG. 2 for explaining a third embodiment according to the present invention. FIG. 14 corresponds to FIG. 3 and is a plan view of a display body with a solar cell panel. 15 is a cross-sectional view taken along line XV-XV in FIG. FIG. 16 is a diagram corresponding to FIG. 2 for explaining the fourth embodiment of the present invention. FIG. 17 is a diagram corresponding to FIG. 6, and is a diagram for explaining the lens function of the lens surface exerted on the light traveling to the light receiving surface of the solar cell panel in the display body of FIG. 16. FIG. 18 is a diagram corresponding to FIG. 2 for explaining the fifth embodiment of the present invention. FIG. 19 is a longitudinal sectional view showing the light control sheet.

  Embodiments of the present invention will be described below 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.

  As used in this specification, the shape and geometric conditions and the degree thereof are specified, for example, terms such as “parallel”, “orthogonal”, “identical”, length and angle values, etc. Without being bound by meaning, it should be interpreted including the extent to which similar functions can be expected.

  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. As a specific example, the “light control sheet” includes members called “light control film”, “light control plate”, and the like.

  Furthermore, in this specification, the “sheet surface (film surface, plate surface, panel surface)” is the plane of the target sheet-like member when the target sheet-like member is viewed as a whole and globally. A surface that matches the direction. In the embodiment described below, a sheet surface of the light control sheet 20 described later and a sheet surface of a main body 40 described later of the light control sheet 20 are parallel to each other. In particular, in the first to third embodiments, the sheet surface of the light control sheet 20, the sheet surface of the main body 40 described later of the light control sheet 20, the panel surface of the solar cell panel 50, and the light reception of the solar cell panel 50. The surfaces 50a are parallel to each other. Furthermore, in this specification, the “normal direction” used for a sheet-like (film-like, plate-like, panel-like) member refers to a normal direction to the sheet surface of the member.

  The display body 10 with a solar cell panel according to the first to fifth embodiments is opposed to the light control sheets 20 and 21 having a plurality of lens surfaces 31 arranged along the sheet surface, and the plurality of lens surfaces 31. Solar cell panels 50 and 55 having light receiving surfaces 50a and 56 arranged at positions to be illuminated, and illumination means 60, 70, and 80 that emit light using the electric power generated by the solar cell panels 50 and 55. ing. A plurality of display surfaces 12 for displaying the display target 13 are provided at positions facing the plurality of lens surfaces 31. The display surface 12 is illuminated with light from the illumination means 60, 70, 80. Examples of the display object 13 include patterns (images) such as figures, patterns, designs, colors, pictures, photographs, and characters, and information such as letters, marks, and numbers. The display target 13 may be stationary or moving. In the following, the “display body with solar cell panel” is also referred to as “display body” for short.

  The lens surface 31 expresses a lens function with respect to light incident on the light control sheets 20 and 21 or light emitted from the light control sheets 20 and 21, and adjusts the traveling direction of the light. The lens surface 31 directs the traveling direction of light incident from a certain direction toward the light receiving surfaces 50a and 56 of the solar cell panels 50 and 55, and travels light emitted from the display surface 12 via the lens surface 31. The direction is directed to another direction different from the certain direction. In particular, in the display body 10 according to the first to fifth embodiments, the lens surface 31 receives light incident on the display body 10 from a direction within a certain angle range AR1, and the light receiving surfaces 50a, 50a, 55b of the solar cell panels 50, 55. 56, the emission direction of the light emitted from the light control sheets 20 and 21 from the display surface 12 through the lens surface 31 is deflected into an angular range AR2 different from the certain angular range AR1. That is, the lens surface 31 refracts light incident from the direction within the first angle range AR1 toward the light receiving surfaces 50a and 56 of the solar cell panels 50 and 55 and refracts light from the display surface 12. The light is emitted in a direction within the second angle range AR2.

  According to such a display body 10, it is possible to make it difficult to visually recognize the light receiving surface of the solar cell panel from the direction in which the front-facing target 13 is visually recognized using the light control sheet. More specifically, by adjusting the first angle range AR1 and the second angle range AR2, the light receiving surfaces 50a and 56 of the solar cell panels 50 and 55 are adjusted from the second angle range AR2 in which the surface pair target 13 is visually recognized. Can be made difficult to see. That is, the visibility of the display target 13 from the direction within the second angle range AR2 can be improved, and the deterioration of the design property due to the observation of the light receiving surfaces 50a and 56 and the inconsistency with the surrounding environment are eliminated. It becomes possible to do. In addition, since the display surface 12 is illuminated by the illumination means 60, 70, 80, the visibility of the display target 13 drawn on the display surface 12 and the concealability of the light receiving surfaces 50a, 56 are effectively improved. In addition, since the illumination by the illumination means 60, 70, 80 uses the electric power generated by the solar cell panel 50, it is not necessary to install wiring for the display body 10 fixed outdoors, for example. It is very useful in that it can.

  In particular, in the display body 10 described below, the first angle range AR1, which is a continuous angle range of the incident angle in which the traveling direction is directed to the light receiving surfaces 50a and 56, and the display target 13 are continuously observed. The second angle range AR2, which is an angle range that can be used, has been devised so that it can be independently adjusted with a high degree of freedom. As a result, it is possible to display the display target 13 with excellent visibility while sufficiently making the light receiving surfaces 50a and 56 invisible.

  Moreover, since the angle range in which the display target 13 is continuously displayed can be adjusted with a high degree of freedom, the display body 10 can be used for various purposes. For example, large panels of several to several tens of meters used for outdoor signboards, road information bulletin boards, building outer wall surfaces, and several tens of centimeters to several meters used for posters, signs, inner wall surfaces of buildings, etc. Examples include a medium-sized panel application of a size and a small panel application of several centimeters to several tens of centimeters used for a table stand, a portable terminal, and the like.

  In the first to third embodiments described below, the configurations of the illumination means 60, 70, and 80 are different from each other, but the light control sheet 20 and the solar cell panel 50 may be configured in common. Further, in the fourth and fifth embodiments, the configurations of the illumination means 60 and 70 are different from each other, but the light control sheet 21 and the solar cell panel 55 can be configured in common. Furthermore, the light control sheet 21 and the solar cell panel 55 of the fourth and fifth embodiments have different configurations from the light control sheet 20 and the solar cell panel 50 of the first to third embodiments. Yes. However, the illumination means 60 of the fourth embodiment can be the same as the illumination means 60 of the first embodiment, and the illumination means 70 of the fifth embodiment is the illumination of the second embodiment. It can be the same as the means 70. In the following description of the plurality of embodiments, the same reference numerals are given to the components corresponding to each other, and overlapping descriptions are omitted as much as possible.

<First Embodiment>
First, a first embodiment will be described mainly with reference to FIGS.

  As well shown in FIGS. 1 and 2, the display 10 includes a light control sheet 20, a solar cell panel 50 disposed on the back surface of the light control sheet 20, a light control sheet 21, and a solar cell panel 50. And at least a portion of the illumination means 60. The light control sheet 20 has a front surface 20a and a back surface 20b facing each other. The surface 20a forms an incident surface for external light such as sunlight that enters the display body 10. Further, the surface 20 a forms an emission surface from which light from the display surface 12 that visualizes the display target 13 is emitted from the display body 10. On the other hand, the back surface 20 b forms an emission surface from which light traveling toward the light receiving surface 50 a of the solar cell panel 50 is emitted from the light control sheet 20. The display surface 12 for displaying the display target 13 is, for example, the inside of the light control sheet 20, the back surface 20 b facing the lens surface 31 of the light control sheet 20, or the lens surface 31 side of the light control sheet 20. It can be provided in a notch 41 formed on the opposite side. In the illustrated example, the display surface 12 is formed in a notch 41 formed on the side opposite to the lens surface 31 side of the light control sheet 20, and the low refractive index portion 45 is filled in the notch 41. As a result, the display surface 12 is disposed inside the light control sheet 20.

  Hereinafter, the solar cell panel 50, the light control sheet 20, and the illumination means 60 will be described in this order.

  The solar cell panel 50 is a power generator that converts light received by the light receiving surface 50a into electric energy. Various types of solar cell panels 50 can be used. For example, a silicon-based solar cell panel, a thin-film solar cell panel, a chalcopyrite solar cell, or the like including a flat silicon substrate made of single crystal silicon or polycrystalline silicon can be used as the solar cell panel 50. Hereinafter, the solar cell panel 50, the light control sheet 20, and the illumination means 60 will be described in this order.

  In addition, the light which goes to the solar cell panel 50 from the light control sheet 20 permeate | transmits the illumination means 60 located between the light control sheet 20 and the solar cell panel 50. FIG. For this reason, the illumination means 60 has translucency in at least a part located between the light control sheet 20 and the solar cell panel 50. Here, “translucency” means that the light transmittance in a band of 400 nm or more and 1000 nm or less is 50% or more. The light transmittance in the band of 400 nm or more and 1000 nm or less is measured using a spectrophotometer (manufactured by Shimadzu Corporation “UV-3100PC”, JISK0115 compliant product) within a measurement wavelength range of 400 nm to 1000 nm. , Specified as an average value of transmittance at each wavelength.

  Next, the illumination means 60 will be described. The illumination means 60 is a device that emits light using the electric power generated by the solar cell panel 50. As shown in FIG. 2, the light emitter 65 of the illumination unit 60 is connected to the solar cell panel 50 via the control circuit 19. The control circuit 19 supplies the electric power generated by the solar battery panel 50 to the illumination unit 60 and causes the illumination unit 60 to emit light. The control circuit 19 is connected to the storage battery 18 and accumulates excess power in the storage battery 18 while the sun is shining on the light receiving surface 50a. Further, the control circuit 19 may cause the illumination unit 60 to emit light with the electric power stored in the storage battery 18 even when the light receiving surface 50a is not exposed to the sun.

  As shown in FIGS. 1 to 3, in the first embodiment, the illuminating means 60 is a light transmissive member disposed between the light receiving surface 50 a of the solar cell panel 50 and the back surface 20 b of the light control sheet 20. It has a light guide plate 61 and a light emitting body 65 arranged to face the side end face 61 a of the light guide plate 61. In the illustrated first embodiment, as shown in FIG. 3, the light guide plate 61 and the solar cell panel 50 have a rectangular plan view shape together with the light control sheet 20 described later. Therefore, the light guide plate 61 includes a pair of front and back surfaces 61b and 61c that are rectangular in plan view, and four side end surfaces that connect the pair of front and back surfaces 61b and 61c. In the illustrated first embodiment, a light emitter 65 is disposed so as to face one side end surface 61 a of the light guide plate 61. 3, the side end surface 61a facing the light emitter 65 is one of the four side end surfaces of the light guide plate 61 in a first axial direction d1 parallel to the arrangement direction of lens surfaces 31 described later. It becomes a side end face located on the side.

  The light emitter 65 can be configured in various modes such as a fluorescent lamp such as a linear cold cathode tube, a spot LED (light emitting diode), an incandescent lamp, and the like. As shown in FIG. 3, in the illustrated first embodiment, a plurality of point light emitters arranged in the longitudinal direction of the side end surface 61 a facing one side end surface 61 a of the light guide plate 61, More specifically, the light emitter 65 is composed of a plurality of light emitting diodes. Note that the light-emitting diode is preferable in terms of low power consumption.

  The illumination unit 60 further includes a reflector 67 that is disposed so as to surround the light emitter 65. The reflection plate 67 guides the light emitted from the light emitter 65 to the side end surface 61 a of the light guide plate 61.

  The light guide plate 61 has a main part 63 and a diffusion component (light scattering component) 64 dispersed in the main part 63. The diffusing component 64 here is a component that can act on the light traveling in the light guide plate 61 by changing the traveling direction of the light by reflection or refraction. That is, the light guide plate 61 includes the main portion 63 and the diffusion component 64, thereby having a diffusion function of diffusing light. Such a light diffusing function (light scattering function) of the diffusing component 64 can be achieved, for example, by configuring the diffusing component 64 from a material having a refractive index different from that of the material forming the diffusing component 64, or for light. It can be applied by constructing the diffusing component 64 from a material that can exert a reflective action. Examples of the diffusion component 64 having a refractive index different from that of the material constituting the main portion 63 include a metal compound, an organic compound, a porous substance containing a gas, and a simple bubble.

  In the illustrated illumination unit 60, light is emitted from the light emitter 65 of the illumination unit 60 using the electric power generated by the solar cell panel 50. As shown in FIG. 2, the light emitted from the light emitter 65 enters the light guide plate 61 via the side end face 61a. The light L23a and L23b incident on the light guide plate 61 is reflected on the pair of main surfaces 61a and 61b of the light guide plate 61, and is repeatedly totally reflected due to the refractive index difference between the material forming the light guide plate 61 and air, It proceeds in the light guide plate 61. However, the diffusion component 64 is dispersed in the main portion 63 of the light guide plate 61. For this reason, as shown in FIG. 2, the light L <b> 23 a and L <b> 23 b traveling in the light guide plate 61 has its traveling direction irregularly changed by the diffusion component 64 and is emitted from the light guide plate 61.

  The collision between the light traveling in the light guide plate 61 and the diffusing component 64 dispersed in the light guide plate 61 is caused by each area along the light guide direction in the light guide plate 61 (the left-right direction in FIG. 1). Occurs. For this reason, the light traveling in the light guide plate 61 is emitted from the light guide plate 61 little by little. The light L23 emitted from the light guide plate 61 is separated from the light emitter 65 with respect to the normal direction in a plane along the light guide direction in the light guide plate 61 and the normal direction of the light guide plate 61. The tendency to incline toward the side to occur. In this way, the light control sheet 20 is illuminated from the back surface 20b side by the light emitted from the front surface 61b of the light guide plate 61 opposite to the solar cell panel 50. The light emitted from the back surface 61 c of the light guide plate 61 on the solar cell panel 50 side enters the light receiving surface 50 a of the solar cell panel 50 and is used for power generation in the solar cell panel 50.

  Next, the light control sheet 20 will be described.

  The light control sheet 20 includes a sheet-like main body portion 40 and a lens portion 25 supported on the main body portion 40. The lens unit 25 includes a large number of unit lenses 30 arranged in the first axial direction d1. Each unit lens 30 has a lens surface 31 formed on the surface facing the opposite side of the main body 40. A large number of unit lenses 30 are arranged such that the optical axes od of the lens surfaces 31 are parallel to each other. In particular, in the illustrated example, the unit lens 30 is arranged such that the optical axis od of the lens surface 31 is parallel to the normal direction nd of the main body 40. The first axial direction d1 is along the sheet surface of the light control sheet 20, and is orthogonal to the normal direction nd of the main body 40. In the illustrated example, the display body 10 is arranged such that the first axial direction d1 is parallel to the vertical direction.

  As shown in FIG. 1, the lens unit 25 constitutes a so-called lenticular lens or cylindrical lens. That is, the unit lenses 30 extend linearly in a direction intersecting the first axis direction d1 that is the arrangement direction. In particular, in the illustrated example, the unit lens 30 extends linearly in a second axial direction d2 that is orthogonal to both the first axial direction d1 and the normal direction nd. The plurality of unit lenses 30 included in the lens unit 25 are configured identically to each other.

  Each unit lens 30 protrudes from the sheet-like main body 40 so as to be convex toward the side opposite to the solar cell panel 50. In other words, each unit lens 30 protrudes from the sheet-like main body 40 in the normal direction nd of the main body 40. In the cross section of FIG. 2 parallel to both the first axial direction d1 and the normal direction nd (hereinafter also referred to as “main cut surface”), the lens surface 31 is symmetric about the optical axis od. . As shown in FIG. 2, the lens surface 31 of each unit lens 30 collects parallel light beams incident on the lens surface 31 in a condensing region. The lens surface 31 of the unit lens 30 shown in FIG. 2 shows an example in which the parallel light L21 incident along the optical axis od of the lens surface 31 is collected at the focal point fp. In this case, the focal point fp is the lens surface. 31 on the optical axis od.

  Incidentally, in the illustrated example, the unit lenses 30 are arranged in the first axial direction d1 with a gap therebetween. That is, a connection surface 38 is provided between the lens surfaces 31 of the two unit lenses 30 adjacent to each other in the first axial direction d1 to connect the base end portions 32b facing each other. In the illustrated example, the connection surface 38 extends along the seat surface of the main body 40. The surface 20 a of the light control sheet 20 is formed by the lens surface 31 and the connection surface 38 of the unit lens 30. For example, the light control sheet 20 including the unit lens 30 can be manufactured by resin molding using a mold. By providing the connection surface 38 and providing a gap between the adjacent unit lenses 30, light from an angle range greatly inclined with respect to the normal direction nd is incident before entering the lens surface 31 of the unit lens 30. The problem of so-called “vignetting” that is blocked by the lens surface 31 of the adjacent unit lens 30 can be effectively alleviated.

  In the present embodiment, each unit lens 30 is formed integrally with the main body 40. That is, no seam is formed on the boundary surface that can be virtually defined between each unit lens 30 and the main body 40.

  The main body 40 has a front side surface 40a and a back side surface 40b as a pair of main surfaces facing each other. The front side surface 40 a forms a surface adjacent to the lens portion 25, and the back side surface 40 b forms a surface facing the solar cell panel 50 side of the light control sheet 20. As shown in FIG. 2, a plurality of notches 41 formed so as to face the corresponding unit lenses 30 are provided on the back side surface 40 b of the main body 40. Each notch 41 is recessed in the normal direction nd of the main body 40 from the other part of the back side surface 40 b of the main body 40. The plurality of notches 41 are arranged in the first axial direction d <b> 1 corresponding to the unit lens 30, which is the arrangement direction of the unit lenses 30. In the present embodiment, each notch 41 is arranged so as to at least partially face the corresponding unit lens 30 along the normal direction nd. In other words, each notch 41 at least partially overlaps the corresponding unit lens 30 when viewed from the normal direction nd of the main body 40. In the present embodiment, each notch 41 is in the same direction as the unit lens 30 in a direction that intersects the first axis direction d1 that is the arrangement direction, more strictly, a second axis direction d2 that is orthogonal to the first axis direction d1. It extends in a straight line.

  As shown in FIG. 2, each notch 41 provided on the back surface 20 b has a first notch surface 42 and a second notch surface 43 extending toward the lens portion 25. In the illustrated example, the first notch surface 42 is located on one side of the second notch surface 43 in the first axial direction d1. The interval between the first notch surface 42 and the second notch surface 43 becomes narrower as the surface 20a of the light control sheet 20 is approached along the normal direction nd of the main body 40. The end portion on the surface 20a side of the first notch surface 42 that is closest to the end portion on the surface 20a side of the second notch surface 43 is connected to each other.

  In the present embodiment, the end on the surface 20a side of the notch 41 is on the connection region between the end on the surface 20a side of the first notch surface 42 and the end on the surface 20a side of the second notch surface 43. To position. The end of the notch 41 on the surface 20 a side is separated from the front side surface 40 a of the main body 40. In other words, the end portion on the surface 20a side of the notch 41 is located closer to the solar cell panel 50 than the base end portion 32b of the lens surface 31 corresponding to the notch 41 in the normal direction nd of the main body portion 40. Yes. According to such a form, since thickness can be ensured between the notch 41 and the front side surface 40a of the main-body part 40, the mechanical strength with respect to a bending or an impact can be ensured.

  In the present embodiment, a low refractive index portion 45 is formed in the notch 41, and along the second notch surface 43 of the notch 41 at a position between the main body portion 40 and the low refractive index portion 45. A display surface 12 is formed.

  As can be understood from FIG. 3, in the illustrated embodiment, the light control sheet 20 has a rectangular shape that is the same as the light receiving surface 50 a of the solar cell panel 50 in plan view. Therefore, in the first embodiment, the light receiving surface 50a of the solar cell panel 50 extends in a planar shape so as to face each of the plurality of unit lenses 30 arranged in the first axial direction d1. In the illustrated example, the light receiving surface 50 a extends in parallel with the sheet surface of the main body 40, in other words, the sheet surface of the light control sheet 20. Accordingly, in the illustrated example, the light receiving surface 50a extends and extends in parallel with the first axis direction d1 that is the arrangement direction of the unit lenses 30, and also extends in parallel with the second axis direction d2 that is the longitudinal direction of the unit lenses 30. It has spread.

  The display surface 12 is disposed in a notch 41 formed in the main body 40. Accordingly, the display surface 12 is located between the unit lens 30 and the light receiving surface 50a in the normal direction nd of the main body 40. The display surface 12 is arranged in the first axial direction d1 corresponding to the unit lens 30 as the arrangement direction of the unit lenses 30. Each display surface 12 is positioned to face one unit lens 30 to which the display surface 12 corresponds. As shown in FIG. 2, each display surface 12 is arranged so as to face at least partially the corresponding unit lens 30 along the normal direction nd. In other words, each display surface 12 overlaps at least partially with the corresponding unit lens 30 when viewed from the normal direction nd of the main body 40. In the present embodiment, like the unit lens 30, the display surface 12 extends linearly in a direction that intersects the first axis direction d1 that is the arrangement direction. More precisely, like the unit lens 30, the display surface 12 extends linearly in a second axial direction d2 orthogonal to the first axial direction d1. In the illustrated example, a large number of display surfaces 12 provided corresponding to the unit lenses 30 are configured identically.

  Each display surface 12 is inclined with respect to the sheet surface of the light control sheet 20 and the light receiving surface 50 a of the solar cell panel 50, and is inclined with respect to a direction parallel to the optical axis od of the lens surface 31. That is, each display surface 12 is non-parallel to both the light receiving surface 50 a of the solar cell panel 50 and the optical axis od of the lens surface 31. According to such a display surface 12, as described later, the second angle range AR2 that is an angle range in which light from the display surface 12 is emitted, in other words, a display target formed on the display surface 12 It is possible to adjust the second angle range AR2 that is an angle range in which 13 is observed with a high degree of freedom. At the same time, it is possible to adjust the first angle range AR1, which is the angle range of the incident light that is guided to the light receiving surface 50a of the solar cell panel 50, with a high degree of freedom.

  As shown in FIG. 2, each display surface 12 has a first end portion 12a located on one side in the first axial direction d1 (in the illustrated example, the upper side in FIG. 2 and the upper side in the vertical direction). Units in the normal direction nd of the main body 40 relative to the second end 12b located on the other side in the first axial direction d1 (in the example shown, the lower side in FIG. 2 and the lower side in the vertical direction). It is inclined with respect to the sheet surface of the light control sheet 20 so as to be close to the lens surface 31 of the lens 30. Therefore, the first end 12 a of the display surface 12 is closer to the unit lens 30 in the normal direction nd of the main body 40 than the second end 12 b of the display surface 12. As understood from FIG. 2, light from a wide angle range inclined to the other side (lower side) with respect to the normal direction nd is likely to enter the display surface 12. In other words, the emission direction of the light refracted and emitted from the display surface 12 by the lens surface 31 can be set to a wide angle range inclined to the other side (downward) with respect to the normal direction nd.

  From the viewpoint of enhancing such a tendency, in the main cut surface of the light control sheet 20, the display surface 12 is stepwise from one side (upper side) to the other side (lower side) in the first axial direction d1. It is preferable to continuously move away from the unit lens 30 along the normal direction nd of the main body 40. In the illustrated example, the display surface 12 is formed as a flat surface. In the main cut surface of the light control sheet 20 shown in FIG. 2, the display surface 12 is continuously inclined at a constant inclination from one side to the other side in the first axial direction d1. It moves away from the unit lens 30 along the normal direction nd of 40. According to such a display surface 12, the display object 13 formed on the display surface 12 can be observed within a wide angle range inclined to the other side with respect to the normal direction nd.

  As shown in FIG. 2, each display surface 12 has a first end portion 12 a located on one side (upper side) in the first axial direction d <b> 1, and a tip end portion 32 a of the lens surface 31 corresponding to the display surface 12. Rather than the first axial direction d1. That is, each display surface 12 has a first end portion 12a located on one side (upper side) in the first axial direction d1 in the first axial direction d1 relative to the optical axis od of the lens surface 31 corresponding to the display surface 12. At one side. As described above, the lens surface 31 is symmetric about the optical axis od, and is refracted by the lens surface 31 and emitted in a direction inclined to the other side with respect to the normal direction nd. Most of the lens surface 31 passes through a region located on the other side of the lens surface 31 in the first axial direction d1 with respect to the optical axis od. Accordingly, the first end portion 12a of each display surface 12 is located on one side in the first axial direction d1 with respect to the optical axis od of the corresponding lens surface 31, so that the first end portion 12a is relatively distant from each position on the display surface 12. Light traveling in a direction within a wide angle range can reach the lens surface 31 and is refracted by the lens surface 31 to be emitted in a wide angle range direction. That is, the angle range of the light L23 emitted from the display surface 12 through the lens surface 31 in a direction inclined to the other side with respect to the normal direction nd can be widened.

  In the illustrated embodiment, in the main cut surface of the light control sheet 20 shown in FIG. 2, the second end portion 12 b that is the end portion on the other side (lower side) in the first axial direction d <b> 1 of the display surface 12. Is located at the same position as the distal end portion 32a of the lens surface 31 corresponding to the display surface 12 in the first axial direction d1. Further, in the main cut surface of the light control sheet 20 shown in FIG. 2, the first end portion 12a that is one end portion in the first axial direction d1 of the display surface 12 is a lens corresponding to the display surface 12. The base end portion 32b on one side of the surface 31 in the first axial direction d1 is located at the same position in the first axial direction d1. However, in the main cut surface of the light control sheet 20 shown in FIG. 2, the first end 12 a of the display surface 12 is a base on one side in the first axial direction d1 of the lens surface 31 corresponding to the display surface 12. It may be displaced from the end 32b in the first axial direction d1. In the illustrated example, in the main cut surface of the light control sheet 20 shown in FIG. 2, the first end portion 12 a of the display surface 12 is a base end portion on one side of the lens surface 31 in the first axial direction d <b> 1. The solar cell panel 50 is separated from 32b along the normal direction nd of the main body 40.

  In the unit lens 30 configured as a convex lens, the tip end portion 32 a of the lens surface 31 is a portion of the lens surface 31 that protrudes most from the main body portion 40 along the normal direction nd of the main body portion 40. is there. Further, the base end portion 32 b of the lens surface 31 is a portion of the lens surface 31 that is closest to the main body portion 40 along the normal direction nd of the main body portion 40 or a portion that is connected to the main body portion 40. It is.

  In addition, as shown in FIG. 2, the second end 12 b of the display surface 12 is located on the focal point fp of the lens surface 31. That is, in the illustrated embodiment, in the main cut surface of the light control sheet 20, the second end portion 12b of the display surface 12 has a parallel light beam L21 (see FIG. 2) that travels in the normal direction nd of the main body 40. It is located on the focal position fp of the lens surface 31 when entering the lens surface 31. In other words, the second end 12 b of the display surface 12 is located on the optical axis od of the lens surface 31. According to such a light control sheet 20, the second angle range AR2 that is an angle range in which the display surface 12 can be observed, and the back surface 20b of the light control sheet 20 are observed without observing the display surface 12. It is possible to separate the range of angles that come to be.

  Here, incident light from an angle range in which the back surface 20b of the light control sheet 20 can be observed without observing the display surface 12, for example, the light L22 in FIG. After passing through the light guide plate 61 of the illumination means 60, the light can enter the solar cell panel 50. Therefore, according to the light control sheet 20 in which the second end 12b of the display surface 12 is positioned on the focal point fp of the corresponding lens surface 31, the traveling direction is received with the normal direction nd of the main body 40 as a boundary. A first angle range AR1 that is a continuous angle range of incident angles that are directed toward the surfaces 50a and 56, a second angle range AR2 that is an angle range in which the display object 13 can be continuously observed, Can be separated.

  As described above, the lens surface 31 receives the light L22 that has entered from the direction inclined to one side in the first axial direction d1 with respect to the normal direction nd of the main body portion 40 through the illuminating means 60, and the solar cell. Guide to panel 50. On the other hand, the light L23 incident from the direction inclined to the other side in the first axial direction d1 with respect to the normal direction nd of the main body 40 is guided to the display surface 12. That is, the emission direction of the light emitted from the light control sheet 20 from the display surface 12 through the lens surface 31 is set to a direction inclined to the other side in the first axial direction d1 with respect to the normal direction nd of the main body 40. Can do. However, as shown in FIG. 2, the light L25 incident on the lens surface 31 from a direction greatly inclined to one side in the first axial direction d1 with respect to the normal direction nd of the main body 40 is the lens surface 31 and the other From the back surface 20b side of the light control sheet 20 toward the display surface 12 facing the lens surface 31 adjacent on the side. Even if the light L25 from such a direction is incident on the display surface 12 from the back surface 20b side, the light L25 may not be effectively used for displaying the display target 13, and further, a double image may be generated. There is also. Therefore, in the present embodiment, the low refractive index portion 45 is provided in the notch 41 in which the display surface 12 is arranged so that such light L25 is guided to the solar cell panel 50 without being incident on the display surface 12. It has been. The low refractive index portion 45 has a refractive index lower than that of the main body portion 40. According to such a low refractive index portion 45, the solar cell panel also emits light L25 incident on the lens surface 31 from a direction greatly inclined to one side in the first axial direction d1 with respect to the normal direction nd of the main body portion 40. In order to be able to guide to 50, the first angle range AR1 can be further widened.

  In FIG. 4, the low refractive index part 45 arrange | positioned in the notch 41 is expanded and shown. As shown in FIG. 4, the low-refractive-index part 45 of this Embodiment is arrange | positioned without the clearance gap in the notch 41 in which the display surface 12 is arrange | positioned. For this reason, the low refractive index portion 45 corresponds to the shape of the notch 41 formed in the main body portion 40. Therefore, the plurality of low refractive index portions 45 are arranged in the first axis direction d <b> 1 that is the arrangement direction of the unit lenses 30, similarly to the notch 41. In the present embodiment, each low refractive index portion 45 is disposed so as to at least partially face the corresponding unit lens 30 along the normal direction nd. Further, the low refractive index portion 45 corresponds to the shape of the notch 41, and intersects with the first axis direction d1 that is the arrangement direction of the unit lenses 30, more strictly, the first direction orthogonal to the first axis direction d1. It extends linearly in the biaxial direction d2.

  As shown in FIG. 4, the low refractive index portion 45 includes a light incident surface 46 disposed along the first notch surface 42 of the notch 41 and a connection surface disposed along the second notch surface 43 of the notch 41. 47 and a light exit surface 48 extending between the end of the light incident surface 46 on the back surface 20b side and the end of the connection surface 47 on the back surface 20b side. Among these, the light incident surface 46 is a surface on which the light L41 refracted by the lens surface 31 is incident, and the light exit surface 48 is a surface on which the light L41 from the light incident surface 46 is emitted. In the example shown in FIG. 4, the light exit surface 48 forms a part of the back surface 20 b of the light control sheet 20. The light incident surface 46 extends from an end portion of the light exit surface 48 located on one side in the first axial direction d1 toward the unit lens 30 side, that is, the surface 20a side of the light control sheet 20. The connection surface 47 extends toward the unit lens 30 side from the end portion located on the other side of the light exit surface 48 in the first axial direction d1. The connection surface 47 is provided along the display surface 12 and is adjacent to the display surface 12.

  As shown in FIG. 4, the distance between the light incident surface 46 and the connection surface 47 corresponds to the normal direction of the main body 40 corresponding to the shape of the first notch surface 42 and the second notch surface 43 of the notch 41. As the distance from the light exit surface 48 increases along nd, the distance decreases. The end portion on the surface 20a side of the light incident surface 46 having the narrowest width and the end portion on the surface 20a side of the connection surface 47 are connected to each other. In particular, in the example shown in FIG. 4, the light incident surface 46, the connection surface 47, and the light exit surface 48 are formed as flat surfaces, and the low refractive index portion 45 has a triangular shape on the main cut surface.

  However, the cross-sectional shapes of the low refractive index portion 45 and the cutout 41 on the main cut surface do not have to be triangular, and may have various shapes. For example, the cross-sectional shape of the low refractive index portion 45 and the notch 41 in the main cut surface is a shape formed by chamfering one or more corners of a triangle, for example, a corner where the light incident surface 46 and the connection surface 47 are connected. Good. Further, an upper surface extending between the end portion of the light incident surface 46 on the surface 20a side and the end portion of the connection surface 47 on the surface 20a side may be further provided. That is, the cross-sectional shapes of the low refractive index portion 45 and the cutout 41 on the main cut surface may be trapezoidal.

  Such a low refractive index portion 45 is not particularly limited as long as it has a lower refractive index than the material forming the other portions of the main body portion 40, and may be a fluid or a solid. Examples of the material forming the portion other than the low refractive index portion 45 of the main body portion 40 include urethane acrylate resins and epoxy acrylate resins having a refractive index adjusted to about 1.50 to 1.60. On the other hand, examples of the resin material forming the low refractive index portion 45 include acrylic, epoxy, and urethane ultraviolet curable resins whose refractive index is adjusted to about 1.45 to 1.51. When the low refractive index portion 45 is made of a resin material having a refractive index lower than that of the resin material forming the main body portion 40, the display surface 12 can be protected by covering the display surface 12 with the resin material. Thereby, the tolerance with respect to disturbances, such as a change of an environment and a vibration, can be provided to the display surface 12 arrange | positioned in the notch 41 formed in the main-body part 40. FIG. Alternatively, the low refractive index portion 45 may be made of gas. In this case, since a large refractive index difference can be generated at the interface between the light incident surface 46 of the low refractive index portion 45 and the main body portion 40, the light L25 (from the unit lens 30 toward the low refractive index portion 45 ( 2) can be greatly changed so that the angle formed with respect to the normal direction nd of the main body 40 becomes small.

  Further, as described above, each unit lens 30 is formed integrally with the main body 40. Therefore, the unit lens 30 is made of the same material as that of the main body 40, and the refractive index of the unit lens 30 is also equal to the refractive index of the main body 40. Therefore, the refractive index of the low refractive index portion 45 is lower than the refractive index of the unit lens 30.

  According to such a low refractive index portion 45, at the interface between the light incident surface 46 and the main body portion 40, from a direction greatly inclined to one side in the first axial direction d1 with respect to the normal direction nd of the main body portion 40. The light L25 incident on the unit lens 30 can be deflected so that the angle formed by the traveling direction of the light L25 with respect to the normal direction nd of the main body 40 is small. According to the low refractive index portion 45, the light L41 from the unit lens 30 can be deflected toward the back surface 20b of the light control sheet 20 instead of the back surface of the display surface 12, as shown in FIG. From the viewpoint of effectively expressing such an optical function, it is preferable that the light incident surface 46 of the low refractive index portion 45 satisfies a geometrical relationship as described below.

  First, as shown in FIG. 4, the light L <b> 41 intended to be deflected by the low refractive index portion 45 approaches the display surface 12 from the back surface 20 b side of the light control sheet 20. For this reason, the angle θ3 formed by the light L41 intended to be deflected by the low refractive index portion 45 with respect to the normal direction nd of the main body 40 is greater than the angle θ1 formed by the display surface 12 with respect to the normal direction nd. Also grows. As understood from the geometrical relationship shown in FIG. 4, in order to make the light L41 intended to be deflected by the low refractive index portion 45 enter the back surface 20b of the light control sheet 20 instead of the display surface 12. The light L41 needs to be incident from the direction opposite to the back surface 20b with respect to the normal direction ND1 of the light incident surface 46, that is, the direction inclined toward the front surface 20a.

  Therefore, the low refractive index portion 45 deflects the light L41 incident at an angle larger than the angle θ1 formed by the display surface 12 with respect to the normal direction nd toward the back surface 20b without entering the display surface 12. In the main cut surface, an angle θ2 formed between the display surface 12 and the light incident surface 46 of the low refractive index portion 45 is at least smaller than an angle formed between the plane P2 orthogonal to the display surface 12 and the display surface 12. It only has to be. That is, the angle θ2 formed between the display surface 12 and the light incident surface 46 of the low refractive index portion 45 may be at least an acute angle, that is, an angle of 0 ° or more and less than 90 °. Here, the plane P <b> 2 is a plane that extends toward the back surface 20 b from the end portion close to the front surface 20 a of the low refractive index portion 45 in the direction orthogonal to the display surface 12. By making the angle θ2 formed by the display surface 12 and the light incident surface 46 an acute angle, at least of the light L41 that the display surface 12 is directed at an angle larger than the angle θ1 formed with respect to the normal direction nd of the main body 40. A part can be bent so that the angle formed by the traveling direction with respect to the normal direction nd of the main body 40 is small. That is, it is possible to avoid the light L41 that has not been corrected in the traveling direction due to refraction at the lens surface 31 from entering from the back surface side of the display surface 12, and to guide the light to the back surface 20b. Thus, the light guided to the back surface 20b can pass through the illumination means 60 and enter the light receiving surface 50a of the solar cell panel 50.

  Further, on the main cut surface, a base end portion 32b located on one side in the first axial direction d1 of the lens surface 31 on which the target light is incident, and the surface of the low refractive index portion 45 where the target light is deflected A straight line connecting the end close to 20a is referred to as SL2. In other words, in the main cut surface, of the base end portion of the lens surface 31 on which the target light is incident, the base end portion 32b located on the side away from the low refractive index portion 45 where the target light is deflected. A straight line connecting the connection position between the light incident surface 46 and the connection surface 47 of the low refractive index portion 45 where the target light is deflected is defined as SL2. As understood from the geometric relationship shown in FIG. 4, the angle formed with respect to the normal direction nd of the main body 40 among the lights L41 and L42 intended to be deflected by the low refractive index portion 45 is the largest. The light becomes light L42 directed from the direction parallel to the straight line SL2 toward the low refractive index portion 45. Therefore, in order to make the light L42 traveling from the direction parallel to the straight line SL2 toward the low refractive index portion 45 incident on the light exit surface 48 of the back surface 20b without entering the display surface 12, as described above, The light L42 needs to be incident from a direction inclined to the opposite side of the back surface 20b with respect to the normal direction ND1 of the light incident surface 46.

  Therefore, in order to deflect the light L42 directed from the direction parallel to the straight line SL2 toward the low refractive index portion 45 toward the back surface 20b, the display surface 12 and the light incident surface 46 are formed on the main cut surface. The angle θ2 is preferably smaller than the angle θ4 formed by the plane P3 orthogonal to the straight line SL2 and the display surface 12. That is, in the main cut surface, the light incident surface 46 is preferably disposed between the plane P3 orthogonal to the straight line SL2 and the display surface 12. Here, the plane P3 is a plane extending toward the back surface 20b side from the end portion close to the surface 20a of the low refractive index portion 45 in the direction orthogonal to the straight line SL2. By making the angle θ2 formed between the display surface 12 and the light incident surface 46 of the low refractive index portion 45 smaller than the angle θ4 formed between the plane P3 orthogonal to the straight line SL2 and the display surface 12, the low refractive index portion 45 is formed. Can be bent so that the angle formed by the traveling direction with respect to the normal direction nd of the main body 40 is small.

  Further, from the viewpoint of improving the fabrication accuracy of the mold, the light incident surface 46 of the low refractive index portion 45 and the display surface 12 are surfaces that are orthogonal to the first axial direction d1 and parallel to the normal direction nd of the main body 40. It is good to incline mutually on the other side. In this case, the protrusion for forming the notch 41 can be accurately formed in the mold for shaping the light control sheet 20. Thereby, the notch 41 can be formed in the main body 40 with high accuracy, and as a result, the low refractive index portion 45 disposed in the notch 41 can be formed with high accuracy.

  Here, FIG. 3 shows an example of the display object 13 formed on the display surface 12. A plurality of display surfaces 12 are arranged in the first axial direction d1, and each display surface 12 extends linearly in a second axial direction d2 orthogonal to the first axial direction d1. Therefore, the display surface 12 located at each position in the first axial direction d1 is provided with the display target element 13a corresponding to the position of the display surface 12 in the first axial direction d1, thereby causing the display surface 12 in the second axial direction d2. The two-dimensional display target 13 can be displayed as a combination of the display target elements 13a formed on the elongated display surfaces 12. In the example shown in FIG. 3, the capital letter “N” of the alphabet is displayed as the display target 13. Thus, since the size of each display surface 12 and each unit lens 30 can be reduced by displaying the display target 13 as a combination of a plurality of display target elements 13a, a case where the second angle range AR2 is expanded or a display body Even when the size of 10 is increased, a better display object 13 can be observed.

  As will be described later, the display surface 12 is actively illuminated by the illumination means 60. As a result, the visibility of the display target 13 formed on the display surface 12 can be improved. Especially, the illumination means 60 is arrange | positioned facing the back surface 20b of the light control sheet 20, and illuminates the display surface 12 from the back surface 20b side. Therefore, it is preferable that the display surface 12 is manufactured so that the display target 13 is displayed by light transmitted through the display surface 12.

  The light control sheet 20 including the display surface 12 described above can be produced as follows as an example. First, as shown in FIG. 7, a molded product 49 is produced by molding a transparent resin. For the molding, hot-melt extrusion processing, injection molding, or the like can be employed. As shown in FIG. 7, in the obtained molded product 49, a notch 41 is formed in a portion that becomes the back side surface 40 b of the main body portion 40 of the light control sheet 20 described above. The molded product 49 is molded with a lens portion 25 including the unit lens 30. Thereafter, as shown in FIG. 8, the display surface 12 is formed in the notch 41 of the molded product 49. As an example, the display target 13 is formed in the notch 41 of the molded product 49 by inkjet printing. Next, a material having a lower refractive index than that of the molded product 49 is filled into the notch 41 to form the low refractive index portion 45. The light control sheet 20 is obtained through the above steps.

  Next, the operation of the display body 10 will be described mainly with reference to FIGS. 2, 5, and 6. For example, the first axial direction d1 is arranged such that the first axial direction d1 that is the arrangement direction of the unit lenses 30 is along the vertical direction. A first end 12a located on one side of the display surface 12 in the first axial direction d1 is located on the upper side in the vertical direction, and a second end located on the other side of the display surface 12 in the first axial direction d1. The display body 10 is arranged so that the portion 12b is positioned on the lower side in the vertical direction.

  A lens portion 25 forming the surface 20a of the light control sheet 20 is provided on the most observer side of the display body 10. The lens surface 31 formed by the unit lens 30 of the lens unit 25 exhibits a lens function with respect to light incident on the display body 10 or light emitted from the display body 10 and adjusts the traveling direction of the light. .

  As shown in FIG. 6, the lens surface 31 is formed inside the light control sheet 20 with light incident from a direction within a certain angular range AR1 directly or using the low refractive index portion 45. The light is directed toward the back surface 20b of the light control sheet 20 without being incident on the display surface 12. On the back surface 20b of the light control sheet 20, the light guide plate 61 of the illumination means 60 is disposed so as to be opposed. However, since the light guide plate 61 has translucency, the light L61 to L64 emitted from the light control sheet 20 through the back surface 20b is transmitted through the light guide plate 61 to receive the light receiving surface 50a of the solar cell panel 50. Is incident on. Therefore, it is preferable that light incident from a wide angle range is guided to the back surface 20b and used for power generation in the solar cell panel 50. In particular, sunlight changes its position according to the time zone and season. In the display body 10, it is preferable if the sunlight that changes the incident direction according to the time zone and the season can be guided to the light receiving surface 50 a of the solar cell panel 50 via the back surface 20 b of the light control sheet 20. . That is, when taking in sunlight that changes the incident direction with high efficiency, it is preferable that the first angle range AR1 described above is widened.

Table 1 below shows the South-South Altitude (°) by season in major cities in some countries of the world. It is preferable that the south and middle altitudes of the equinox in the major cities of the country where the use is assumed be included in the first angle range AR1. This is because there is a high possibility that it can be used effectively in that country. For example, when the country assumed to be used is Japan, the altitude from 54 ° to 56 ° may be included in the first angle range AR1. Furthermore, it is preferable that an altitude of 49 ° to 61 ° is included in the first angle range AR1, since there is a high possibility that it can be used effectively in many countries in the world. Further, it is more preferable that the first angular range AR1 includes a range from the southern middle altitude of the summer solstice to the southern middle altitude of the winter solstice in the main cities of the country where use is assumed. This is because there is a high possibility that it can be used effectively throughout the year in that country. For example, when the country assumed to be used is Japan, the altitude from 31 ° to 79 ° may be included in the first angle range AR1. Furthermore, it is preferable that an altitude of 25 ° to 84 ° is included in the first angle range AR1, since it is highly likely that the altitude can be effectively used in many countries in the world. In order to make it easy for the desired altitude to be included in the first angle range AR1, it is preferable that the angle range of the first angle range AR1 is continuous by about 45 ° or more. However, it is possible to make the desired altitude fall within the first angle range AR1 by arranging the display body 10 at an angle. On the other hand, the upper limit of the angle range of the first angle range AR1 may be set as appropriate in balance with the second angle range AR2, but by setting it to less than about 135 °, as described later, The feature of the display body 10 can be exhibited more.

  On the other hand, as shown in FIG. 5, the light traveling from the display surface 12 for displaying the display target 13 to the lens surface 31 is emitted in a direction within the second angle range AR2 due to refraction at the lens surface 31. become. Therefore, it is possible to observe the display target 13 formed on the display surface 12 from the second angle range AR2. In this application, the second angle range AR2 is a viewing angle at which the display target 13 can be observed. In general, it is preferable that the second angle range AR2 that is a viewing angle is widened. In order to further exhibit the features of the display body 10 of the present embodiment, it is preferable that the viewing angle of the second angle range AR2 is about 45 ° or more. Note that the upper limit of the viewing angle of the second angle range AR2 may be set as appropriate in balance with the first angle range AR1, but it is considered that there are many cases where it is less than about 135 °.

  Further, if the solar cell panel 50 is observed together with the display target 13 while observing the display target 13, the visibility and design of the display target 13 are significantly impaired. Therefore, the second angle range AR2 in which the display surface 12 to which the display target 13 is applied can be observed is separated from the first angle range AR1 in which the solar cell panel 50 may be observed, that is, overlaps. Preferably not.

  In this regard, in the display body 10 according to the present embodiment described above, the display surface 12 is inclined and spreads with respect to the direction orthogonal to the optical axis od of the lens surface 31. On the other hand, the back surface 20 b of the light control sheet 20 extends in a direction orthogonal to the optical axis od of the lens surface 31. In such a display body 10, as well shown in FIG. 5, the second angle range in the emission direction of the light L <b> 52, L <b> 53, and L <b> 54 emitted from the inclined display surface 12 via the lens surface 31. The angle range AR2 can be widened. That is, the display object 13 formed on the display surface 12 can be observed from the widened second angle range AR2.

  Here, FIG. 19 illustrates the light control sheet A in which the observed surface changes between the first display surface a and the second display surface b according to the observation direction. In the light control sheet A, for example, the first and second display surfaces a and b form a pattern forming surface on which different patterns are formed. The observer can observe different patterns applied to the first and second display surfaces a and b according to the observation direction in which the light control sheet A is observed. As shown in FIG. 19, in this light control sheet A, a plurality of unit lenses c that form lens surfaces are provided on the light incident side, and regions facing each unit lens c are the first display surface a and the second display. Divided into plane b. In the example shown in FIG. 19, the boundary between the first display surface a and the second display surface b is disposed at a position that becomes the focal point fp of the unit lens c with respect to the light La from the optical axis direction od. And in the observation from the direction inclined to the one side (upper side in FIG. 19) from the normal direction of the light control sheet A, the pattern displayed by the first display surface a is observed (see the light Lb in FIG. 19). In the observation from the direction inclined to the other side from the normal direction of the light control sheet a, the pattern displayed on the second display surface b is observed.

  Such a light control sheet A is generally produced using a transparent resin. And the refractive index of the cheap resin material generally used is about 1.40-1.60. Therefore, the light traveling direction cannot be greatly bent due to refraction at the lens surface of the unit lens c. For this reason, the light Lc traveling in a direction inclined by about 30 ° to the one side from the normal direction of the light control sheet A is refracted by the lens surface formed by the unit lens c, and then another light adjacent to the unit lens c. The light enters the second display surface b facing the unit lens c. Further, the light Ld traveling in the direction inclined more greatly to one side also proceeds in the direction inclined more greatly inside the light control sheet A, and the first display surface a facing another unit lens c, or further away It is incident on the display surface at the position.

  For this reason, the light control sheet A shown in FIG. 19 has not been able to secure a large angle range in which the first display surface a or the second display surface b can be observed continuously. . That is, with such a light control sheet A, for example, the first display surface a or the second display surface b cannot be observed with a wide viewing angle. Therefore, in the light control sheet A of FIG. 19, the visibility of the display target was extremely low.

  In this embodiment, the display surface 12 is inclined with respect to the light control sheet A of FIG. Thus, according to the present embodiment, the display surfaces a and b are arranged along a wide range of directions inclined with respect to the optical axis od than the light control sheet A of FIG. 19 in which the display surfaces a and b are arranged on the back surface 20b. Light L52, L53, and L54 can enter the lens surface 31 from 12. As a result, the range of the emission direction of the light emitted from the light control sheet 20 from the display surface 12 through the lens surface 31 can be expanded. That is, according to the present embodiment, compared with the light control sheet A in FIG. 19, the second angle range AR2, which is the angle range in the emission direction of the light emitted from the display surface 12 through the lens surface 31, is widened. Can be made.

  In addition, in the illustrated example, the back surface 20 b extends and spreads over the entire region facing each unit lens 30 along the normal direction nd of the main body 40. The light traveling along the direction inclined to the same side as the display surface 12 with respect to the sheet surface of the light control sheet 20 does not enter the display surface 12 and passes between the two adjacent display surfaces 12 to be wide. It becomes easy to reach the extending back surface 20b. Therefore, light incident on the light control sheet 20 from a wide angle range can enter the light receiving surface 50a of the solar cell panel 50 via the back surface 20b. That is, the first angle range AR1 that is the angle range of the light that can reach the light receiving surface 50a of the solar cell panel 50 to the light control sheet 20 can be widened.

  In addition, the second angle range AR2 that is an angle range in the emission direction of the light emitted from the display surface 12 through the lens surface 31, and the angle of the light that can reach the light receiving surface 50a of the solar cell panel 50 to the light control sheet 20. It is possible to shift the first angle range AR1 as the range. In particular, in the present embodiment, the first angle range AR1 and the second angle range AR2 can be divided with the normal direction of the light control sheet 20 interposed therebetween. For this reason, when observing the display surface 12, it can prevent that the light-receiving surface 50a of the solar cell panel 50 will be visually recognized.

  Even if the light L64 is incident on the lens surface 31 while proceeding to the other side in the first axial direction d1, if the angle formed with respect to the normal direction nd of the main body 40 is large, The display surface 12 facing the adjacent lens surface 31 may go from the back surface 20b side of the light control sheet 20 to the display surface 12. In the present embodiment, the low refractive index portion 45 is provided on the back side of the display surface 12 in order to guide such light L64 to the back surface 20b without entering the display surface 12. According to the low refractive index portion 45, as shown in FIG. 6, the traveling direction of the light L64 incident on the light incident surface 46 forming the interface between the low refractive index portion 45 and the other portion of the main body portion 40 is The body portion 40 can be bent so that the angle formed with respect to the normal direction nd of the main body portion 40 is small. Thereby, even if it is the light L64 which injected into the unit lens 30 from the direction largely inclined to the one side in the 1st axial direction d1 with respect to the normal direction nd of the main-body part 40, light is not incident on the display surface 12. The control sheet 20 can be transmitted. The light transmitted through the light control sheet 20 enters the light receiving surface 50a of the solar cell panel 50 and can be used for power generation in the solar cell panel 50.

  As described above, the light control sheet 20 of light that can reach the light receiving surface 50a of the solar cell panel 50 by tilting the display surface 12 in the region between the unit lens 30 and the light receiving surface 50a of the solar cell panel 50. It is possible to adjust the first angle range AR1 that is an angle range to the second angle range AR2 and the second angle range AR2 that is the angle range of the light emitted from the display surface 12 through the lens surface 31, and in particular, it is possible to widen the angle. Become.

  By the way, the display target 13 can be visually recognized when light that travels from the display surface 12 to the lens surface 31 and is emitted from the light control sheet 20 is secured. Therefore, especially when the display body 10 is installed outdoors, the visibility of the display object 13 changes according to the time zone and further according to the season due to the change of the position of the sun. become. In this regard, in the first embodiment, the display surface 12 is illuminated by the light from the illumination unit 60. Therefore, even if it is arranged outdoors or at night, the display surface 12 is illuminated by the illumination means 60, so that the display object 13 on the display surface 12 can be viewed well. Become. In addition, the illumination means 60 emits light using the electric power generated by the solar cell panel. Therefore, it is very useful for the display body 10 fixed outdoors, for example, in that it is not necessary to install a power supply or wiring.

  Further, according to the first embodiment, at least a part of the illumination unit 60 is disposed between the back surface 20 b of the light control sheet 20 and the light receiving surface 50 a of the solar cell panel 50. And a part of illumination means 60 arrange | positioned between the light control sheet | seat 20 and the solar cell panel 50 has translucency. That is, the illuminating means 60 covers the light receiving surface 50a while allowing the light receiving surface 50a of the solar cell panel 50 to receive light, and further emits light in a planar shape. Therefore, the illumination means 60 emits light and makes the light receiving surface 50a invisible without impairing the power generation function of the solar cell panel 50. In this way, by concealing the light receiving surface 50a of the solar cell panel 50, the solar cell panel 50 including the light receiving surface 50a made of black or dark color may destroy the design of the display body 10, or the display body 10 It is possible to avoid harming the harmony with the surrounding environment where the is disposed. That is, it is possible to improve the design of the display body 10 and achieve harmony with the surrounding environment.

  Furthermore, in the first embodiment, the light guide plate 61 having translucency is disposed between the light receiving surface 50 a of the solar cell panel 50 and the back surface 20 b of the light control sheet 20. Therefore, it becomes possible to make the entire light receiving surface 50a invisible. Thereby, the design of the display body 10 can be more effectively improved and better harmony with the surrounding environment can be achieved.

  Furthermore, in the first embodiment, as shown in FIG. 2, the display surface 12 has an end portion located on one side in the first axial direction d <b> 1 that is the arrangement direction of the lens surfaces 31, in the first axial direction. It is inclined with respect to the sheet surface of the light control sheet 20 so as to be closer to the lens surface 31 in the normal direction of the light control sheet 20 than the end located on the other side at d1. The light emitter 65 of the illumination unit 60 is disposed so as to face the side end surface 61a of the light guide plate 61 located on one side in the first axial direction d1 parallel to the arrangement direction of the lens surfaces 31. In FIG. 2, one side in the first axial direction d1 is the upper side of the paper surface, and the other side in the first axial direction d1 is the lower side of the paper surface. In such an illuminating means 60, the traveling direction of most of the light L23a and L23b emitted from the surface 61b of the light guide plate 61 on the main cut surface of the light control sheet is due to the light guide direction in the light guide plate 61. The direction is inclined to the other side with respect to the normal direction of the light guide plate 61.

  As can be understood from FIGS. 2 and 5, the light emitted from the surface 61 b of the light guide plate 61 along the direction inclined to the other side with respect to the normal direction of the light guide plate 61 on the main cut surface of the light control sheet. The first end 12a located on one side in the first axial direction d1 is closer to the lens surface 31 in the normal direction of the light control sheet 20 than the end located on the other side in the first axial direction d1. The light is incident on the display surface 12 inclined with respect to the sheet surface of the light control sheet 20 with high probability. Further, a lot of light from the illumination means 60 that has made the display surface 12 transparent enters the lens surface 31. That is, according to the combination of the display surface 12 and the illumination unit 60 in the first embodiment, the display surface 12 can be efficiently illuminated by the light from the illumination unit 60, and thereby the display target 13. Can be clearly displayed.

  Furthermore, in 1st Embodiment, the light-guide plate 61 arrange | positioned between the back surface 20b of the light control sheet 20 and the light-receiving surface 50a of the solar cell panel 50 has a spreading | diffusion function. Therefore, the light receiving surface 50a of the solar cell panel 50 can be more reliably invisible. Thereby, the design of the display body 10 can be more effectively improved, and harmony with the surrounding environment can be further improved.

  Moreover, the incident light to the light receiving surface 50a of the solar cell panel 50 is diffused by the light guide plate 61 having a diffusion function. Therefore, light enters the regions in the light receiving surface 50a with a substantially uniform light amount. In this case, the solar cell panel 50 can generate electric power with excellent power generation efficiency even if it is any type of solar cell panel that has been widely used.

  According to the solar cell panel-equipped display body 10 of the first embodiment as described above, the lens surface 31 is directed toward the light receiving surface 50a of the solar cell panel 50 by refraction of the traveling direction of light incident from a certain direction. In addition, the traveling direction of the light emitted from the display surface 12 via the lens surface 31 can be directed to another direction different from a certain direction by refraction. Therefore, when the display object 13 formed on the display surface 12 is observed, the light receiving surface 50a of the solar cell panel 50 can be prevented from being visually recognized. In many types of solar cell panels, the light receiving surface is black or dark. When the light receiving surface of such a solar cell panel is exposed, the design is inferior, and harmony with the surrounding environment of the area where the solar cell panel is installed is impaired. However, according to the display body 10 with a solar cell panel according to the first embodiment, such a problem can be avoided.

  Further, according to the first embodiment, the display surface 12 is illuminated by the light from the illumination unit 60. Therefore, even if the display body 10 with the solar battery panel is disposed outdoors, the display surface 12 is illuminated by the illumination means 60 even at night, so that the display target 13 on the display surface 12 is good. Can be visually recognized.

  In addition, the illumination means 60 emits light using the electric power generated by the solar cell panel. Therefore, for example, it is very useful in that it is not necessary to install a power source or wiring for the display body 10 fixed outdoors.

  Furthermore, the electric power generated by the solar cell panel 50 can be used for the light emission of the illumination means 60. Accordingly, it is possible to omit securing a separate power source and installing facilities, wiring, and the like for supplying power from the separate power source to the illumination means 60. Such a display body 10 has a very high degree of freedom in selecting an installation location and can be used for various purposes. For example, the display body 10 can be used as an outdoor signboard, a road information bulletin board, or an outer wall of a building. Further, in a situation where the sun does not shine on the light receiving surface 50a of the solar battery panel 50, it is possible to cause the illumination means 60 to emit light and display the display target 13 using the power stored in the storage battery 18. It becomes.

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

  First, the modification about the illumination means 60 is demonstrated.

  The light emitters 65 may be arranged at positions facing a plurality of side end surfaces of the light guide plate 61. Further, as a means for extracting light from the light guide plate 61, various known light extraction means can be used instead of providing the diffusion component 64 or in addition to providing the diffusion component 64. As an example, the pair of main surfaces 61 b and 61 c of the light guide plate 61 may be inclined with respect to each other so as to approach each other as the distance from the light emitter 65 increases. For example, the main surface 61c of the light guide plate 61 facing the solar cell panel 50 may be formed as a flat inclined surface or a curved surface. Further, the main surface 61c of the light guide plate 61 facing the solar cell panel 50 may be configured to connect a plurality of inclined surfaces via a connection surface extending in a substantially normal direction of the light guide plate 61. Furthermore, as another example, it is possible to impart a diffusion function for diffusing light to at least one of the pair of main surfaces 61 b and 61 c of the light guide plate 61. Examples of the configuration for imparting a diffusion function to the main surfaces 61b and 61c include a configuration in which the main surface 61c is an uneven surface and a configuration in which a pattern of a white scattering layer is provided on the main surface 61c.

  Furthermore, an optical sheet that can exhibit various optical functions may be disposed on the side of the light guide plate 61 opposite to the solar cell panel 50. Examples of such an optical sheet include a diffusion sheet that diffuses light, and a prism sheet and a lens sheet that deflect the optical path of light emitted from the light guide plate 61. Furthermore, a display sheet having a display surface 21 for displaying the display target 13 may be provided on the opposite side of the light guide plate 61 from the solar cell panel 50.

  Next, a modified example related to the light control sheet 20 will be described.

  In the first embodiment described above, as shown in FIG. 2, the second end located on the other side (lower side in the drawing) of the display surface 12 in the first axial direction d1 on the main cut surface of the light control sheet. The portion 12 b was located on the focal position fp of the lens surface 31 when the parallel light beam L <b> 21 (see FIG. 2) traveling in the normal direction nd of the main body portion 40 was incident on the lens surface 31. However, the arrangement of the second end portion 12b of the display surface 12 is not limited to such an example. 9 and 10 show an arrangement example of the second end portion 12b in the first axial direction d12. In the example shown in FIGS. 9 and 10, the second end 12 b of the display surface 12 is the focal point of the lens surface 31 when the parallel light beams L 91 and L 101 traveling in the normal direction nd of the main body 40 are incident on the lens surface 31. The position is shifted from the position fp.

  Among these, in the example shown in FIG. 9, the second end portion 12 b of the display surface 12 is located on the other side in the first axial direction d <b> 1 with respect to the focal point fp of the corresponding lens surface 31. Further, the second end portion 12 b of the display surface 12 is connected to the back surface 20 b of the light control sheet 20 located on a virtual surface defined by the focal points fp of the many lens surfaces 31. According to such a configuration, the first angle range AR1 and the second angle range AR2 are centered on the direction da inclined to one side (upper side) in the first axial direction d1 with respect to the normal direction nd of the main body 40. Can be carved. In this case, for example, it is suitable when the display body 10 is installed at a position that is not so high with respect to the line of sight in a use as a display plate assumed as a typical use. That is, when the observer observes the display body 10 from the direction db with a small angle with respect to the horizontal direction or the direction dc inclined upward in the vertical direction, the display formed on the display surface 12 is displayed. The object 13 can be observed. On the other hand, the sunlight L92 that travels downward in the vertical direction and enters the lens surface 31 passes through the light control sheet 20 without entering the display surface 12, and receives the light receiving surface 50a of the solar cell panel 50. Can be incident. Therefore, according to such a form, while sufficiently allowing light reception on the light receiving surface 50a of the solar battery panel 50, the display object 13 given to the display surface 12 is the same as or above the line of sight. It can be observed with excellent visibility.

  On the other hand, in the example shown in FIG. 10, the second end 12 b of the display surface 12 is located on one side in the first axial direction d <b> 1 with respect to the focal point fp of the corresponding lens surface 31. Further, the second end portion 12 b of the display surface 12 is connected to the back surface 20 b of the light control sheet 20 located on a virtual surface defined by the focal points fp of the many lens surfaces 31. According to such a configuration, the first angle range AR1 and the second angle range AR2 centering on the direction de inclined to the other side (downward) in the first axial direction d1 relative to the normal direction nd of the main body 40. Can be separated. In this case, for example, it is suitable when the display body 10 is installed at a position relatively higher than the line of sight in a use as a display plate assumed as a typical use. That is, since the observer observes the display body 10 while looking up at the upper side in the vertical direction, the observer looks up at the display object 13 given to the display surface 12 by looking up in the direction df inclined upward in the vertical direction. Can do. On the other hand, the sunlight L101 and L102 which enter the display body 10 from a direction having a small angle with respect to the horizontal direction or entering a direction inclined downward in the vertical direction does not enter the display surface 12. The light passes through the control sheet 20 and can enter the light receiving surface 50 a of the solar cell panel 50. Therefore, according to such a form, it is possible to look up at the display object 13 given to the display surface 12 with sufficient visibility, and the sunlight is very high on the light receiving surface 50a of the solar cell panel 50. It can be captured efficiently.

  In the example shown in FIGS. 2, 9, and 10, a virtual surface in which the second end portion 12 b of the display surface 12 is defined by the focal points fp of the many lens surfaces 31 in the main cut surface of the light control sheet. Although the example located above was shown, it is not limited to such an example. The second end portion 12 b of the display surface 12 may be arranged so as to be shifted from the virtual surface defined by the focal points fp of the multiple lens surfaces 31. In particular, the second end portion 12b of the display surface 12 is arranged on a virtual surface defined by the focal points fp of a large number of lens surfaces 31 or at a position closer to the lens surface 31 than the virtual surface. Further, it is possible to prevent a possibility that the display near the first end portion 12a and the display near the second end portion 12b appear to be reversed depending on the observation angle.

<Second Embodiment>
Next, a second embodiment will be described with reference mainly to FIGS.

  The display body 10 with a solar cell panel according to the second embodiment includes a light control sheet 20, a solar cell panel 50 disposed on the back surface of the light control sheet 20, and light, as in the first embodiment. And lighting means 70 disposed at least partially between the control sheet 21 and the solar cell panel 50. In the display body 10 according to the second embodiment, the illumination means 70 is different from the illumination means 60 of the display body 10 according to the first embodiment, and other configurations are the same as those in the first embodiment. The display body can be the same. That is, in the display body 10 according to the second embodiment, the light control sheet 20, the solar battery panel 50, the storage battery 18, and the control circuit 19 can be the same as those in the first embodiment described above.

  In the first embodiment, as shown in FIGS. 2 and 3, the light emitter 65 of the illumination unit 60 is disposed at a position that does not overlap the light receiving surface 50a of the solar cell panel 50 in plan view. On the other hand, in 2nd Embodiment, the light-emitting body 75 of the illumination means 70 is arrange | positioned in the position which overlaps with the light-receiving surface 50a of the solar cell panel 50 in planar view. Therefore, in the planar shape of the display 10 according to the second embodiment, there is no portion that protrudes laterally and does not emit light. For this reason, the planar shape of the display body 10 can be reduced in size, and the design is excellent. Hereinafter, the illumination means 70 of the display body 10 according to the second embodiment will be described in detail.

  As shown in FIG. 11, the illumination means 70 has a light emitting sheet 71 disposed between the back surface 20 b of the light control sheet 20 and the light receiving surface 50 a of the solar cell panel 50. The light emitting sheet 71 includes a translucent support 72 disposed to face the light receiving surface 50a of the solar cell panel 50, a plurality of light emitters 75 disposed on the support 72 and spaced apart from each other, and a support. And a wiring 73 provided on the body 72 and connected to the light emitting body 75. As shown in FIG. 11, in the illumination means 70 by 2nd Embodiment, light inject | emits from the light-emitting body 75 of the illumination means 70 using the electric power generated with the solar cell panel 50. As shown in FIG.

  The support 72 is a sheet-like member made of translucent resin, glass, or the like, and functions as a support member that supports the light emitter 75.

  As the light emitter 75, various known light emitters can be used as in the first embodiment. In the example shown in FIGS. 11 and 12, a light emitter 75 is configured by a plurality of point-like light emitters regularly arranged on the support 72, more specifically, a plurality of light emitting diodes. . As an example, the light emitters 75 are arranged on the support 72 in two directions intersecting each other at a constant arrangement pitch. According to such an arrangement of the light emitters 75, it is possible to make the brightness distribution uniform when the illumination unit 70 emits light.

  As shown in FIG. 11, in the illustrated example, the light emitter 75 is disposed at a position facing the display surface 12 from the back side. Further, as indicated by dotted lines in FIG. 12, the lens surface 31 of the light control sheet 20 extends in the second axial direction d <b> 2, and a plurality of light emission along the longitudinal direction of the display surface 12 corresponding to each lens surface 31. The bodies 75 are arranged at the same pitch, for example. However, the present invention is not limited to this example, and a linear light emitting body extending in the longitudinal direction of the lens surface 31 may be provided at a position facing each lens surface 31.

  It is preferable that the orientation characteristics of the light emitter 75 are adjusted according to the relative position with respect to the display surface 12 so that the emitted light is mainly incident on the display surface 12. In this case, the light emitted from the light emitter 75 can be efficiently used for illumination of the display surface 12.

  The wiring 73 is made of, for example, copper, aluminum, silver, or the like, and extends between each light emitting body 75 and the control circuit 19. Such a light emitting sheet 71 can be formed as a so-called printed board.

  The light emitting sheet 71 is configured such that 50% or more of the entire region of the support 72 is exposed when the light emitting sheet 71 is observed from the normal direction. That is, the area covered with the wiring 73 and the light emitter 75 in the entire region of the support 72 is less than 50%. According to such a light emitting sheet 71, the light transmittance when the said light emitting sheet 71 is caught as a whole can be ensured to 50% or more. That is, it becomes possible for the light emitting sheet 71 to ensure translucency as a whole.

  According to the solar cell panel-equipped display body 10 according to the second embodiment having the above-described configuration, the same operational effects as those of the first embodiment described above can be achieved.

  That is, according to the solar cell panel-equipped display body 10 of the second embodiment, the lens surface 31 is directed toward the light receiving surface 50a of the solar cell panel 50 by refraction with the traveling direction of light incident from a certain direction, and The traveling direction of light emitted from the display surface 12 via the lens surface 31 can be directed in a different direction from a certain direction by refraction. Therefore, when the display object 13 formed on the display surface 12 is observed, the light receiving surface 50a of the solar cell panel 50 can be prevented from being visually recognized. In many types of solar cell panels, the light receiving surface is black or dark. If the light receiving surface of such a solar cell panel is exposed in the direction in which the display surface 12 is observed, the design is inferior and harmony with the surrounding environment of the region where the solar cell panel is installed is impaired. Become. However, according to the display body 10 with a solar cell panel according to the second embodiment, such a problem can be avoided.

  According to the second embodiment, the display surface 12 is illuminated by the light from the illumination means 70. Therefore, even if the display body 10 with the solar battery panel is arranged outdoors, the display surface 12 is illuminated by the illumination means 70 even at night, so that the display target 13 on the display surface 12 is good. Can be visually recognized.

  Furthermore, the electric power generated by the solar cell panel 50 can be used for the light emission of the illumination means 70. Therefore, it is possible to omit securing a separate power source and installing facilities and wiring for supplying power from the separate power source to the illumination means 70. Such a display body 10 has a very high degree of freedom in selecting an installation location and can be used for various purposes. For example, the display body 10 can be used as an outdoor signboard, a road information bulletin board, or an outer wall of a building. Further, in a situation where the sun does not shine on the light receiving surface 50a of the solar cell panel 50, it is possible to cause the illumination means 70 to emit light using the power stored in the storage battery 18 to display the display target 13. It becomes.

  Each display surface 12 is inclined with respect to the sheet surface of the light control sheet 20 and the light receiving surface 50a of the solar cell panel 50, and is inclined with respect to a direction parallel to the optical axis od of the lens surface 31. . According to such a display body 10, the second angle range AR <b> 2 that is an angle range in which light from the display surface 12 is emitted via the lens surface 31, in other words, the display formed on the display surface 12. It is possible to adjust the second angle range AR2 that is an angle range in which the object 13 is observed with a high degree of freedom, and in particular, it is possible to widen the second angle range AR2.

  Further, the display surface 12 is disposed between the light receiving surface 50 a of the solar cell panel 50 and the plurality of lens surfaces 31, and is inclined with respect to the light receiving surface 50 a of the solar cell panel 50. According to such a display body 10, the first angle range AR1, which is the angle range of incident light that is guided to the light receiving surface 50a of the solar cell panel 50, is adjusted with a high degree of freedom, in particular, the first angle range. It is also possible to widen AR1. In addition, the first angle range AR1 and the second angle range AR2 can be shifted.

  Further, according to the second embodiment, the light emitting sheet 71 constituting the illumination means 70 is disposed between the back surface 20 b of the light control sheet 20 and the light receiving surface 50 a of the solar cell panel 50. However, the light emitting sheet 71 disposed between the light control sheet 20 and the solar cell panel 50 has translucency. Therefore, the illuminating means 70 can cover the light receiving surface 50a and illuminate the display surface 12 while enabling the light receiving surface 50a of the solar cell panel 50 to receive light. Therefore, the illuminating means 70 can also emit light and at least partially hide the light receiving surface 50a without impairing the power generation function of the solar cell panel 50.

  In particular, in the second embodiment, a plurality of light emitters 75 are distributed on the support 72 of the light emitting sheet 71. Therefore, it is possible to illuminate a desired region with the light emitter 75 without unevenness. In particular, in the illustrated example, the light emitter 75 is disposed at a position facing the display surface 12, and can efficiently illuminate the display surface 12.

  In the illustrated example, the light emitter 75 is disposed at a position facing the display surface 12 from the side opposite to the unit lens 30. Therefore, as shown in FIG. 11, a lot of light L111 from the light emitter 75 that has made the display surface 12 transparent enters the lens surface 31. That is, illumination for displaying the display target 13 can be efficiently performed by the light from the illumination unit 70.

  The solar cell panel-equipped display body 10 according to the second embodiment has been described above, but various modifications can be made to the second embodiment. For example, the light control sheet 20 can be modified in the same manner as in the first embodiment. Further, as will be described below, the illumination means 70 can be variously modified. In the following description, for parts that can be configured in the same manner as in the above-described embodiment, the same reference numerals as those used for the corresponding parts in the above-described embodiment are used, and redundant description is omitted.

  First, the support 72 of the light emitting sheet 71 may have a diffusion function. As a configuration for imparting a diffusion function to the support 72, a configuration in which the support 72 contains a diffusing component or a configuration in which the support 72 has an uneven surface can be employed. Further, a diffusion sheet capable of diffusing light may be provided between the light emitting sheet 71 and the light control sheet 20 or between the light control sheet 20 and the solar cell panel 50. When the illumination means 70 has a diffusing function, the light receiving surface 50a of the solar cell panel 50 can be effectively invisible. Thereby, the design of the display body 10 can be more effectively improved, and harmony with the surrounding environment can be further improved. Further, when the incident light on the light receiving surface 50a of the solar cell panel 50 is diffused by the illumination means 70, the light enters the regions in the light receiving surface 50a with a substantially uniform light amount. In this case, the solar cell panel 50 can generate electric power with excellent power generation efficiency even if it is any type of solar cell panel that has been widely used.

  Furthermore, it replaces with the light emission sheet | seat 71, and the well-known translucent illumination means and translucent display apparatus can be used. Examples of the translucent illumination unit and the translucent display device include an organic EL illumination unit and an organic EL display device in which a pair of electrodes are formed of a transparent conductor.

<Third Embodiment>
Next, a third embodiment will be described with reference mainly to FIGS.

  The display body 10 with a solar cell panel according to the third embodiment is similar to the first and second embodiments in the light control sheet 20 and the solar cell panel 50 disposed on the back surface of the light control sheet 20. And illumination means 80 for illuminating the display surface 12. In the display body 10 according to the third embodiment, the illumination means 80 is different from the illumination means 60 and 70 of the display body 10 according to the first and second embodiments. And it can be made the same as the display body according to the second embodiment. That is, in the display body 10 according to the third embodiment, the light control sheet 20, the solar battery panel 50, the storage battery 18, and the control circuit 19 may be the same as those in the first and second embodiments described above. it can.

  As shown in FIGS. 13 to 15, in the display body 10 according to the third embodiment, the illumination unit 80 has a plurality of light emitters 85 arranged facing the side end surface 20 c of the light control sheet 20. doing. The side end surfaces 20c on which the light emitters 85 are arranged to face each other are a pair of side end surfaces 20c facing the second axial direction d2 of the light control sheet 20. In the example illustrated in FIG. 14, the light emitter 85 is disposed so as to face each of the pair of side end surfaces 20c facing the second axial direction d2. However, the present invention is not limited to this example, and the light emitter 85 may be disposed so as to face only one of the pair of side end faces 20c.

  As the light emitter 85, various known light emitters can be used as in the first and second embodiments. In the example shown in FIGS. 13 to 15, the light emitter 85 is configured by a plurality of point light emitters arranged in the first axial direction d <b> 1, more specifically, a plurality of light emitting diodes. In the illustrated example, each light emitter 85 is provided corresponding to each unit lens 30. The light emitters 85 are offset from the corresponding unit lenses 30 in the normal direction nd of the light control sheet 20 and face the main body 40 of the light control sheet 20. However, the present invention is not limited to the illustrated example, and the pointed light emitters may be arranged in the first axial direction d1 at a narrower pitch than the unit lens 30 along the side end surface 20c of the light control sheet 20. . Further, a linear light emitting body extending in the first axial direction d1 may be provided along the side end face 20c of the light control sheet 20.

  As shown in FIG. 13, in the illumination means 80 by 3rd Embodiment, light inject | emits from the light-emitting body 85 of the illumination means 80 using the electric power generated with the solar cell panel 50. As shown in FIG. As shown in FIGS. 13 and 15, the lights L131 and L151 emitted from the light emitter 85 enter the light control sheet 20 through the side end surface 20c of the light control sheet 20. The light L131 and L151 incident on the light control sheet 20 is reflected on the front surface 20a and the back surface 20b of the light control sheet 20 and repeatedly totally reflected due to the difference in refractive index between the material forming the light control sheet 20 and air. The light control sheet 20 is advanced. The unit lens 30 is formed as a convex lens that protrudes to the side away from the back surface 20b. Therefore, the light L151 traveling in the light control sheet 20 is suppressed from traveling in the first axial direction d1, and generally travels in the second axial direction d2, as shown in FIG.

  However, the display surface 12 on which the display target 13 is formed is provided at a position facing the lens surface 31 of the unit lens 30. And since the lens surface 31 is non-parallel to the back surface 20b, the light L131 and L151 which repeat the reflection in the surface 20a and the back surface 20b and advance in the light control sheet 20 will also inject into the display surface 12. . Then, the lights L131 and L151 are diffused on the display surface 12 and the traveling direction thereof is irregularly changed, and are emitted from the light control sheet 20.

  As described above, in the third embodiment, the display target 13 is displayed by the light diffused on the display surface 12, particularly the diffusely reflected light. Therefore, in 3rd Embodiment, it is preferable that the display surface 12 is produced so that the display target 13 may be displayed with the light reflected on the display surface 12. FIG. In the third embodiment, the display surface 12 may have a diffusion function. Examples of methods for imparting a diffusing function to the display surface 12 include making the surface of the display surface 12 rough and forming the display object 13 with diffusible ink.

  According to the solar cell panel-equipped display body 10 according to the third embodiment having the above-described configuration, the same functions and effects as those of the first and second embodiments described above can be achieved.

  That is, according to the solar cell panel-equipped display body 10 of the third embodiment, the lens surface 31 is directed toward the light receiving surface 50a of the solar cell panel 50 by refraction, with the traveling direction of light incident from a certain direction being refracted. The traveling direction of light emitted from the display surface 12 via the lens surface 31 can be directed in a different direction from a certain direction by refraction. Therefore, when the display object 13 formed on the display surface 12 is observed, the light receiving surface 50a of the solar cell panel 50 can be prevented from being visually recognized. In many types of solar cell panels, the light receiving surface is black or dark. If the light receiving surface of such a solar cell panel is exposed in the direction in which the display surface 12 is observed, the design is inferior and harmony with the surrounding environment of the region where the solar cell panel is installed is impaired. Become. However, according to the display body 10 with a solar cell panel according to the third embodiment, such a problem can be avoided.

  According to the third embodiment, the display surface 12 is illuminated by the light from the illumination unit 80. Therefore, even if the display body 10 with the solar cell panel is arranged outdoors, the display surface 12 is illuminated by the illumination means 80 even at night, so that the display target 13 on the display surface 12 is good. Can be visually recognized.

  Furthermore, the electric power generated by the solar cell panel 50 can be used for the light emission of the illumination means 80. Therefore, it is possible to omit securing a separate power source and installing facilities and wiring for supplying power from the separate power source to the lighting unit 80. Such a display body 10 has a very high degree of freedom in selecting an installation location and can be used for various purposes. For example, the display body 10 can be used as an outdoor signboard, a road information bulletin board, or an outer wall of a building. Further, in a situation where the sun does not shine on the light receiving surface 50a of the solar cell panel 50, it is possible to cause the illumination means 80 to emit light using the electric power stored in the storage battery 18 to display the display target 13. It becomes.

  Each display surface 12 is inclined with respect to the sheet surface of the light control sheet 20 and the light receiving surface 50a of the solar cell panel 50, and is inclined with respect to a direction parallel to the optical axis od of the lens surface 31. . According to such a display body 10, the second angle range AR <b> 2 that is an angle range in which light from the display surface 12 is emitted via the lens surface 31, in other words, the display formed on the display surface 12. It is possible to adjust the second angle range AR2 that is an angle range in which the object 13 is observed with a high degree of freedom, and in particular, it is possible to widen the second angle range AR2.

  Further, the display surface 12 is disposed between the light receiving surface 50 a of the solar cell panel 50 and the plurality of lens surfaces 31, and is inclined with respect to the light receiving surface 50 a of the solar cell panel 50. According to such a display body 10, the first angle range AR1, which is the angle range of incident light that is guided to the light receiving surface 50a of the solar cell panel 50, is adjusted with a high degree of freedom, in particular, the first angle range. It is also possible to widen AR1. In addition, the first angle range AR1 and the second angle range AR2 can be shifted.

  Further, according to the third embodiment, the illumination means 80 has the side end surface of the light control sheet 20 located on one side or the other side in the second axial direction d2 parallel to the direction in which the lens surface 31 extends linearly. It has the light-emitting body 85 arrange | positioned facing 20c. Such a configuration of the illumination unit 80 is not only very simple, but also eliminates the need to arrange any member between the solar cell panel 50 and the light control sheet 20. For this reason, the solar cell panel 50 can be disposed close to the light control sheet 20, and the display body 10 can be downsized. Thereby, the freedom degree of the installation place of the display body 10 further improves.

  The solar cell panel-equipped display body 10 according to the third embodiment has been described above, but various modifications can be made to the third embodiment. For example, the light control sheet 20 can be modified in the same way as in the first and second embodiments. Further, as already described, various modifications can be made to the illumination means 80.

<Fourth embodiment>
Next, a fourth embodiment will be described mainly with reference to FIGS. 16 and 17.

  The display body 10 with a solar cell panel according to the fourth embodiment is similar to the first to third embodiments, the light control sheet 21, the solar cell panel 55, the display surface 12, and the display surface 12. And illuminating means 60 for illuminating. The display body 10 according to the fourth embodiment is different from the first to third embodiments mainly on the arrangement of the solar cell panel 55. Further, in the display body 10 according to the fourth embodiment, the light control sheet 21 is slightly different from the first to third embodiments in relation to the difference of the solar cell panel 55.

  On the other hand, the display 10 according to the fourth embodiment has illumination means 60 that is substantially the same as that of the first embodiment. However, the illumination means 60 of the display body 10 according to the fourth embodiment has a reflection sheet 68 on the side opposite to the side facing the light control sheet 21 in relation to the arrangement of the solar cell panel 55. However, it may be configured in the same manner as the illumination unit of the first embodiment. Moreover, the display body 10 according to the fourth embodiment has the same storage battery 18 and control circuit 19 as those in the first to third embodiments. However, in FIGS. 17 and 18, the storage battery 18 and the control circuit 19 are not shown.

  As shown in FIGS. 16 and 17, in the fourth embodiment, a plurality of solar cell panels 55 are provided at positions facing the plurality of lens surfaces 31. The light receiving surfaces 56 of the solar cell panels 55 are alternately arranged with the display surface 12 in the first axial direction d1 that is the arrangement direction of the lens surfaces 31. In the fourth embodiment, the plurality of solar battery panels 55 and the plurality of display bodies 12 are disposed between the plurality of lens surfaces 31 of the light control sheet 21 and the illumination unit 60. Accordingly, the light receiving surface 56 of the solar battery panel 55 is, for example, the same as the display surface 12, for example, inside the light control sheet 21, on the back surface 21 b facing the lens surface 31 of the light control sheet 21, and the lens surface of the light control sheet 21. It can be provided in a notch 41 formed on the side opposite to the 31 side. In the illustrated example, the light receiving surface 56 is disposed inside the light control sheet 21 in the same manner as the display surface 12.

  The solar cell panel 55 is a power generation device that converts the light received by the light receiving surface 56 into electric energy, and uses various types of devices, like the solar cell panel 50 of the first to third embodiments. be able to. Each solar cell panel 55 is connected to the light emitter 65 of the illumination means 60 via the control circuit 19. Therefore, also in the illumination means 60 by 4th Embodiment, the light can be inject | emitted from the light-emitting body 65 of the illumination means 60 using the electric power generated with the solar cell panel 55. FIG.

  In the display body 10 according to the fourth embodiment, the display surface 12, the light guide plate 61 of the illumination means 60, and the light emitter 65 can be configured in the same manner as in the first embodiment. Therefore, it is possible to adjust the second angle range AR2, which is an angle range in which the display target 13 can be continuously observed, with a high degree of freedom, in particular, to widen the second angle range AR2. Moreover, the display surface 12 can be efficiently illuminated by the illumination means 60, and thereby the visibility of the display surface 12 can be effectively improved. Furthermore, in the display body 10 according to the fourth embodiment, the first angle range AR1, which is a continuous angle range of the incident angle in which the traveling direction can be directed to the light receiving surface 56, can be adjusted with a high degree of freedom. The idea to make it is also made. As a result, even in the display body 10 according to the fourth embodiment, the display target 13 can be displayed with excellent visibility while the light receiving surface 56 is sufficiently invisible. Hereinafter, the configuration related to the light receiving surface 56 of the solar cell panel 55 will be described in more detail.

  As described above, in the fourth embodiment, the light receiving surface 56 and the display surface 12 of the solar cell panel 55 are disposed in the main body 40. As shown in FIG. 16, each light receiving surface 56 is disposed to face one unit lens 30 corresponding to the light receiving surface 56, and each display surface 12 is also one unit lens 30 corresponding to the display surface 12. It is arranged to face. The display surface 12 disposed corresponding to each unit lens 30 is disposed on one side in the first axial direction d1 relative to the light receiving surface 56 disposed corresponding to the unit lens 30. Here, the one side in the first axial direction d1 is the upper side of the paper surface in FIGS.

  Similar to the first to third embodiments described above, the display surface 12 is arranged in the first axial direction d1 and is inclined with respect to the sheet surface of the light control sheet 21. The light receiving surface 56 of the solar cell panel 55 is arranged in the first axial direction d1 and is inclined with respect to the sheet surface of the main body 40 at an angle different from that of the display surface 12.

  On the other hand, the light receiving surface 56 inclined at an angle different from that of the display surface 12 is arranged so as to face the corresponding unit lens 30 at least partially along the normal direction nd. In the fourth embodiment, like the unit lens 30, the light receiving surface 56 is a second direction orthogonal to the first axial direction d1 in a direction intersecting the first axial direction d1 that is the arrangement direction. It extends linearly in the axial direction d2. In the illustrated example, a large number of solar cell panels 55 and their light receiving surfaces 56 provided corresponding to the unit lenses 30 are configured identically.

  Each light receiving surface 56 is inclined with respect to the sheet surface of the main body 40, that is, the sheet surface of the light control sheet 21, and is also inclined with respect to a direction parallel to the optical axis od of the lens surface 31. That is, each light receiving surface 56 is non-parallel to both the sheet surface of the main body 40 and the direction parallel to the optical axis od of the lens surface 31. According to the light receiving surface 56 inclined in this way, the traveling direction can be understood by considering the optical path of the light traveling in the opposite direction to the light emitted from the display surface 12 via the lens surface 31 described above. It is possible to adjust the first angle range AR1, which is a continuous angle range of the incident angle where the light is directed toward the light receiving surface 56, with a high degree of freedom, in particular, to widen the first angle range AR1.

  As shown in FIG. 2, each light receiving surface 56 has a second end portion 56b located on the other side (lower side) in the first axial direction d1 and a second end portion 56b located on one side (upper side) in the first axial direction d1. It is inclined with respect to the sheet surface of the light control sheet 21 so as to be closer to the surface 21a in the normal direction nd of the light control sheet 21 than the one end 56a. Therefore, the second end portion 56 b of the light receiving surface 56 is closer to the lens surface 31 of the unit lens 30 in the normal direction nd of the light control sheet 21 than the first end portion 56 a of the light receiving surface 56. As can be understood from FIGS. 16 and 17, light from an angle range inclined to one side (upper side) with respect to the normal direction nd easily enters the light receiving surface 56.

  From the viewpoint of enhancing such a tendency, in the main cut surface of the light control sheet, the light receiving surface 56 is stepwise or continuous from the other side (lower side) to the one side (upper side) in the first axial direction d1. In particular, it is preferable to move away from the unit lens 30 in the normal direction nd of the light control sheet. In the illustrated example, the light receiving surface 56 is formed as a flat surface. And in the main cut surface of the light control sheet shown in FIG. 16 and FIG. 17, the light receiving surface 56 is continuously at a constant inclination from the other side to the one side in the first axial direction d1. The unit is separated from the unit lens 30 along the normal direction nd of the light control sheet. Light from a wide angle range inclined to one side (upper side) with respect to the normal direction nd is likely to enter such a light receiving surface 56.

  In the illustrated embodiment, in the main cut surface of the light control sheet shown in FIG. 16, the first end 56 a that is an end on one side (upper side) in the first axial direction d <b> 1 of the light receiving surface 56 is: The front end portion 32a of the lens surface 31 corresponding to the light receiving surface 56 is located at the same position in the first axial direction d1. Further, in the main cut surface of the light control sheet shown in FIG. 16, the second end portion 56 b that is the other end (lower side) end portion of the light receiving surface 56 in the first axial direction d <b> 1 is formed on the light receiving surface 56. The corresponding lens surface 31 is located on the other side in the first axial direction d1 than the base end portion 32b on the other side in the first axial direction d1.

  Next, the arrangement relationship between the light receiving surface 56 and the display surface 12 will be described. As shown in FIG. 16, the distance between the second end portion 56 b of the light receiving surface 56 and the first end portion 12 a of the display surface 12 is such that the first end portion 56 a of the light receiving surface 56 and the display surface 12 are It is wider than the distance between the second end 12b. Further, the distance between each position on the light receiving surface 56 and the corresponding display surface 12 changes stepwise or continuously. In the present embodiment, the distance along the first axis direction d1 between each position on the light receiving surface 56 and the corresponding display surface 12 is such that the position on the light receiving surface 56 is in the normal direction nd of the light control sheet. As the distance from the unit lens 30 increases, the width gradually decreases stepwise or continuously. Therefore, the first end portion 56a of the light receiving surface 56 and the second end portion 12b of the display surface 12 are closest to each other. In the illustrated embodiment, the first end 56 a of the light receiving surface 56 and the second end 12 b of the display surface 12 are connected. However, the first end portion 56a of the light receiving surface 56 and the second end portion 12b of the display surface 12 may be separated from each other.

  Also, as shown in FIG. 16, the connection region between the first end portion 56a of the connected light receiving surface 56 and the second end portion 12b of the display surface 12 is the method of the light control sheet on the main cut surface of the light control sheet. The parallel light beam L221 traveling in the linear direction nd is located on the focal position fp of the lens surface 31 when it enters the lens surface 31. That is, a connection region between the first end portion 56 a of the connected light receiving surface 56 and the second end portion 12 b of the display surface 12 is located on the optical axis od of the lens surface 31. According to such a display body 10, it is possible to separate the first angle range AR1 and the second angle range AR2 with the normal direction nd of the light control sheet 21 as a boundary.

  As shown in FIG. 16, the second end portion 56b of the light receiving surface 56 is connected to the first end portion 12a of the display surface 12 adjacent to the light receiving surface 56 on the other side in the first axial direction d1. The connection region between the second end portion 56b of the connected light receiving surface 56 and the first end portion 12a of the display surface 12 is controlled from the connection surface 38 that connects between the base end portions 32b of the two adjacent lens surfaces 31. It is located at a position separated along the normal direction nd of the sheet. However, the second end portion 56b of the light receiving surface 56 may be separated from the first end portion 12a of the display surface 12 adjacent to the light receiving surface 56 on the other side in the first axial direction d1.

  According to the display body 10 with a solar cell panel according to the fourth embodiment described above, the following operational effects can be achieved.

  First, similarly to the first to third embodiments, each display surface 12 is inclined with respect to the sheet surface of the light control sheet 21 and is parallel to the optical axis od of the lens surface 31. Inclined. According to such a display body 10, the second angle range AR <b> 2 that is an angle range in which light from the display surface 12 is emitted via the lens surface 31, in other words, the display formed on the display surface 12. It is possible to adjust the second angle range AR2 that is an angle range in which the object 13 is observed with a high degree of freedom, and in particular, it is possible to widen the second angle range AR2.

  On the other hand, the light receiving surface 56 inclined at a different angle from the display surface 12 efficiently receives light L172, L173, and L174 incident from a direction different from the light incident on the display surface 12, as shown in FIG. It becomes possible. As well shown in FIG. 17, the light receiving surface 56 can efficiently receive the light L <b> 172, L <b> 173, and L <b> 174 coming to the light receiving surface 56 from the front. In the example illustrated in FIG. 17, the light receiving surface 56 is inclined to the other side in the first axial direction d1 with respect to the optical axis od of the lens surface 31, and therefore, one in the first axial direction d1 with respect to the optical axis od. It becomes possible to efficiently receive the light L172, L173, and L174 incident on the lens surface 31 from the direction inclined to the side. Therefore, according to the present embodiment, as shown in FIG. 17, the light L174 incident on the lens surface 31 from a direction greatly inclined to one side in the first axial direction d1 with respect to the optical axis od is also incident on the lens. Light is received by the light receiving surface 56 facing the surface 31. As indicated by a dotted line in FIG. 17, the light L 174 is incident on the incident lens surface 31 if the light receiving surface 56 and the display surface 12 are alternately arranged on the same surface as the back surface 21 b of the light control sheet 21. May proceed to a region facing a different lens surface and cause the inconvenience described with reference to FIG.

  That is, when the light receiving surface 56 is inclined with respect to the sheet surface of the main body 40, the first angle range AR1 that is the angle range in the incident direction to the light control sheet that is guided to the light receiving surface 56 is shown in FIG. Compared with the example shown in (1), it is possible to adjust with a high degree of freedom, and in particular, to widen the angle. In particular, the light receiving surface 56 is inclined with respect to the sheet surface of the main body 40 in the main body 40 closer to the unit lens 30 than the back surface 21 b of the light control sheet 21. As a result, the light receiving surface 56 receives light L172, L173, and L174 tilted with respect to the normal direction of the light control sheet from the front. As a result, the light receiving surface 56 can effectively receive light L172, L173, and L174 coming from a wide range of directions inclined with respect to the optical axis od, and the first angle range AR1 can be widened. it can.

  As described above, according to the display body 10 according to the fourth embodiment, the first angle range AR1, which is a continuous angle range of the incident angle in which the traveling direction can be directed to the light receiving surface 56, has a high degree of freedom. In particular, the first angle range AR1 can be widened. Therefore, in the display body 10 according to the fourth embodiment, sunlight that changes the incident direction according to the time zone and season can be efficiently received and used for power generation in the solar cell panel 50. It becomes.

  By the way, when observing the display target 13 formed on the display surface 12, the solar cell panel 55 superimposed on the light receiving surface 56 of the solar cell panel 55 together with the display target 13 is observed. Visibility and designability will be significantly impaired. Therefore, the second angle range AR2 in which the display surface 12 on which the display target 13 is formed can be observed is separated from the first angle range AR1 in which the solar cell panel 55 can be observed, that is, does not overlap. It is preferable.

  Therefore, in the display body 10 according to the fourth embodiment, as shown in FIG. 2, each display surface 12 is disposed on one side in the first axial direction d1 with respect to the corresponding light receiving surface 56. In each light receiving surface 56, the second end portion 56b located on the other side in the first axial direction d1 is lighter than the first end portion 56a located on one side in the first axial direction d1. The display surface 12 is inclined with respect to the sheet surface of the main body portion 40 so as to be close to the unit lens 30 in the line direction nd, and each display surface 12 has a first end portion 12a positioned on one side in the first axial direction d1. It is inclined with respect to the sheet surface of the main body 40 so as to be closer to the unit lens 30 in the normal direction nd of the light control sheet than the second end 12b located on the other side in the one axial direction d1.

  According to such a fourth embodiment, the light incident on the light control sheet 21 from the direction inclined to the other side in the first axial direction d1 with respect to the normal direction nd of the light control sheet, in other words, the first Light that enters the light control sheet 210 while proceeding to one side in the axial direction d <b> 1 can be selectively guided to the display surface 12 rather than the light receiving surface 56. In other words, the light L161 (see FIG. 16) from the display surface 12 is easily emitted in a direction inclined to the other side in the first axial direction d1 with respect to the normal direction nd of the light control sheet. Further, the light L162 (see FIG. 16) incident on the light control sheet 21 from a direction inclined to one side in the first axial direction d1 with respect to the normal direction nd of the light control sheet, in other words, the other in the first axial direction d1. The light L162 incident on the light control sheet 21 while proceeding to the side can be guided to the light receiving surface 56 rather than the display surface 12.

  That is, according to such a form, the first angle range AR1 that is the angle range of the incident direction to the light control sheet 21 that is guided to the light receiving surface 56 is relative to the normal direction nd of the light control sheet. The second angle range AR2 corresponding to the direction inclined to one side in the first axial direction d1 and the direction in which the light is emitted from the light control sheet 21 from the display surface 12 via the lens surface 31 is a light control sheet. This corresponds to a direction inclined to the other side in the first axial direction d1 with respect to the normal direction nd. For this reason, the first angle range AR1 and the second angle range AR2 are easily divided. In other words, the first angle range AR1 and the second angle range AR2 are difficult to overlap. Thereby, the first angle range AR1 and the second angle range AR2 can each be effectively widened.

  If the overlap between the first angle range AR1 and the second angle range AR2 is reduced in this way, and if the first angle range AR1 and the second angle range AR2 can be further separated, the display surface 12 is provided. When observing the displayed display object 13, it is possible to effectively prevent the light receiving surface 56 of the solar cell panel 55 from being observed together with the display object 13. In this case, the visibility of the display target 13 and the design of the display target 13 can be improved.

  The distance between the second end 56b of the light receiving surface 56 and the first end 12a of the display surface 12 is such that the first end 56a of the light receiving surface 56 and the second end 12b of the display surface 12 are the same. It is wider than the interval between and. According to such a form, the light receiving surface 56 and the display surface 12 can be arranged in a well-balanced manner, and the first angle range AR1 and the second angle range AR2 can be divided.

  Further, the distance along the first axis direction d1 between each position on the light receiving surface 56 and the corresponding display surface 12 is such that the position on the light receiving surface 56 is along the normal direction nd of the light control sheet. As it gets away from 30, it becomes narrower. According to such a form, the light receiving surface 56 blocks light to be emitted from the light control sheet 21 from the display surface 12 via the lens surface 31, or the display surface 12 is directed to the light receiving surface 56. It is possible to effectively suppress blocking of light to be incident.

  Further, the first end portion 56 a located on one side in the first axial direction d 1 of the light receiving surface 56 is connected to the second end portion 12 b located on the other side in the first axial direction d 1 of the display surface 12. According to such a configuration, it is possible to prevent light bent by the lens surface 31 from being transmitted between the first end portion 56 a of the light receiving surface 56 and the second end portion 12 b of the display surface 12. . As a result, the light incident on the light control sheet 21 can be efficiently used for power generation by the solar cell panel 55 or display of the display target 13.

  In particular, the connection region between the first end portion 56a of the light receiving surface 56 and the second end portion 12b of the display surface 12 is when the parallel light beams L163 and L171 traveling in the normal direction nd of the light control sheet are incident on the lens surface 31. Is located on the focal position fp of the lens surface 31 in FIG. According to such a light control sheet 21, the first angle range AR1 and the second angle range AR2 can be separated with the normal direction nd of the light control sheet as a boundary.

  Furthermore, the second end portion 56b located on the other side in the first axial direction d1 of the light receiving surface 56 is the first axial direction d1 of the display surface 12 adjacent to the light receiving surface 56 on the other side in the first axial direction d1. The first end portion 12a located on one side is connected to the first end portion 12a. According to such a configuration, the light incident on the light control sheet 21 is prevented from being transmitted between the second end portion 56b of the light receiving surface 56 and the first end portion 12a of the adjacent display surface 12. can do. As a result, the light incident on the light control sheet 21 can be efficiently used for power generation by the solar cell panel 55 or display of the display target 13.

  Further, the fourth embodiment includes the illumination means 60 that illuminates the display surface 12 as in the first to third embodiments. Therefore, even if it is arranged outdoors or even at night, the display surface 12 is illuminated by the illumination means 60 so that the display object 13 on the display surface 12 can be viewed well. it can. In addition, the illumination means 60 emits light using the electric power generated by the solar cell panel. Therefore, for example, it is very useful in that it is not necessary to install a power source or wiring for the display body 10 fixed outdoors.

  Moreover, the illumination means 60 in 4th Embodiment has the reflection sheet 68 arrange | positioned facing the light-guide plate 61 from the side opposite to the light control sheet 21 side. According to this reflection sheet 68, the light emitted from the light guide plate 61 toward the side opposite to the light control sheet 21 side can be returned to the light control sheet 21 side. Therefore, the display surface 12 can be illuminated by effectively using the light from the illumination unit 60.

  In addition, the illumination means 60 in 4th Embodiment can be comprised similarly to 1st Embodiment except having the reflective sheet 68. FIG. Therefore, although the description which overlaps is abbreviate | omitted, also in 4th Embodiment, there can exist an effect resulting from the illumination means 60 demonstrated in 1st Embodiment.

  According to the solar cell panel-equipped display body 10 of the fourth embodiment as described above, the lens surface 31 is directed toward the light receiving surface 56 of the solar cell panel 55 by refraction of the traveling direction of light incident from a certain direction. In addition, the traveling direction of the light emitted from the display surface 12 via the lens surface 31 can be directed to another direction different from a certain direction by refraction. Therefore, when the display target 13 formed on the display surface 12 is observed, the light receiving surface 56 of the solar cell panel 55 can be prevented from being visually recognized. In many types of solar cell panels, the light receiving surface is black or dark. When the light receiving surface of such a solar cell panel is exposed, the design is inferior, and harmony with the surrounding environment of the area where the solar cell panel is installed is impaired. However, according to the display body with a solar cell panel 10 according to the fourth embodiment, such a problem can be avoided.

  Further, according to the fourth embodiment, the display surface 12 is illuminated by the light from the illumination unit 60. Therefore, even if the display body 10 with the solar battery panel is disposed outdoors, the display surface 12 is illuminated by the illumination means 60 even at night, so that the display target 13 on the display surface 12 is good. Can be visually recognized.

  Furthermore, the electric power generated by the solar cell panel 55 can be used for the light emission of the illumination means 60. Therefore, it is possible to omit securing a separate power source and installing facilities and wiring for supplying power to the illumination means 60 from the separate power source. Such a display body 10 has a very high degree of freedom in selecting an installation location and can be used for various purposes. For example, the display body 10 can be used as an outdoor signboard, a road information bulletin board, or an outer wall of a building. Further, in a situation where the sun does not shine on the light receiving surface 56 of the solar battery panel 55, it is possible to display the display target 13 by using the power stored in the storage battery 18 to cause the illumination means 60 to emit light. It becomes.

  The solar cell panel-equipped display body 10 according to the fourth embodiment has been described above, but various modifications can be made to the fourth embodiment. For example, the illumination unit 60 can be modified in the same manner as in the first embodiment.

  In addition, the surface facing the light receiving surface 56 may be formed as the second light receiving surface so that the solar cell panel 55 can effectively receive the illumination light from the lighting unit 60.

<Fifth embodiment>
Next, a fifth embodiment will be described with reference mainly to FIG.

  The display body 10 with a solar cell panel according to the fifth embodiment includes the light control sheet 21, the solar cell panel 55, the display surface 12, and the display surface 12, as in the first to fourth embodiments. And illumination means 70 for illuminating. The display body 10 according to the fifth embodiment shown in FIG. 18 is configured in the same manner as in the first to fourth embodiments with respect to the light control sheet 21, the solar cell panel 55, and the display surface 12.

  Moreover, the display body 10 according to the fifth embodiment shown in FIG. 18 can be configured in the same manner as the second embodiment with respect to the illumination means 70. However, in the fifth embodiment, the solar cell panel 55 is located between the lens surface 31 and the light emitting sheet 71 of the illumination means 70. Therefore, the light emitting sheet 71 does not need to have transparency. For this reason, the support body 72 of the light emitting sheet 71 may not have translucency. The support 72 may have reflectivity, particularly diffuse reflectivity. Since the support 72 reflects the incident light, the light incident on the support 72 can be efficiently used for power generation in the solar cell panel 55 or display of the display target 13.

  According to the solar cell panel-equipped display body 10 according to the fifth embodiment having the above-described configuration, the lens surface 31 receives the light receiving surface 56 of the solar cell panel 55 by refraction of the traveling direction of light incident from a certain direction. And the traveling direction of the light emitted from the display surface 12 via the lens surface 31 can be directed to another direction different from a certain direction by refraction. Therefore, when the display target 13 formed on the display surface 12 is observed, the light receiving surface 56 of the solar cell panel 55 can be prevented from being visually recognized. In many types of solar cell panels, the light receiving surface is black or dark. If the light receiving surface of such a solar cell panel is exposed in the direction in which the display surface 12 is observed, the design is inferior and harmony with the surrounding environment of the region where the solar cell panel is installed is impaired. Become. However, according to the display unit 10 with the solar cell panel according to the fifth embodiment, such a problem can be avoided.

  According to the fifth embodiment, the display surface 12 is illuminated by the light from the illumination means 70. Therefore, even if the display body 10 with the solar battery panel is arranged outdoors, the display surface 12 is illuminated by the illumination means 70 even at night, so that the display target 13 on the display surface 12 is good. Can be visually recognized.

  Furthermore, the electric power generated by the solar cell panel 50 can be used for the light emission of the illumination means 70. Therefore, it is possible to omit securing a separate power source and installing facilities and wiring for supplying power from the separate power source to the illumination means 70. Such a display body 10 has a very high degree of freedom in selecting an installation location and can be used for various purposes. For example, the display body 10 can be used as an outdoor signboard, a road information bulletin board, or an outer wall of a building. Further, in a situation where the sun does not shine on the light receiving surface 56 of the solar battery panel 55, it is possible to cause the illumination means 70 to emit light and display the display target 13 using the electric power stored in the storage battery 18. It becomes.

  In addition, according to the display body 10 with a solar cell panel according to the fifth embodiment, the first to fourth embodiments described above are caused by the same configuration as the first to fourth embodiments described above. The same effects as those of the embodiment can be obtained.

  The solar cell panel-equipped display body 10 according to the fifth embodiment has been described above, but various modifications can be made to the fifth embodiment. For example, the illumination unit 70 can be modified in the same manner as in the second embodiment. Further, the light control sheet 21, the solar battery panel 55, and the display surface 12 can be variously modified as in the fourth embodiment.

DESCRIPTION OF SYMBOLS 10 Display body 12 Display surface 12a 1st edge part 12b 2nd edge part 13 Display object 13a Display object element 18 Storage battery 19 Control circuit 20 Light control sheet 20a Front surface 20b Back surface 20c Side end surface 21 Light control sheet 21a Surface 21b Surface 25 Lens part 30 unit lens 31 lens surface 32a distal end portion 32b base end portion 38 connection surface 40 main body portion 40a front side surface 40b rear side surface 41 notch 42 first notch surface 43 second notch surface 45 low refractive index portion 46 light incident surface 47 connection surface 48 Light exit surface 49 Molded product 50 Solar cell panel 50a Light receiving surface 55 Solar cell panel 56 Light receiving surface 56a First end portion 56b Second end portion 60 Illuminating means 61 Light guide plate 61a Side end surface 61b Surface 61c Back surface 63 Main portion 64 Diffusing component 65 Light emission Body 67 Reflecting plate 68 Reflecting sheet 70 Illuminating means 71 Light emitting sheet 72 Support body 73 Wiring 75 Light emitting body 8 Illumination means 85 illuminant

Claims (16)

A light control sheet having a plurality of lens surfaces arranged along the sheet surface;
A solar cell panel having a light receiving surface arranged at a position facing the plurality of lens surfaces;
Illuminating means for emitting light using the power generated by the solar cell panel,
A plurality of display surfaces for displaying a display target are provided at positions facing the plurality of lens surfaces,
The display surface is illuminated by light from the illumination means,
The lens surface directs the traveling direction of light incident from a certain direction toward the light receiving surface of the solar cell panel, and the traveling direction of light emitted from the display surface via the lens surface. A display with a solar panel that faces in a different direction from the direction.   The display body with a solar cell panel according to claim 1, wherein the display surface is inclined with respect to a sheet surface of the light control sheet.   The display surface is provided in the light control sheet, on the back surface of the light control sheet facing the lens surface, or in a notch formed on the back surface of the light control sheet facing the lens surface. The display body with a solar cell panel according to claim 1 or 2.   The display surface is disposed between the light receiving surface of the solar cell panel and the plurality of lens surfaces, and is inclined with respect to the light receiving surface of the solar cell panel. The display body with a solar cell panel according to one item. Each lens surface extends linearly in a direction intersecting with the arrangement direction of the plurality of lens surfaces,
5. The light emitting device according to claim 4, wherein the illuminating unit includes a light emitter that is disposed to face a side end surface of the light control sheet that is located on one side or the other side in a direction parallel to a direction in which the lens surface extends linearly. Display body with solar cell panel as described.   The display body with a solar cell panel according to claim 4, wherein at least a part of the illumination means is disposed between the light control sheet and the solar cell panel and has translucency.   The illumination means includes a light-transmitting light guide plate disposed between the light control sheet and the solar battery panel, and a light emitter disposed to face a side end surface of the light guide plate. Item 7. A display body with a solar cell panel according to item 4 or 6. In the display surface, an end portion located on one side in the arrangement direction of the lens surfaces is closer to the lens surface in a normal direction of the light control sheet than an end portion located on the other side in the arrangement direction. Inclined with respect to the sheet surface of the light control sheet,
The said light-emitting body is a display body with a solar cell panel of Claim 7 arrange | positioned facing the side end surface of the said light-guide plate located in the said one side in the direction parallel to the arrangement direction of the said lens surface.   The said light guide plate is a display body with a solar cell panel of Claim 7 or 8 which has a spreading | diffusion function which diffuses light.   The illumination means is provided on the support, a translucent support disposed between the light control sheet and the solar cell panel, a plurality of light emitters disposed on the support, and the support. And the display body with a solar cell panel of Claim 4 or 6 which has a light emission sheet containing the wiring connected to the said light emitter. A plurality of solar battery panels are provided at positions facing the plurality of lens surfaces,
The light receiving surface of the solar cell panel is alternately arranged with the display surface in the arrangement direction of the lens surface,
The plurality of solar cell panels and the plurality of display surfaces are arranged between the plurality of lens surfaces of the light control sheet and the illumination unit, respectively. Display with solar panel.   The display body with a solar cell panel according to claim 11, wherein the light receiving surface of the solar cell panel is inclined with respect to a sheet surface of the light control sheet.   The display body with a solar cell panel according to claim 11 or 12, wherein the light receiving surface of the solar cell panel is inclined to a side opposite to the display surface with respect to a sheet surface of the light control sheet.   The said illumination means has a light-guide plate arrange | positioned facing the said light control sheet | seat, and the light-emitting body arrange | positioned facing the side end surface of the said light-guide plate, The any one of Claims 11-13. The display body with a solar cell panel described in 1. In the display surface, an end portion located on one side in the arrangement direction of the lens surfaces is closer to the lens surface in a normal direction of the light control sheet than an end portion located on the other side in the arrangement direction. Inclined with respect to the sheet surface of the light control sheet,
The said light-emitting body is a display body with a solar cell panel of Claim 14 arrange | positioned facing the side end surface of the said light-guide plate located in the said one side in the direction parallel to the sequence direction of the said lens surface.   The illuminating means includes a support body disposed to face the light control sheet, a plurality of light emitters disposed on the support body, and a wiring provided on the support body and connected to the light emitter. The display body with a solar cell panel according to claim 11, comprising a light emitting sheet containing

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