JP5401650B2 - Lighting device - Google Patents

Description

  The present invention relates to an illuminating device using a plurality of light sources, and more specifically, a uniform surface with a wide area using a plurality of point light sources having a strong directivity, for example, light emitting diodes (hereinafter referred to as LEDs). It is related with the illuminating device which can obtain a shaped illumination light. This illuminating device can be used as an illuminating device for various display boards, electronic bulletin boards, or in-vehicle lighting for automobiles, railway vehicles, airplanes, and the like.

  For example, a planar illumination device uses a diffusion plate made of a plate-like body having a predetermined thickness and area as seen in a backlight for a liquid crystal panel, and a light source such as a fluorescent lamp is arranged directly below the diffusion plate. And using a light source plate composed of a plate-shaped body having a predetermined thickness and area, and a direct illumination device that directly irradiates the diffuser plate with the light source to emit light. 2. Description of the Related Art An edge light type illumination device is known in which a light source such as a fluorescent lamp or an LED is disposed on one side to emit light from a light guide plate surface.

  Of these direct type and edge light type illumination devices, the direct type illumination device has a structure in which a predetermined gap, that is, a predetermined distance is provided between the light source and the diffusion plate. The external shape of the light source is projected on the light source, making it difficult to see and the lighting quality may be reduced.If a light source with strong directivity is used, the brightness of the diffuser plate directly above the light source will become extremely high, There may be a difference in luminance between the illumination area and the uniform illumination light cannot be obtained. Further, as a method for making the brightness uniform, it is conceivable to increase the distance between the diffuser plate and the light source. However, when this method is adopted, the overall distance becomes darker as the distance between the diffuser plate and the light source increases. There is a problem that illumination light cannot be obtained and the thickness cannot be reduced. Since the direct type illumination device has such a problem, it may be difficult to adopt such a direct type illumination device depending on the application.

  Therefore, since this direct type illumination device has the above-mentioned problems, an edge light type illumination device is used instead of this direct type illumination device, and many of this type of illumination device have been proposed. (For example, see Patent Documents 1 to 3 below).

  For example, Patent Literature 1 below discloses an edge light type illumination device. This illuminating device includes a light emitting diode, a light guide plate having a size of a public postcard having a light introduction portion formed on a flat surface, and a reflecting mirror that reflects light from the light emitting diode, and is provided on the flat surface of the light guide plate. A light emitting diode is mounted, and the light emitting diode is covered with a reflecting mirror. And the irradiation light from a light emitting diode is irradiated to a reflective mirror, and is introduce | transduced into a light-guide plate. According to this illumination device, the light emitted from the light emitting diode is efficiently taken into the light guide plate.

  Patent Document 2 listed below discloses an illumination device that includes a light source device that includes an LED and a light source rod, and a light guide plate that guides irradiation light from the light source device. The light source rod is composed of a prism array having a predetermined shape. Then, by this light source rod, the irradiated light from the LED is irradiated to the irradiated object through the light guide plate, and the luminance is equalized.

  In the following Patent Document 3, a plurality of light emitting diodes are arranged at equal intervals on the light incident surface of the light guide, the light from the light emitting diodes is irregularly reflected by the reflector, and the light exit surface of the light guide is reflected by the scattered light. A registration guide lamp is disclosed that emits light and illuminates a display body that is disposed to face a light exit surface of a light guide.

Japanese Patent Laying-Open No. 2005-149848 (paragraph [0012], FIG. 1) JP 2001-236811 (paragraphs [0012] to [0014], FIG. 1) Japanese Patent Laying-Open No. 2005-99406 (paragraphs [0016] and [0017], FIG. 3)

In each of the illumination devices disclosed in Patent Documents 1 to 3, an LED is used as a light source having a strong directivity, and one or more LEDs are arranged on one side or all sides of the rectangular light guide plate. This is an edge light type planar illumination device capable of obtaining uniform illumination light from the light surface.
However, this type of planar illumination device has the following problems. That is, one of the problems is that it is difficult to increase the size because a relatively expensive light guide plate having a predetermined thickness and size is required. For example, in the illuminating device of Patent Document 1, the light guide plate is made of glass or acrylic that is about a postcard made by a government agency, so that it is difficult to increase the size further. Further, if the size is to be increased, a large light guide plate is required, and a plurality of light emitting diodes are required as in the illumination device of Patent Document 3, and the plurality of light emitting diodes are connected to the light guide plate. It must be disposed on the light receiving surface on all sides of the. Therefore, the weight of the lighting device increases, the number of parts increases, and the assembling work becomes troublesome, and the cost further increases. Moreover, although the illumination apparatus of the said patent document 2 needs the light source rod of a special shape, even if it uses this light source rod, the enlargement becomes difficult.
Another problem is that when the size is increased to increase the light emitting area, a large-sized light guide plate is indispensable in proportion thereto, and a thick glass plate or plastic plate is used for such a light guide plate. The weight increases, the weight of the lighting device incorporating the same increases, and the price increases. In addition, when such a large light guide plate is used, the light path from the light source to the light emitting surface is lengthened, so that the attenuation of light increases, making it difficult to obtain uniform illumination light, and high illumination light. It becomes difficult to get. In order to obtain such a high illuminance, a high-power light source is essential and the cost is increased.
Although other problems are related to the above problems, the light path from the light source to the light emitting surface is long even if the light source is arranged on one side of the light guide plate as seen in the illumination devices of Patent Documents 1 and 2 above. As a result, the light attenuation increases, and eventually the size of the light guide plate is limited, so that the size cannot be increased.

  Therefore, the conventional edge light type illumination device uses a light guide plate and has a structure in which a light source is arranged around the light guide plate. Therefore, it is suitable as a small illumination device, but there is a limit to enlargement. There is something.

  In light of the fact that a light guide plate is used in the conventional edge-light type illuminating device, and thus it is difficult to obtain a large area of planar illumination light, the present inventor has a directivity. Even if it was a strong light source, it was searched by repeating trial and error whether it was possible to obtain a plane illumination light with a large area without using a light guide plate. As a result, a point light source with strong directivity, for example, a plurality of LEDs, is used as the light source, and a gap between a pair of opposing reflectors provided with a predetermined reflection / transmission pattern, that is, one end side of both reflectors It is found that the light emitted from a plurality of LEDs can be transmitted efficiently and substantially uniformly dispersed to the other end side relatively distant from the one end side of both reflectors, The present invention has been completed based on the findings.

Therefore, an object of the present invention is an edge light type illumination device, and even if a point light source having strong directivity is used as a light source, a light guide plate that is essential to the prior art is not required, and a uniform surface with a large area is obtained. It is providing the illuminating device which can obtain a shaped illumination light.
Another object of the present invention is to obtain a flat surface illumination light that is thin, lightweight and inexpensive, and has a wide area on either a double-sided or single-sided surface, that is, a single-sided illumination or a double-sided illumination. It is in providing the illuminating device which can be performed.
Another object of the present invention is to provide an illuminating device that saves energy in addition to the above-described object.

The object can be achieved by the following configuration. That is, the invention of the lighting device according to claim 1 of the present application is configured such that a point light source array in which a plurality of point light sources are arranged in a row at a predetermined interval, and the point light source array are positioned between one side portion. A pair of first and second reflecting plate members arranged to face each other at a predetermined distance from the point light source array, and either one of these reflecting plate members or the outside of both reflecting plate members spaced a predetermined distance G ₄ from the reflecting surface and a diffusing plate member disposed so as to face, the distance between the first, second reflector member as G _2, these relationships is G _{4 <G 2} The reflecting plate member facing the diffuser plate member is divided into a plurality of point light source groups by several point light sources adjacent to the point light source array, and each of the plurality of point light source groups Correspondingly, it is subdivided into multiple small reflectors, these Several small reflectors have high reflectance and low light transmittance at locations close to individual point light sources corresponding to each point light source, and the reflectance gradually decreases as the distance from the location increases. Are formed in a single reflection / transmission pattern in which the light transmittance is increased , and the first and second reflection plate members are connected to each other by connecting the plurality of small reflection plates on one side. It is characterized in that the gap is connected by a partition connecting member that transmits or reflects light .

  According to a second aspect of the present invention, in the illumination device according to the first aspect, the small reflector is common to a plurality of individual light source reflection areas respectively corresponding to a plurality of point light sources of the point light source group, and the point light sources. The individual light source reflection area has a high reflectance and a low light transmittance at a location close to each point light source, and gradually increases as the distance from the location increases. The common light source reflection area is formed with an individual reflection / transmission pattern in which the light transmittance is increased while the reflectance is decreased, and the common light source reflection area is lower in reflectance than the decreased reflectance at a position close to each of the individual light source reflection areas. In addition, a common reflection / transmission pattern in which the light transmittance is higher than the increased light transmittance, and the reflectance further decreases as the distance from the portion increases, while the light transmittance further increases. Characterized in that it is formed by down.

According to a third aspect of the present invention, there is provided a lighting device according to a first aspect, wherein a plurality of point light sources are arranged in a line at predetermined intervals, and the first and second point light source arrays. One point light source array is positioned between one end side and the other point light source array is positioned between the other end side part facing the one end side part and away from the one end side part, and separated from each point light source array by a predetermined distance. And a pair of first and second large reflector members made of a relatively large area reflector, and one of these large reflector members, or both large reflectors. and a diffuser member that is disposed opposite from the outer reflection surface of the member spaced a predetermined distance G _4, wherein the first, the distance between the second large-sized reflection plate member as G _2, these relationships G ₄ <Yes set so as to be in G _2,
The large reflector member facing the diffuser member includes third and fourth reflector members, and the first and second point light source rows are adjacent to the third and fourth reflector members. Several point light sources are divided into a plurality of point light source groups, and are divided into a plurality of first and second small reflectors corresponding to the plurality of point light source groups, respectively. The second small reflector has a high reflectance and a low light transmittance at locations close to the individual point light sources corresponding to the respective point light sources, and the reflectance gradually decreases as the distance from the location is increased. On the other hand, it is formed by a single reflection / transmission pattern in which the light transmittance increases.

  According to a fourth aspect of the present invention, in the illumination device according to the third aspect, the small reflecting plate includes a plurality of individual light source reflecting areas respectively corresponding to a plurality of point light sources of the point light source group, and these point light sources. The individual light source reflection region has a high reflectance and a low light transmittance at a location close to each point light source, and gradually increases as the distance from the location increases. The common light source reflection region is formed with an individual reflection / transmission pattern in which the light transmittance is increased while the reflectivity is decreased, and the common light source reflection region is lower in reflection than the decreased reflectivity at a location close to each of the individual light source reflection regions. Common reflection / transmission with a light transmittance that is higher than that of the increased light transmittance, and the reflectance further decreases as the distance from the location increases. Characterized in that it is formed by turns.

The invention according to claim 5 is the illumination apparatus according to any crab of claims 1 to 4, wherein the distance _{G 2} is in the range of 10Mm～25mm, and wherein the distance _{G 4} are at 1mm or more To do.

  According to a sixth aspect of the present invention, in the illumination device according to any one of the first to fourth aspects, the reflection / transmission pattern is formed in a pattern that increases a light transmission area as the distance from the point light source increases. Features.

  According to a seventh aspect of the present invention, in the illumination device according to the sixth aspect, the reflection / transmission pattern is formed by a light conduction hole penetrating the small reflector.

  The invention according to claim 8 is the lighting device according to any one of claims 1 to 4, wherein the point light source is a light emitting diode or a laser diode in which one light emitting element or a plurality of light emitting elements are assembled. And

  According to a tenth aspect of the present invention, in the lighting device according to the third aspect, the first and second large reflector members are the first and second sheets of the third and fourth reflector members. The second small reflecting plates are connected on one side, and the connecting portions facing each other are connected by a partition connecting member that transmits or reflects light.

  The invention according to claim 11 is the illuminating device according to any one of claims 1 to 10, wherein the small reflector and the partition connecting member are formed of an ultrafine foamed light reflecting member.

According to the first and second aspects of the present invention, the light guide plate required in the prior art is not required, the weight can be reduced and the price can be reduced, and the surface illumination light having a large area can be obtained. That is, since the light guide plate is eliminated, it is possible to reduce the weight and the price, and further, uniform light emitted from the point light source array is obtained by a predetermined reflection / transmission pattern to obtain uniform illumination light over a wide area. It becomes possible. In addition, an illumination device that produces illumination light from one side or both sides by providing a predetermined reflection / transmission pattern on one of the first and second reflector members or on both reflector members is produced. It can be used and the usage can be expanded. Moreover, since the connection part of a small reflector is connected by the partition connection member which permeate | transmits or permeate | transmits light, it does not become dark at a connection part and the fall of illumination quality can be prevented. Further, the gap between the opposing reflectors can be secured and maintained at a predetermined distance.

  According to the third and fourth aspects of the present invention, the light guide plate required in the prior art is not required, the weight can be reduced and the price can be reduced, and the surface illumination light having a larger area can be obtained. . In other words, since the light guide plate is eliminated, it is possible to reduce the weight and the price. Further, the predetermined reflection / transmission pattern provided on the reflection plate member makes the emitted light from the point light source array uniform and further increases. It becomes possible to obtain illumination light that is uniform in area. In addition, by providing a predetermined reflection / transmission pattern on one or both of the first and second reflector members, illumination light can be obtained from one or both sides, and an illumination device can be manufactured. To expand the usage.

According to the invention of claim 5, the distance G ₂ by a range of 10Mm～25mm, can be transferred to a position away from the point source of the reflector member without attenuating the light from the point light source. Further, by the G ₄ or more 1.0 mm, comprising a reflection pattern of the reflection plate member hardly visible through the diffuser member. As a result, the thickness can be reduced.

  According to the invention of claim 6, the reflection / transmission pattern can be easily created. That is, a desired reflection / transmission pattern can be easily created by setting the light transmission area of the small reflector to a predetermined size.

  According to the seventh aspect of the present invention, the reflection / transmission pattern can be easily created by providing the small reflector with the through hole for conducting light.

  According to invention of Claim 8, since a light emitting diode or a laser diode is used for a point light source, it is long-lived, power consumption decreases, and an illuminating device can be energy-saving.

According to invention of Claim 9 , since the connection part of a small reflector is connected by the partition connection member which transmits or permeate | transmits light, it does not become dark at a connection part and the fall of illumination quality can be prevented. Further, the gap between the opposing reflectors can be secured and maintained at a predetermined distance.

According to the invention of claim 10 , by adopting the ultrafine foamed light reflecting member, it is easy to obtain and processing is easy.

FIG. 1 is an external perspective view of a lighting apparatus according to Embodiment 1 of the present invention. FIG. 2 is a cross-sectional view taken along line II-II of the illumination device of FIG. 3 is an assembled perspective view of a point light source, a reflecting plate member, and a diffusing plate member housed in the frame of the lighting device of FIG. FIG. 4 is an exploded view of the point light source, the reflecting plate member, and the diffusing plate member of FIG. FIG. 5 is a side view showing part of the point light source array and the reflector member of FIG. 6 is a front view of a connecting member that connects the pair of small reflectors shown in FIG. FIG. 7 is a front view of the connecting member showing a modification of the connecting member of FIG. 8A is an enlarged view of the portion A1 in FIG. 5, and FIG. 8B is an enlarged view of the portion A2 in FIG. FIG. 9 is an explanatory diagram for obtaining the illuminance at a predetermined position. FIG. 10 is a diagram showing the light distribution characteristics of the LED. FIG. 11 is an exploded view of a point light source, a reflecting plate, and a diffusing plate constituting the illumination device of Embodiment 2 of the present invention. FIG. 12 is an exploded view of a point light source, a reflecting plate, and a diffusing plate constituting the illuminating device according to Embodiment 3 of the present invention. FIG. 13 is a side view showing a part of the point light source array and the reflector member of FIG. FIG. 14 is an exploded view of a point light source, a reflecting plate, and a diffusing plate constituting the illumination device of Embodiment 4 of the present invention.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. However, the embodiment described below exemplifies a lighting device for embodying the technical idea of the present invention, and is not intended to specify the present invention. It is equally applicable to the other embodiments included.

With reference to FIGS. 1-3, the whole structure of the illuminating device which concerns on Embodiment 1 of this invention is demonstrated. 1 is an external perspective view of the illumination device according to Embodiment 1 of the present invention, FIG. 2 is a cross-sectional view of the illumination device taken along line II-II in FIG. 1, and FIG. 3 is a frame of the illumination device in FIG. FIG.
As shown in FIGS. 1 and 2, the lighting device 1 according to Embodiment 1 of the present invention has a pair of long side frames 2a, 2b and short side frames 2c, 2d facing each other, and has a predetermined size on the front and rear surfaces. Point frame 3 provided with window 2e, 2e ', point light source array 3 in which a plurality of point light sources are arranged in a line at predetermined intervals in the frame, and the point light source array first pair by interposing the point light source array 3 from the predetermined gaps G ₃ was placed in parallel to each away respectively between the second reflector member 4A, and 4B, the outer of these reflector member first pair of the predetermined gap G ₄ from the reflecting surface and arranged to be parallel to each opened respectively, the second diffusion plate member 7A, has a structure in which 7B and are housed. The frame 2 has a frame shape having a length X of each of the opposing long side frames 2a, 2b, a length Y of each short side frame, and a thickness Z and having windows 2e, 2e 'of predetermined sizes on the front and rear surfaces, respectively. None, formed of a synthetic resin molding or a metal plate. The frame 2 has a narrow frame by narrowing the width a of the frame. By narrowing the frame, the area of the window increases, and as a result, the illumination area can be expanded. This narrowing of the frame is achieved by a configuration in which a member housed inside the frame body 2, particularly the point light source array 3, is interposed between one end sides of the pair of first and second reflectors 4 </ b> A and 4 </ b> B.

In this embodiment, the dimensions of each side frame have the following values. That is, the length X of each long side frame 2a, 2b is 650 mm, each short side frame Y is 400 mm, and thickness Z is 38 mm. The first, second reflector member 4A, spacing _{G 2} 4B is 20 mm, the first, second reflector 4A, 4B and the first and second diffusion plate member 7A, intervals _{G 4} between 7B Is 5 mm. Furthermore, the width length a of the frame is 25 mm. Spacing _{G 4} are 5mm or less, for example may be about 1 to 2 mm.

Arrangement of these reflector member and the diffusion plate member has first and second reflector members 4A, when narrowing the gap G ₂ of 4B, hardly propagation of the reflected light between the two reflecting plate members, or light attenuation becomes large, it becomes difficult to reach the light emitted from the point light source to a remote second end sides of the reflector member, whereas, when broadly this interval G _2, the thickness of the illuminating device is increased.
Therefore, in this embodiment, first, second reflector member 4A, was confirmed by either experimental be narrowed to what extent the gap G ₂ 4B. Conditions of the experiment are described below reflector member, i.e., is obtained by forming a predetermined reflection and transmission pattern using a material of the reflecting plate members, the limit value of the gap G ₂ is, it found that generally preceding and 20mm It was. By changing the material and the reflection and transmission pattern of the light reflection plate member, it was confirmed to be able to avoid the above problem if the distance G ₂ 15 mm or more.
Moreover, when narrowing the gap G ₄ between the reflector member diffusing plate member, easily visible through the diffuser member reflection and transmission pattern of the reflector member to be described later, may cause a reduction in illumination quality, whereas, the a broad gap G _4, the lighting device becomes thick. Limit of the gap G ₄ are was confirmed under the conditions of the experiment, can not zero value, it was confirmed that it was possible narrowed to about 1 to 2 mm.
Accordingly, first, second reflector member 4A, the gap _{G 2} 4B is an attempt to obtain illumination light having a large area can not be narrowed, minimum 15mm~20mm is required, whereas, the gap _{G 4} are It can be narrowed to about 1-2 mm. Incidentally, those gaps G ₂ is changed by the size of the lighting device, may be 10mm or less for small lighting apparatus. As a result, the illuminating device can be made thinner and more lightweight. Therefore, these gaps G ₂ and G ₄ are set to the above dimensions in consideration of the above points.

  In this embodiment, the frame body 2 is provided with windows 2e and 2e 'on the front and rear surfaces, respectively, and is a double-sided illumination that can emit light from the front and back surfaces. Also good. In the case of this single-side illumination, one of the pair of first and second reflectors is formed by a reflector having a predetermined reflection / light transmission pattern, which will be described later, and the other ordinary reflector A member, that is, a reflector having a reflective surface with a high reflectance is used. When this reflector is used, the diffuser member becomes unnecessary. Further, the frame 2 has a horizontally long shape in the state of FIG. 1, but may be a vertically long shape, and when this vertically long shape is used, the point light source array has a long side portion. It will be arranged between.

As shown in FIG. 5, the point light source array 3 uses a highly directional point light source such as an LED or a laser diode, and the point light source has a predetermined interval L ₁₁ on a substrate 3A having a predetermined length. They are arranged in a row. In addition, you may use LED and the laser diode which attached the lens to each light emission part. Since these LEDs and laser diodes have characteristics of long life and low power consumption, it is possible to save energy in the lighting device. In this embodiment, an example using LEDs will be described. The substrate 3A is made of a material having a high reflectance. When the lighting device is assembled, the reflector 3A ′ is mounted at a position facing the substrate 3A, that is, at the other end of the pair of first and second reflector members 4A and 4B (FIG. 2). reference). The reflector 3A ′ has a plurality of point light sources arranged in the illumination device according to the second embodiment to be described later.

The light source array 3 is grouped by several adjacent LEDs, that is, a plurality of, for example, _two adjacent LEDs _{3 1} , 3 ₂ , similarly adjacent LEDs _{3 3} , 3 ₄ , adjacent LEDs 3 ₅ , 3 ₆ , respectively. Has been. Individual small reflectors are irradiated using the grouped LEDs (see FIG. 4). Note that the number of LEDs to be grouped is not limited to two and may be more. When two or more are grouped, a small reflector described later is changed depending on the number. Further, the number of groups may be one instead of plural.

The first and second reflecting plate members 4A and 4B will be described with reference to FIGS. 4 is an exploded perspective view of the point light source, the reflecting plate member, and the diffusing plate member of FIG.
The first and second reflecting plate members 4A and 4B are made of a rectangular plate having a predetermined width length W ₁ and height Y ₁ (X> W ₁ , Y> Y ₁ ) and a thickness, and are highly reflective. It is made of a material having a low transmittance, a low light transmittance, and a low light absorption rate. Moreover, what reflects on both surfaces is preferable. In addition to this, a material that diffusely reflects is preferable. An example of such a material is an ultrafine foamed light reflecting member. These reflector members 4A and 4B have the same size as the diffuser members 7A and 7B. As this ultrafine foamed light reflecting member, those having a reflectance of 98%, a light transmittance of 1% and a light absorption of about 1% are known, and it is preferable to use this material. As other materials, titanium white fine particles emulsified or polytetrafluoroethylene fine particles emulsified may be provided on the member by coating or screen printing. The first and second reflecting plate members 4A and 4B are made of the above-described material having a high light reflectance (including irregular reflection) and a low light transmittance and a low light absorption rate. Is configured to control.

As shown in FIG. 4, the first reflecting plate member 4 </ b> A is configured by connecting _three small reflecting plates (hereinafter referred to as small reflecting plates) 4 </ b> A _{1 to} 4 </ b> A _3. is composed of one plate member 4B to be connected to three small reflector _4B 1 _{~4B 3.} Individual small reflectors 4A _{1 to} 4A ₃ and 4B _{1 to} 4B ₃ have the same configuration. The number of small reflectors may be any number, for example, one, two, or even four or more. The point light source array 3, that is, the number of groups is changed depending on the number of small reflectors. The three small reflectors 4A _{1 to} 4A ₃ are each composed of two LEDs grouped, namely adjacent LEDs 3 ₁ , 3 ₂ , as well as adjacent LEDs _{3 3} , 3 ₄ , adjacent LEDs 3 ₅ , 3 ₆ . Irradiated. First, second reflector members 4A, 4B are each continuously connected multiple sheets of small reflector _4A 1 to 4A ₃ and _4B 1 _{~4B 3,} further the respective small reflecting plates _4A 1 to 4A ₃ Small The reflectors 4B _{1 to} 4B ₃ are arranged to face each other and are connected by the partition wall connecting member 6 at the connecting portion.

The partition wall connecting member will be described with reference to FIGS. 6 is a front view of the partition wall connecting member, and FIG. 7 is a front view showing a modification of the partition wall connecting member.
A partition wall connecting member (hereinafter referred to as a connecting member) 6 is a member that connects between the connecting portions of the opposing small reflectors and mechanically connects them, and also serves to open a predetermined gap between the connecting portions. It has become. Further, the connecting member 6 reflects the light from each LED and limits the transmission distance. As a result, the light attenuation factor is suppressed, and the light use efficiency is increased. The connecting member 6 is composed of a long strip having a width L ₂ that opens a predetermined gap G ₂ between the opposing small reflectors and a length Y ₁ in the longitudinal direction, and has reflective surfaces on both sides. It is formed of a reflector plate material. This reflection plate material is formed of the same material as the reflection plate member. It is preferable to use an ultrafine foamed reflective member. Length in the longitudinal direction is the same as the length Y ₁ of the small reflector. In the longitudinal direction, at predetermined intervals Y _4, a pair of locking claws 6 ₂ protruding a predetermined length from both sides in the direction orthogonal to the longitudinal direction is provided. The connecting portions facing each other are joined by these locking claws. Moreover, the strip, each the same distance Y _4, through holes 6 ₁ is provided extending through the member. Through holes 6 ₁ has a predetermined opening area, the light from the opening is conductive. Further, strip is engaging claw 6 ₂ pair at predetermined intervals Y ₄ is provided, in the middle is connecting for connecting the pair of engaging claw 6 ₂ and another pair of engaging claw 6 ₂ It is narrowed down, that is, the width of the strip is narrowed. Light is also conducted from this narrowed portion.
A plurality of connecting members 6 are prepared, and the connecting portions of the respective opposing small reflectors are connected. This connection, first, second reflector member 4A, between 4B, the gap _{G 2} is ensured. Moreover, since these connection members 6 allow light to pass through, the connection portions 6 do not become dark.
The connecting member 6 is not limited to the above shape, and can be changed to any shape. A modification of the connecting member will be described with reference to FIG. The connecting member 6 </ _b > A has the same width length L < _b > ₂ by eliminating the narrowing portion of the connecting member 6. According to this connecting member 6A, the mechanical strength can be increased. It is also a through hole 6 ₁ in the coupling member 6A provided. Further, the connecting members 6 and 6A are formed of long strips, but may be changed to small pieces provided with a pair of locking claws, for example, the shapes shown in B1 to B3 in FIG. These connecting members B1 to B3 are particularly suitable for thinning.

With reference to FIG. 5, the relationship between _one small reflector 4A ₁ and the grouped LEDs 3 ₁ and 3 ₂ will be described. FIG. 5 is a side view showing part of the point light source array and the small reflector in FIG. Small reflector 4A ₁ is closed and the bottom 4a of predetermined width length W _2, a pair of side edges 4b extending a predetermined length Y ₁ from both side ends of the base, and 4c, the upper side 4d connecting the both sides And it has a rectangular shape.
Two adjacent LEDs 3 ₁ , 3 ₂ grouped have a length L ₁ corresponding to the small reflector 4A ₁ of the substrate 3A, and a predetermined distance L ₁₁ on the substrate of this length portion. It is arranged with a gap. That is, in these LEDs, both LEDs 3 ₁ and 3 ₂ are spaced from each other by a distance L ₁₁ , but the distance from both ends of the length L ₁ is a distance L ₁₂ . The distance _{L 12} is in the one-half of the distance _{L 11.} The length _{L 1} is the same as the width dimension _{W 2} of the small reflector 4A _1. The width length 3W ₂ was connected to three small reflector has a W ₁ in FIG.

This small reflector 4A _1, to the two LED 3 _{1, 3 2} adjacent grouped, three regions, i.e., two adjacent LED 3 _{1, 3 2} into two separate individually corresponding to The light source reflection areas 5A and 5B and the common light source reflection area 5AB common to the LEDs 3 ₁ and 3 ₂ are partitioned. Individual light source reflection region 5A, 5B includes a width dimension _{W 21} which bisects the length _{W 2} of the bottom side 4a, and has a region surrounded from the bottom 4a at a predetermined height _{Y 2.} The height Y ₂ of the individual light source reflection region is set by such an opening area of the LED power and below light introducing hole for substantially the entire height of Y _1, one third or a neighboring high Is set. These individual light sources reflecting regions 5A, 5B are in the respective LED 3 _{1, 3 2} each LED 3 ₁ light emitted from, _{3 2} close to the area is reflected by the high reflectance and low light transmittance, these The reflection / transmission pattern (hereinafter also referred to as individual reflection / transmission pattern) that gradually lowers the reflectance and increases the light transmittance as the distance from the light sources, that is, the LEDs 3 ₁ and 3 ₂ increases. The individual reflection / transmission patterns of the two individual light source reflection areas 5A and 5B are the same. The common light source reflection region 5AB is a top side 4d from the upper side with a predetermined length Y ₃ surrounded by the lowered partial regions, each individual light source reflection region 5A, the individual light sources reflected light reflected by the 5B A reflection / transmission pattern (hereinafter also referred to as a common reflection / transmission pattern) is formed that reflects with a reflectance lower than that of the reflection regions 5A and 5B and transmits with a higher light transmittance. That is, the area close to the individual light source reflection areas 5A and 5B is reflected with a high reflectance (but this reflectance is lower than the reflectance of the individual light source reflection areas 5A and 5B) and has a low light transmittance (however, The light transmittance is higher than the light transmittance of the individual light source reflection areas 5A and 5B), and the reflectance is gradually lowered as the distance from the individual light source reflection areas 5A and 5B increases. It is formed with a reflection / transmission pattern that increases the rate. These individual reflection / transmission patterns and common reflection / transmission patterns may be arbitrary as long as they have the above-described reflection and transmission characteristics.

An example of the individual reflection / transmission pattern of the individual light source reflection areas 5A and 5B and the common reflection / transmission pattern of the common light source reflection area 5AB will be described with reference to FIGS. 8A is an A1 portion of FIG. 5, FIG. 8B is an enlarged view of the A2 portion of FIG. 5, FIG. 9 is a positional relationship diagram of a point light source (LED) and a predetermined position for obtaining illuminance, and FIG. It is a figure showing a characteristic.
Since the individual reflection / transmission patterns of the individual light source reflection areas 5A and 5B are the same, the individual reflection / transmission pattern of one individual light source reflection area 5A will be described.
As shown in FIG. 5, the small reflector 4A ₁ of individual light source reflection region 5A, the light introducing hole comprising a plurality of through holes for passing light is formed. Each of these photoconductive holes has an opening (area) of a predetermined size and is arranged with a predetermined regularity. In this embodiment, these light introducing hole is made a predetermined size on a predetermined optical axis of the LED 3 _1, i.e. the sequence of the through-hole having a predetermined opening area.

The size of the opening of these photoconductive holes is determined as follows. First, the illuminance L is calculated by calculation, and as shown in FIG. 8A, a circular opening having the maximum radius Rmax is provided in an area Dmax where the illuminance L is lowest. The radius Rmax is 40% of the length of one side of the area, that is, the diameter is 80% of the length of one side of the area.
Larger more radial apertures and a portion between the openings (hereinafter, bars hereinafter) becomes thinner, because the durability of the small reflector 4A ₁ is lowered. If the durability can be maintained, this value of 80% can be reduced to about 90%. Further, the shape of the aperture is not circular, satisfies the transmittance at a predetermined location, as long as the durability of the small reflector 4A ₁ part of bars is not too thin is maintained, a triangle or a quadrangle, star, etc., which Such a shape may be used.

Next, the size of the opening provided in the area Di, j other than Dmax is determined based on the radius Rmax provided in Dmax. First, the distance Li from the point light source _{3 1} to another area Di, position Pi of the j, j (area Di, such as the shortest position of the gravity center position and the point light source _{3 1} j), and j, the directivity angle φi , J. The illuminance Ii, j in the predetermined area Di, j may be measured using an illuminometer, or an approximate value may be obtained by calculation.

The illuminance Ii, j at the predetermined position Pi, j is calculated by the distance Li, j and the directivity angle φi, j.
An origin point light source 3 ₁ 9, a direction parallel to the small reflective plate 4A ₁ the x-axis, a direction perpendicularly intersecting the y-axis on the x-axis a substrate parallel to the plane, a z-axis The orthogonal coordinates of the predetermined position Pi, j are (x _{i, j} , y _{i, j} , z _{i, j} ) in the direction perpendicular to the substrate. Maximum luminous intensity LImax, as shown in FIG. 9 emitted from the point light source _{3 1} is perpendicular to the direction of the z-axis positive, a predetermined position Pi, the luminous intensity in the j direction is the LImax · cosφ _{i, j.} Since the illuminance is proportional to the luminous intensity and inversely proportional to the square of the distance from the light source, the illuminance Ii, j at the predetermined position Pi, j can be expressed as follows:
Ii, j = K · cos φ _{i, j} / L _{i, j} ²
It becomes. That is, the illuminance Ii, j at a given position Pi, j are determined distance _{L i} from the point light source _{3 1,} and _j, the directivity angle phi _{i, j.}
here,
cos φ _{i, j} = z _{i, j} / (x _{i, j} ² + y _{i, j} ² + z _{i, j} ² ) ^1/2 , Li, j = (x _{i, j} ² + y _{i, j} ² + z _{i, j} ² ) ^1/2
Because
Ii, j = K · z _{i, j} / (x _{i, j} ² + y _{i, j} ² + z _{i, j} ² ) ^3/2
Call it. the distance y-axis direction is constant, predetermined position Pi, illuminance on the j Ii, j is easily calculated on the surface of the small reflector 4A _1, by determining the x-axis direction, distance in the z-axis direction can do.

The size of the opening radius Ri, j at the predetermined position Pi, j is an area inversely proportional to the calculated illuminance, so that the ratio of the illuminance Ii, j and the illuminance Imin in the predetermined region Dmax is routed. calculate. That means
Ri, j = Rmax · √ (Imin / Ii, j)
And Accordingly, the higher the illuminance in the predetermined area Di, j, the smaller the area of the opening in the predetermined area Di, j. The above calculation shows an approximate tendency. Actually, since the illuminance is determined by reflecting a number of times between the reflecting members having a large number of apertures, correction according to the actual illuminance flatness is required. When the aperture value is calculated based on the measured value of illuminance, correction may be required in the same manner.

  Although it is preferable to reduce the opening area of the light conducting hole of the individual light source reflecting region 5A, if it is made small, it becomes difficult to perforate the reflecting plate. Therefore, in this embodiment, the diameter at the minimum opening is set to 0.05 mm to 0.1 mm. The light conducting holes having the minimum opening are arranged in an area close to a point light source (LED).

As shown in the light distribution characteristic of FIG. 10, the luminous intensity of the LED decreases as the inclination from the optical axis increases. Accordingly, as shown in FIG. 5, the distance equal from the point light source, than the opening H _{1, 10} in a direction perpendicular to the substrate, larger luminous intensity towards _the opening H _{10, 1} in a direction parallel to the substrate It has become.
Here, the point light source 3 ₁ around the area of the opening is much smaller, it may be provided with a light introducing hole having a small opening is technically difficult. In this case, the radius of the opening is doubled, for example, and the reflector is thinned, that is, a non-through hole. By doubling the radius, the range of thinning increases, making it easier to cut. Moreover, since it is not penetrating, the direct light from the point light source does not reach and it becomes easy to make the illuminance uniform.

The individual reflection / transmission pattern of the individual light source reflection area 5A has been described above. The common reflection / transmission pattern of the common light source reflection area 5AB is also provided with a light conduction hole of a predetermined size in the same manner.
Since the light conduction holes of the common light source reflection region 5AB correspond to the adjacent LEDs 3 ₁ and 3 ₂ , it is assumed that the virtual point light source 3 ₁₂ illustrated in FIG. The opening area of the hole is determined.

  The opening area is determined by the above method. As a result, in the individual light source reflection regions 5A and 5B, the reflectance is low and the light transmittance is low at a location close to each LED, and the reflectance gradually decreases as the distance from the location is increased. On the other hand, it is formed of an individual reflection / transmission pattern in which the light transmittance increases, and the common light source reflection area 5AB has a lower reflectance than the lowered reflectance in the vicinity of the individual source reflection areas 5A and 5B. In addition, the light transmittance is higher than that of the increased light transmittance, and the common light reflection / transmission pattern is formed such that the reflectance further decreases as the distance from the portion increases, while the high light transmittance further increases. .

In this embodiment, in the first and second reflectors 4A and 4B, a plurality of light conducting holes having openings of a predetermined size are arranged on a predetermined regularity, that is, on a directional angle line, but other methods, for example, The opening area may be determined by the distance from the point light source.
In this embodiment, the number of grouped point light sources is two, but the number of point light sources may be three or more. That is, even if the first and second reflectors 4A and 4B are provided with the individual light source reflection area for each individual LED and the common light source reflection area common to all the LEDs included in the group, the same effect is obtained. can get.

  Since the first and second diffusion plate members 7A and 7B use known diffusion plates, description thereof is omitted.

The illuminating device 1 of Embodiment 1 is assembled using these small reflectors, a connecting member, a substrate provided with a point light source array, a diffusion plate member, and a frame. In the assembly, first, the three small reflectors 4A _{1 to} 4A ₃ are connected to form the first reflector member 4A. Similarly, three small reflectors 4B _{1 to} 4B ₃ are connected to form a second reflector member 4B. The first and second reflecting plate members are opposed to each other, and the connecting portions of the reflecting plates facing each other are connected by the partition wall connecting member 6. Next, the connected first and second reflecting plate members 4A and 4B and the first and second diffusing plate members 7A and 7B are assembled into the frame body 2. At that time, the substrate 3A provided with a point light source in advance is mounted. These components are accommodated in the long side frame 2b, and the assembly is completed.
According to this illuminating device, the light guide plate required in the prior art is not required, the weight can be reduced and the price can be reduced, and uniform surface illumination light can be obtained in a large area. That is, since the light guide plate is eliminated, the weight can be reduced and the price can be reduced. Further, the light emitted from the point light source array can be obtained by the individual reflection / transmission pattern of the individual light source reflection area and the common reflection / transmission pattern of the common light source area. It is possible to obtain uniform illumination light over a wide area. That is, the light from the point light source array is between the first and second reflecting plate members, and is first reflected and transmitted by the individual light source reflecting region of each small reflecting plate, and then reflected and transmitted by the common light source reflecting region. Therefore, uniform surface illumination light can be obtained over a wide area. In addition, by providing individual reflection / transmission patterns and common reflection / transmission patterns on one or both of the first and second reflection plate members, illumination light can be obtained from one side or both sides. The usage can be expanded. Furthermore, since a light-emitting diode or a laser diode is used as the point light source, it has a long life and power consumption is reduced, so that the lighting device can save energy.

Next, with reference to FIG. 11, the illuminating device which concerns on Embodiment 2 of this invention is demonstrated. FIG. 11 is an exploded view of a point light source array, a reflecting plate member, and a diffusing plate member that constitute the illumination device according to the second embodiment of the present invention. FIG. 11 corresponds to FIG. 4 of the illumination device of the first embodiment.
The illuminating device according to Embodiment 2 of the present invention increases the number of point light source arrays of the illuminating device 1 according to Embodiment 1 by one, and increases the size of the reflecting plate member and the diffusing plate member with the addition of the point light source array. The size of the frame that accommodates these components is also increased. Therefore, since the function is the same as that of the lighting device 1 although the size is different from that of the lighting device 1, the same components as those in the lighting device 1 are denoted by the same reference numerals, and a detailed description of the different configurations will be omitted without redundant description.
The illuminating device according to Embodiment 2 includes first and second point light source rows 3 and 3 ′ in which a plurality of point light sources are arranged in a row at predetermined intervals, and the first and second point light sources. One point light source column 3 of the point light source column is positioned between one end side and the other light source column 3 ′ is positioned between the other end side facing the one end side and away from the one end side. A pair of first and second large reflector members 41A, 41B arranged to face each other at a predetermined distance from each other, and a pair arranged to face each other with a predetermined distance from the outer reflecting surface of these large reflector members Diffusion plate members 7A ′ and 7B ′ are provided. Each of the diffusion plate members 7A ′ and 7B ′ has a large size in accordance with the first and second large-format reflection plate members 41A and 41B, and the large-format reflection plate members 41A and 41B and the point light source array 3A, In 3A ′ and the like, the number of small reflectors and the number of point light sources are large.
Of the first and second point light source arrays 3A and 3A ′, one point light source array 3A ′ is an additional one.
The configuration is such that the point light source array 3A is turned upside down. Of the first and second large reflector members 41A and 41B, one first large reflector member 41A is the reflector member 4A having the same configuration as the first reflector member of the lighting device 1 of the first embodiment. And a reflecting plate member 4A ′ which is added upside down in the state shown in FIG. These reflector members 4A and 4A 'are expressed as third and fourth reflector members in the claims. Each of these reflecting plate members 4A, 4A 'is composed of a plurality of small reflecting plates, and these are connected to each other. That is, the first large-sized reflecting plate member 41A is composed of reflecting plate members 4A and 4A ′, and these reflecting plate members 4A and 4A ′ are connected vertically in the state of FIG. In 4A ′, a plurality of small reflectors are connected in the horizontal direction in the state of FIG.
The other second large-sized reflecting plate member 41B is the reflecting plate member 4B having the same configuration as the first reflecting plate member of the lighting device 1 of Embodiment 1, and this reflecting plate member is turned upside down in the state of FIG. It is comprised with the additional reflecting plate member 4B '. These reflector members 4B and 4B 'are expressed as third and fourth reflector members in the claims. Each of these reflecting plate members 4B and 4B ′ is composed of a plurality of small reflecting plates, which are connected to each other. That is, the second large-sized reflecting plate member 41B includes reflecting plate members 4B and 4B ′, and these reflecting plate members 4B and 4B ′ are connected vertically in the state of FIG. In 4B ′, a plurality of small reflectors are connected in the horizontal direction in the state of FIG.
These first and second large reflector members 41A and 41B are opposed to each other with a predetermined gap, and the opposed small reflectors are respectively coupled by a partition wall connecting member and accommodated in a large frame, and the lighting device Has been made.

  According to this illuminating device, the light guide plate required in the prior art is not required, the weight can be reduced, and the surface illumination light can be obtained in a large area and evenly. That is, since the light guide plate is eliminated, it is possible to reduce the weight and the price, and further, the light emitted from the point light source array can be obtained by the individual reflection / transmission pattern of the individual light source region and the common reflection / transmission pattern of the common light source region. It is possible to obtain uniform illumination light with a larger area evenly. In addition, by providing individual reflection / transmission patterns and common reflection / transmission patterns on one or both of the first and second reflection plate members, illumination light can be obtained from one side or both sides. Can be manufactured and the usage can be expanded.

  The illumination devices according to these Embodiments 1 and 2 are divided into individual light source reflection areas and common light source reflection areas for LEDs in which small reflectors are grouped. Instead, each LED may be provided with a reflection / transmission pattern. Hereinafter, an illumination device provided with such a reflection / transmission pattern will be described.

With reference to FIG. 12, FIG. 13, the illuminating device which concerns on Embodiment 3 of this invention is demonstrated. 12 is an exploded view of a point light source array, a reflecting plate member, and a diffusing plate member constituting the illumination device of Embodiment 3 of the present invention, and FIG. 13 shows a part of the point light source array and the reflecting plate member of FIG. FIG.
The illumination device according to Embodiment 3 of the present invention is different in only the configuration of part of the first and second reflector members of the illumination device 1 according to Embodiment 1, and the other configurations are the same. The same components as those in the lighting device 1 are denoted by the same reference numerals, and a description of the different components will be described in detail by omitting redundant description.
The illumination device according to Embodiment 3 of the present invention is different in the reflection / transmission patterns of the first and second reflector members 4A and 4B constituting the illumination device 1. That is, the first and second reflecting plate members 4C and 4D of the lighting device according to the third embodiment have their respective reflection / transmission patterns divided into the individual light source reflection area and the common light source reflection area, and the respective LEDs. On the other hand, a single reflection / transmission pattern (hereinafter referred to as a single reflection / transmission pattern) is formed. This single reflection / transmission pattern is obtained by extending the individual reflection / transmission pattern in a direction away from the LED.
The first and second reflecting plate members 4C and 4D are composed of a plurality of small reflecting plates, like the first and second reflecting plate members 4A and 4B of the lighting device 1. These small reflectors have the same configuration.
As shown in FIG. 13, the small reflector 4C ₁ is not divided into an individual light source reflection area and a common light source reflection area, but is configured by a single reflection / transmission pattern for each LED. Is different from the small reflector 4A ₁ (see FIG. 5).
These single reflection / transmission patterns are formed by the same method as the individual reflection / transmission patterns. That is, each LED 3 ₁ and LED 3 ₂ are created by the individual reflection / transmission pattern forming method.
Although the illumination apparatus according to Embodiment 3 has a reflection / transmission pattern different from that of the illumination apparatus 1, the same operational effects as this apparatus can be achieved.

With reference to FIG. 14, the illuminating device which concerns on Embodiment 4 of this invention is demonstrated. FIG. 14 is an exploded view of the point light source array, the reflecting plate member, and the diffusing plate member that constitute the illumination device according to the fourth embodiment of the present invention. FIG. 14 corresponds to FIG. 12 of the illumination device of the third embodiment.
Since the illumination device according to Embodiment 4 of the present invention is different only in the partial configuration of the first and second large reflector members of the illumination device according to Embodiment 2, the other configurations are the same. The components common to the illumination device according to the second embodiment are denoted by the same reference numerals, and a detailed description of the different components will be omitted without redundant description.
The illumination device according to Embodiment 4 of the present invention includes first and second reflector members 4A and 4A ′ in the first and second large reflector members 41A and 41B constituting the illumination device according to Example 2. The reflection / transmission patterns of 4B and 4B ′ are different. Of the first and second large reflector members 41C and 41D of the illumination device according to Embodiment 4, one first large reflector member 41C is the same as the first reflector member of the illumination device of Embodiment 3. The reflection plate member 4C has the same configuration, and the reflection plate member 4C ′ is obtained by adding the reflection plate member upside down in the state shown in FIG. These reflector members 4C and 4C ′ are expressed as third and fourth reflector members in the claims. That is, the first large-sized reflecting plate member 41C includes reflecting plate members 4C and 4C ′, and these reflecting plate members 4C and 4C ′ are connected in the vertical direction in the state of FIG. 14, and further, these reflecting plate members 4C, In 4C ′, a plurality of small reflectors are connected in the horizontal direction in the state of FIG. Each of these reflecting plate members 4C and 4C ′ is composed of a plurality of small reflecting plates, which are connected to each other. In these small reflectors, the single reflection / transmission pattern is formed for each LED.
The other second large-format reflecting plate member 41D is added to the reflecting plate member 4D having the same configuration as the second reflecting plate member of the lighting device of Embodiment 3, and this reflecting plate member is turned upside down in the state of FIG. And the reflecting plate member 4D ′. These reflector members 4D and 4D ′ are expressed as third and fourth reflector members in the claims. Each of these reflecting plate members 4D and 4D ′ is composed of a plurality of small reflecting plates, which are connected to each other. That is, the second large-sized reflecting plate member 41D is composed of reflecting plate members 4D and 4D ′, and these reflecting plate members 4D and 4D ′ are connected vertically in the state of FIG. 11, and further, these reflecting plate members 4D, In 4D ′, a plurality of small reflectors are connected in the horizontal direction in the state of FIG. The single reflection / transmission pattern is also formed on each of these small reflectors for each LED.
Although the illumination device according to the fourth embodiment has a reflection / transmission pattern different from that of the illumination device according to the second embodiment, the same effects as the device can be achieved.

DESCRIPTION OF SYMBOLS 1 Illumination device 2 Frame 3, 3 'Point light source row | line | column 3A, 3A' board | substrate, reflector 4A, 4A ', 4B, 4B', 4C, 4C '4D, 4D' Reflector member 41A, 41B, 41C, 41D Large format Reflective plate members 4A _{1 to} 4A ₃ , 4B _{1 to} 4B ₃ Small reflective plates 5A and 5B Individual light source reflective regions 5AB Common light source reflective regions 6, 6A and 6B Bulkhead connecting members 7A, 7B, 7A ′ and 7B ′ Diffusing plate members

Claims (10)

A point light source array in which a plurality of point light sources are arranged in a row at a predetermined interval, and the point light source array are positioned between one end and facing each other at a predetermined distance from the point light source array first pair that, a second reflector member, diffusion and disposed opposite from the outer reflective surface spaced a predetermined distance G ₄ of either one of the reflecting plate member or both of the reflector member of these reflector member A plate member,
The first, the distance between the second reflector member as G _2, these relationships Yes set to be in the G _{4 <G 2,}
The reflection plate member facing the diffusion plate member is divided into a plurality of point light source groups by several point light sources adjacent to the point light source array, and a plurality of small light sources corresponding to the plurality of point light source groups, respectively. The plurality of small reflectors are divided into reflectors, and the plurality of small reflectors have a high reflectance and a low light transmittance at locations close to the individual point light sources corresponding to the point light sources, and are separated from the locations. Are formed with a single reflection / transmission pattern in which the reflectance gradually decreases while the light transmittance increases ,
The first and second reflecting plate members are characterized in that the plurality of small reflecting plates are connected at one side and the connecting portions facing each other are coupled by a partition wall connecting member that transmits or reflects light. Lighting device. The small reflector has a region partitioned into a plurality of individual light source reflection regions respectively corresponding to a plurality of point light sources of the point light source group and a common light source reflection region common to these point light sources, The light source reflection area has a high reflectivity and a low light transmittance at locations close to the respective point light sources, and the individual reflectivity / transmission in which the reflectivity gradually decreases and the light transmittance increases while moving away from the location. The common light source reflection region is formed in a pattern, and the light source reflection region has a lower reflectance than the reduced reflectance and a higher light transmittance than the increased light transmittance at a location close to each individual light source reflection region. The common reflection / transmission pattern is formed, wherein the reflectance further decreases as the distance from the surface decreases, while the light transmittance further increases. Akira apparatus. The first and second point light source arrays in which a plurality of point light sources are arranged in a line at predetermined intervals, and one of the first and second point light source arrays is connected between one end portion. And the other point light source array facing the one end side part and positioned between the other end side parts away from the one end side part and arranged facing each other at a predetermined distance from each point light source array. A pair of first and second large reflector members made of a reflector and a predetermined distance G ₄ from the outer reflective surface of one of these large reflector members or both of the large reflector members. A distance between the first and second reflector members is set as G ₂ , and these relationships are set to satisfy G ₄ <G ₂ .
The large reflector member facing the diffuser member includes third and fourth reflector members, and the first and second point light source rows are adjacent to the third and fourth reflector members. Several point light sources are divided into a plurality of point light source groups, and are divided into a plurality of first and second small reflectors corresponding to the plurality of point light source groups, respectively. The second small reflector has a high reflectance and a low light transmittance at locations close to the individual point light sources corresponding to the respective point light sources, and the reflectance gradually decreases as the distance from the location is increased. On the other hand, the lighting device is formed by a single reflection / transmission pattern in which the light transmittance increases. The small reflector has a region partitioned into a plurality of individual light source reflection regions respectively corresponding to a plurality of point light sources of the point light source group and a common light source reflection region common to these point light sources, The light source reflection area has a high reflectivity and a low light transmittance at locations close to the respective point light sources, and the individual reflectivity / transmission in which the reflectivity gradually decreases and the light transmittance increases while moving away from the location. The common light source reflection region is formed in a pattern, and the light source reflection region has a lower reflectance than the reduced reflectance and a higher light transmittance than the increased light transmittance at a location close to each individual light source reflection region. The common reflection / transmission pattern is formed, wherein the reflectance further decreases as the distance from the surface decreases, while the light transmittance further increases. Akira apparatus. The distance _{G 2} is in the range of 10Mm～25mm, illumination device according to any crab of claims 1 to 4, wherein the distance _{G 4} are at 1mm or more. 5. The illumination device according to claim 1, wherein the reflection / transmission pattern is formed in a pattern in which a light transmission area increases with distance from the point light source. The lighting device according to claim 6, wherein the reflection / transmission pattern is formed by a light conduction hole penetrating the small reflector. The lighting device according to claim 1, wherein the point light source is a light emitting diode or a laser diode in which one light emitting element or a plurality of light emitting elements are assembled. The first and second large reflecting plate members are formed by connecting the plurality of first and second small reflecting plates of the third and fourth reflecting plate members on one side, and between connecting portions facing each other. The lighting device according to claim 3, wherein the two are coupled by a partition connecting member that transmits or reflects light. The small reflective plate and the partition connecting member, the lighting device according to any one of claims 1 to 9, characterized in that it is formed by ultra-fine foamed light reflecting member.

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