JP2002050220A - Light guide unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a light guide unit which can effectively balance light leakage and transmission in prism films that form a light guide space and which can meet a requirement for slimming down. SOLUTION: The light guide unit has a first prism film and a second prism film. Each prism film has two principal planes, respectively. One of the principal planes of each prism film is a prism face on which prisms are arranged roughly in parallel, and the other principal plane is a flat face. The two prism films are so arranged that there is an opening at one end of the prism films, a light guide space is formed between the prism films, and the height of the light guide space does not increase from the opening to the far end. The principal plane of the first prism film that faces the outside of light guide space is a light emitting plane. In this light guide unit, the arrangement of the prism faces of the prism films, and the relationship between the light incident direction and the prism arrangement direction of the prism films are defined in specific condition.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a backlight for a liquid crystal display, a signboard backlight for indoor and outdoor use, an interior,
The present invention relates to a light guide unit used as a component of a surface light source such as environmental lighting such as an exterior. The light guide unit according to the present invention can be used as a substitute for a conventional light guide plate, and has a hollow light guide space, so that the light guide unit and the surface light source can be reduced in weight.

[0002]

2. Description of the Related Art In a conventional surface light source, as shown in FIG. 1, a point light source or a line light source (in the illustrated case, a lamp (4)) emits light emitted in a planar manner. Of the light guide plate (10). The light guide plate is usually formed from a polymer material such as an acrylic resin. Light from a light source enters the light guide plate from an incident end (incident side surface) located at one end edge of the light guide plate, and propagates light toward a far end facing the incident end, while one main surface of the light guide plate The light is emitted from the light emitting surface composed of the light emitting element, and the planar light emission is realized. Light is propagated in the light guide plate by utilizing total reflection at the air-light guide plate interface due to the difference in the refractive index between air and the light guide plate (polymer material). Such a light guide plate is indispensable, for example, as a component constituting a backlighting surface light source (simply referred to as a backlight) of a liquid crystal display device. Such a light guide plate and a backlight using the same are described in, for example,
It is disclosed in, for example, JP-A-142845.

However, when a solid light guide plate is used, it has been difficult to reduce the weight of the surface light source. For example, today, as the size of the liquid crystal display screen increases, the area (light emitting area) of the light guide plate of the surface light source tends to be large and the thickness tends to be large. Therefore, an increase in the weight (mass) of the light guide plate has made it very difficult to reduce the weight of the surface light source and the liquid crystal display device including the same. Further, even in a small liquid crystal display device, it is strongly required that the surface light source be made as light as possible in mobile terminals such as mobile personal computers, mobile phones, and PHSs.

Therefore, it has been proposed to use a hollow light guide unit instead of a solid light guide plate. For example, a light emitting plate and a back plate arranged in parallel to form a hollow light guide space, and facing the inside of the light guide space,
2. Description of the Related Art A hollow light guide unit including a light emitting plate and two prism films disposed on respective surfaces of a back plate is known. A prism film is well known as an optical component, and has a plurality of prisms (also referred to as parallel prisms) in which one main surface is a flat surface and the other main surface is arranged parallel to each other along a length direction. )). In addition, such a translucent film is generally used by being arranged between the above-described light guide plate and an illuminated body (such as a liquid crystal display panel).

In order to make such a light guide unit emit light in a plane, a linear light source (such as a fluorescent tube) is usually arranged along an opening formed at one end of the light guide space, and the light is transmitted through the opening. Light enters the light guide space. The opening is formed by arranging one end edges of the two prism films so as to be substantially parallel to each other. The two prism films are usually arranged such that their flat surfaces are parallel to each other. Therefore, such a light guide unit is formed at the first opening formed at one end and at the other end (the far end which is the end furthest from the one end) at a position facing the one end. And two light sources are usually arranged in both of them, and light enters the light guide space. Since the two prism films are arranged in parallel to each other, the height of the light guide space (the thickness direction, ie, the dimension in the direction perpendicular to the light emitting surface).
Does not substantially change from the first opening on one end side to the second opening on the far end side facing the first opening.

The present inventor has proposed such a hollow light guide unit and one form of a surface light source in which such a light guide unit is combined with a light source in Japanese Patent Application Laid-Open No. Hei 6-180552. However, before the inventor's proposal,
Another form was known. In such another type of light guide unit, (i) the prism array direction of the prism film on the light emitting plate side is parallel to the incident direction of light from the light source, and the other surface including the parallel prism, that is, The prism surface is arranged toward the outside of the light guide space. On the other hand, (ii) the prism arrangement direction of the back plate side prism film is also parallel to the light incident direction, and the prism surface is similarly directed to the outside of the light guide space. In a surface light source using this light guide unit, the illuminance (light emission luminance) of light emitted from the light emitting surface tends to decrease as the distance from the light source increases. Therefore, another optical component for correcting this was required. Such another optical component is generally called an extractor, and has a saw-tooth-shaped reflecting projection that becomes wider as it goes away from the light source. Such an extractor is usually arranged on the smooth surface of the prism film on the back side.

On the other hand, in order to provide an inexpensive light guide unit and a surface light source that do not require the above-described extractor and are thus very easy to design and manufacture, the present inventor has proposed the following: The improved light guide unit is disclosed in Japanese Patent Laid-Open No.
-180552. That is, 2
In a hollow light guide unit formed by fixing the positions of two prism films so that each prism film has a predetermined three-dimensional arrangement, (I) the prism arrangement direction of one of the prism films serving as the light-emitting surface is shifted from the light source. The prism surface is arranged so as to be perpendicular to the incident direction of the light and the inside of the light guide space. (II) The prism arrangement direction of the other prism film is arranged parallel to the incident angle of light from the light source, and the prism surface is arranged toward the inside of the light guide space. Thus, the luminance on the light emitting surface can be made uniform without using an extractor. In this hollow light guide unit, part of the light emitted from the light source is reflected by the prism film, but the remaining part passes through the prism film on the light emitting surface side and is emitted from the light emitting surface.
The light reflected by the prism film repeats reflection and transmission in the light guide space, and repeats light leakage (light emission) from the light emitting surface and propagation from one end close to the light source to the far end. That is, the balance between the light leakage effect and the propagation effect is important. If the light leakage effect is too high, the propagation effect tends to decrease, and the uniformity of light emission tends to decrease. On the other hand, increasing the light leakage effect
It acts to increase the light emission luminance. Therefore, in order to balance the light leakage effect and the propagation effect according to the application and dimensions of the light guide unit, that is, the surface light source, and to obtain desired luminance and uniform light emission, the three-dimensional arrangement of the two prism films and It is necessary to optimally determine the configuration of the light guide unit, such as optimizing the combination of prism shapes or optimally selecting and adding optical components such as extractors.

[0008]

As described above, a hollow light guide unit formed by arranging two prism films in parallel and fixing their positions to each other includes the unit itself, a surface light source, and a surface light source. Lightening of the device (such as a liquid crystal display device) can be easily realized. However, it is not easy for the above-mentioned conventional light guide unit to form a relatively thin light guide unit. For example, while the size of liquid crystal display screens is increasing, there is also a strong demand for thinner liquid crystal display devices. Further, in the above-mentioned portable terminals and the like, further thinning is required. In order to meet such a requirement, for example, the thickness of the light guide unit, that is, the thickness (height) of the light guide space is 30 mm or less, and the more strict requirement is 20 mm.
mm or less.

By the way, thinning of the light guide unit means that the height of the light guide space, that is, the dimension in the direction orthogonal to the light propagation direction is reduced. On the other hand, the area of the light emitting surface,
That is, the light propagation distance is not so small as compared with the case where the unit becomes thin. The inventor of the present invention disclosed in Japanese Patent Laid-Open
After proposing the light guide unit at -180552, further studies have shown that if the height of the light guide space is relatively small, a large amount of light leaks near one end where the light source is arranged, or almost It has been found that the amount of light has a strong tendency to propagate to the far end without leaking. Therefore, in order to easily realize a thin unit, it is necessary to more effectively balance the light leakage effect and the propagation effect. In addition, it is not desirable to add an optical component such as an extractor for the purpose because the structure of the unit is complicated and the weight reduction may be difficult. Therefore, an object of the present invention is to achieve a light-balancing effect that can effectively balance the light leakage effect and the propagation effect of the prism film forming the light guide space, and can meet the demand for thinning as described above. It is to provide a light guide unit.

[0010]

According to a first aspect of the present invention, each of the two surfaces has two main surfaces, one of the main surfaces is a prism surface, and the other is a flat surface having no prism. A first prism film and a second prism film, in each of which a plurality of prisms are arranged substantially in parallel along the length direction of the prism, and the two prism films are: One end edges of the respective prism films are arranged substantially parallel to each other at intervals to form an opening, and a light guide space continuous with the opening is formed between the prism films, and the height of the light guide space is increased. The thickness (dimensions in the thickness direction) from the opening,
The main surface of the first prism film, which is arranged so as not to increase substantially toward the far edge facing the opening, and faces the outside of the light guide space from the first prism film, enters the light guide space from the opening. In the light guide unit, which is a light emitting surface that emits light by incident light, the prism surface of the first prism film is disposed toward the outside of the light guide space, and the prism arrangement direction of the first prism film is the light direction. To provide a light guide unit that is not parallel to the incident direction of the light, and solves the above-mentioned problem.

Further, in the second surface of the present invention, each has two main surfaces, one of the main surfaces is a prism surface, and the other main surface is a flat surface without a prism, Each prism surface includes a first prism film and a second prism film, in which a plurality of prisms are arranged substantially in parallel along the length direction of the prism,
The two prism films are arranged such that one end edges of the respective prism films are arranged substantially parallel to each other with an interval therebetween to form an opening, and a light guide space continuous with the opening is formed between the prism films. The height (dimension in the thickness direction) of the light guide space is arranged so as not to increase substantially from the opening toward a far end edge facing the opening, and the light guide space of the first prism film is In the light guide unit, the main surface facing the outside of the light space is a light emitting surface that emits light by light incident into the light guide space from the opening, wherein the prism surface of the first prism film is the light guide. The prism arrangement direction of the first prism film is parallel to the incident direction of the light, and the prism arrangement direction of the second prism film is Wherein the non-parallel to the incident direction of light, providing a light guiding unit, to solve the above problems.

Further, in the third aspect of the present invention, each has two principal faces, one of the principal faces is a prism face, and the other principal face is a flat face having no prism, Each of the prism surfaces includes a first prism film and a second prism film in which a plurality of prisms are arranged substantially in parallel along the length direction of the prisms. Are arranged so as to be substantially parallel to each other at an interval to form an opening, and are arranged so as to form a light guide space continuous with the opening between the prism films, and the first prism film In the light guide unit, a main surface facing the outside of the light guide space is a light emitting surface that emits light by light incident into the light guide space from the opening. A prism surface of the first prism film is arranged outside the light guide space, a prism arrangement direction of the first prism film is parallel to an incident direction of the light, and a prism surface of the second prism film is arranged in the light guide space. The prism array direction of the second prism film is disposed outside the optical space, and the prism arrangement direction of the second prism film is parallel to the incident direction of the light, and the height (the thickness direction dimension) of the light guide space is from the opening. A light guide unit, wherein the two prism films are arranged so as to become smaller toward a far edge facing the opening,
Solution to the Problems

On the other hand, in the fourth aspect of the present invention, each has two main faces, one of the main faces is a prism face, and the other main face is a flat face having no prism, Each prism surface includes a first prism film and a second prism film, in which a plurality of prisms are arranged substantially in parallel along the length direction of the prism,
The two prism films are arranged such that one end edges of the respective prism films are arranged substantially parallel to each other with an interval therebetween to form an opening, and a light guide space continuous with the opening is formed between the prism films. The height (dimension in the thickness direction) of the light guide space is arranged so as not to increase substantially from the opening toward a far end edge facing the opening, and the light guide space of the first prism film is In the light guide unit, the main surface facing the outside of the light space is a light emitting surface that emits light by light incident into the light guide space from the opening, wherein the prism surface of the first prism film is the light guide. A light guide unit is provided toward a space, and a prism surface of the second prism film is provided toward the outside of the light guide space.

Further, in the fifth aspect of the present invention, each has two main faces, one of the main faces is a prism face, and the other is a flat face without a prism, Each prism surface includes a first prism film and a second prism film, in which a plurality of prisms are arranged substantially in parallel along the length direction of the prism,
The two prism films are arranged such that one end edges of the respective prism films are arranged substantially parallel to each other with an interval therebetween to form an opening, and a light guide space continuous with the opening is formed between the prism films. The height (dimension in the thickness direction) of the light guide space is arranged so as not to increase substantially from the opening toward a far end edge facing the opening, and the light guide space of the first prism film is In the light guide unit, the main surface facing the outside of the light space is a light emitting surface that emits light by light incident into the light guide space from the opening, wherein the prism surface of the first prism film is the light guide. The prism surface of the second prism film is disposed toward the light guide space, and the prism arrangement direction of the first prism film is determined by the direction of incidence of the light. Wherein the non-orthogonal to, providing light guiding unit, to solve the above problems.

Further, in the sixth aspect of the present invention, each has two main faces, one of the main faces is a prism face, and the other is a flat face having no prism, Each of the prism surfaces includes a first prism film and a second prism film in which a plurality of prisms are arranged substantially in parallel along the length direction of the prisms. Are formed substantially parallel to each other at an interval to form an opening, a light guide space continuous with the opening is formed between the prism films, and the height (thickness) of the light guide space Directional dimension) is arranged so as not to increase substantially from the opening toward the far edge facing the opening, and the first prism film faces the outside of the light guiding space. Is a light emitting surface that emits light by light incident into the light guide space from the opening, in the light guide unit, the prism surface of the first prism film is disposed facing the light guide space, The prism surface of the second prism film is arranged toward the light guide space, and the prism arrangement direction of the first prism film is orthogonal to the light incident direction;
A light guide unit is provided, wherein the prism apex angle of the prism film is smaller than the prism apex angle of the second prism film.

[0016]

DESCRIPTION OF THE PREFERRED EMBODIMENTS [Operation] In a prism film, incident light is totally reflected or refracted and transmitted depending on the size of the prism apex angle, the surface on which light is incident, the incident angle, and the like. Such an optical action will be described with reference to FIG. In the illustrated prism film, a plurality of parallel prisms having substantially the same shape and the same dimensions are arranged on the prism surface of the prism film along the length direction of the prism. The illustrated example qualitatively shows an optical action when a prism having a vertical angle of 90 degrees and a base angle of 45 degrees is provided. When light enters the center of the hemisphere shown in FIG.
In both (a) and FIG. 2 (b), the light incident on the film after passing through the area indicated by A was totally reflected, and was incident on the film through the area other than A. Light enters the film and is refracted. Depending on the angle of refraction and the number of times of refraction, the refracted light returns to the hemisphere again from the incident surface of the film, or is transmitted through the film and emitted (light leakage) from the surface opposite to the incident surface. That is, depending on the incident angle of light, the light is selectively totally reflected and propagates toward the far end, or is refracted and transmitted through the film, and is emitted from the light emitting surface. The shape and size of the region A vary depending on whether the light incident surface (that is, the surface facing the light guide space) is a prism surface or a flat surface, and depending on the shape and size of the prism. . Therefore, by effectively combining two prism films having such an optical action, the balance between the light leakage effect and the propagation effect can be effectively adjusted.

According to the present invention, of the two prism films forming the light guide space, the three-dimensional arrangement of the prism films and the combination of the prism shapes are optimally selected to effectively balance the light leakage effect and the propagation effect. As a result, the unit can be easily reduced in thickness. In the present invention, the three-dimensional arrangement of prism films and combinations of prism shapes to be optimally designed are summarized as follows. (A) Combination of the orientations of the respective prism faces of the two prism films (that is, whether they face the light guide space or the outside of the light guide space). (B) Each of the two prism films Of the prism arrangement directions (that is, angles formed with respect to the direction of incidence of light from the light source); when parallel to the direction of incidence of light from the light source, an angle of 0 degrees is assumed, and When orthogonal to the light incident direction, the angle is 90 degrees. (C) Combination of the prism apex angles of the two prism films; that is, have prisms with the same apex angle or prisms with apex angles of different sizes from each other. (D) Combination of the extending directions of the two prism films; that is, whether their flat surfaces are parallel or non-parallel. In the case of non-parallel, the two prism films are arranged such that the height of the light guide space decreases from the opening at one end of the prism film on which the light source is arranged toward the far end. In this case, in a vertical cross section along the light incident direction, the cross-sectional shape of the light guide space is wedge-shaped.

A preferred embodiment of the light guide unit of the present invention formed by effectively combining such a three-dimensional arrangement of prism films and a prism shape will be described with reference to FIG. FIG. 3 is a vertical sectional view of a surface light source (60) including a light guide unit (6) according to the present invention and a light source (4). This figure shows the light (4) from the light source (4).
It is sectional drawing cut | disconnected by the surface perpendicular | vertical to a light emission surface along the incident direction with respect to the light guide space (3) of (0). In the example shown in FIG. 3, two prism films (1, 2) are arranged at a predetermined distance, and a hollow light guide space (3) is provided between them. , 2) are formed. Also, 2
One edge (11, 21) of each of the two prism films (1, 2) is arranged parallel to and separated from each other to form an opening (30), and the opening (30) and the light guide space ( 3) is continuous.

In the vicinity of the opening (30), a light source (4) is provided so as to effectively irradiate (enter) light into the light guide space (3).
Are arranged, and the surface light source (6) is provided together with the light guide unit (6).
0). In the example of FIG. 3, the reflector (41) is arranged so as to partially cover the light emitting surface of the light source (4). The reflection plate (41) is useful for preventing light other than the light guide space (3) from being irradiated. Usually, the second
A reflection film (5) is disposed on the back surface (outer surface with respect to the light guide space) of the prism film (2) to increase the luminance of the light emitting surface (upper surface in FIG. 3) of the first prism film (1). ing. When a thin light guide unit is formed as in the example shown in FIG. 3, the light guide space (3) preferably has a wedge-shaped cross section. That is, the flat surfaces of the prism films (1, 2) are non-parallel, and the light guide space (3)
Height of one end edge (11, 12) where the light source (4) is arranged.
The two prism films are arranged so as to decrease in size from the opening (30) of 1) toward the far edges (12, 22).

In the first embodiment of the present invention, of the two prism films, the prism surface of the first prism film located on the light emitting surface side is arranged facing the outside of the light guide space. At this time, it is necessary that the prism arrangement direction of the first prism film is not parallel to the light incident direction. Thus, the light leakage effect and the propagation effect can be effectively balanced, and the light guide unit can be easily made thin. In this case, the third prism film 3
The dimensional arrangement and the prism shape are not particularly limited. However, the prism arrangement direction of the second prism film is
It is preferable that the angle between the two arrangement directions is not parallel to the prism arrangement direction of the first prism film.
It is particularly preferred that the angle be in the range of 0 degrees. As a result, 30
Even in the case of a light guide space having a height of not more than 20 mm, particularly preferably not more than 20 mm, the balance between the light leakage effect and the propagation effect becomes extremely easy. When the angle between the two arrangement directions is 0 degree or close to 0 degree, the prism apex angle of the first prism film is in the range of 80 to 95 degrees, and the prism apex angle of the second prism film is 65 to 95 degrees. Preferably it is in the range of 80 degrees. Thereby, even in the case of a light guide space having a height of 30 mm or less, the balance between the light leakage effect and the propagation effect becomes extremely easy. In the first embodiment, the angle formed by the prism arrangement direction of the first prism film and the light incident direction is not 0 degree, that is, not necessarily parallel, but is usually in the range of 40 to 90 degrees.

In a second embodiment of the present invention, the prism surface of the first prism film is arranged toward the outside of the light guide space, and the prism arrangement direction of the first prism film is parallel to the light incident direction. In this case, the three-dimensional arrangement of the second prism film is defined as follows. That is, the prism arrangement direction of the second prism film is not parallel to the light incident direction. Thus, the light leakage effect and the propagation effect can be effectively balanced, and the light guide unit can be easily made thin. Note that the angle formed by the prism arrangement direction of the second prism film and the light incident direction is not 0 degree, that is, it may not be parallel, but is usually in the range of 40 to 90 degrees.

Further, in the third aspect of the present invention, the prism surface of the first prism film is arranged toward the outside of the light guide space, and the prism arrangement direction of the first prism film is parallel to the light incident direction. When the prism arrangement direction of the second prism film is parallel to the light incident direction, the relative arrangement of the two prism films is defined as follows. That is, as shown in FIG. 3, the two prism films are arranged such that the height (dimension in the thickness direction) of the light guide space decreases from the opening at one end to the far end. In addition, the prism surface of the second prism film is disposed toward the outside of the light guide space. Thus, the light leakage effect and the propagation effect can be effectively balanced, and the light guide unit can be easily made thin. In general, a structure in which the prism surfaces of the first prism film are arranged toward the outside of the light guide space, and the prism arrangement of the two prism films is parallel to the light incident direction is not enough to enhance the light leakage effect. Disadvantageous. However, with the relative arrangement of the two prism films as described above,
Such a disadvantage can be eliminated by making the vertical sectional shape of the light guide space into a wedge shape.

On the other hand, on the other hand, the prism surface of the first prism film can be arranged facing the light guide space. In such a case, the three-dimensional arrangement and the prism shape of the second prism may be defined as described below. First, in the fourth embodiment of the present invention, the prism surface of the first prism film is arranged toward the light guide space, and the prism surface of the second prism film is arranged toward the outside of the light guide space. Thus, the light leakage effect and the propagation effect can be effectively balanced, and the light guide unit can be easily made thin. In such a case, the prism arrangement direction of the second prism film is preferably substantially parallel to the light incident direction. Thereby, even in the case of a light guide space having a height of 30 mm or less, the balance between the light leakage effect and the propagation effect becomes extremely easy. On the other hand, in the fourth embodiment, the prism arrangement direction of the first prism film is:
It is preferable to form an angle in the range of 40 to 90 degrees with respect to the light incident direction. Thereby, even in the case of a thinner light guide space having a height of 20 mm or less, the balance between the light leakage effect and the propagation effect becomes extremely easy.

In a fifth aspect of the present invention, the prism surface of the first prism film is disposed so as to face the light guide space, and the prism surface of the second prism film faces the light guide space. In the arrangement, the prism arrangement direction of the first prism film is not perpendicular to the light incident direction in order to effectively balance the light leakage effect and the propagation effect. In this case, the angle between the prism arrangement direction of the first prism film and the light incident direction is 30 degrees.
It is preferably in the range of 〜60 degrees. As a result, 30
Even in the case of a light guide space having a height of not more than mm, the balance between the light leakage effect and the propagation effect becomes extremely easy. From such a viewpoint, the angle formed by the prism arrangement direction of the first prism film and the light incident direction is particularly preferably 40 to 50 degrees. On the other hand, in the fifth embodiment, the prism arrangement direction of the second prism film is preferably substantially parallel to the light incident direction. Further, the angle formed by the prism arrangement direction of the first prism film and the light incident direction is in a range of 30 to 60 degrees, and the prism arrangement direction of the second prism film is substantially parallel to the light incident direction. Is particularly preferred. Thereby, even in the case of a thinner light guide space having a height of 20 mm or less, the balance between the light leakage effect and the propagation effect becomes extremely easy.

Further, in the sixth aspect of the present invention, the prism surface of the first prism film is arranged toward the light guide space, the prism surface of the second prism film is arranged toward the light guide space, And when the prism arrangement direction of the first prism film is orthogonal to the light incident direction,
By setting the angle of the prism apex angle of the first prism film to be smaller than the prism apex angle of the second prism film, the light leakage effect and the propagation effect can be effectively balanced. Also in this case, the prism arrangement direction of the second prism film is preferably substantially parallel to the light incident direction. Thereby, even in the case of a light guide space having a height of 30 mm or less, the balance between the light leakage effect and the propagation effect becomes extremely easy. In the sixth embodiment, the prism apex angle of the first prism film is 65 to 65.
It is preferably in the range of 80 degrees, and the prism apex angle of the second prism film is preferably in the range of 80 to 95 degrees.

In the prism film used in the present invention, each of the plurality of prisms usually extends along the length direction of the prism, and the respective extending directions are parallel to each other. The apex (apex) of each prism has a rectangular shape having a predetermined apex angle, or a rounded shape (a shape in which the apex angle is rounded off). In order to effectively increase the propagation effect, it is preferable that the prism apex has a rectangular shape having a predetermined apex angle. When the prism apex is a square apex, the apex angle is usually 60 to 100.
Degrees, preferably 65-95 degrees, particularly preferably 70-90 degrees.

The prism film used in the present invention comprises:
It is formed from a polymer having a light transmittance of usually at least 80%, preferably at least 85%, particularly preferably at least 90%. In addition,
The light transmittance in the present specification is a total light transmittance measured according to JIS K-7105. The prism film can be manufactured by molding a polymer using a mold having a predetermined shape and arrangement corresponding to the prism, for example. As the polymer forming the prism film, a polymer having a high refractive index in the range of 1.4 to 1.9 is preferable. For example, polymers such as acrylic, epoxy-modified acrylic, and polycarbonate are used.

The dimensions of the prism film are not particularly limited as long as the effects of the present invention are not impaired. Usually, the thickness of the prism film (the distance from the flat surface to the top of the prism) is usually 50 μm to 2 mm. The prism pitch (= top interval) is usually 0.020 to 0.5 mm,
Preferably 0.022-0.3 mm, height of prism (height from valley between adjacent prisms to measured top)
Is usually 0.01 to 1 mm, preferably 0.011 to 0.6
mm.

As a specific example of a commercially available prism film that can be used in the present invention, "BEF (trademark)" manufactured by 3M Company.
Series "," IDF (trademark) series ", and" TRAF (trademark) "of the company.

According to the present invention, a surface light source can be manufactured in the same manner as the above-described conventional one. That is, the configuration other than the light guide unit can be the same as that of a normal surface light source. For example, the light source is a line (bar),
A light source having an ordinary shape such as a spherical shape can be used. For example, a fluorescent tube, a cold cathode tube, a light emitting diode and the like can be used. Further, in addition to the light source disposed near the first opening formed on one end side of the light guide space, the light source is disposed near the second opening formed on the other end side opposite to the first opening. You can also. In this case, the height of the light guide space is from the first opening,
It is preferable that the two prism films are not substantially changed toward the second opening located at the far end opposite to the first opening, that is, the flat surfaces of the two prism films are substantially parallel. Also, when manufacturing a surface light source, surround the light guide space,
A frame or a frame that prevents light from leaking from other than the light emitting surface of the prism film can also be used. Also,
It is preferable to arrange a light-impermeable film such as a reflection film on the outer surface of the second prism film with respect to the light guide space.

As described above, one main surface of the first prism film, that is, the surface outside the light guide space is the light emitting surface. On the other hand, the light guide unit is turned upside down,
When the second prism film is regarded as the first prism film and the first prism film is regarded as the second prism film, there is also a film having a configuration included in any of the above embodiments. In such a case, the outer surface of the second prism film can be used as a light emitting surface.

The area of the light emitting surface is not particularly limited. For example, in the case of a liquid crystal display device, the light emitting surface of the present invention ranges from a small screen device of about 2 cm ² to a large screen of about 1 m ² . Light guide units are available.

As described above, according to the present invention, the height of the light guide space can be reduced, and the thickness of the light guide unit and the surface light source can be reduced. The height of the light guide space is usually 1 to 30 m
m, preferably 2 to 20 mm. The height of the light guide space is a distance between two main surfaces of the prism film facing each other, measured at an opening at one end where the light source is arranged. When the prism surface of one of the prism films faces the light guide space, the distance is from the top of the prism of one of the prism films to the principal surface of the prism of the other film. Furthermore, if the prism faces of both films face into the light guide space, it is the distance from the top of one prism to the top of the other prism.

[0034]

EXAMPLES Light guide units of Examples and Comparative Examples were manufactured as follows. The structures and dimensions of the prism films used in each example were as shown below. The planar dimensions of the prism film used in each example were 40 mm × 40 mm. BEF II: 3M prism film (brightness increasing film) "BEF (trademark) II, product number: 90/50". This is one in which a plurality of parallel prisms are arranged on the prism surface, and the cross-sectional shape in the width direction of each prism has a vertex angle of 90 degrees.
It was an equilateral triangle. The distance (prism pitch) between adjacent prism apex angles (apex) was 50 μm, and the thickness of the prism film (the distance from the flat surface of the prism film to the prism apex of the prism surface) was 155 μm. TRAF: 3M prism film "TRAF (trademark) II". This is one in which a plurality of parallel prisms are arranged on the prism surface, and the cross-sectional shape in the width direction of each prism is an isosceles triangle with a vertex angle of 70 degrees. The prism pitch was 31 μm, and the thickness of the prism film was 145 μm. IDF20: Prism film “IDF manufactured by 3M Corporation”
(Trademark) 20 ". This is a configuration in which a plurality of parallel prisms are arranged on a prism surface. Each prism has a cross-sectional shape in the width direction having a vertex angle of 70.7 degrees, one base angle of 77.6 degrees, and the other base angle of 31 degrees. It was a 0.7 degree triangle. The prism pitch was 50 μm, and the thickness of the prism film was 150 μm.

When such a prism film having an asymmetric cross section in the width direction of a prism is used without making the prism arrangement direction parallel to the light incident direction of the light source,
Which slope of the prism faces the light source is not particularly limited. What is necessary is just to determine suitably so that the light leakage effect and the propagation effect can be effectively balanced. In Examples 4, 7, 12, 20, and 24 among the examples described later, the prism slope having the larger base angle (the base angle of 77.6 degrees in the case of the IDF 20) is moved to the one edge side (in the direction where the light source exists). )
In Examples 3 and 16, on the other hand, in Examples 3 and 16, the prism slope having the smaller bottom angle (31.7 degrees in the case of IDF20) faces one edge side (the direction in which the light source is located). Was placed. It should be noted that the third and fourth embodiments differ only in the direction of such a prism slope (of the first prism film) with respect to the light source.

(Examples 1 to 24) A light guide unit having the structure shown in FIG. 3 was manufactured as follows. Combinations of types and three-dimensional arrangements of the prism films in each example were as shown in Table 1. Here, the procedure of manufacturing the light guide unit will be described taking the case of the first embodiment as an example. First, as a first prism film, a prism film “BEF (trademark) II” manufactured by 3M is placed on the light emitting surface side such that the prism surface faces the outside of the light guide space (indicated by “O” in Table 1). As the second prism film,
EF (trademark) II "was arranged on the back side such that the prism surface faces the inside of the light guide space (indicated by the symbol" I "in Table 1).
An opening was provided at one edge of each of the two prism films, and the height of the light guide space measured at this opening was 4 mm. On the other hand, the far edges of the two prism films were brought close to each other so that they almost touched each other.

In FIG. 3, the prism arrangement direction of the first prism film was perpendicular to the paper surface, and the prism arrangement direction of the second prism film was parallel to the paper surface. That is, the prism arrangement direction of the first prism film is orthogonal to the incident direction of light from the light source disposed in the opening (indicated by the symbol “H” in Table 1), and the second prism The prism arrangement directions of the film were arranged so as to be parallel (indicated by the symbol “V” in Table 1) to the incident direction of light from the light source arranged in the opening. In the same manner as in Example 1, using the combinations shown in Table 1, light guide units of other examples were manufactured in the same manner.

With respect to the light guide unit of each embodiment, the state of light propagation and light leakage from the light emitting surface were observed as follows. The light guide unit of each example was placed in a dark room, and four point light sources (LEDs) were arranged in a row in parallel with the opening and lit, and the state of light emission and propagation was observed from the light emitting surface. In each case, the light emitting surface (principal film main surface)
It was observed that the light rays emitted by the LED continuously run with high luminance from one edge with the opening to the far edge.
That is, in the light guide unit of the present invention, in the thin light guide space, the light leakage effect and the propagation effect are balanced to obtain desired brightness and uniformity of light emission according to the brightness (illuminance) of the light source itself. I knew I could do it.

(Comparative Example 1) The light guide unit of the present example was performed in the same manner as in Example 1 except that two transparent acrylic films (no prisms were formed on both sides) were used instead of the two prism films. Was prepared. About the light guide unit of this example, the state of light propagation and light leakage from the light emitting surface was observed in the same manner as in the example. However, bright light was emitted only near the one edge on the light emitting surface, and no light was emitted near the far edge. That is, it was found that the light leakage effect and the propagation effect could not be balanced only by the film without the prism.

(Comparative Example 2) The three-dimensional arrangement of the first prism film is such that the prism surface is on the outside and the prism arrangement is parallel to the incident direction of light ("VO" in the symbol).
Three-dimensional arrangement of prism film, prism surface inside,
A light guide unit of this example was manufactured in the same manner as in Example 1, except that the prism array was made parallel to the light incident direction ("VI" as represented by a symbol). About the light guide unit of this example, the state of light propagation and light leakage from the light emitting surface was observed in the same manner as in the example. However, as in the case of Comparative Example 1, only near the one end edge on the light emitting surface emitted bright light, and near the far end edge did not emit light at all. That is, even if the same prism film was used, it was found that the light leakage effect and the propagation effect could not be balanced unless the three-dimensional arrangement of the prism films was appropriate.

[0041]

[Table 1] Note: H: The prism arrangement direction is orthogonal to the light source emission direction. V: The prism arrangement direction is parallel to the light source emission direction. 45: The prism array direction is inclined 45 degrees with respect to the light source emission direction. I: The prism surface faces the inside of the light guide space. O: The prism surface faces the outside of the light guide space.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view of a conventional surface light source.

FIG. 2 is a diagram illustrating an optical action depending on the structure of a prism film.

FIG. 3 is a sectional view of a surface light source using a preferred example of a light guide unit according to the present invention.

[Explanation of symbols]

1, 2: prism film, 11, 21: one edge, 12,
22: far edge 3: light guide space, 30: opening 4: light source, 41: reflector 5: reflection film 6, light guide unit, 60: surface light source

Claims (6)

[Claims] 1. Each prism has two principal surfaces, one principal surface is a prism surface, the other principal surface is a flat surface having no prism, and each prism surface has a plurality of prisms. Comprises a first prism film and a second prism film arranged substantially in parallel along the length direction of the prism, wherein the two prism films are arranged such that one edge of each prism film is spaced apart from each other. An opening is formed substantially in parallel, a light guide space continuous with the opening is formed between the prism films, and the height (dimension in the thickness direction) of the light guide space is increased from the opening. A main surface of the first prism film facing the outside of the light guide space is arranged so as not to substantially increase toward a far edge facing the opening; In the light guide unit, which is a light emitting surface that emits light by light incident on the first prism film, the prism surface of the first prism film is disposed toward the outside of the light guide space, and the prism arrangement direction of the first prism film is A light guide unit, which is not parallel to a light incident direction. 2. A method according to claim 1, wherein each of the prism surfaces has two principal surfaces, one of the principal surfaces is a prism surface, and the other principal surface is a flat surface having no prism. Comprises a first prism film and a second prism film arranged substantially in parallel along the length direction of the prism, wherein the two prism films are arranged such that one edge of each prism film is spaced apart from each other. An opening is formed substantially in parallel, a light guide space continuous with the opening is formed between the prism films, and the height (dimension in the thickness direction) of the light guide space is increased from the opening. A main surface of the first prism film facing the outside of the light guide space is arranged so as not to substantially increase toward a far edge facing the opening; In the light guide unit, which is a light emitting surface that emits light by light incident on the first prism film, the prism surface of the first prism film is disposed toward the outside of the light guide space, and the prism arrangement direction of the first prism film is The light guide unit is parallel to a light incident direction, and a prism arrangement direction of the second prism film is not parallel to the light incident direction. 3. Each of the two principal surfaces, one of the principal surfaces is a prism surface, the other principal surface is a flat surface having no prism, and each prism surface has a plurality of prisms. Comprises a first prism film and a second prism film arranged substantially in parallel along the length direction of the prism, wherein the two prism films are arranged such that one edge of each prism film is spaced apart from each other. The openings are formed substantially parallel to each other to form an opening, and a light guide space continuous with the opening is arranged between the prism films, and is directed to the outside of the light guide space of the first prism film. In the light guide unit, the main surface is a light emitting surface that emits light by light incident into the light guide space from the opening, wherein the prism surface of the first prism film is the light guide surface. The prism arrangement direction of the first prism film is arranged toward the outside of the light space, the prism arrangement direction of the first prism film is parallel to the incident direction of the light, and the prism surface of the second prism film is arranged toward the outside of the light guide space. And the prism arrangement direction of the second prism film is parallel to the incident direction of the light, and the height (the thickness direction dimension) of the light guide space is a far edge facing the opening from the opening. The light guide unit, wherein the two prism films are arranged so as to become smaller toward. 4. Each prism has two principal surfaces, one principal surface is a prism surface, the other principal surface is a flat surface having no prism, and each prism surface has a plurality of prisms. Comprises a first prism film and a second prism film arranged substantially in parallel along the length direction of the prism, wherein the two prism films are arranged such that one edge of each prism film is spaced apart from each other. An opening is formed substantially in parallel, a light guide space continuous with the opening is formed between the prism films, and the height (dimension in the thickness direction) of the light guide space is increased from the opening. A main surface of the first prism film facing the outside of the light guide space is arranged so as not to substantially increase toward a far edge facing the opening; In the light guide unit, which is a light emitting surface that emits light by light incident on the light guide unit, the prism surface of the first prism film is disposed toward the light guide space, and the prism surface of the second prism film is the light guide surface. A light guide unit, wherein the light guide unit is arranged toward the outside of the space. 5. Each prism has two principal surfaces, one principal surface is a prism surface, the other principal surface is a flat surface having no prism, and each prism surface has a plurality of prisms. Comprises a first prism film and a second prism film arranged substantially in parallel along the length direction of the prism, wherein the two prism films are arranged such that one edge of each prism film is spaced apart from each other. An opening is formed substantially in parallel, a light guide space continuous with the opening is formed between the prism films, and the height (dimension in the thickness direction) of the light guide space is increased from the opening. A main surface of the first prism film facing the outside of the light guide space is arranged so as not to substantially increase toward a far edge facing the opening; In the light guide unit, which is a light emitting surface that emits light by light incident on the light guide unit, the prism surface of the first prism film is disposed toward the light guide space, and the prism surface of the second prism film is the light guide surface. A light guide unit, which is arranged in an optical space, wherein a prism arrangement direction of the first prism film is not orthogonal to a light incident direction. 6. Each prism surface has two principal surfaces, one principal surface is a prism surface, the other principal surface is a flat surface having no prism, and each prism surface has a plurality of prisms. Comprises a first prism film and a second prism film arranged substantially in parallel along the length direction of the prism, wherein the two prism films are arranged such that one edge of each prism film is spaced apart from each other. An opening is formed substantially in parallel, a light guide space continuous with the opening is formed between the prism films, and the height (dimension in the thickness direction) of the light guide space is increased from the opening. A main surface of the first prism film facing the outside of the light guide space is arranged so as not to substantially increase toward a far edge facing the opening; In the light guide unit, which is a light emitting surface that emits light by light incident on the light guide unit, the prism surface of the first prism film is disposed toward the light guide space, and the prism surface of the second prism film is the light guide surface. The prism arrangement direction of the first prism film is arranged perpendicular to the incident direction of the light, and the prism apex angle of the first prism film is the second prism angle.
A light guide unit having an angle smaller than a prism apex angle of a prism film.