JP2006351286A - Light guide plate and flat lighting system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide uniform and bright emission light without having luminance spots. <P>SOLUTION: This flat lighting system 1 is roughly composed of a light source 9, this light guide plate 2 and a case 10. In the light guide plate 2, ends of side surface parts 4 adjacent to each other are formed into an incident end surface part 3; concentrically recessed ridges 7 being ridges concentrically recessed and concentrically projecting ridges being ridges each having a concentrically projecting shape are formed, by centering the center position of the incident end surface part 3, on a surface part 5 opposite to an emission surface; and recessed ridges and projecting ridges 8 are formed on the emission surface part 6 in parallel with the incident end surface part 3. The case 10 covers areas other than the light emission surface of the light source 9, the incident end surface part 3 and the emission end surface part 6 and reflects leakage light and the like without being emitted from the light source 9 and the emission surface part 6 to enter them into the light guide plate again. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention provides a concentric concave ridge or a concentric convex ridge concentrically around the center position of the incident end face portion of the light source or the light guide plate on the non-emission surface portion, and an arbitrary corresponding to the concentric ridge from the incident end face portion. All the light emitted from the light source is deflected (reflected) toward the exit surface portion at the opposite exit surface portion so that the light energy travels (reflects) equally at the distance of Uniform and bright outgoing light with no unevenness in brightness on the exit surface by providing concave or convex ridges on the exit surface parallel to the entrance end surface so that the light traveling from the surface exits with a spread. The present invention relates to a light guide plate capable of obtaining the above and a flat illumination device using the light guide plate and the like.

  As a conventional flat illumination device, a reflective member is provided on the front surface portion and the back surface portion of the light guide plate, and a cutout portion that is a band-like slit is provided on either one, and the smaller the cutout portion is closer to the light source, the light source is a dot-like shape. In some cases, an arc-shaped slit centering on the light emitting part of the point light source is provided so that the distance between the slits becomes narrower as the distance from the light source increases.

  Moreover, the conventional flat illumination device has a diffusion member on the front surface side of the light guide plate, a reflection member on the back surface side, and a cross section V having a predetermined length on the reflection surface (back surface) of the light guide plate. The V-shaped grooves are arranged in a row parallel to the light source and spaced apart from each other by a predetermined distance, and the adjacent rows of the V-shaped grooves are alternately arranged in a staggered manner, with the spacing being increased as the distance from the light source increases. Some are also arranged so that they gradually become smaller.

  Furthermore, as a conventional light guide plate, a large number of V-groove recesses that are reflected and refracted on the entire front and back surfaces are provided intermittently in a staggered or arcuate manner parallel to the incident direction, and between the recesses along the light traveling direction. There is known a structure in which a gap is provided in the gap so that the interval gradually decreases as the distance from the light source increases.

Further, as a conventional flat illumination device, at least one substantially point-shaped primary light source, a light incident surface on which light emitted from the primary light source is incident, and a light output surface on which incident light is guided and emitted A surface light source system is constituted by a light guide body having a light source and a light deflection element that controls the direction of light emitted from the light guide body, and the primary light source is disposed at a corner portion or an end face of the light guide body. There are also known those in which a large number of lens rows are arranged in parallel in a substantially arc shape so as to surround the primary light source on at least one side of the lens.
JP 62-109003 A Japanese Patent Laid-Open No. 5-216030 JP-A-8-286037 JP 2002-245823 A

The above-described conventional flat illumination device is provided with a reflective member on the front surface portion and the back surface portion of the light guide plate, and provided with a notch portion that is a strip-shaped slit on one of them, and by making the notch portion closer to the light source, the light source is reduced. The amount of light leaking from the slit is controlled as it is closer to, so that the entire light is emitted uniformly. However, since the emitted light has a slit shape, it looks bad. In particular, since the slit is small in the vicinity of the light source, it appears as a bright line, and there is a problem that the light is close to the light source and the energy of the light is large, resulting in a stronger bright line.
In addition, when the light source is point-like, an arc-shaped slit centering on the light emitting part of the point light source is provided so that the gap between the slits becomes narrower as the distance from the light source becomes larger. There is a problem that arc-like bright lines appear.

Further, as a conventional flat illumination device, the light guide plate has a diffusion portion on the front surface side, a reflection member on the back surface side, and a reflection surface (back surface) of the light guide plate having a predetermined length on the V shape. The V-shaped grooves are arranged in a row parallel to the light source and spaced apart from each other by a predetermined distance. Adjacent rows of the V-shaped grooves are alternately arranged in a staggered pattern, and the distance gradually increases as the distance from the light source increases. In a configuration in which the light guide plate is arranged so as to be smaller, light incident on the light guide plate is reflected by the inclined surface of the V-shaped groove with respect to the traveling direction and deflected to the surface side. For this reason, since particularly strong emitted light is always emitted parallel to the light source, there is a problem that, for example, the luminance of the emitted light is lowered at both ends of the light source.
In particular, when the light source is a point light source, the luminance distribution is often not uniform depending on the position from the light source.

  In addition, as a conventional light guide plate, a large number of V-groove recesses that are reflected and refracted on the entire front and back surfaces are provided in a staggered or arcuate manner in parallel with the incident direction, and between the recesses along the light traveling direction. In a configuration in which a gap is provided so that the interval gradually decreases as the distance from the light source increases, there is a problem that a large light guide plate is blocked by the depression even if the interval is gradually decreased as the distance from the light source increases.

  In addition, a large number of V-groove dents are provided intermittently in an arc shape with respect to the incident direction on the entire front and back surfaces, and the distribution is uniform even when the central portion of the cathode ray tube is strong and weak at the peripheral portion. However, in order to reflect the light from the central part of the cathode ray tube, it has an arc shape, and the parallel light from the cathode ray tube cannot be used. For this reason, the light from the central portion of the cathode ray tube can only be used from the oblique direction, has lower energy than the parallel light from the cathode ray tube, and the emission position (shape) of the reflected light is different (as a whole). There is a problem with the luminance distribution emitted from the surface.

  Further, as a conventional flat illumination device, at least one substantially point-shaped primary light source, a light incident surface on which light emitted from the primary light source is incident, and a light output surface on which incident light is guided and emitted A surface light source system comprising a light guide having a light source and a light deflection element for controlling the direction of light emitted from the light guide, wherein the primary light source is disposed at a corner or an end face of the light guide, In the case where a large number of lens arrays are arranged in parallel in a substantially arc shape so as to surround the primary light source on at least one side, firstly, the light of the primary light source is completely emitted from the light guide from the light incident surface. There is no means. Secondly, since all the light from the back surface is positively raised upward by the light deflecting element, there is a problem that the emitted light does not spread and becomes a narrow viewing angle as well as luminance spots.

(Object of invention)
As described above, in the conventional configuration, since the light reflected from the light source is reflected directly from the front surface portion, the position and the amount of light reflected by the back surface portion are directly applied to the front surface portion (exit surface portion). Since this is reflected, there are problems in luminance spots, viewing angles, and the like. Therefore, the light guide plate of the present invention is provided with concentric concave ridges and concentric convex ridges concentrically around the center position of the light source and the incident end surface portion, and corresponds to the concentric ridges from the incident end surface portion. The light energy from the light source is deflected (reflected) in the direction of the exit surface portion at the opposite exit surface portion without waste so that the light energy is equally traveled (reflected) toward the exit surface portion at an arbitrary distance. By providing a concave or convex ridge parallel to the incident end surface portion on the exit surface portion so that the light traveling from the non-emission surface portion spreads out to the outside, there is no brightness unevenness at the exit surface portion of the light guide plate. A light guide plate capable of obtaining bright emission light, a flat illumination device using this light guide plate, and the like, and based on the theory of the present invention, the light guide plate is incident above the output surface portion of the light guide plate having the opposite exit surface portion as described above. Concave or convex ridges parallel to the end face It is to provide a flat lighting device including a Hikari Keta deflector.

  The light guide plate according to claim 1 of the present invention has at least one adjacent side surface portion or at least one side surface portion as an incident end surface portion, and a concentrically concave ridge centered on the center position of the incident end surface portion. A concentric concave ridge or / and a concentric convex ridge that is a concentrically convex ridge are provided on the non-emission surface portion, and a concave ridge or / and a convex ridge are provided on the emission surface portion in parallel to the incident end surface portion. It is characterized by.

  The light guide plate according to claim 1 has at least one adjacent side surface portion or at least one side surface as an incident end surface portion, and is a concentric shape that is a concentric concave ridge centering on the center position of the incident end surface portion. Concentric convex ridges, which are concave ridges and / or concentrically convex ridges, are provided on the anti-emission surface portion, and concave ridges or / and convex ridges are provided on the emission surface portion in parallel to the incident end surface portion, so that anti-emission On the surface, the light corresponding to the concentric ridges from the incident end surface part is emitted parallel to the radiating surface part, and the light traveling from the non-emission surface part is emitted to the outside at the emission surface part.

  The light guide plate according to claim 2 is concentrically concave with the end portion of at least one adjacent side surface portion or at least one side surface portion as an incident end surface portion, and the center position of the incident end surface portion as the center. And a concentric convex ridge that is a concentrically convex ridge and a mirror surface or a plurality of micro light deflecting elements.

  The light guide plate according to claim 2 has at least one adjacent side surface portion or at least one side surface portion as an incident end surface portion, and a counter-exit surface portion that is concentrically concave with the center position of the incident end surface portion as a center. Concentric concave ridges and / or concentric convex ridges that are concentrically convex and a mirror surface or a plurality of micro light deflecting elements are provided on the exit surface, so that concentric ridges can be accommodated from the incident end surface The light energy travels in the direction of the exit surface portion at an arbitrary distance, and the light corresponding to the concentric ridges travels from the opposite exit surface portion at the exit surface portion because of the minute light deflection element on the exit surface portion. The incoming light can be refracted in a desired direction or controlled such as condensing, so that the light from the entire emission surface can be collected or emitted to the outside with a spread.

  Furthermore, the light guide plate according to claim 3 is characterized in that concentric concave ridges and concentric convex ridges are provided continuously or discontinuously on one concentric circle.

  In the light guide plate according to claim 3, the concentric concave ridges and the concentric convex ridges are provided continuously or discontinuously on one concentric circle, so that (reflected) light traveling in the direction of the emission surface portion is spread over the entire emission surface portion. In addition, it is possible to partially advance (reflect) to the position of the target exit surface.

  Further, in the light guide plate according to claim 4, the concentric concave ridge and the concentric convex ridge have an apex angle of 45 ° to 179 °, and have an inclined surface in the direction of the incident end surface portion, and are parallel to the anti-exit surface portion. The angle formed with the virtual horizontal plane is 0.1 ° to 67.5 °.

In the light guide plate according to claim 4, the concentric concave ridge and the concentric convex ridge have a vertex angle of 45 ° to 179 ° and have an inclined surface in the direction of the incident end surface portion and are parallel to the anti-exit surface portion. Is from 0.1 ° to 67.5 °, the range of light incident from the incident end face is light as indicated by Sin ⁻¹ (1 / n) (where n is the refractive index). Can be reflected in the direction of the exit surface. Moreover, the pitch between ridges can be changed with the change in the angle of concentric ridges.

  Furthermore, the light guide plate according to claim 5 is characterized in that the inclined surface is such that the straight line from the center position of the incident end surface portion and the normal of the inclined surface coincide with each other at one point.

  In the light guide plate according to claim 5, since the inclined surface has a straight line from the center position of the incident end face portion and the normal of the inclined surface always coincides with each other, the size and shape of the inclined surface can be controlled. it can.

  The light guide plate according to claim 6 is characterized in that the concave ridge and the convex ridge are provided continuously or discontinuously.

  In the light guide plate according to the sixth aspect, the concave ridge and the convex ridge are provided continuously or discontinuously, so that all of the reflected light from the anti-incident surface portion is emitted to the outside with a spread, or the reflected light A part of the light can be emitted outside.

Furthermore, the flat illumination device according to claim 7 includes a light source,
An end of at least one adjacent side surface or at least one side surface is an incident end surface, and a concentric concave ridge or / and a concentrically convex concentrically concave ridge centered on the center position of the incident end surface. And a light guide plate provided with a concave ridge or / and a convex ridge on the exit surface portion in parallel with the incident end surface portion. .

The flat illumination device according to claim 7 includes a light source,
An end of at least one adjacent side surface or at least one side surface is an incident end surface, and a concentric concave ridge or / and a concentrically convex concentrically concave ridge centered on the center position of the incident end surface. A concentric convex ridge that is a ridge-shaped ridge is provided on the anti-emission surface portion and at least a light guide plate having a concave ridge or / and a convex ridge provided on the emission surface portion in parallel with the incident end surface portion. , The light energy travels equally in the direction of the exit surface at an arbitrary distance corresponding to the concentric ridge from the light source or the incident end surface, and the light corresponding to the concentric ridge is parallel ridges on the exit surface. Therefore, in the emission surface portion, the light traveling from the opposite emission surface portion is emitted to the outside with a spread.

Moreover, the flat illumination device according to claim 8 includes a light source,
An end of at least one adjacent side surface or at least one side surface is an incident end surface, and a concentric concave ridge or / and a concentrically convex concentrically concave ridge centered on the center position of the incident end surface. A light guide plate in which concentric convex ridges that are shaped ridges are provided on the anti-light-emitting surface portion and the light-emitting surface portion is provided with a plurality of minute light deflection elements on the mirror surface or the light-emitting surface portion;
An optical deflector provided with at least a concave ridge or / and a convex ridge parallel to the incident end surface portion of the light guide plate on the output surface portion of the light guide plate.

The flat illumination device according to claim 8 comprises a light source,
An end of at least one adjacent side surface or at least one side surface is an incident end surface, and a concentric concave ridge or / and a concentrically convex concentrically concave ridge centered on the center position of the incident end surface. A light guide plate in which concentric convex ridges that are shaped ridges are provided on the anti-light-emitting surface portion and the light-emitting surface portion is provided with a plurality of minute light deflection elements on the mirror surface or the light-emitting surface portion;
Since the light deflector provided with a concave ridge or / and a convex ridge parallel to the incident end surface portion of the light guide plate on the output surface portion of the light guide plate, at least a concentric ridge from the light source or the incident end surface portion The light energy travels equally in the direction of the exit surface at an arbitrary distance corresponding to the light, and the light corresponding to the concentric ridges from the counter-exit surface at the exit surface due to the minute light deflection element at the exit surface. The light that has traveled can be refracted in a desired direction or controlled to be condensed, and the light from the entire emission surface can be emitted outside by a light deflector on the emission surface. .

  Furthermore, the planar illumination device according to claim 9 is characterized in that the light deflector is provided with a concave ridge and a convex ridge continuously or discontinuously.

  In the planar illumination device according to claim 9, since the light deflector is provided with concave ridges and convex ridges continuously or discontinuously, all the emitted light from the light guide plate is emitted outside with a spread, A part of the emitted light can be emitted to the outside with a spread.

  The planar illumination device according to claim 10 is characterized in that the light source is provided so as to be centered on the same line as the center position of the incident end face portion.

  In the flat illumination device according to the tenth aspect, the light source is provided so as to be centered on the same line as the center position of the incident end surface portion. The light energy can travel in the direction of the exit surface at the same distance.

  Furthermore, in the flat illumination device according to claim 11, the light source is a semiconductor light emitting device or monochromatic light emitting semiconductor light emitting device or monochromatic light emitting device comprising an integrated red light emission (R), green light emission (G), and blue light emission (B). Alternatively, R, G, and B are arrayed or CCFL (cold cathode fluorescent discharge tube) or HCFL (hot cathode fluorescent discharge tube).

  In the flat illumination device according to claim 11, the light source is a semiconductor light emitting element or monochromatic light emitting semiconductor light emitting element or monochromatic light emitting element or R light emitting element composed of integrated red light emission (R), green light emission (G), and blue light emission (B). , G, and B are in the form of an array, CCFL (cold cathode fluorescent discharge tube) or HCFL (hot cathode fluorescent discharge tube), it is possible to select a color of emitted light that suits the purpose.

  As described above, the light guide plate according to claim 1 has at least one adjacent side surface portion or at least one side surface portion as the incident end surface portion, and is concentrically concave with the center position of the incident end surface portion as the center. Concentric concave ridges that are ridges and / or concentric convex ridges that are concentrically convex ridges are provided on the anti-emission surface portion, and concave ridges and / or convex ridges that are parallel to the incident end surface portion on the emission surface portion Since the light corresponding to the concentric ridge from the incident end surface portion is parallel to the radiating surface portion on the opposite exit surface portion, the light traveling from the opposite exit surface portion spreads widely on the exit surface portion. To exit. Therefore, uniform and bright outgoing light without luminance spots can be obtained.

  The light guide plate according to claim 2 is concentrically concave with the end portion of at least one adjacent side surface portion or at least one side surface portion as an incident end surface portion, and the center position of the incident end surface portion as the center. Concentric concave ridges that are ridges and / or concentric convex ridges that are concentrically convex ridges and a mirror surface or a plurality of micro light deflecting elements are provided on the exit surface, so that concentric ridges are formed from the incident end surface. The light energy travels equally in the direction of the exit surface at an arbitrary distance corresponding to the light, and the light corresponding to the concentric ridges from the counter-exit surface at the exit surface due to the minute light deflection element at the exit surface. The light that has traveled can be refracted in a desired direction or controlled such as condensing, so that the light from the entire exit surface can be gathered or emitted to the outside with a spread. Therefore, the emitted light from the emission surface portion can be emitted according to the purpose.

  Furthermore, the light guide plate according to claim 3 is provided with concentric concave ridges and concentric convex ridges continuously or discontinuously on one concentric circle, so that (reflected) light traveling in the direction of the emission surface portion is distributed over the entire emission surface portion. In addition to being able to do this, it is possible to partially advance (reflect) to the position of the target exit surface. Therefore, for example, in a place near the light source position or in a place where the luminance from the light source is high, the concentric concave ridges and the concentric convex ridges are provided discontinuously, and in others, they are provided continuously so as to proceed uniformly with respect to the exit surface portion direction. (Reflect).

Further, in the light guide plate according to claim 4, the concentric concave ridge and the concentric convex ridge have an apex angle of 45 ° to 179 °, and have an inclined surface in the direction of the incident end surface portion, and are parallel to the anti-exit surface portion. Since the angle formed with the imaginary horizontal plane is 0.1 ° to 67.5 °, the range of light incident from the incident end face is expressed by Sin ⁻¹ (1 / n) (where n is the refractive index). Light can be reflected in the direction of the exit surface. Moreover, the pitch between ridges can be changed with the change in the angle of concentric ridges. For this purpose, uniform light is emitted to the light exit surface by controlling the apex angle and the angle formed with the virtual horizontal surface corresponding to the energy (luminance) of light incident within the range of Sin ⁻¹ (1 / n) from the light incident end surface. Can be reflected.

  Furthermore, in the light guide plate according to claim 5, since the inclined surface has a straight line from the center position of the incident end face portion and the normal of the inclined surface always coincides with each other, the size and shape of the inclined surface are controlled. be able to. Therefore, all of the light incident from the incident end surface portion can be reflected in the direction of the exit surface portion.

  Further, in the light guide plate according to claim 6, since the concave ridge and the convex ridge are provided continuously or discontinuously, all of the reflected light from the non-incident surface part is emitted outside or reflected A part of the light can be emitted to the outside with a spread. Therefore, it is possible to control how light spreads on the exit surface, and to control the viewing angle and the like.

Furthermore, the flat illumination device according to claim 7 includes a light source,
An end of at least one adjacent side surface or at least one side surface is an incident end surface, and a concentric concave ridge or / and a concentrically convex concentrically concave ridge centered on the center position of the incident end surface. A concentric convex ridge that is a ridge-shaped ridge is provided on the anti-emission surface portion and at least a light guide plate having a concave ridge or / and a convex ridge provided on the emission surface portion in parallel with the incident end surface portion. , The light energy travels equally in the direction of the exit surface at an arbitrary distance corresponding to the concentric ridge from the light source or the incident end surface, and the light corresponding to the concentric ridge is parallel ridges on the exit surface. Therefore, in the emission surface portion, the light traveling from the opposite emission surface portion is emitted to the outside with a spread. Therefore, uniform and bright outgoing light without luminance spots can be obtained.

Moreover, the flat illumination device according to claim 8 includes a light source,
An end of at least one adjacent side surface or at least one side surface is an incident end surface, and a concentric concave ridge or / and a concentrically convex concentrically concave ridge centered on the center position of the incident end surface. A light guide plate in which concentric convex ridges that are shaped ridges are provided on the anti-light-emitting surface portion and the light-emitting surface portion is provided with a plurality of minute light deflection elements on the mirror surface or the light-emitting surface portion;
Since the light deflector provided with a concave ridge or / and a convex ridge parallel to the incident end surface portion of the light guide plate on the output surface portion of the light guide plate, at least a concentric ridge from the light source or the incident end surface portion The light energy travels equally in the direction of the exit surface at an arbitrary distance corresponding to the light, and the light corresponding to the concentric ridges from the counter-exit surface at the exit surface due to the minute light deflection element at the exit surface. The light that has traveled can be refracted in a desired direction or controlled to be condensed, and the light from the entire emission surface can be emitted outside by a light deflector on the emission surface. . Therefore, uniform and bright outgoing light without luminance spots can be obtained.

  Further, in the planar illumination device according to claim 9, since the light deflector is provided with the concave ridge and the convex ridge continuously or discontinuously, all the light emitted from the light guide plate is emitted to the outside with a spread. Or part of the emitted light can be emitted to the outside with a spread. Therefore, it is possible to control how the outgoing light from the flat illumination device spreads and to control the viewing angle and the like.

  Further, in the planar illumination device according to claim 10, since the light source is provided so as to be centered on the same line as the center position of the incident end surface portion, the light emitting plate corresponds to a concentric ridge from the incident end surface portion on the opposite exit surface portion. The light energy can travel in the direction of the exit surface portion at an arbitrary distance. Therefore, a sufficient function can be exhibited with respect to a ridge parallel to the incident end surface provided on the exit surface, a minute light deflection element provided on the exit surface, an optical deflector provided above the exit surface, and the like.

  Furthermore, in the flat illumination device according to claim 11, the light source is a semiconductor light emitting device or monochromatic light emitting semiconductor light emitting device or monochromatic light emitting device comprising an integrated red light emission (R), green light emission (G), and blue light emission (B). Alternatively, since R, G, and B are in the form of an array, CCFL (cold cathode fluorescent discharge tube), or HCFL (hot cathode fluorescent discharge tube), it is possible to select an emitted light color that suits the purpose. Therefore, it can respond to all purposes such as the size, emission luminance, color, monochrome, power consumption, price, etc. of the flat illumination device.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.
In the present invention, the end portion or one side surface portion of the adjacent side surface portion is used as the incident end surface portion, and the concentric concave ridge or the concentric convex ridge is provided concentrically with the center position of the incident end surface portion as the center on the opposite emission surface portion. Furthermore, a concave or convex ridge is provided on the exit surface portion in parallel to the entrance end surface portion so that the ridges provided on the opposite exit surface portion and the exit surface portion do not become symmetrical, and the light from the light source is reflected back. At the surface portion, the light energy advances in the direction of the exit surface portion (reflected) at an arbitrary distance corresponding to the concentric ridge from the light source or the incident end surface portion, and proceeds from the non-emission surface portion at the exit surface portion. It is intended to provide a light guide plate and a flat illumination device capable of obtaining a uniform and bright outgoing light having no brightness spots by emitting the emitted light to the outside with a spread.

  In the same manner as described above, concentric concentric concave ridges or concentric convex ridges are provided concentrically around the center position of the incident end surface portion on the opposite exit surface portion, and concave or convex ridges are provided parallel to the incident end surface portion. The light deflector is provided above the light exit surface, and the ridges provided on the light exit surface and the light deflector are not symmetrical. At an arbitrary distance corresponding to the edge of the light, the light energy travels equally (reflects) toward the exit surface, and the light deflector emits the light traveling from the opposite exit surface to the outside with a spread. Thus, a light guide plate and a flat illumination device capable of obtaining uniform and bright outgoing light free from luminance spots are provided.

  1 to 4 are schematic perspective views of a flat illumination device according to the present invention, FIGS. 5 and 6 are schematic front views of the back side of the light guide plate according to the present invention, and FIGS. 7 to 10 are diagrams of the light guide plate according to the present invention. FIG. 11 and FIG. 12 are three-dimensional light locus diagrams of the flat illumination device according to the present invention.

  A flat illumination device 1 shown in FIG. 1 includes a light guide plate 2, a light source 9, and a case 10.

  The light guide plate 2 is formed of a transparent acrylic resin (PMMA) or polycarbonate (PC) having a refractive index of about 1.4 to 1.7. As shown in FIG. 1, the light guide plate 2 is positioned on the opposite side of the exit surface portion 6, the incident end surface portion 3 that guides light from the light source 9, the exit surface portion 6 that emits light from the incident end surface portion 3. The light emitting surface portion 5 and the side surface portion 4 intersecting the light emitting surface portion 6 and the light emitting surface portion 5 are formed. The light guide plate 2 has the end portions of the adjacent side surface portions 4 as the incident end surface portions 3, and the concentric concave ridges 7 that are concentrically concave ridges around the center position of the incident end surface portion 3 or the concentrically convex shapes. Concentric convex ridges 7 b, which are ridges, are provided on the non-emission surface portion 5. Furthermore, the exit surface portion 6 is provided with a plurality of concave ridges and convex ridges parallel to the incident end surface portion 3. Further, the light source 9 is provided so that the emission surface faces the center position of the incident end surface portion 3.

3 is substantially the same as that shown in FIG. 1, but the positions of the incident end face 3 of the light guide plate 2c and the light source 9 are different. As shown in FIG. 3, the light guide plate 2 c includes an exit surface portion 6 that emits light, a counter-exit surface portion 5 that is located on the opposite side of the exit surface portion 6, and a side surface that intersects the exit surface portion 6 and the counter-exit surface portion 5. Part 4. In the light guide plate 2 c, at least one side surface 4 (the short side surface portion 4 on the near side of the four side surface portions 4 in the example of FIG. 3) is used as the incident end surface portion 3 that guides light from the light source 9. Concentric concave ridges 7 that are concentrically concave ridges and concentric convex ridges 7b that are concentrically convex ridges are provided on the anti-light-emitting surface portion 5.
Here, the number of the light sources 9 is one, and the light exit surface is provided so as to face the center position of the incident end surface portion 3, but it may be provided in the vicinity of the incident end surface portion 3 (one side surface portion 4).
Further, the exit surface portion 6 is provided with a plurality of concave ridges and convex ridges parallel to the incident end surface portion 3 (one side surface portion 4 on the light source 9 side).

In the light guide plates 2 and 2c configured as described above, the light incident on the light guide plates 2 and 2c is within the range where the refractive index γ satisfies 0 ≦ | γ | ≦ Sin ⁻¹ (1 / n). , 2c. For example, since the refractive index of acrylic resin, which is a resin material used for general light guide plates 2 and 2 c, is about n = 1.49, the direction from the exit surface portion 6 of the incident end surface portion 3 to the opposite exit surface portion 5 direction. The light and the light from the counter-exiting surface portion 5 direction to the emitting surface portion 6 direction have a maximum incident angle of 90 °. The refraction angle γ refracted at the incident end face 3 is in the range of γ = 0 to ± 42 ° and propagates from the incident end face 3 through the light guide plates 2 and 2c.
Note that only γ = −42 ° only in the direction of the counter-exit surface 5 in the vicinity of the exit surface 6 and only γ = + 42 ° only in the direction of the output surface 6 in the vicinity of the counter-exit surface 5.

Further, the light incident on the light guide plates 2 and 2c within the range of the refraction angle γ = 0 to ± 42 ° is Sin α = at the boundary surface between the light guide plates 2 and 2c and the air layer (refractive index n = 1). The critical angle can be expressed by (1 / n). For example, since the refractive index of acrylic resin, which is a resin material used for general light guide plates 2 and 2c, is about n = 1.49, the critical angle α is about α = 42 °. For this reason, if the exit surface 6 and the opposite exit surface 5 of the light guide plate 2.2c have no projections or depressions for deflecting light rays or do not exceed the critical angle α, the light in the light guide plates 2 and 2c is emitted from the exit surface 6. In other words, the light travels in the opposite direction of the incident end face part 3 while being totally reflected by the counter outgoing face part 5.
However, in the above case, the thickness of the light guide plates 2 and 2c is uniform and flat. In the case of a wedge-shaped light guide plate, the critical angle α is broken by the wedge-shaped taper (degree of inclination), and a taper leak is generated. cause.

As shown in FIG. 5, the counter-exiting surface portion 5 is provided with concentric concave ridges 7 that are concentric concave ridges around the center position of the incident end surface portion 3.
Although not shown in FIGS. 1 and 3, the anti-light-emitting surface portion 5 has a concentric convex ridge 7b that is a concentric convex ridge centered on the center position of the incident end surface portion 3, as shown in FIG. May be provided.
Furthermore, these concentric concave ridges 7 and concentric convex ridges 7b may be provided alternately.

  1, 2, and 5, the incident end surface portion 3 is provided at the end portion of the adjacent side surface portion 4, and the concentric concave ridge 7 and the concentric convex ridge 7 b are provided on the non-emission surface portion 5. 3, 4, and 6, the incident end surface portion 3 is provided on one side surface portion 4, and the concentric concave ridge 7 and the concentric convex ridge 7 b are provided on the non-emission surface portion 5. It is.

5A and 5B show concentric concave ridges 7 that are concentrically concave ridges and concentric convex ridges 7b that are concentrically convex ridges with the center position of the incident end face 3 as the center. FIG. In the example of FIG. 5A, the incident end surface portion 3 is provided so as to have the same angle with respect to two adjacent side surface portions 4 (the side surface portion in the short direction and the side surface portion in the longitudinal direction). Further, in the example of FIG. 5B, one end portion is provided as the incident end surface portion 3 so as to be perpendicular to the diagonal line with reference to the diagonal line of the two end portions located diagonally.
Needless to say, the incident end face portions 3 coincide with the normal lines of the concentric concave ridge 7 and the concentric convex ridge 7b, and therefore FIG. 5A and FIG. ) Intersects with the line h shown at right angle.

Moreover, as shown in FIG. 8, each concentric concave ridge 7 can be provided continuously (FIG. 8 (a)) or discontinuously (FIG. 8 (b)) on one concentric circle.
In addition, although demonstrated here with the concentric concave ridge 7, since it is the same also with the concentric convex ridge 7b, description is abbreviate | omitted here.

  In this way, by providing the concentric concave ridges 7 and the concentric convex ridges 7b continuously or discontinuously on one concentric circle, the light traveling (reflecting) in the direction of the exit surface 6 can be spread over the entire exit surface 6. In addition to being able to do so, it is possible to partially advance (reflect) to the target position of the exit surface 6.

  Therefore, for example, in a place near the position of the light source 9 or in a place where the luminance from the light source 9 is high, the concentric concave ridge 7 or the concentric convex ridge 7b is provided discontinuously on one concentric circle, and on the other one on the concentric circle. By providing them continuously, the light can travel uniformly (reflect) in the direction of the exit surface 6, and the final exit light can be controlled by controlling the amount of reflected light reflected from the counter exit surface 5 toward the exit surface 6. Can be adjusted.

Further, FIG. 10 shows an example of the concentric concave ridge 7, but the concentric concave ridge 7 or the concentric convex ridge 7b has an angle θ of the ridge or apex of the concentric concave ridge 7 or the concentric convex ridge 7b. It is 45 ° to 179 °. Moreover, it has the inclined surface 7c in the incident end surface part 3 direction, and the angle (phi) which the virtual horizontal surface F parallel to the counter-light-emitting surface part 5 shown in FIG. 10 parallel is 0.1 degrees-67.5 degrees.
Further, the pitch between the ridges can be changed in accordance with the change in the angle θ of the concentric ridges within the above range.

Therefore, uniform light can be obtained by controlling the apex angle θ and the angle φ formed with the virtual horizontal plane corresponding to the energy (luminance) of the light incident from the incident end face portion 3 in the range of Sin ⁻¹ (1 / n). The light can be reflected in the direction of the exit surface 6.

  Furthermore, although not shown here, as described above, when the light source 9 is provided on the center line with the center position of the incident end face portion 3 as the center, the inclined surface 7c is the center of the incident end face portion 3. The straight line from the position always coincides with the normal of the inclined surface 7c.

Further, when a plurality of light sources 9 are used without the light source 9 on the center line with the center position of the incident end surface portion 3 as the center, for example, when a plurality of light sources 9 are provided in the vicinity of the incident end surface portion 3, the inclined surface 7c. However, the straight line from the center position of the incident end face part 3 and the normal line of the inclined surface 7c coincide at one point.
Therefore, by controlling the size and shape of these inclined surfaces 7c, all of the light incident from the incident end surface portion 3 can be reflected in the direction of the exit surface portion 6.

Further, as shown in FIGS. 7 and 9, the inclined surface 7c of the concentric concave ridge 7 or the concentric convex ridge 7b has a flat, curved, or arcuate shape, a concave shape, and a ridge that is not flat. It can be formed in a cut shape.
FIG. 7A shows a concentric concave ridge 7 having a straight inclined surface 7c, and FIG. 9A shows a concentric convex ridge 7b having a straight inclined surface 7c.

  FIG. 7B shows a concentric concave ridge 7 in which the inclined surface 7c is a straight line, but the ridge portion is cut out flat. Thereby, light with a small amount of refraction from the incident end face part 3 can be advanced to a place far from the incident end face part 3 without being blocked by the ridge.

  FIG. 9B shows a concentric convex ridge 7b in which the inclined surface 7c is a straight line, but the ridge is notched flat. As a result, light having a large amount of refraction from the incident end face portion 3 is emitted to the outside. For example, when a reflector is present below the light guide plates 2 and 2c, the light exits the light guide plates 2 and 2c again at the same angle as the emission angle. Can be reflected (incident).

  FIG. 7 (c) shows a concentric concave ridge 7 in which the inclined surface 7c is recessed in a curved line or a circular arc shape, and the concentric concave ridge 7 reflects at a narrow range of angles.

  FIG. 9 (c) shows a concentric convex ridge 7b in which the inclined surface 7c is recessed in a curved line or arc shape, and the concentric convex ridge 7b reflects at a wide range of angles.

  FIG. 7D shows a concentric concave ridge 7 in which the inclined surface 7 c swells in a curved or arc shape, and the concentric concave ridge 7 reflects at a wide range of angles.

  FIG. 9D shows a concentric convex ridge 7b in which the inclined surface 7c swells in a curved or arc shape, and the concentric convex ridge 7b reflects at a narrow range of angles.

Further, as shown in FIGS. 1 and 3, a plurality of convex ridges 8 are provided on the exit surface portion 6 of the light guide plate 2 in parallel to the incident end surface portion 3.
That is, in the example of FIG. 1, a plurality of convex ridges 8 are provided on the exit surface portion 6 in parallel to the incident end surface portion 3 provided at the ends of the two adjacent side surface portions 4. Further, in the example of FIG. 3, a plurality of convex ridges 8 are provided on the exit surface portion 6 in parallel to the incident end surface portion 3 which is one side surface portion 4.

Further, although the convex ridge 8 is shown in FIGS. 1 and 3, a concave ridge (not shown) may be used instead of the convex ridge 8.
Furthermore, these convex ridges 8 and concave ridges may be provided alternately.

1 and 3, the convex ridges are provided continuously, but the concave ridges and the convex ridges may be provided continuously or discontinuously.
Further, the concave ridges and the convex ridges 8 may be provided continuously in a direction away from the position of the incident end face part 3 or may be provided independently on the outgoing face part 6.

  In this way, by providing a concave ridge or a convex ridge on the emission surface portion 6, all of the reflected light from the anti-emission surface portion 5 is emitted to the outside with a spread, or a part of the reflected light is spread. It can be emitted to the outside. As a result, it is possible to control how the light spreads on the exit surface 6 and to control the viewing angle and the like.

  Here, as shown in FIG. 11, incident light L0 obtained by taking the light from these light sources 9 into the light guide plates 2 and 2c at the incident end face 3 is microscopically like light rays L1, L2, and L3. The azimuth angle is slightly different, and the process proceeds to the concentric concave ridge 7 provided on the anti-light-emitting surface portion 5. These light rays L1, L2, L3 are reflected in the direction of the exit surface 6 by the inclined surface 7c of the concentric concave ridge 7. At this time, since the concentric concave ridge 7 is an arc in the direction of the side surface portion 4, the reflected light Lr 1, Lr 2, Lr 3 having different reflection positions travels in the direction of the exit surface portion 6. Then, the reflected lights Lr 1, Lr 2, Lr 3 are refracted by the convex ridge 8 provided on the exit surface 6. At this time, since the reflected light Lr1, Lr2, and Lr3 are different in reflection position, the positions reaching the convex ridge 8 are different, and are emitted with different emission angles.

  Here, the reflected light Lr1 and the reflected light Lr2 are emitted from the front prism surface of the convex ridge 8 to become the emitted light Lr01 and the emitted light Lr02, and the reflected light Lr3 is emitted from the rear prism surface of the convex ridge 8. The emitted light Lr03 is emitted to the outside.

  Next, the flat illumination device 1b shown in FIG. 2 is roughly configured by a light source 9, a light guide plate 2b, a light deflector 8c, and a case 10. The light guide plate 2b includes an incident end surface portion 3 that guides light from the light source 9, an exit surface portion 6 that emits light from the incident end surface portion 3, a counter-exit surface portion 5 that is located on the opposite side of the exit surface portion 6, and these It consists of a side surface portion 4 that intersects the exit surface portion 6 and the opposite exit surface portion 5. And the edge part of the adjacent side surface part 4 is made into the incident end surface part 3, and it is the concentric concave ridge 7 which is a concentric concave ridge centering on the center position of the incident end surface part 3, and the concentric convex ridge. Concentric convex ridges 7 b are provided on the anti-light-emitting surface portion 5. Further, the exit surface portion 6 is a mirror surface, or a plurality of minute light deflection elements 8b are provided on the exit surface portion 6 as shown in FIG. Further, the light source 9 is provided so that the emission surface faces the center position of the incident end surface portion 3.

Furthermore, the light deflector 8c is provided on the exit surface portion 6 of the light guide plate 2b, and is provided with a concave ridge 8d or a convex ridge parallel to the incident end surface portion 3 of the light guide plate 2b.
The light deflector 8c is provided with an incident end face direction portion 8e at a position corresponding to the incident end face portion 3 of the light guide plate 2b. Then, the light deflector 8c is positioned so as to correspond to the reflected light from the counter-emitting surface portion 5 of the light guide plate 2b.

4 is substantially the same as that shown in FIG. 2, but the positions of the incident end face 3 and the light source 9 are different. As shown in FIG. 4, the light guide plate 2 d includes an exit surface portion 6 that emits light, a counter-exit surface portion 5 that is located on the opposite side of the exit surface portion 6, and a side surface that intersects the exit surface portion 6 and the counter-exit surface portion 5. Part 4. In the light guide plate 2d, at least one side surface portion 4 (the short side surface portion 4 on the near side of the four side surface portions 4 in the example of FIG. 4) serves as an incident end surface portion 3 that guides light from the light source 9, and the incident end surface portion. Concentric concave ridges 7 that are concentrically concave ridges and concentric convex ridges 7 b that are concentrically convex ridges are provided on the anti-light-emitting surface portion 5.
Here, the number of the light sources 9 is one, and the light exit surface is provided so as to face the center position of the incident end surface portion 3, but it may be provided in the vicinity of the incident end surface portion 3 (one side surface portion 4).
Further, the exit surface portion 6 is a mirror surface, or a plurality of minute light deflection elements 8b are provided on the exit surface portion 6 as shown in FIG.
Further, the light deflector 8c is provided on the light exit surface 6 of the light guide plate 2d, and is provided with a concave ridge or a convex ridge 8d parallel to the incident end surface portion 3 (one side surface portion 4) of the light guide plate 2d.

  In addition, since the description about the concentric concave ridge 7, the concentric convex ridge 7b, etc. (FIGS. 5 to 10 regarding the shape and the like) in the counter-emitting surface portion 5 is duplicated, the description is omitted here.

  Although not shown, the plurality of minute light deflecting elements 8b provided on the exit surface portion 6 are formed of convex or concave shapes such as a part of a sphere and an elliptical sphere, a triangular pyramid, a cone, a quadrangular pyramid, a triangular prism, a quadrangular prism, and a cylinder. The minute light deflection element 8b is provided uniformly on the emission surface 6 or randomly and partially. Further, various shapes may be combined, and selection is made so that the optimum light suitable for the purpose is emitted.

  The light deflector 8c is made of transparent polyethylene terephthalate (PET), acrylic resin (PMMA), polycarbonate (PC), etc., and the convex ridge 8d and the concave ridge are continuous or discontinuous. Provide.

2 and 4 show the optical deflector 8c provided with the convex ridge 8d, but a concave ridge (not shown) may be provided in the optical deflector 8c instead of the convex ridge 8d. good.
Furthermore, these convex ridges 8d and concave ridges may be provided alternately.

Further, in the example of FIG. 2, the convex ridges 8d are provided in a staggered manner, and in the example of FIG. 4, the convex ridges 8d are provided in a jumping manner. However, the convex ridges 8d and the concave ridges are continuous or discontinuous. May be provided.
Further, the convex ridge 8d and the concave ridge may be provided continuously in a direction away from the position of the incident end face portion 3, or may be provided independently on the emission surface portion 6.

The light deflector 8c shown in FIG. 2 has a portion corresponding to the incident end surface portion 3 of the light guide plate 2b as an incident end surface direction portion 8e, and is provided with a concave ridge 8d parallel to the incident end surface direction portion 8e. Positioning is performed so as to correspond to the reflected light from the counter-emitting surface portion 5 of the light plate 2b.
Similarly, the light deflector 8c shown in FIG. 4 is provided with a convex ridge 8d parallel to the incident end face part 3 (one side face part 4) of the light guide plate 2d, and reflects light reflected from the counter-emission surface part 5 of the light guide plate 2d. Perform positioning to correspond.

  Thus, by providing the light deflector 8c provided with the convex ridge 8d or the concave ridge on the emission surface portion 6, all of the reflected light from the non-emission surface portion 5 is emitted to the outside with a spread. Or part of the reflected light can be emitted outside with a spread. As a result, it is possible to control how the light spreads on the exit surface 6 and to control the viewing angle and the like.

  Here, as shown in FIG. 12, incident light L0 obtained by taking the light from these light sources 9 into the light guide plates 2b and 2d at the incident end face 3 is microscopically like light rays L1, L2, and L3. The azimuth angle is slightly different, and the process proceeds to the concentric concave ridge 7 provided on the anti-light-emitting surface portion 5. These light rays L1, L2, and L3 are reflected in the direction of the exit surface 6 by the inclined surface 7c of the concentric concave ridge 7. At this time, since the concentric concave ridge 7 is an arc in the direction of the side surface portion 4, the reflected light Lr 1, Lr 2, Lr 3 having different reflection positions travels in the direction of the exit surface portion 6. The reflected lights Lr1, Lr2, and Lr3 are once emitted from the emission surface portion 6 and refracted by the convex ridge 8d of the light deflector 8c provided on the light guide plate 2b. At this time, since the reflected light Lr1, Lr2, and Lr3 have different reflection positions, the positions reaching the convex ridge 8d are different, and are emitted with different emission angles.

  Here, the reflected light Lr1 and the reflected light Lr2 from the opposite exit surface portion 5 of the light guide plates 2b and 2d are emitted from the near prism surface of the convex ridge 8d to become the emitted light Lr01 and the emitted light Lr02, and the reflected light Lr3 is convex. Is emitted from the rear prism surface of the ridge 8 and is emitted to the outside as outgoing light Lr03.

The light source 9 is a semiconductor light emitting device composed of integrated red light emission (R), green light emission (G), and blue light emission (B), a monochromatic light emitting semiconductor light emitting device of these semiconductor light emitting devices, and a single color light emitting semiconductor light emitting device in an array shape. Or a pseudo white semiconductor light emitting device using a blue light emitting semiconductor light emitting device and a fluorescent material, or the like.
As the light source 9, CCFL (cold cathode fluorescent discharge tube) or HCFL (hot cathode fluorescent discharge tube) can also be used.

The case 10 is made of a material in which a white material such as titanium oxide is mixed in a thermoplastic resin, a material in which a metal vapor deposition such as aluminum is applied to a thermoplastic resin, or a metal foil is laminated.
In the illustrated example, the case 10 is configured to accommodate the light guide plate 2, but basically covers the light source 9 except the light emitting surface, the incident end surface portion 3, and the light emitting surface portion 6, and emits the light to the light source 9 and the light emitting surface portion 6. Light such as leaked light other than the reflected light is reflected and incident again on the light guide plates 2, 2b, 2c, and 2d.

  Instead of the case 10 of this example, a reflector is provided on the back side of the light guide plates 2, 2 b, 2 c, 2 d to reflect light such as leaked light other than that emitted to the light source 9 and the emission surface 6 and again. It can also be set as the structure which injects into the light-guide plates 2, 2b, 2c, and 2d. Further, a reflector may be disposed on the back side of the light guide plates 2, 2 b, 2 c, 2 d and provided in the case 10.

  As described above, in the flat illumination device 1, the end portion of one side surface portion 4 adjacent to the light guide plate 2 is the incident end surface portion 3, and in the flat illumination device 1 c, one side surface portion 4 is incident on the light guide plate 2 c. Concentric concave ridges 7 that are concentrically concave ridges and / or concentric convex ridges 7b that are concentrically convex ridges with the center position of the incident end face portion 3 as the center are the light exit surface portions 5. Provided. Thereby, the light from the light source 9 is guided from the incident end surface portion 3 into the light guide plate 2 or the light guide plate 2c, and this light is concentric from the light source 9 or the incident end surface portion 3 to the concentric ridges 7 and 7b in the anti-light emitting surface portion 5. The light energy is equally reflected and travels in the direction of the exit surface 6 at an arbitrary distance corresponding to, and is anti-emitted by a concave ridge or / and a convex ridge 8 parallel to the incident end surface 3 provided on the exit surface 6. Light corresponding to the concentric ridges 7 and 7b that have advanced from the surface portion 5 is emitted to the outside with a spread. Therefore, uniform and bright outgoing light without luminance spots can be obtained.

  Further, in the flat illumination device 1b, an end portion of one side surface portion 4 adjacent to the light guide plate 2b is an incident end surface portion 3, and in the flat illumination device 1d, one side surface portion 4 is disposed on the light guide plate 2d. Concentric concave ridges 7 that are concentrically concave ridges and / or concentric convex ridges 7b that are concentrically convex ridges are provided on the counter-exit surface portion 5. ing. Thereby, the light from the light source 9 is guided into the light guide plate 2b and the light guide plate 2d from the incident end surface portion 3, and this light is concentric from the light source 9 and the incident end surface portion 3 to the concentric ridges 7 and 7b in the anti-light emitting surface portion 5. The light energy is equally reflected and travels in the direction of the exit surface portion 6 at an arbitrary distance corresponding to, and this light corresponds to the concentric ridges 7 and 7b from the light source 9 and the incident end surface portion 3 on the opposite exit surface portion 5. At an arbitrary distance, the light energy is equally reflected and travels in the direction of the exit surface portion 6, and exits from the exit surface portion 6 provided with a plurality of minute light deflection elements 8b and the mirror surface of the exit surface portion 6, and the emitted light is guided. The spread is provided by the concave ridges and / or the convex ridges 8 provided in parallel to the incident end surface portions 3 of the light guide plates 2b and 2d of the light deflector 8c provided on the light exit surface 6 of the light plate 2b and the light guide plate 2d. Hold it out. Therefore, uniform and bright outgoing light without luminance spots can be obtained.

Further, the concentric concave ridges 7 and the concentric convex ridges 7b provided on the light emitting plate 2, the light guide plate 2c, the light guide plate 2b, and the opposite light emitting surface portion 5d of the light guide plate 2d are provided continuously or discontinuously on one concentric circle. The light emitted from the light guide plate can be emitted to the outside with a spread, or a part of the emitted light can be emitted to the outside with a spread. Therefore, it is possible to control how the outgoing light from the flat illumination device spreads and to control the viewing angle and the like.
In this way, it is possible to obtain a wide range of emitted light with any radiation pattern such as a light source.

  As described above, the concentric concave ridge 7 and the concentric convex ridge 7b provided on the anti-light emitting surface portion 5 and the concave ridge and the convex ridge 8d parallel to the incident end surface portion 3 provided on the outgoing surface portion 6 are mutually connected. By providing the shape and position asymmetrically, most of the reflected light from the concentric convex ridge 7b etc. from the non-exiting surface portion 5 corresponds to only one point or one line at the convex ridge 8d etc. of the outgoing surface portion 6. Further, the reflected light beam from the counter-exiting surface portion 5 is not refracted in the same direction by the convex ridges 8d of the emitting surface portion 6 and becomes an outgoing light having a spread.

  Similarly, the concentric concave ridges 7 and the concentric convex ridges 7b provided on the counter-exit surface portion 5 and the light deflector 8c provided on the exit surface portion 6 (the exit surface portion 6 is provided with a plurality of minute light deflection elements 8b). Convex ridges 8d and the like (concave ridges and convex ridges 8d are parallel to the incident end face portion 3) are provided with asymmetrical shapes and positions so that the concentric convex ridges 7b from the anti-emission surface portion 5 and the like are provided. Since most of the reflected light corresponds to only one point or one line at the convex ridge 8d or the like of the exit surface portion 6, all of the reflected light beam from the anti-exit surface portion 5 is at the convex ridge 8d or the like of the exit surface portion 6. The output light is spread without being refracted in the same direction.

  Suitable for all sizes from small mobile product backlights to large backlights, and because the light of the final emitted light from the flat lighting device has a wide spread, it can obtain a wide viewing angle, so it can be used outdoors or in car navigation systems. It is possible to provide a light guide plate and a flat illumination device that can be used from a mobile liquid crystal device such as a large liquid crystal television.

1 is a schematic perspective view of a flat illumination device according to the present invention. 1 is a schematic perspective view of a flat illumination device according to the present invention. 1 is a schematic perspective view of a flat illumination device according to the present invention. 1 is a schematic perspective view of a flat illumination device according to the present invention. It is a back surface side schematic front view of the light-guide plate which concerns on this invention. It is a back surface side schematic front view of the light-guide plate which concerns on this invention. It is a back surface side partial partial enlarged view of the light-guide plate which concerns on this invention. It is a back surface side partial partial enlarged view of the light-guide plate which concerns on this invention. It is a back surface side partial partial enlarged view of the light-guide plate which concerns on this invention. It is a back surface side partial partial enlarged view of the light-guide plate which concerns on this invention. It is a three-dimensional light locus diagram of the flat illumination device according to the present invention. It is a three-dimensional light locus diagram of the flat illumination device according to the present invention.

Explanation of symbols

1, 1 b, 1 c, 1 d Flat illumination device 2, 2 b, 2 c, 2 d Light guide plate 3 Entrance end face part 4 Side face part 5 Anti-emission surface part 6 Emission surface part 7 Concentric concave ridge 7 b Concentric convex ridge 7 c Inclined surface 8 Convex shape Edge 8b Micro-light deflector 8c Optical deflector 8e Incident end face direction portion 9 Light source 10 Case γ Refraction angle n Refractive index α Critical angle h Line connecting to light source φ Angle formed with virtual horizontal plane θ Angle of ridge (vertical angle)
L0, L1, L2, L3, Lr1, Lr2, Lr3, Lr01, Lr02, Lr03

Claims (11)

An incident end face that guides light from a light source, an exit face that emits light from the incident end face, a counter-exit face located on the opposite side of the exit face, and the exit face and the counter exit face. In the light guide plate having intersecting side portions,
Concentric concave ridges that are concentrically concave ridges centered on the center position of the incident end surface portion, with the end of at least one adjacent side surface portion or at least one of the side surface portions as the incident end surface portion, and / or A concentric convex ridge that is a concentrically convex ridge is provided on the anti-light-emitting surface portion, and a concave ridge or / and a convex ridge are provided on the light-emitting surface portion in parallel to the incident end surface portion. Light board. An incident end face that guides light from a light source, an exit face that emits light from the incident end face, a counter-exit face located on the opposite side of the exit face, and the exit face and the counter exit face. In the light guide plate having intersecting side portions,
Concentric concave ridges that are concentrically concave ridges centered on the center position of the incident end surface portion, with the end of at least one adjacent side surface portion or at least one of the side surface portions as the incident end surface portion, and / or A light guide plate, wherein concentric convex ridges that are concentrically convex ridges are provided on the anti-light-emitting surface portion, and the light-emitting surface portion is provided with a mirror surface or a plurality of minute light deflection elements. The light guide plate according to claim 1, wherein the concentric concave ridge and the concentric convex ridge are provided continuously or discontinuously on one concentric circle. The concentric concave ridge and the concentric convex ridge have a vertex angle of 45 ° to 179 ° and an inclined surface in the direction of the incident end surface portion, and an angle formed with a virtual horizontal plane parallel to the anti-light emitting surface portion. The light guide plate according to claim 1, wherein the light guide plate is 0.1 ° to 67.5 °. 3. The light guide plate according to claim 1, wherein a straight line from a center position of the incident end surface portion and a normal line of the inclined surface coincide with each other at one point or always on the inclined surface. The light guide plate according to claim 1, wherein the concave ridge and the convex ridge are provided continuously or discontinuously. A light source;
An end of at least one adjacent side surface or at least one side surface is an incident end surface, and is a concentric concave ridge or / and concentric that is a concentric concave ridge centered on the center position of the incident end surface. A concentric convex ridge, which is a convex ridge, is provided on the anti-emission surface portion and at least a light guide plate provided with a concave ridge or / and a convex ridge on the emission surface portion in parallel to the incident end surface portion. A flat illumination device. A light source;
An end of at least one adjacent side surface or at least one side surface is an incident end surface, and is a concentric concave ridge or / and concentric that is a concentric concave ridge centered on the center position of the incident end surface. A light guide plate in which concentric convex ridges that are convex ridges are provided on the anti-light-emitting surface portion and the light-emitting surface portion is provided as a mirror surface or a plurality of minute light deflecting elements on the light-emitting surface portion;
A flat illumination device comprising at least a light deflector provided with a concave ridge or / and a convex ridge parallel to the incident end surface portion of the light guide plate on the emission surface portion of the light guide plate . 9. The flat illumination device according to claim 8, wherein the light deflector is provided with the concave ridge and the convex ridge continuously or discontinuously. 9. The flat illumination device according to claim 7, wherein the light source is provided so as to be centered on the same line as a center position of the incident end surface portion. The light source is a semiconductor light emitting device or monochromatic light emitting semiconductor light emitting device or monochromatic light emitting device comprising an integrated red light emission (R), green light emission (G), or blue light emission (B), or an R, G, B array or cold. The flat illumination device according to claim 7 or 8, wherein the flat illumination device is a cathode fluorescent discharge tube or a hot cathode fluorescent discharge tube.

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