1. Field of the Invention
The present invention relates to an illuminator that allows a wide luminous intensity distribution.
2. Description of the Related Art
Conventionally, when considering light sources for a general lighting purpose used, for example, in indoor situations, an incandescent lamp or a fluorescent lamp has been used; however, through today's technical advancement of blue light-emitting diodes (the LEDs), the LEDs have come into use as the light sources applied to, for example, a ceiling light or a downlight. As one of the examples,
The present invention has been made in light of the above problem, and it is an object of the present invention to achieve that the luminous intensity distribution properties of an illuminator provided with a light guide plate are allowed to have a wide luminous intensity distribution to be needed.
Embodiments according to the present invention hereinbelow exemplify some structures of the present invention, and are itemized for facilitating understanding of various structures of the present invention. Note that each item does not intend to limit the technical scope of the present invention. While considering the best modes to carry out the present invention, even if components of each item are partially substituted or deleted, or even if another component is added thereto, these should be regarded as the elements of the technical scope of the present invention.
In order to achieve the object described above, according to a first aspect of the present invention, there is provided an illuminator comprising: a light source unit composed of a point light source; a light guide plate including an incidence surface into which light emitted from the light source unit is introduced, and an exit surface out which the light that has been introduced from the incidence surface exits; and a prism body where a plurality of prisms are arranged so as to refract the light that has exited out from the exit surface of the light guide plate, wherein the prism body is arranged at a specific area on the entire exit surface of the light guide plate so as to refract part of the light that has exited out from the exit surface of the light guide plate
In the illuminator that is structured as the above, since the prism body is arranged at a specific area on the entire exit surface of the light guide plate to refract part of the exited lights, it makes possible that part of the emitted lights is refracted in a certain direction. With this structure, a necessary wide luminous intensity distribution is achievable by means of the following exited lights: 1) lights that have been exited from the exit surface of the light guide plate and refracted by the prism body; and 2) the other exited lights, that is, lights that have been exited from an area at which the prism body is not arranged.
In the first aspect of the present invention, the plurality of prisms of the prism body are configured as that a luminous intensity distribution of the light emitted from the exit surface of the light guide plate where the prism body is not provided, and a luminous intensity distribution of the light obtainable by which the emitted light is refracted with the prism body have a complementary relation therebetween so as to obtain certain luminous intensity distribution properties.
In the illuminator that is structured as the above, the plurality of prisms of the prism body are configured as that a luminous intensity distribution of the light emitted from the exit surface of the light guide plate where the prism body is not provided, and a luminous intensity distribution of the light obtainable by which the emitted light is refracted by the prism body have a complementary relation therebetween so as to obtain certain luminous intensity distribution properties. Accordingly, a necessary wide luminous intensity distribution is achievable by means of the combination of the following two luminous intensity distributions, that is: 1) a luminous intensity distribution of the exited lights that have been refracted by the prism body; and 2) a luminous intensity distribution of the other exited lights that have exited out from an area on which the prism body is not arranged.
In the first aspect of the present invention, the illuminator further comprises an optical path modification means on a reflection surface facing the exit surface of the light guide plate so that an optical path of the light introduced from the incidence surface of the light guide plate is adapted to direct toward the exit surface of the light guide plate, wherein the optical path modification means is configured as that a luminous intensity distribution of the light emitted from the exit surface of the light guide plate where the prism body is not provided, the optical path of the light being changed by means of the optical path modification means, and a luminous intensity distribution of the light obtainable by which the emitted light is refracted with the prism body have a complementary relation therebetween so as to obtain certain luminous intensity distribution properties.
In the illuminator that is structured as the above, the optical path modification means formed on the reflection surface facing the exit surface of the light guide plate is configured as that a luminous intensity distribution of the light emitted from the exit surface where the optical path is changed due to the optical path modification means, and a luminous intensity distribution of the light that is obtainable by which the emitted light is refracted with the prism body have a complementary relation therebetween so as to obtain certain luminous intensity distribution properties. Accordingly, a necessary wide luminous intensity distribution is achievable by means of the combination of the following two luminous intensity distributions, that is: 1) a luminous intensity distribution of the exited lights that have been refracted by the prism body; and 2) a luminous intensity distribution of the other exited lights that have exited out from an area on which the prism body is not arranged.
In the first aspect of the present invention, the prisms of the prism body and the optical path modification means of the light guide plate are each configured to have a mono-shape in section.
In the illuminator that is structured as the above, a necessary wide luminous intensity distribution is achievable by means of the combination of the following two luminous intensity distributions, that is: 1) a luminous intensity distribution of the lights that have exited out from the exit surface of the light guide plate where the prism body is not provided through the optical path modification means with the mono-shape in section; and 2) a luminous intensity distribution of the emitted lights that have been refracted by the prism body of the single sectional area.
Also, in the above illuminator, considering the light source unit to be influenced the most, the prisms of the prism body and the optical modification means of the light guide plate may be formed to have a mono-configuration in section. Specifically, in a case where the opposed left-and-right lateral end surfaces of the light guide plate are defined as the incidence surfaces, the following structure is possible. That is, the prisms of the prism body and the optical modification means of the light guide plate are bilaterally symmetrical at the center of the light guide plate.
In the first aspect of the present invention, the light guide plate is formed to have a certain symmetrical configuration in a plan view, and the light source unit and the prism body are each arranged to have a certain symmetrical configuration in a plan view.
The illuminator that is structured as the above is composed of: the light guide plate configured to have a certain symmetrical configuration in a plan view; the light source unit arranged to have a certain symmetrical configuration in a plan view; and the prism body to have a certain symmetrical configuration in a plan view so as to refract only part of emitted lights in the entire light that has been emitted from the exit surface of the light guide plate. A necessary wide luminous intensity distribution is thus achievable by means of the following exited lights: 1) exited lights that have been refracted by the prism body; and 2) the other exited lights that have exited out from the exit surface of the light guide plate on which the prism body is not provided.
In the first aspect of the present invention, the light guide plate is formed to have a square configuration in a plan view; each of opposed end surface sides of the light guide plate is formed to define the incidence surface at which the light source unit is each arranged; and the prism body is arranged on at least either a certain near-center area of the light guide plate or a certain area of the opposed end surface sides of the light guide plate.
In the illuminator that is structured as the above, the illuminator is composed of: the light guide plate that is formed to have a square configuration in a plan view; the light source unit; and the prism body that is arranged at a specific portion on the entire exit surface of the light guide plate so as to refract only part of the emitted lights. Accordingly, a necessary wide luminous intensity distribution is achievable by means of the following exited lights: 1) exited lights that have been refracted by the prism body; and 2) the other exited lights that have exited out from the exit surface of the light guide plate where the prism body is not provided. Here, in this corresponding structure, the prism body may be arranged on at least either a certain near-center area of the light guide plate or a certain area of the opposed end surface sides of the light guide plate. Further, the area where the prism body is provided and the area where the prism body is not provided may be alternatively arranged.
In the first aspect of the present invention, all of the opposed end surface sides of the light guide plate is formed to define the incidence surface of the light guide plate at which the light source unit is each arranged.
In the illuminator that is structured as the above, all of the opposed end surface sides of the light guide plate squared in a plan view is formed to define the incidence surface at which the light source unit is each arranged. Accordingly, a necessary wide luminous intensity distribution is achievable by means of the following exited lights: 1) exited lights that have been refracted by the prism body arranged on at least either a certain near-center area of the light guide plate or a certain area of the opposed end surface sides of the light guide plate, 2) the exited lights that have exited out from an area where the prism body is not provided on the exit surface of the light guide plate.
In the first aspect of the present invention, the light source unit and the incidence surface into which the light emitted from the light source unit is introduced are arranged at a center area of the light guide plate in a plan view; and the prism body is arranged on at least either a certain area near the incidence surface or a certain area near the outer periphery of the light guide plate in a plan view.
In the illuminator that is structured as the above, the exited light from the light source unit that is arranged at the center area of the light guide plate in a plan view is introduced into the incidence surface arranged at the center area of the light guide plate in a plan view. Accordingly, a necessary wide luminous intensity distribution achievable by means of the following exited lights: 1) exited lights that have been refracted by the prism body that is partially arranged at a specific area on the entire area of the exit surface of the light guide plate so as to refract part of the exited lights; and exited lights that have exited out from the exit surface of the light guide plate where the prism body is not provided. In this structure, the area where the prism body is arranged can be defined by: at least either a certain area near the incidence surface or a certain area near the outer periphery of the light guide plate in a plan view. Further, the area where the prism body is arranged and the area where the prism body is not arranged may be alternatively arranged.
In the first aspect of the present invention, the light guide plate is formable to have a circular or a polygonal configuration in a plan view.
In the illuminator that is structured as the above, the emitted lights from the light source unit that is arranged at the center area of the light guide plate formed to have a circular or polygonal configuration in a plan view are introduced into the incidence surface arranged at the center area of the light guide plate in a plan view. Accordingly, a necessary wide luminous intensity distribution is achievable by means of the following exited lights: 1) exited lights that have been refracted by the prism body arranged on at least either a certain area near the incidence surface or a certain area near the outer periphery of the light guide plate in a plan view; and exited lights emitted from the exit surface of the light guide plate where the prism body is not arranged.
In the first aspect of the present invention, the prism body is a prism sheet that is provided individually from the light guide plate.
In the illuminator that is structured as the above, the prism body is configured by the prism sheet individually formed from the light guide plate. This includes that: 1) A piece of the prism sheet has a group of prisms at a certain area thereof, and this prism sheet is used in plural; and 2) A piece of the prism sheet has several groups of prisms thereon, and this prism sheet is used alone. Accordingly, a necessary wide light luminous distribution is achievable by means of the following exited lights: 1) exited lights that are refracted by the prisms on the prism sheet individually provided; and the other emitted lights, that is, the emitted lights emitted from the area where the prism body is not arranged on the exit surface of the light guide plate.
In the first aspect of the present invention, a positive prism sheet or an inverse prism sheet is applicable according to a luminous intensity distribution of the light emitted from the exit surface of the light guide plate.
In the illuminator that is structured as the above, according to the luminous intensity distribution of the emitted lights from the exit surface of the light guide plate, the positive prism sheet (the prism sheet where the convex edge lines of the multiple prisms are directed opposite to the light guide plate) and the inverse prism sheet (the prism sheet where the convex edge lines of the multiple prisms are directed toward the light guide plate) are used. Accordingly, a necessary wide luminous intensity distribution is achievable by that a luminous intensity distribution of the emitted light from the exit surface of the light guide plate and a luminous intensity distribution by the emitted light that has been refracted by the prism body have a complementary relation therebetween, thereby being able to obtain desired luminous intensity distribution properties.
In the first aspect of the present invention, the prism body is integrally formable with the exit surface of the light guide plate.
In the illuminator that is structured as the above, the prism body is integrally with but partially arranged at the exit surface of the light guide plate, thereby being able to refract part of the lights exited out from the exit surface of the light guide plate. Accordingly, a necessary wide light intensity distribution is achievable by means of the following exited lights: 1) exited lights that are refracted by the prism body on the exit surface of the light guide plate; and the other emitted lights, that is, the emitted lights emitted from the area where the prism body is not formed at the exit surface of the light guide plate.
In the first aspect of the present invention, the illuminator is mountable at a ceiling or a wall surface.
In the illuminator that is structured as the above, the same operational effects discussed hereinabove is obtainable even though the illuminator is mounted at the ceiling or the wall surface.
Hereinafter, some embodiments of the present invention will be explained with reference to the accompanied drawings. Here, portions identical with or corresponding to prior arts will be indicated with the same reference numerals, and the detail explanations thereof will be omitted. An illuminator 10 according to the embodiments of the present invention is composed of a light source unit 12, a light guide plate 14, and a prism body 16. Here, the light source unit 12 is linearly illustrated in
The light guide plate 14 is formed by which transparent resin materials such as polycarbonate resin, etc. are shaped into a certain thickness. Further, the light guide plate 14 is formed to have a certain symmetric configuration in a plan view. In
As shown in
In the example of
The prism body 16, in the example of
The prism 16a of the prism body 16 is formed as that a luminous intensity distribution of the emitted light L0 from the exit surface 14b of the light guide plate 14 where the prism body 16 is not provided, and a luminous intensity distribution of the emitted light L1 obtainable by which the emitted light L0 is refracted by the prism body 16 have a complementary relation therebetween being thus able to obtain desired luminous intensity distribution properties. As discussed hereinabove, in the example of
Also, in the prism 16a of
Next,
As shown in
According to the embodiments of the present invention as discussed hereinabove, the following operational effects are obtainable. Considering the illuminator 10, by arranging the prism body 16 only on the certain area of the emitted surface 14b of the light guide plate 14, the emitted lights L0 are partially refracted in a desired direction. Accordingly, a necessary wide luminous intensity distribution can be achieved through the emitted light L1 that has been emitted from the exit surface 14b of the light guide plate 14 and that has been refracted by the prism body 16, and the other emitted lights, that is, the emitted light L0 that has been emitted form an area where the prism body 16 is not arranged on the exit surface 14b of the light guide plate 14.
According to the example of
As shown above, the prism 16a of the prism body 16 is formed as that a luminous intensity distribution of the emitted light L0 from the exit surface 14b of the light guide plate 14 where the prism body 16 is not provided, and a luminous intensity distribution of the emitted light L1 obtainable by which the emitted light is refracted by the prism body 16 have a complementary relation therebetween thereby being able to obtain desired luminous intensity distribution properties. Accordingly, a necessary wide luminous intensity distribution can be achieved through a combination of 1) a luminous intensity distribution of the emitted light L1 that have been refracted by the prism body 16; and 2) a luminous intensity distribution of the emitted light L0 that has exit out from an area where the prism body 16 is not arranged on the exit surface 14b of the light guide plate 14.
In other words, the optical path modification means 14d formed on the reflection surface 14c of the light guide plate 14 is formed as that a luminous intensity distribution of the emitted light L0 that is emitted from the emitted surface 14b, the optical path of the emitted light L0 being changed by means of the optical path modification means 14d, and a luminous intensity distribution of the emitted light L1 obtainable by which the emitted light is refracted by the prism body 16 have a complementary relation therebetween thereby being able to obtain desired luminous intensity distribution properties. Accordingly, a necessary wide luminous intensity distribution can be achieved through a combination of 1) a luminous intensity distribution of the emitted light L1 that have been refracted by the prism body 16; and 2) a luminous intensity distribution of the emitted light L0 that have been emitted from an area where the prism body 16 is not arranged on the exit surface 14b of the light guide plate 14. The size and the inclined angle of both the light path modification means 14d formed on the reflection surface 14c of the light guide plate 14 and the prism 16a of the prism body 16 are optionally adjustable, so that an area to be illuminated will be thus adjustable accordingly.
In addition to the above, since the illuminator according to the embodiments of the present invention is composed only of the light source unit 12, the light guide plate 14, and the prism body 16, its member composition can be said as simple, but its light extraction efficiency can be kept at an advanced level. Further, through the optical path modification means 14d with a mono-shape in section, a necessary wide luminous intensity distribution can be achieved by a combination of 1) a luminous intensity distribution of the emitted light L0 that has exited out from an area where the prism body 16 is not arranged on the exit surface 14b of the light guide plate 14; and 2) a luminous intensity distribution of the emitted light L1 that has been refracted by the prism body 16 with a mono-shape in section. With this sectional mono-shape, it becomes possible to manufacture the light guide plate 14 and the prism body 16 through well-known and general methods thereby readily responding to a demand for large-sized applications.
In
In
In
In
Number | Date | Country | Kind |
---|---|---|---|
2010-285788 | Dec 2010 | JP | national |