JP5831895B2 - Fluorescent rod system - Google Patents

Description

  The present invention relates to a columnar light emitter that can be used in place of a conventional fluorescent lamp.

  Conventionally, there is a rod-shaped fluorescent lamp as one of columnar light emitters used in a lighting fixture. Such a fluorescent lamp emits light from the side, but by arranging a plurality of fluorescent lamps, it can easily irradiate a wide area. For example, it is arranged in large numbers in public institutions such as offices and factories ceilings, stations, etc. It is used as. However, power consumption increases particularly when many arrays are used.

  On the other hand, as a device using a light-emitting diode with low power consumption and a long life, there is a device that realizes surface light emission by arranging a large number of light-emitting diodes on a plane. However, when a large number of light emitting diodes are arranged, there is a problem that even if the power consumption of each of the light emitting diodes is small, the power consumption is large as a whole, so that sufficient power saving cannot be realized. In addition, when a large number of light emitting diodes are used, the total heat radiation amount of the light emitting diodes increases, but there is a problem that it is difficult to solve this heat radiation and a large heat radiation area is required.

As a solution to this problem, there is known a columnar light emitter in which light from a small number of light emitting diodes is incident from the end of the columnar light emitter to realize side light emission (Patent Document 1).
JP2003-141904A

  However, columnar light emitters that emit light from a small number of light-emitting diodes from the edge of the columnar light emitters to achieve side emission can achieve power savings, but the number of light-emitting diodes is small, so the conventional fluorescent Compared with the light, sufficient brightness cannot be obtained. In particular, the central portion far from the light emitting diode as the light source is darkened, and the irradiation distance of the light emitted from the side surface is short and is limited to about 1.5 m to 2 m.

  In order to solve the above problems, the applicant of the present application provides the invention described below.

  As 1st invention, the cylindrical light guide, the light emitting diode which injects light into the cylindrical light guide from the edge part of a cylindrical light guide, and at least 1 along the longitudinal direction of a cylindrical light guide A columnar light-emitting body comprising: a belt-like light reflecting layer, and at least one or more saddle-shaped lens layers along a longitudinal direction of a cylindrical light guide.

  As 2nd invention, the columnar light-emitting body as described in 1st invention provided with a light reflection board in at least one end part of a cylindrical light guide is provided.

  As a third invention, there is provided the columnar light emitter according to the first invention or the second invention, wherein the light emitting front surface of the light emitting diode is inclined with respect to the band-like light reflecting layer of the cylindrical light guide.

  As a fourth invention, the light reflecting plate is arranged according to the first invention to the third invention in which the light reflecting surface is inclined from the center direction of the cylindrical light guide body axis to the strip light reflection layer of the cylindrical light guide body. A columnar light emitter according to any one of the above is provided.

  As a fifth invention, the light reflecting plate provides the columnar light emitter according to any one of the first invention to the third invention which is a convex mirror or a concave mirror.

  The columnar light emitter of the present invention can provide a brighter columnar light emitter even when the number of light emitting diodes is small.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In addition, this invention should not be limited to these embodiments at all, and can be implemented in various modes without departing from the gist thereof. The first embodiment mainly relates to claim 1 and the like. The second embodiment mainly relates to claims 2 to 5 and the like.
<< Embodiment 1 >>
<Embodiment 1: Overview>

The columnar light emitter of this embodiment is characterized by including at least one row of saddle-shaped lens layers along the longitudinal direction of the cylindrical light guide.
<Embodiment 1: Overall configuration>

  FIG. 1 is a conceptual perspective view of a columnar light emitter of the present embodiment.

  FIG. 2 is a conceptual diagram of the columnar light emitter of the present embodiment, in which (a) is a longitudinal sectional view along the longitudinal direction, and (b) is a transverse sectional view perpendicular to the longitudinal direction.

The columnar light emitter of the present embodiment includes a cylindrical light guide (0201), a light emitting diode (0202), a strip-shaped light reflecting layer (0203), and a lens layer (0204). The longitudinal direction refers to the direction indicated by the double arrow 0205.
<Embodiment 1: Configuration of each part>
(Cylindrical light guide)

  The “cylindrical light guide” (0201) is a cylindrical light emitting member whose entire side surface is brightly illuminated by light incident from a light emitting diode described later. Made of material with high light transmittance. For example, transparent acrylic resin or glass resin, gel, quartz and the like. In addition, quartz is preferable when the light emitting diode which injects light into a cylindrical light guide is ultraviolet LED.

  For example, the cylindrical light guide may be configured by a two-layer structure including a central portion called a core and a clad covering the core. The core is made of a material having a higher refractive index than the cladding. For this reason, light that enters the boundary surface between the core and the clad at an incident angle larger than the critical angle is reflected by the boundary surface and spreads over the entire cylindrical light guide. On the other hand, light that enters at an incident angle smaller than the critical angle is emitted to the outside of the cylindrical light guide, so that the entire side surface of the cylindrical light guide shines brightly.

  Alternatively, the cylindrical light guide may have a single layer structure. In this case, since the constituent material of the cylindrical light guide has a higher refractive index than air, light that enters the boundary surface with the air outside the cylindrical light guide at an incident angle larger than the critical angle is at the boundary surface. It is reflected and spreads throughout the cylindrical light guide. On the other hand, light that enters at an incident angle smaller than the critical angle is emitted to the outside of the cylindrical light guide, so that the entire side surface of the cylindrical light guide shines brightly.

  It is preferable that the columnar light guide has a columnar shape without corners or a substantially columnar shape. This is because the shape having no corners is uniformly reflected at the boundary surface, so that the entire cylindrical light guide shines uniformly and brightly. However, a part of the belt-like light reflecting layer, which will be described later, may be planarly configured.

In addition, about manufacture of the columnar light-emitting body of this embodiment, the sheet-like gel of the same or different material as the gel which forms a cylindrical light guide in the middle of a light emitting diode and the tip part of a cylindrical light guide, or Alternatively, compression may be performed so as to sandwich a sheet-like gel made of a material different from the material forming the cylindrical light guide. Alternatively, the light-emitting diode substrate case (0207) that houses the light-emitting diode substrate may be filled with a gel (0208) made of the same or different material as the cylindrical light guide. In these cases, the light output from the light emitting diode is not reflected at the boundary surface of the cylindrical light guide end, and the attenuation factor of the light incident on the cylindrical light guide can be reduced. As a result, the brightness of the cylindrical light guide can be improved by about 20% or more.
(Light emitting diode)

  A “light emitting diode” (0202) is a semiconductor element that emits light using electricity. In this specification, the term “LED” has the same meaning. By using a light emitting diode, power saving and a long life effect can be expected. Particularly, since the frequency of periodic replacement can be drastically reduced, it is particularly suitable for use in a place where replacement work occurs. When used as illumination, the light emitting diode is preferably white, but it may be any color. This light-emitting diode has a function of allowing light to enter the cylindrical light guide from the end of the cylindrical light guide.

The number of light emitting diodes is not particularly limited. Further, the light emitting diode may be configured such that light enters the cylindrical light guide from both ends of the cylindrical light guide. Since the light-emitting diode near the light source is brighter, if the light from the light-emitting diode is incident from both ends, the difference in brightness at both ends is eliminated, and the cylindrical light guide can be illuminated more uniformly.
(Striped light reflection layer)

  The “band-shaped light reflecting layer” (0203) is a band-shaped layer that reflects light.

The band-shaped light reflecting layer may be formed by, for example, printing or applying a white pigment or a scattering material on the outside or inside of the cylindrical light guide. The white pigment and the scattering material are materials having a strong light scattering property, for example, metal oxide particles such as Al ₂ O ₃ , TiO ₂ and SiO ₂ , sulfate particles such as BaSO ₄ , carbonate particles such as CaCO ₃ , glass, and the like. What is necessary is just to consist of 1 type (s) or 2 or more types, such as a fine foam, the inorganic compound particle | grains, such as a glass balloon, and the micro foam which formed the micro air cell.

  At this time, if a part of the cylindrical light guide is configured to be planar, printing and application are easy. However, the strip-shaped light reflecting layer is not necessarily configured to be planar, and may be configured by a curved surface having a shape along the side surface shape of the cylindrical light guide.

Or a strip | belt-shaped light reflection layer can also be formed by using a part of cylindrical light guide as reflecting material mixed resin. Specifically, the transparent material forming the columnar light guide is made of a highly light scattering material, for example, metal oxide particles such as Al ₂ O ₃ , TiO ₂ , and SiO ₂ , and sulfate particles such as BaSO _4. It is formed by mixing one or two or more of carbonate particles such as CaCO ₃ , inorganic compound particles such as glass fine powder and glass balloon, and micro-foamed bodies forming minute air cells.

  Alternatively, the band-like light reflecting layer may be a mirror surface obtained by polishing a metal, depositing or plating a metal on a resin, metal, glass, or the like, or a reflecting material in which prisms or glass beads are embedded.

  Moreover, the strip | belt-shaped light reflection layer is arrange | positioned along the longitudinal direction of a cylindrical light guide.

  Since light is reflected by the band-shaped light reflecting layer, the surface of the cylindrical light guide on which the band-shaped light reflecting layer is disposed is not emitted and becomes dark. On the contrary, the surface of the belt-like light reflecting layer facing the reflecting surface becomes brighter because the emitted light flux increases. Since the belt-like light reflecting layer is arranged along the longitudinal direction of the cylindrical light guide, a portion that emits light brighter than the other portions is formed in a belt along the longitudinal direction of the cylindrical light guide.

  The area around the light-emitting diode that is the light source is relatively bright and darker as it moves away from the light source.Conversely, the area of the band-shaped light reflecting layer is smaller in the vicinity of the light source. By enlarging, the side surface of the cylindrical light guide can be uniformly illuminated in the longitudinal direction.

At least one strip-shaped light reflecting layer may be disposed, but a plurality of strip-shaped light reflecting layers may be disposed.
(Lens layer)

  The “lens layer” (0204) is a layer constituted by a convex lens. The cross section is substantially bowl-shaped.

  FIG. 3 is an example of a schematic diagram showing the function of the lens layer. (A) shows a case where one lens layer is arranged, and (b) shows a case where three lens layers are arranged. . As shown in this figure, when the light reflected by the band-shaped light reflecting layer (0303) is emitted from the side surface of the cylindrical light guide (0301), the light is focused when passing through the lens layer (0304). The luminous flux irradiated per area increases after passing through the lens layer. Therefore, the illuminance increases. Thereby, the irradiation distance of the light emitted from the side surface as the light source is also improved, and a columnar light emitter suitable for practical use as a lighting device can be realized.

  FIG. 4 is an example of a conceptual diagram when the columnar light emitter of the present embodiment is used as illumination. The dotted line shows the main irradiation range when there is no lens layer. On the other hand, the solid line shows the main irradiation range when there is a lens layer. Within this irradiation range, the illuminance is higher than when there is no lens layer.

  Also, the irradiation distance can be extended by aligning the emitted light beams in parallel by the lens layer.

  As the material of the lens layer, glass resin, acrylic resin, gel lens, and the like are conceivable. As the gel lens, a Fresnel lens may be used.

  It is sufficient that at least one lens layer is disposed along the longitudinal direction of the cylindrical light guide. Two or more may be arranged. For example, as shown in FIG. 3B, three are arranged. In this case, the irradiation direction of the cylindrical light emitter can be expanded, and the illuminance in the irradiation direction can be further improved.

  Alternatively, the lens layer may be formed by arranging a plurality of bowl-shaped lenses instead of the saddle type. In this case, the effect of illumination can be obtained.

  The lens layer may be integrally formed with the cylindrical light guide. In this case, there is no boundary surface between the cylindrical light guide and the lens layer, and light emitted from the cylindrical light guide enters the lens layer without being attenuated, so that the light transmission efficiency is high.

Alternatively, the lens layer may be bonded or pressure-bonded to the cylindrical light guide. For example, a gel lens with good adhesion is pressure-bonded. When the gel lens is pressure-bonded, light emitted from the cylindrical light guide is incident on the gel lens without passing through another substance, so that the light transmission efficiency is high.
<Embodiment 1: Effect>

The columnar light emitter of this embodiment can provide a brighter columnar light emitter even when the number of light emitting diodes is small.
<< Embodiment 2 >>
<Embodiment 2: Overview>

  The columnar light emitter of the present embodiment is based on the first embodiment, and further includes a light reflecting plate at least at one end of the cylindrical light guide.

  Furthermore, the light emitting front face of the light emitting diode is inclined with respect to the band-shaped light reflecting layer of the cylindrical light guide, and is characterized in that it is arranged.

  Furthermore, the light reflecting plate is characterized in that the light reflecting surface is disposed so as to be inclined from the center of the cylindrical light guide axis to the belt-like light reflecting layer of the cylindrical light guide.

Furthermore, the light reflecting plate is a convex mirror or a concave mirror.
<Embodiment 2: Overall configuration>

FIG. 5 is an example of a conceptual diagram showing a longitudinal section in the longitudinal direction of the columnar light emitter of the present embodiment. The columnar light emitter of the present embodiment includes a cylindrical light guide (0501), a light emitting diode (0502), a strip-shaped light reflecting layer (0503), a lens layer (0504), a light reflecting plate (0505), Is provided. Since the cylindrical light guide, the light emitting diode, the belt-like light reflection layer, and the lens layer are the same as those described in the first embodiment, the description thereof is omitted.
(Light reflector)

  The “light reflector” (0505) is a plate-like member provided at the other end of the cylindrical light guide to reflect light from the light emitting diode incident from the end of the cylindrical light guide. It is. The light reflector prevents light from leaking from the end of the cylindrical light guide and increases the amount of light emitted from the side surface of the cylindrical light guide, thereby improving the brightness of the columnar light emitter. Have

The light reflecting plate may be formed, for example, by printing, applying, or the like with a white pigment or a scattering material on the end of the cylindrical light guide. The white pigment and the scattering material are materials having a strong light scattering property, for example, metal oxide particles such as Al ₂ O ₃ , TiO ₂ and SiO ₂ , sulfate particles such as BaSO ₄ , carbonate particles such as CaCO ₃ , glass, and the like. What is necessary is just to consist of 1 type (s) or 2 or more types, such as a fine foam, the inorganic compound particle | grains, such as a glass balloon, and the micro foam which formed the micro air cell.

Or a light reflection board can also be formed by making the edge part of a columnar light guide into reflecting material mixed resin. Specifically, in the transparent material forming the columnar light guide, a material having strong light scattering properties, for example, metal oxide particles such as Al ₂ O ₃ , TiO ₂ and SiO ₂ , sulfate particles such as BaSO ₄ , For example, carbonate particles such as CaCO ₃ , inorganic compound particles such as glass fine powder and glass balloon, and micro foams forming fine air cells are mixed to form one or more kinds.

  Alternatively, the light reflection plate may be a mirror surface obtained by polishing a metal, vapor-depositing or plating a metal on a resin, metal, glass, or the like, or a reflecting material in which prisms or glass beads are embedded.

  As shown in this figure, when the light from the light emitting diode is incident on both ends of the cylindrical light guide, a hole is made in a part of the reflecting plate, and the light of the light emitting diode is incident from there. And it is sufficient. Alternatively, the reflecting plate is a reflecting plate that transmits only light of a specific wavelength and reflects light of other wavelengths, transmits light having a wavelength incident from the light emitting diode, and the light emitting diode is a fluorescent material of the band-shaped light reflecting layer. It is also possible to reflect light having a wavelength that is emitted by exciting the light.

Furthermore, a convex lens or a concave lens may be disposed on the cylindrical light guide side of the light reflecting plate so that the light reflected by the light reflecting plate spreads uniformly on the cylindrical light guide.
(Light emitting diode arrangement angle)

  The arrangement angle of the light emitting diode is not particularly limited. For example, the light emitting diode may be arranged such that the light emitting front surface of the light emitting diode is inclined with respect to the strip light reflection layer of the cylindrical light guide. The light emitting front surface is a surface from which light from the light emitting diode is emitted, and is a portion 0206 indicated by hatching in the schematic diagram of the light emitting diode in FIG.

More preferably, as shown in FIG. 2 (a), the light emitting front surface of the light emitting diode is inclined at an angle so as to face a half of the longitudinal direction of the strip-shaped light reflecting layer of the cylindrical light guide. What is necessary is just to arrange. When light emitting diodes are provided at both ends of the cylindrical light guide, the central portion of the cylindrical light guide is farthest from the light emitting diode that is the light source and becomes darker. In this case, the light emitting front surface of the light emitting diode is inclined at an angle so as to face a half of the longitudinal direction of the strip-shaped light reflecting layer of the cylindrical light guide. Among them, the light at the brightest central portion is directly incident on a half of the longitudinal direction of the strip-shaped light reflecting layer of the cylindrical light guide, so that the central portion can be brightened.
(Distribution angle of light reflector)

The arrangement angle of the light reflecting plate is not particularly limited. For example, as shown in FIG. 5, the light reflecting surface is inclined from the center of the cylindrical light guide axis (0506) to the strip light reflecting layer of the cylindrical light guide. Are preferably arranged. This is because the luminous flux incident on the band-shaped light reflecting layer is increased, and the surface of the band-shaped light reflecting layer facing the reflecting surface can be brightened. Furthermore, when the light emitting front surface of the light emitting diode is arranged perpendicular to the axial center of the cylindrical light guide, the light traveling along the cylindrical light guide axis center is transmitted to the cylindrical light guide. It is preferable to arrange at an angle that reflects to a half of the longitudinal direction of the band-like light reflecting layer. By arranging in this way, the light of the brightest central portion of the light from the light emitting diode is reflected on the light reflecting surface of the light reflecting plate, and in the longitudinal direction of the strip-shaped light reflecting layer of the cylindrical light guide. On the other hand, since it is incident on a half portion, the central portion can be brightened.
(Light reflector shape)

The shape of the light reflecting plate is not particularly limited, but may be, for example, a convex mirror or a concave mirror. In this case, the light reflected by the light reflecting plate is focused or diffused and spreads uniformly on the cylindrical light guide, so that the entire cylindrical light guide can be illuminated uniformly.
<Embodiment 2: Effect>

The columnar light emitter of this embodiment can provide a brighter columnar light emitter even when the number of light emitting diodes is small.
<< Other >>

In addition, a bright columnar light emitter can be provided by efficiently entering light into the cylindrical light guide. For the columnar light emitter described below, the lens layer is not an essential component.
<Technology related to gel use>

In the middle of the light emitting diode and the tip of the cylindrical light guide, a sheet-like gel of the same or different material as the gel forming the cylindrical light guide, or a material different from the material forming the cylindrical light guide You may compress so that the sheet-like gel of this may be pinched | interposed. Alternatively, the light-emitting diode substrate case (0207) that houses the light-emitting diode substrate may be filled with a gel (0208) made of the same or different material as the cylindrical light guide. In these cases, the light output from the light emitting diode is not reflected at the boundary surface of the cylindrical light guide end, and the attenuation factor of the light incident on the cylindrical light guide can be reduced. As a result, the brightness of the cylindrical light guide can be improved by about 20% or more.
<Technology related to light emitting diode placement angle>

  The arrangement angle of the light emitting diodes may be arranged by inclining the light emitting front surface of the light emitting diodes with respect to the band-like light reflecting layer of the cylindrical light guide. The light emitting front surface is a surface from which light from the light emitting diode is emitted, and is a portion 0206 indicated by hatching in the schematic diagram of the light emitting diode in FIG.

More preferably, as shown in FIG. 2 (a), the light emitting front surface of the light emitting diode is inclined at an angle so as to face a half of the longitudinal direction of the strip-shaped light reflecting layer of the cylindrical light guide. What is necessary is just to arrange. When light emitting diodes are provided at both ends of the cylindrical light guide, the central portion of the cylindrical light guide is farthest from the light emitting diode that is the light source and becomes darker. In this case, the light emitting front surface of the light emitting diode is inclined at an angle so as to face a half of the longitudinal direction of the strip-shaped light reflecting layer of the cylindrical light guide. Among them, the light at the brightest central portion is directly incident on a half of the longitudinal direction of the strip-shaped light reflecting layer of the cylindrical light guide, so that the central portion can be brightened.

Conceptual perspective view of the columnar light emitter of the first embodiment. Conceptual diagram of the columnar light emitter of Embodiment 1 Example of schematic diagram showing the function of the lens layer An example of the conceptual diagram at the time of using the columnar light-emitting body of Embodiment 1 as illumination. An example of the conceptual diagram which shows the longitudinal cross-section of the longitudinal direction of the columnar light-emitting body of Embodiment 2. FIG.

Cylindrical light guide 0101, 0201, 0301, 0501
Light emitting diode 0102, 0202, 0502
Band-shaped light reflection layer 0103, 0203, 0303, 0503
Lens layer 0104, 0204, 0304, 0504
Longitudinal direction 0205
Light emitting diode light emitting front face 0206
Light emitting diode substrate case 0207
Gel 0208
Light reflector 0505
Cylindrical light guide axis central direction 0506

Claims (4)

A cylindrical light guide having a two-layer structure of a core and a clad covering the core and having a refractive index lower than that of the core;
A light emitting diode that makes light incident on the cylindrical light guide from the end of the cylindrical light guide,
At least one strip-shaped light reflecting layer along the longitudinal direction of the cylindrical light guide;
At least one or more saddle-shaped lens layers along the longitudinal direction of the cylindrical light guide,
A sheet-like gel that is sandwiched between the light emitting diode and the tip of the cylindrical light guide, and
With
The light emitting diode is disposed so that the light emitting front surface is inclined at an angle facing a half of the longitudinal direction of the band-shaped light reflecting layer,
The lens layer is integrally formed with a clad of a cylindrical light guide.   The columnar light emitter according to claim 1, further comprising a light reflecting plate at least at one end of the cylindrical light guide. The columnar light emitter according to claim 2 , wherein the light reflection plate is disposed such that a light reflection surface is inclined from a center direction of the columnar light guide axis to a band-shaped light reflection layer of the columnar light guide. The columnar light emitter according to claim 2 , wherein the light reflecting plate is a convex mirror or a concave mirror.

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