DE112013004356T5 - lighting device - Google Patents

Abstract

A reflective member does not overlap with an annular groove portion receiving an annular group of elements consisting of a plurality of light emitting elements, and a groove width of the groove portion is greater at regions corresponding to spaces between adjacent ones of the light emitting elements than at areas corresponding to the light emitting elements.

Description

[Technical area]

The present invention relates to lighting devices having as light sources light emitting elements, such as LEDs (light emitting diodes). More particularly, the present invention relates to a luminance unevenness reducing technology of a lighting device that includes a light guide plate and performs surface light emission.

[State of the art]

20 illustrates a lighting device 800 by patent literature 1 is disclosed. The lighting device 800 is a so-called edge-lit lighting device (at the edge) and is an example of a lighting device that includes a light guide plate and performs surface light emission. In the lighting device 800 are on an outer periphery of a light guide plate 840 several light emission elements 822 arranged to form an annular group. The light emission elements 822 each with a main light emission direction thereof are the light guide plate 840 arranged facing. Light, that of the light emission elements 822 is emitted, from a light entrance surface 840c having an outer circumferential surface of the light guide plate 840 is in the light guide plate 840 one. Then, light becomes uniform from a light emission surface 840a emitted, which is a forward facing surface of the light guide plate 840 is. A frame element 870 is at an outer circumferential edge of the light guide plate 840 appropriate. The frame element 870 covers the light emission elements 822 from. The frame element 870 protects the light emission elements 822 and improves the appearance of the lighting device 800 ,

While having the advantages described above, the frame member blocks 870 Light coming from the outer circumferential edge of the light guide plate 840 is emitted. Thus, a forward side of the lighting device emits 800 no light from a whole of it.

21 illustrates a lighting device 900 , The lighting device 900 is a directly illuminated lighting device, and is another example of a lighting device that includes a light guide plate and performs surface light emission. In the lighting device 900 are in a backward direction from a light guide plate 940 several light emission elements 922 arranged to form an annular group. The light emission elements 922 each with a main light emission direction thereof are the light guide plate 940 arranged facing. Light, that of the light emission elements 922 is emitted, from a light entrance surface 944b located in a rearward side of a ring section 941 the light guide plate 940 is formed, in the light guide plate 940 one. Then the light is at a reflection surface 941a which reflects a forwardly facing surface of the ring section 941 is, and is in a section located within the ring 942 the light guide plate 940 and a section outside the ring 943 the light guide plate 940 guided. Moreover, light becomes uniform from a light emission surface 942a and a light emission surface 943a emits the forward facing surfaces of the portion located within the ring 942 or the section outside the ring 943 are.

When the light emission elements 922 in a backward direction of the light guide plate 940 are arranged, as in the lighting device 900 There is no need to attach a frame member to an outer peripheral edge of the light guide plate 940 , So will light coming from an outer umlautender edge of the light guide plate 940 is not blocked by a frame element. In itself can be a forward side of the lighting device 900 Emit light from a whole of it.

[List of Citations]

[Non-patent literature]

• [Patent Literature 1] Japanese Patent Application Publication No. 2012-084316
• [Patent Literature 2] Japanese Patent Application Publication No. 2012-104476

[Summary]

[Technical task]

Meanwhile, in a structure such as that of the lighting device 900 , dark areas that emit almost no light, in the reflection surface 941a of the ring section 941 the light guide plate 940 educated. Such dark areas lead to unevenness of the luminance of the lighting device 900 , To explain in more detail: The reflective surface 941a Reflects substantially all of the light that is incident on it to effectively effect light to the portion located within the ring 942 and the outside the ring located section 943 respectively. Because of this, the reflective surface emits 941a almost no light in a forward direction, except for areas of the reflective surface 941a , in the backward direction of the light emitting elements 922 are arranged. So become areas of the reflective surface 941a which differ from the areas, in the reverse direction, the light-emitting elements 922 are arranged, to dark areas, which lead to a nonuniformity of the luminance.

In view of such problems, the present invention aims to provide a lighting device which emits light from an entire forward side thereof and which has a reduced unevenness of luminance.

[Technical solution]

To achieve the above-described object, one aspect of the present invention relates to a lighting apparatus comprising: a light guide plate; a plurality of light emitting elements; and a reflective member, wherein the light emitting elements are arranged in a rearward direction from the light guide plate, are arranged such that adjacent ones thereof are spaced from each other, to form an annular element group, and are respectively arranged facing the light guide plate with a main light emission direction thereof; and the reflecting member has a light-reflecting surface and is disposed near the guide member having the light-reflecting surface facing a part of the rear surface of the light guide plate, and in the lighting apparatus according to one aspect of the present invention viewed from a direction perpendicular to the back directed surface of the light guide plate, the reflective element does not overlap with an annular groove portion which receives the annular element group, and a groove width of the groove portion at areas corresponding to spaces between the adjacent ones of the light emitting elements is larger than at areas corresponding to the light emitting elements.

[Advantageous Effects]

In the lighting apparatus according to one aspect of the present invention, the plurality of light emitting elements are arranged to form an annular group in the backward direction of the light guide plate. Thus, there is no need to attach a frame member to an outer peripheral portion of the light guide plate to cover the plurality of light emitting elements. As a result, light emitted from an outer peripheral edge of the light guide plate is not blocked by a frame member, and therefore, a forward side of the lighting device emits light from a whole thereof.

Moreover, in the lighting apparatus according to one aspect of the present invention, the reflecting member is disposed at a portion that does not overlap with an annular groove portion receiving the annular element group consisting of a plurality of light emitting elements, and the width of the groove portion is at portions, which correspond to the spaces between adjacent ones of the light emitting elements, are larger than those corresponding to the light emitting elements. Accordingly, light is more likely to be guided out of areas corresponding to the spaces between the light emitting elements than the areas corresponding to the light emitting elements. Thus, the luminance of areas corresponding to the spaces between the light emitting elements becomes higher than in conventional lighting devices, and for this reason, the lighting device according to one aspect of the present invention has unevenness in luminance which is reduced as compared with conventional lighting devices.

[Brief Description of the Drawings]

1 illustrates how the lighting device according to embodiment 1 is attached to a ceiling plate.

2 FIG. 15 is a perspective view illustrating the lighting apparatus according to Embodiment 1. FIG.

3 FIG. 10 is an exploded perspective view illustrating the lighting apparatus according to Embodiment 1. FIG.

4 FIG. 10 is a cross-sectional view illustrating the lighting apparatus according to Embodiment 1. FIG.

5 is an enlarged cross-sectional view of a part of 4 which is surrounded by a dashed double dotted line,

6 FIG. 12 includes plan views illustrating the reflective element according to Embodiment 1, wherein section (a) illustrates the reflective element according to Embodiment 1 viewed from the forward direction and Section (b) illustrates the reflective element according to FIG Embodiment 1 viewed from the backward direction illustrated.

7 FIG. 12 includes plan views illustrating the light guide plate according to Embodiment 1, wherein section (a) illustrates the light guide plate according to Embodiment 1 viewed from the forward direction, and Section (b) illustrates the light guide plate according to Embodiment 1 viewed from the backward direction.

8th Fig. 12 is a diagram for explaining the luminance unevenness that occurs in a conventional lighting apparatus.

9 Fig. 12 is a schematic diagram for explaining the luminance unevenness that occurs in a conventional lighting apparatus.

10 Fig. 12 is a schematic diagram for explaining the path of light reflected on the element mounting surface of a substrate.

11 Fig. 12 is a schematic diagram for explaining the effect of reducing the unevenness of the luminance of the reflective element.

12 Fig. 12 is a schematic diagram for explaining the path of light entering light guide plate directly from light emitting elements.

13 Fig. 12 is a schematic diagram for explaining the effect of reducing the unevenness of luminance of the light guide plate.

14 Fig. 12 is a diagram for explaining the effect of reducing the luminance unevenness of the combination of the light guide plate and the reflective element.

15 Fig. 12 is a schematic diagram for explaining the effect of reducing the luminance unevenness of the combination of the light guide plate and the reflective element.

16 FIG. 10 is an exploded perspective view illustrating the lighting device according to Embodiment 2. FIG.

17 FIG. 10 is a cross-sectional view illustrating the lighting apparatus according to Embodiment 2. FIG.

18 is an enlarged cross-sectional view of a part of 17 which is surrounded by a dashed double dotted line.

19 Fig. 16 is a cross-sectional view for explaining the light guide plate and the reflective member according to a modification.

20 FIG. 10 is a plan view illustrating a conventional edge-lit lighting apparatus. FIG.

21 Fig. 10 is a plan view illustrating a conventional direct-lighting lighting apparatus.

[Description of the Embodiments]

In the following, the lighting apparatus according to one aspect of the present invention will be described with reference to the accompanying drawings. It should be noted that elements that appear in the drawings are illustrated with a scale that differs from their actual sizes and proportions. Moreover, in the present disclosure, numerical ranges include their minimum and maximum values.

<Embodiment 1>

(Overall structure)

1 illustrates how a lighting device according to embodiment 1 is attached to a ceiling plate. As in 1 illustrates is a lighting device 1 According to one aspect of the present invention, a ceiling radiator, for example, in an embedded state on a ceiling plate 2 is appropriate. It should be noted that the lighting device 1 According to the present embodiment, it does not have to be a ceiling lamp and may be any lighting device attachable to an architectural structure, such as a ceiling lamp, or any other type of lighting device, such as a backlight.

The lighting device 1 This will cause the ceiling panel 2 attached that first part of a housing 10 in a through hole 2a is inserted in the ceiling plate 2 is provided, and then causes engagement elements 3 that look similar to leaf springs and to the case 10 are mounted, in a rearward surface 2 B the ceiling plate 2 intervention. Although the description is provided on the assumption that the engagement elements 3 look like leaf springs, the engaging members 3 do not look like leaf springs. Moreover, the lighting device must 1 not by intervention of the engagement elements 3 on the ceiling plate 2 be attached and can by using one or more screws, adhesive and / or the like to the ceiling plate 2 to be appropriate.

A circuit unit 4 for illuminating the lighting device 1 is on the rearward surface 2 B the ceiling plate 2 arranged. The lighting device 1 is over a power line 23 electrically with the circuit unit 4 connected. The circuit unit 4 is electrically connected to an external AC power source (not illustrated) and supplies power supplied from the AC power supply to the lighting device 1 , According to the present embodiment, the circuit unit 4 and the lighting device 1 separately required. However, the lighting device according to the present invention may be the circuit unit 4 include.

2 FIG. 15 is a perspective view illustrating the lighting apparatus according to Embodiment 1. FIG. 3 FIG. 10 is an exploded perspective view illustrating the lighting apparatus according to Embodiment 1. FIG. 4 FIG. 10 is a cross-sectional view illustrating the lighting apparatus according to Embodiment 1. FIG. 5 is an enlarged cross-sectional view of a part of 4 which is surrounded by a dashed double dotted line. As in the 2 to 5 illustrates, includes the lighting device 1 for example: a housing 10 ; a light emission module 20 ; a reflective element 30 ; a light guide plate 40 ; and a scattering coverage 50 ,

(Casing)

As in 3 illustrates the housing 10 For example, the shape of a shell and is made of die-cast aluminum. The housing 10 has a main body 11 and a flange 12 on. The main body 11 has the shape of a bottom closed cylinder. The flange 12 has an annular, plate-like shape and extends from an opening of the main body 11 ,

The main body 11 has a lower section 13 and a side wall portion 14 on. The lower section 13 has a circular, plate-like shape. The sidewall section 14 has a cylindrical shape and extends from an outer circumferential rim of the lower portion 13 , The interior of the main body 11 takes the light emission module 20 , the reflective element 30 and a part of the light guide plate 40 on, like in 4 illustrated. Referring again to 3 has the side wall portion 14 of the main body 11 a through hole formed therein 15 on, in which the power line 23 is introduced.

The flange 12 has a main body 16 and a flange portion 17 on. The main body 16 has an annular plate-like shape and comes with the ceiling plate 2 in contact. The flange section 17 extends from an outer circumferential rim of the main body portion 16 , As in 4 Illustrated are the housing 10 and the scattering coverage 50 using adhesive, for example, secured together, with a sidewall portion 52 the scatter coverage 50 on the flange section 17 is mounted.

(Light emitting module)

Referring again to 3 , includes the light emission module 20 a substrate 21 and a plurality of light emitting elements 22 , The light emission module 20 is in a backward direction of the light guide plate 40 arranged. The substrate 21 has an annular plate-like shape. The light emission elements 22 are on an element attachment surface 21a arranged, which is a major surface of the substrate 21 is. The light emission elements 22 are arranged to form an annular element group on the element attachment surface 21a of the substrate 21 to build. The light emission elements 22 are arranged such that adjacent ones thereof are spaced apart from each other. The light emission elements 22 each with a main light emission direction thereof are the light guide plate 40 arranged facing.

For example, the substrate has 21 a double-layered structure composed of an insulating layer made of a ceramic substrate, thermally conductive resin or the like, and a metal layer made of an aluminum plate or the like. The substrate 21 has a wiring pattern (not illustrated) formed thereon. The light emission elements 22 are about this wiring pattern and a connection 24 electrically with the power line 23 connected. The element attachment surface 21a of the substrate 21 is light reflecting and effectively reflects light toward the light guide plate 40 ,

Each light emission element 22 For example, an LED is an LED upside down on the element mounting surface using COB (Chip On Board) technology 21a appropriate. It should be noted that the light emitting elements according to the present invention for Example, LDs (laser diodes), EL elements (electroluminescent elements) or the like may be. Alternatively, the light emitting elements according to the present invention may be surface mount device (SMD) type elements disposed on a substrate.

(Reflective element)

The reflective element 30 includes an inner reflective element 30a having a circular plate-like shape and an outer reflective element 30b having an annular plate-like shape and disposed so as to form an outer circumference of the inner reflective element 30a surrounds. Moreover, this is the reflective element 30 , as in 4 illustrates, in the reverse direction of the light guide plate 40 near the light guide plate 40 arranged. In particular, the inner reflective element 30a in the backward direction from a portion located within the ring 42 the light guide plate 40 arranged and the outer reflective element 30b is in the backward direction from a section outside the ring 43 the light guide plate 40 arranged. As a whole, the reflective element is seen 30 in the backward direction of the light guide plate 40 arranged so it does not interfere with the light emitting elements 22 overlaps. In other words, the reflective element 30 from a direction perpendicular to a rearward surface of the light guide plate 40 considered that a back-facing surface 42b and a rearward surface 43b includes, arranged such that it does not have a groove 60 for receiving an annular member (hat portion) which receives the annular element group consisting of the light emitting elements 22 consists. It should be noted that in the present disclosure, the term "forward direction" means a lighting direction of the lighting device 1 and the term "reverse direction" refers to the direction opposite to the "forward direction". Moreover, with reference to each 2 to 5 the upper part of the drawing farthest in the forward direction and the lower part of the drawing is furthest in the backward direction.

An outer diameter of the reflective element 30b is substantially equal to an inner diameter of the main body 11 of the housing 10 , This is how the outer reflective element becomes 30b placed in a predetermined position by simply the outer reflective element 30b within the main body 11 is housed. As material for the inner reflecting element 30a and the outer reflective element 30b is most suitable material having a high reflectance, such as high-reflectance polycarbonate resin, high-reflectance nylon resin, high-reflectance polybutylene terephthalate, or high-reflectance foam resin.

As in 5 includes a forward facing surface of the inner reflective portion 30a a first light-reflecting surface 31a and a second light-reflecting surface 32a , The first light reflecting surface 31a is the rear-facing surface 42b of the section located within the ring 42 the light guide plate 40 facing. The first light reflecting surface 31a reflects light in the reverse direction from the section located inside the ring 42 is transmitted, thereby causing such light in the section located within the ring 42 returns. The second light-reflecting surface 32a is a rear-facing surface 46b a second light scattering section 46 a ring section 41 the light guide plate 40 facing. The second light-reflecting surface 32a reflects light in the reverse direction from the second light scattering section 46 is transmitted, thereby causing such light in the second light scattering section 46 returns.

The first light reflecting surface 31a is in surface contact with the rearward surface 42b of the section located within the ring 42 and the second light-reflecting surface 32a is in surface contact with the rearward surface 46b of the second light scattering section 46 , Due to this surface contact, the first light reflecting surface 31a and the second light-reflecting surface 32a able to cause light to effectively guide the light guide plate 40 returns. Moreover, this surface contact allows the inner reflective element 30a and the light guide plate 40 be brought into their predetermined positions with high accuracy.

It should be noted that the first light-reflecting surface 31a and the second light-reflecting surface 32a in the lighting device according to the present invention need not be in surface contact. For example, a space between the first light-reflecting surface 31a and the rearward surface 42b of the section located within the ring 42 to be available. Moreover, a space may also be provided between the second light-reflecting surface 32a and the rearward surface 46b of the second light scattering section 46 to be available.

A forward facing surface of the outer reflective element 30b comprises a first light-reflecting surface 31b and a second light-reflecting surface 32b , The first light reflecting surface 31b is the rear-facing surface 43b the section outside the ring 43 the light guide plate 40 facing. The first light reflecting surface 31b reflects light in the reverse direction from the section outside the ring 43 is transmitted, thereby causing such light in the section located outside the ring 43 returns. The second light-reflecting surface 32b is a rear-facing surface 48b a fourth light scattering section 48 of the ring section 41 the light guide plate 40 facing. The second light-reflecting surface 32b reflects light in the reverse direction from the fourth light scattering section 48 is transmitted, thereby causing such light in the fourth light scattering section 48 returns.

The first light reflecting surface 31b is in surface contact with the rearward surface 43b the section outside the ring 43 and the second light-reflecting surface 32b is in surface contact with the rearward surface 48b the fourth light scattering section 48 , Due to this surface contact, the first light reflecting surface 31b and the second light-reflecting surface 32b able to cause light to effectively guide the light guide plate 40 returns. Moreover, this surface contact allows the outer reflective element 30b and the light guide plate 40 be brought into their predetermined positions with high accuracy. It should be noted that the first light-reflecting surface 31b and the second light-reflecting surface 32b in the lighting device according to the present invention need not be in surface contact. For example, a space between the first light-reflecting surface 31b and the rearward surface 43b the section outside the ring 43 to be available. Moreover, a space may also be provided between the second light-reflecting surface 32b and the rearward surface 48b the fourth light scattering section 48 to be available.

As in 4 are in the backward direction of the light guide plate 40 the inner reflective element 30a and the outer reflective element 30b arranged such that an outer circumferential surface 33a of the inner reflective element 30a and an inner circumferential surface 33b the outer reflective element 30b facing each other with a space in between. So determine the inner reflective element 30a and the outer reflective element 30b the groove receiving the annular member 60 that the light emitting elements 22 receives. In the backward direction of the ring section 41 the light guide plate 40 is a section where the inner reflective element 30a and the outer reflective element 30b are not present, the element recording groove 60 ,

The outer circumferential surface 33a of the inner reflective element 30a forms an inner circumferential surface of the element receiving groove 60 , and the inner circumferential surface 33b the outer reflective element 30b forms an outer circumferential surface of the element receiving groove 60 , Moreover, the element mounting surface forms 21a of the substrate 21 a lower surface of the element receiving groove 60 , Moreover, as in 5 illustrates the outer circumferential surface 33a of the inner reflective element 30a and the element attachment surface 21a of the substrate 21 an angle θ1 which is an acute angle. Similarly, the inner circumferential surface form 33b the outer reflective element 30b and the element attachment surface 21b of the substrate 21 an angle θ2, which is also an acute angle. Moreover, each of the outer circumferential surface 33a of the inner reflective element 30a and the inner circumferential surface 33b the outer reflective element 30b light-reflecting.

6 10 includes plan views illustrating the reflective element according to Embodiment 1, wherein section (a) illustrates the reflective element viewed from the forward direction and section (b) illustrates the reflective element viewed from the rearward direction. In 6 For example, the positions of the light emitting elements with respect to the reflective element are indicated using dashed double dotted lines. Moreover, in 6 the center of the reflective element 30 indicated by the reference "O".

As in 6 illustrates, the groove width of the element receiving groove 60 at areas where the light emission elements 22 are not present (areas that are the spaces between adjacent ones of the light emitting elements 22 greater than at areas where the light emitting elements 22 are present (areas that the multiple light emitting elements 22 correspond). It should be noted that in the present disclosure, the groove width of the element receiving groove 60 a distance between the outer circumferential surface 33a of the inner reflective element 30a and the inner circumferential surface 33b the outer reflective element 30b in a radial direction of the reflective element 30 equivalent.

As a result, the groove width of the element receiving groove 60 described in more detail. As in 5 illustrates, takes the groove width of the element receiving groove 60 when approaching the reverse direction from the forward direction gradually closed. Moreover, as in section (a) of 6 illustrates a groove width W2 at a forward opening of the element receiving groove 60 at the areas where the light emission elements 22 are not greater than a groove width W1 at the areas where the light emitting elements 22 available. Similarly, as in section (b) of 6 illustrates a groove width W4 in a rearward opening of the element receiving groove 60 at the areas where the light emission elements 22 are not greater than a groove width W3 at the areas where the light emitting elements 22 available.

(Light guide plate)

As in 3 illustrates, the light guide plate 40 a circular plate-like shape. The light guide plate 40 includes: the ring section 41 which has a ring shape and runs along the element group consisting of the light emitting elements 22 consists; the section inside the ring 42 having a circular plate-like shape and within the ring portion 41 is formed to be continuous with the ring section 41 to be executed; and the section outside the ring 43 which has a ring shape and outside of the ring portion 41 is formed to be continuous with the ring section 41 to be executed. The ring section 41 , the section located within the ring 42 and the section outside the ring 43 are molded in one piece. As material for the light guide plate 40 It is best to use material that has excellent light-guiding properties, such as acrylic resin, polycarbonate resin, polystyrene resin or glass.

The ring section 41 includes: a section facing the element group 44 ; a first light scattering section 45 ; the second light scattering section 46 ; a third light scattering section 47 ; and the fourth light scattering section 48 , The section facing the element group 44 has a ring shape and overlaps with the element group consisting of the light emitting elements 22 consists. The first light scattering section 45 is located inside the ring, passing through the element group facing section 44 is formed, has a ring shape and extends along the element group facing portion 44 , The second light scattering section 46 is inside the ring passing through the first light scattering section 45 is formed, has a ring shape and extends along the first light scattering portion 45 , The first light scattering section 45 and the second light scattering section 46 form an inner reflective section. The third light scattering section 47 is outside the ring, passing through the element group facing section 44 is formed, has a ring shape and extends along the element group facing portion 44 , The fourth light scattering section 48 is outside the ring passing through the third light scattering section 47 is formed, has a ring shape and extends along the third light scattering portion 47 , The third light scattering section 47 and the fourth light scattering section 48 form an outer reflective section.

In each of 4 and 5 is an area indicated by reference W41, the ring portion 41 That is, an area indicated by the reference character W42 is the portion located inside the ring 42 and an area indicated by reference W43 is the portion outside the ring 43 , An outer circumferential rim portion of the portion located outside the ring 43 is brought to a predetermined position when over the main body portion 16 of the flange 12 of the housing 10 is housed and between the main body portion 16 and an outer circumferential rim section 51a the scatter coverage 50 is arranged. In 5 is an area indicated by the reference W44, the section facing the element group 44 That is, an area indicated by the reference character W45 is the first light diffusing section 45 That is, an area indicated by reference character W46 is the second light diffusion section 46 That is, an area indicated by the reference character W47 is the third light diffusing section 47 and an area indicated by reference W48 is the fourth light diffusion section 48 ,

As in 5 illustrated includes a forward facing surface of the light guide plate 40 The following: a forward facing surface 41a of the ring section 41 ; a forward facing surface 42a of the section located within the ring 42 ; and a forward facing surface 43a the section outside the ring 43 , The forward facing surface 41a of the ring section 41 includes: a forward facing surface 44a of the element group facing portion 44 ; a forward facing surface of the inner reflective portion; and a forward facing surface of the outer reflective portion. The forward facing surface of the inner reflective portion is light reflective and includes: a first light diffusion region 45a which is a forward-facing surface of the first light-scattering portion 45 is; and a second light scattering area 46a of the front surface of the second light scattering section 46 is. The forward facing surface of the outer reflective portion is also light reflecting and includes: a third light scattering area 47a which is a forward-facing surface of the third light-scattering portion 47 is; and a fourth light scattering area 48a which is a forward-facing surface of the fourth light-scattering portion 48 is.

Moreover, a rear surface of the light guiding plate comprises 40 The following: a rearward surface 41b of the ring section 41 ; the rearward surface 42b of the section located within the ring 42 ; and the rearward surface 43b the section outside the ring 43 , The backward surface 41b of the ring section 41 includes: a rearward facing surface 44b of the element group facing portion 44 ; a backward surface 45b the first light scattering section 45 ; the rearward surface 46b of the second light scattering section 46 ; a backwards respected area 47b of the third light scattering section 47 ; and the rearward surface 48b the fourth light scattering section 48 ,

It should be noted that the light guide member according to the present invention need not have a circular plate-like shape and may have any other shape. For example, the light guide member according to the present invention may have a polygonal plate-like shape, such as a rectangular plate-like shape, a hexagonal plate-like shape, or an octagonal plate-like shape. Moreover, each of the ring portion, the inside ring portion, the outside ring portion, the element group facing portion, the first light diffusing portion, the second light diffusing portion, the third light diffusing portion, and the fourth light diffusing portion may have any shape corresponding to the shape of Light guide element corresponds. Moreover, the element arrangement, the substrate shape, etc., may be changed according to the shape of the light guide member.

The forward facing surface 41a of the ring section 41 is light-reflecting and reflects light that enters the ring section 41 enters, from the reverse direction towards the portion located within the ring 42 and the section outside the ring 43 , It should be noted that the light here originally by the light emission elements 22 is produced. As in each case in 4 and 5 illustrates, the forward facing surface 41a of the ring section 41 in a vertical cross section of the Lichführungsplatte 40 is substantially the shape of a V having at its center a portion which appears to be folded back and protrudes in the reverse direction. It should be noted that the vertical cross section of the light guide plate 40 a cross section according to a section of the light guide element 40 is along an imaginary plane passing through the center of the forward facing surface of the light guide plate 40 runs and aligns with the forward facing surface of the light guide plate 40 cuts at a right angle. The folded-back portion of the forward facing surface 41a has a curved shape that protrudes in the reverse direction. Moreover, both sides of the folded-back portion have substantially arcuate shapes protruding in the forward direction, allowing light to be effectively directed toward the portion located inside the ring 42 and the section outside the ring 43 to reflect.

Moreover, the forward facing surface 41a of the ring section 41 treated to cause light scattering (such treatment will hereinafter be referred to as "light scattering treatment"). In particular, the first light scattering area 45a by the light scattering treatment with recesses 45c provided, the second light scattering area 46a is with depressions 46c provided, the third light scattering area 47a is with depressions 47c provided and the fourth light scattering area 48a is with depressions 48c Mistake. Due to the light scattering treatment, light becomes the forward facing surface 41a from the ring section 41 achieved, not completely reflected. Instead, part of the light passes through the pits 45c . 46c . 47c . 48c scattered and to the outside of the light guide plate 40 emitted. It should be noted that the forward facing surface 44a of the element group facing portion 44 not provided with depressions.

In the present embodiment, the recesses 45c . 46c . 47c . 48c all substantially in the form of hemispheres and all of the same size. However, the pits according to the present invention may have any shape or size as long as a light scattering effect is achieved. For example, the recesses according to the present invention may have substantially conical shapes or substantially circular truncated cone-like shapes.

7 10 includes plan views illustrating the light guide plate according to Embodiment 1, wherein section (a) illustrates the light guide plate viewed from the forward direction and section (b) illustrates the light guide plate viewed from the backward direction. As in section (a) of 7 is illustrated when comparing the first light scattering section 45 with the second light scattering section 46 it can be seen that the first light scattering area 45a and the second light scattering area 46a subjected to different light scattering treatments. In particular, the number of pits per unit area in the second light scattering area 46a higher than in the first light scattering area 45a (wells 45c and depressions 46c ). Thus, a larger amount of light from the second light scattering section 46 emitted as from the first light scattering section 45 ,

Similarly, when comparing the third light scattering section 47 and the fourth light scattering section 48 the third light scattering area 47a and the fourth light scattering area 48a subjected to different light scattering treatments. In particular, the number of pits per unit area is in the fourth light scattering area 48a higher than in the third light scattering area 47a (wells 47c and depressions 48c ). Thus, a larger amount of light from the fourth light scattering section 48 emitted as from the third light scattering section 47 ,

It should be noted that the present embodiment is an example in which the same light scattering treatment with respect to the first light scattering portion 45 and the third light scattering section 47 was performed and the same light scattering treatment with respect to the second light scattering section 46 and the fourth light scattering section 48 was carried out. In other words, the number of pits per unit area is in the first light scattering area 45a the same as in the third light scattering area 47a (wells 45c and depressions 47c ). Moreover, the number of pits per unit area is in the second light scattering area 46a the same as in the fourth light scattering area 48a (wells 46c and depressions 48c ).

Referring again to 5 serves a part of the rearward surface 41b of the ring section 41 as a light entrance surface through which light from the light emitting elements 22 in the light guide element 40 entry. The backward surface 44b of the element group facing portion 44 corresponds to this light entry surface. The backward surface 44b of the element group facing portion 44 has a ring shape facing the element group consisting of the light emitting elements 22 consists. Moreover, it should be mentioned that within the element recording groove 60 the entirety of the rearward surface 41b of the ring section 41 as a light entrance surface works, via the light that is on the element attachment surface 21a of the substrate 21 is reflected in the ring section 41 entry.

The forward facing surface 42a of the section located within the ring 42 serves as a light-emitting surface, from which a portion of the light enters the section located within the ring 42 occurred, is emitted. The forward facing surface 43a the section outside the ring 43 serves as a light-emitting surface from which a portion of the light enters the section located outside the ring 43 occurred, is emitted.

The backward surface 42b of the section located within the ring 42 has pits due to the fact that it has been subjected to light scattering treatment 42c on. So will light that is at the pits 42c in the section located inside the ring 42 arrives, scattered light and is from the forward facing surface 42a emitted. As in section (b) of 7 illustrates, decreases the number of wells 42c per unit area as it approaches the center of the rearward surface 42b of the section located within the ring 42 to. Thus, light becomes uniform from the entirety of the forward surface 42a emitted.

The backward surface 43b the section outside the ring 43 has pits due to the fact that it has been subjected to light scattering treatment 43c on. So will light that is at the pits 43c in the section outside the ring 43 arrives, scattered light and is from the forward facing surface 43a emitted. The number of wells 43c per unit area decreases as it approaches the center of the rearward surface 43b the section outside the ring 43 to. Thus, light becomes uniform from the entirety of the forward surface 43a emitted. Meanwhile, as in 3 illustrates an outer circumferential surface 43d the section outside the ring 43 a processing for preventing the passage of light from the outer circumferential surface 43d to the outside of the light guide plate 40 subjected. This is how light becomes after passing through the section located outside the ring 43 on the outer circumferential surface 43d arrives at the outer circumferential surface 43d reflected. Thus, such light does not become from the portion outside the ring 43 emits and instead becomes returning light and moves towards the ring section 41 ,

It should be noted that the light scattering treatment, with respect to the section located within the ring 42 and the section outside the ring 43 performed, may differ from the previously described. For example, the section located within the ring 42 and the section outside the ring 43 as a result of Light diffusing treatment with bulges and not be provided with depressions or may be provided as well as recesses as well as recesses as a result of the light scattering treatment. Moreover, light scattering treatment may be with respect to the back surfaces 42b and 43b instead of using them in terms of the forward surfaces 42a and 43a or it may be in relation to both the rearward surfaces 42b and 43b as well as on the forward facing surfaces 42a and 43a be performed. In any case, it is exemplary that the light scattering treatment causes light to be uniform from the entirety of the forward facing surface 42a of the section located within the ring 42 and of the entirety of the forward facing surface 43a the section outside the ring 43 is emitted.

(Scattering cover)

The scattering coverage 50 contains, for example, translucent material, for example, silicone resin, acrylic resin, polycarbonate resin or glass. Light coming from the light guide plate 40 is emitted crosses the scattering coverage 50 before putting it on the outside of the lighting device 1 is emitted.

The scattering coverage 50 includes: a main body portion 51 which has a dome-like shape and the light guide plate 40 covers; and a side wall portion 52 arising from a circumferential rim portion of the main body portion 51 extends in the reverse direction. The sidewall section 52 is on the flange section 17 of the flange 12 attached. The main body section 51 was subjected to light scattering treatment. So will the light coming from the light guide plate 40 is emitted, scattered light when it is the main body portion 51 crosses. Thereby, the unevenness of the luminance is further reduced. It should be noted that the lighting device according to the present invention does not have to include a scattering cover.

(Effect of Reflecting Element to Reduce Luminance Nonuniformity)

8th Fig. 12 is a diagram for explaining the unevenness of luminance that occurs in a conventional lighting apparatus, and includes a photograph of a conventional lighting apparatus in the illuminated state and results of the analysis of the unevenness of luminance based on the photograph. 9 FIG. 12 is a schematic diagram explaining the unevenness of luminance which occurs in a conventional lighting apparatus, and a schematic illustration of the apparatus shown in FIG 8th illustrated luminance unevenness provides. It should be mentioned that while 8th represents the unevenness of the luminance observed over a scattering coverage, 9 illustrates the unevenness of the luminance on a forward surface of a light guide member.

In a conventional directly illuminated lighting device, luminance unevenness occurs as in FIG 8th illustrated. As in

9 illustrates are areas 62 where no light emission elements 22 are present, compared to areas 61 where light emission elements 22 darker, which is a cause of the luminance unevenness. To reduce such luminance unevenness, in the present embodiment, the groove width of the element-receiving groove is 60 at the areas 61 where light emission elements 22 available. relatively small and is at the areas 62 where no light emission elements 22 are present, relatively large.

10 Fig. 12 is a schematic diagram for explaining the paths of light reflected at the element mounting surface of the substrate. In particular, illustrated 10 a vertical cross section of a region where no light emitting element 22 is available. Moreover, includes 10 also an illustration of an area where a light emitting element 22 present, which is indicated using a dashed double dotted line. L1 and L2 respectively indicate returning light at the outer circumferential surface 43d the section outside the ring 43 is reflected and to the inside of the element recording groove 60 returns. However, L3 and L4 each indicate light from that of the light emitting elements 22s is emitted, but not in the light entry surface (the rear surface 44b of the element group facing portion 44 ) entry.

As in 10 illustrates is at an area where no light emitting element 22 is present, the groove width of the element receiving groove 60 ie the distance between the outer circumferential surface 33a of the inner reflective element 30a and the inner circumferential surface 33b the outer reflective element 30b , relatively large. Therefore, a relatively small area of the rearward surface 41b of the ring section 41 through the reflective element 30 covered and it is thus relatively easy for light, from within the Elementaufnahmenut 60 in the ring section 41 enter. Accordingly, a relatively large amount of light from the front surface 41a of the ring section 41 emitted to the outside. In particular, light traveling along all paths L1, L2, L3 and L4 is emitted to the outside.

However, as illustrated by the dashed double-dotted lines, it is at an area where a light-emitting element 22 is present, the groove width of the element receiving groove 60 ie the distance between the outer circumferential surface 33a of the inner reflective element 30a and the inner circumferential surface 33b the outer reflective element 30b , relatively small. Therefore, a relatively large area of the rear surface 41b of the ring section 41 through the reflective element 30 so it is relatively difficult for light from within the element recording groove 60 in the ring section 41 enter. Accordingly, a relatively small amount of light is emitted from the forward surface 41a of the ring section 41 emitted to the outside. In particular, light traveling along the paths L1 and L3 is emitted to the outside, while light traveling along the paths L2 and K4 is not emitted to the outside because it passes through the reflective element 30 is blocked, and moves toward other areas within the element receiving groove 60 , such as towards the areas 62 where no light emission elements 22 available.

11 Fig. 12 is a diagram for explaining the effect of reducing luminance unevenness (hereinafter referred to as "luminance unevenness reduction effect") obtained by the reflective element. In 11 For example, the luminance is illustrated without considering the effect of reducing the luminance unevenness caused by performing the light scattering treatment with respect to the ring portion 41 the light guide plate 40 is achieved. As in 11 illustrates, in the present embodiment, the groove width of the element receiving groove 60 at the areas 62 where the light emission elements 22 are not present, relatively large. That's why light gets off the sections 62 where the light emission elements 22 are absent, compared to the sections 61 where the light emission elements 22 are present, emitted more easily. Accordingly, the luminance at the sections 62 where the light emission elements 22 are absent, thus increasing the unevenness of luminance.

Moreover, in the present embodiment, the combination of each of the outer circumferential surface is 33a of the inner reflective element 30a , the inner circumferential surface 33b the outer reflective element 30b and the element mounting surface 21a of the substrate 21 that the element shots groove 60 forms, light-reflecting. Therefore, the element attachment surface reflects 21a Light inside the element reception groove 60 and causes light to be effective in the ring section 41 entry. In itself, it is more likely that light from within the element recording groove 60 from the ring section 41 is emitted, and thus it is less likely that dark areas in the ring section 41 be formed.

Moreover, in the present embodiment, the angle θ1 passing through the outer circumferential surface 33a of the inner reflective element 30a and the element attachment surface 21a of the substrate 21 is formed, pointed and the angle θ2 passing through the inner circumferential surface 33b the outer reflective element 30b and the element attachment surface 21a of the substrate 21 is formed is also pointed. Accordingly, light is more likely to be within the element recording groove 60 at the element mounting surface 21a is collected, which reflects the light and causes light on the rearward surface 41a of the ring section 41 arrives. By itself light is more likely to hit the rearward surface 41a of the ring section 41 one. In itself, it is more likely that light from within the element recording groove 60 from the ring section 41 is emitted, and thus it is less likely that dark areas in the ring section 41 be formed. It should be noted that it increases the likelihood of using the light within the element recording groove 60 at the element mounting surface 21a it is preferable to provide each of the angles θ1 and θ2 at an angle not greater than 90 ° or, more preferably, at an angle within the range of 45 ° to 75 °.

(Effect of the light guide plate for reducing the unevenness of the luminance)

In a conventional direct-illuminated lighting device, almost no light is emitted from portions of the ring portion that are different from the element group-facing portion that faces the light-emitting elements and emits light. Therefore, dark areas are formed in the ring portion, such as in 8th illustrated. Moreover, the luminance of the dark areas conventionally decreases as the distance from the element group-facing portion increases. In particular, the luminance is as in 9 illustrated at areas 63 that are relatively close to the light emitting elements 22 are relatively high, while the luminance on areas 64 , the relatively far from the light emitting elements 22 lying away, is relatively low. This difference in luminance is one reason for the luminance unevenness. To reduce such luminance unevenness, the ring portion becomes 41 according to the present embodiment, subjected to a light scattering treatment. Moreover, this light scattering treatment is performed such that a larger amount of light from the second light scattering portion 46 is emitted as from the first light scattering section 45 , and such that a larger amount of light from the fourth light scattering section 48 is emitted as from the third light scattering section 47 ,

12 Fig. 12 is a schematic diagram for explaining the paths of light entering light guide plate directly from light emitting elements. Light that in the backward surface 44b of the element group facing portion 44 entry, for example, may first be on the forward facing surface 41a of the ring section 41 are reflected to the inside of the section located inside the ring 42 before being guided through the inside of the ring 42 Section moves forward by repeating it on the forward facing surface 42a and the rearward surface 42b of the section located within the ring 42 is reflected as indicated by reference L5 in FIG 12 illustrated. Also, light that is in the rearward surface 44b of the element group facing portion 44 enters, for example, first at the forward facing surface 41a of the ring section 41 be reflected to the inside of the section outside the ring 43 to be guided before passing through the outside of the ring 43 Section moves forward by repeating it on the forward facing surface 43a and the rearward surface 43b the section outside the ring 43 is reflected as indicated by reference L6 in FIG 12 illustrated.

The light moves along the paths L5 and L6, later becomes scattered light when it reaches the pits 42c respectively 43c arrives and from the forward facing surfaces 42a respectively 43a is reflected. For example, light moving along the path L6 will move from behind. front-facing surface 43a emitted. Moreover, light traveling along the path L5 will also be viewed from the front-facing surface 42a emitted when the light is later a recess 42c reaches and becomes scattered light after it reaches the section located inside the ring 42 has crossed.

As previously described, the forward facing surface is 41a of the ring section 41 basically light reflecting and reflecting, thereby guiding light into the ring section 41 enters, to the section located within the ring 42 and the section outside the ring 43 , Therefore, light does not become light from the ring portion 41 emitted, and the probability that dark areas in the ring section 41 is formed, is high. Meanwhile, in the present embodiment, the front surface is 41a of the ring section 41 with depressions 45c . 46c . 47c . 48c Mistake. Accordingly, light is also from the forward surface 41a of the ring section 41 emitted as illustrated by reference numerals L7 and L8. So the likelihood is that dark areas in the ring section 41 be formed, low.

Not all areas of the forward facing surface emit here 41a of the ring section 41 with the same probability light. In particular, the probability of light emission of the second light scattering area 46a and the fourth light scattering area 48a higher than that of the first light scattering area 45a and the third light scattering area 47a , This difference is the result of the difference in the number of wells ( 45c . 46c . 47c . 48c ) provided per unit area.

It should be noted that the forward facing surface 44a of the element group facing portion 44 as previously described, has a bent folded-back portion. At this folded-back section, light passes directly through the light guide plate 40 and emitted to the outside, as illustrated by L9. Thus, there is no need to provide any indentations in the forward facing surface 44a of the element group facing portion 44 and around them, and providing pits at this area, the brightness and visual emergence of the area become extremely high. Here, it is preferable that this area has a width in a vertical cross section two to three times the width of a light emitting element 22 When the area has a width smaller than twice the width of a light emitting element 22 , the brightness and the visual emergence of the area become too high. On the other hand, if the area has a width greater than three times the width of a light-emitting element 22 is, the brightness of the area is too low. Moreover, it is preferable that the radius of the folded-back portion is not larger than 5/100 and not smaller than 2/100. If the radius of the folded-back portion is larger than 5/100, the bright portion of the folded-back portion is too prominent.

13 Fig. 12 is a schematic diagram for explaining the effect of reducing the unevenness obtained by the light guiding plate. In 13 The luminance is illustrated while the effect of reducing the unevenness of the luminance caused by the reflective element 30 is not taken into account. As in 13 illustrates, in the present embodiment, the forward-facing surface 41a of the ring section 41 subjected to a light scattering treatment and so also emits the ring portion 41 Light. As such, in the present embodiment, the luminance of the ring portion 41 higher than a conventional lighting device and the unevenness of the luminance is reduced.

In addition, a larger amount of light from the second light scattering section 46 and the fourth light scattering section 48 extending relatively far from the element group facing portion 44 are emitted as emitted from the first light scattering section 45 and the third light scattering section 47 that are relatively close to the element group facing portion 44 lie. So, the difference in luminance between the areas becomes 63 that are relatively close to the light emitting elements 22 lie, and the areas 64 that are relatively far from the light-emitting elements 22 are removed, eliminated and the unevenness of the luminance is reduced. (Synergetic effect of the combination of reflective element and light guide plate to reduce the unevenness of luminance)

14 FIG. 12 is a diagram for explaining the effect of reducing the unevenness of luminance achieved by the combination of the light guide plate and the reflective element, and includes a photograph of the lighting device in the illuminated state and the results of the luminance nonuniformity analysis based on FIG the photography was done. 15 Fig. 12 is a diagram for explaining the effect of reducing the unevenness of luminance achieved by the combination of the light guide plate and the reflective element, and provides a schematic illustration of the luminance unevenness shown in Figs 14 is illustrated. It should be mentioned that while 14 illustrates the luminance unevenness observed over the scattering coverage 15 illustrates the unevenness of the luminance at the forward surface of the light guide member.

The lighting device 1 According to the present embodiment, the combination of the reflective element comprises 30 and the light guide plate 40 , This is how the lighting device achieves 1 both the effect of reducing the unevenness of the luminance of the reflective element and the effect of reducing the unevenness of the luminance of the light guide plate. By itself, the lighting device 1 almost no luminance unevenness, as in 14 and 15 illustrated.

It should be noted that the lighting device according to the present invention may or may not include the light guide plate as long as it includes the reflective element to achieve the effect of reducing the unevenness of the luminance of the reflective element. As such, the lighting device according to the present invention may comprise a light guide plate having a conventional structure.

<Embodiment 2>

16 FIG. 10 is an exploded perspective view illustrating a lighting device according to Embodiment 2. FIG. 17 FIG. 10 is a cross-sectional view illustrating the lighting apparatus according to Embodiment 2. FIG. 18 is an enlarged cross-sectional view of a part of 17 which is surrounded by a dashed double dotted line.

In a lighting device 100 According to Embodiment 2, there is the reflective element 30 only from the inner reflective element 30a , Moreover, the lighting device comprises 100 a light guide plate 140 that does not have a portion outside the ring. This is how the lighting device differs 100 very much from the lighting device 1 according to embodiment 1. Since the lighting device 100 however, in many other aspects of the lighting device 1 is similar, only the differences between the lighting device in the sequence 100 and the lighting device 1 wherein the same reference numerals are used and no further explanation is provided for elements comprising the lighting device 100 and the lighting device 1 have in common.

As in the 16 to 18 illustrates, includes the lighting device 100 for example: a housing 110 ; a light emission module 120 ; the inner reflective element 30a ; the light guide plate 140 ; and a scattering coverage 150 ,

(Casing)

As in 16 illustrates the housing 110 For example, the shape of a shell and is made of die-cast aluminum. The housing 110 has a main body 111 and has the shape of a bottom-side closed cylinder. The main body 111 has a lower section 113 and a side wall portion 114 on. The lower section 113 has a circular, plate-like shape. The sidewall section 114 has a cylindrical shape and extends from an outer circumferential rim of the lower portion 113 , The interior of the main body 111 takes the light emission module 120 , the reflective element 30a and a part of the light guide plate 140 on, like in 17 illustrated. Referring again to 16 has the side wall portion 114 of the main body 111 a through hole formed therein 115 on, in which the power line 23 is introduced.

(Light emitting module)

The light emission module 120 includes a substrate 121 and the plurality of light emitting elements 22 , The substrate 121 has an annular plate-like shape. The light emission elements 22 are on an element attachment surface 121 arranged, which is a major surface of the substrate 121 is. The light emission elements 22 are arranged to form an annular element group on the element attachment surface 121 of the substrate 121 to build. The light emission elements 22 are arranged such that adjacent ones thereof are spaced apart from each other. The light emission elements 22 each with a main light emission direction thereof are the light guide plate 140 arranged facing. The substrate 121 is essentially the substrate 21 according to Embodiment 1, while the substrate 121 a smaller outline than the substrate 21 having. The light emission elements 22 are electrically over the connection 24 and a wiring pattern on the substrate 121 is formed (not illustrated), electrically connected to the power line 23 connected. The element attachment surface 121 of the substrate 121 is light reflecting and effectively reflects light toward the light guide plate 140 ,

(Reflective element)

The reflective element of the lighting device 100 consists only of the inner reflective element 30a according to embodiment 1. As in 17 illustrates is the reflective element 30a in the backward direction of the light guide plate 40 near the light guide plate 140 arranged. In particular, the reflective element 30a in the backward direction from a portion located within the ring 142 the light guide plate 140 arranged so it does not interfere with the light emitting elements 22 overlaps. In other words, the reflective element 30a from a direction perpendicular to a rearward surface of the light guide plate 140 (a back-facing surface 142b considered) arranged so that it does not have a groove 160 overlaps with an annular member (groove portion) receiving the annular element group consisting of the light emitting elements 22 consists.

As in 18 is the first light reflecting surface 31a of the inner reflective element 30a the rear-facing surface 142b of the section located within the ring 142 the light guide plate 140 arranged facing. The first light reflecting surface 31a reflects light in the reverse direction from the section located inside the ring 142 is transmitted, thereby causing such light in the section located within the ring 142 returns. The second light-reflecting surface 32a is a rear-facing surface 146b a second light scattering section 146 a ring section 141 the light guide plate 140 facing. The second light-reflecting surface 32a reflects light in the reverse direction from the second light scattering section 146 is transmitted, thereby causing such light in the second light scattering section 146 returns. The first light reflecting surface 31a is in surface contact with the rearward surface 142b of the section located within the ring 142 and the second light-reflecting surface 32a is in surface contact with the rearward surface 146b of the second light scattering section 146 ,

In the backward direction of the light guide plate 140 are the inner reflective element 30a and the case 110 arranged such that the outer circumferential surface 33a of the inner reflective element 30a and a part of a sidewall portion 114 of the main body 111 of the housing 110 facing each other with a space in between. So determine the inner reflective element 30a and the case 110 the annular element receiving groove 160 that the light emitting elements 22 receives. In the backward direction of the ring section 141 the light guide plate 140 is a. Section where the inner reflective element 30a is not present, the element recording groove 160 ,

The outer circumferential surface 33a of the inner reflective element 30a forms an inner circumferential surface of the element receiving groove 160 , and an inner circumferential surface of the Sidewall portion 114 of the housing 110 forms an outer circumferential surface of the element receiving groove 160 , Moreover, the element mounting surface forms 121 of the substrate 121 a lower surface of the element receiving groove 160 , Moreover, the outer circumferential surface form 33a of the inner reflective element 30a and the element attachment surface 121 of the substrate 121 an angle θ1 which is an acute angle. Moreover, the groove width of the element receiving groove decreases 160 gradually increases from a forward side to a rearward side. Moreover, the inner circumferential surface of the side wall portion 114 of the housing 110 light-reflecting.

(Light guide plate)

As in 16 illustrates, the light guide plate 140 a circular plate-like shape. The light guide plate 140 includes: the ring section 141 which has a ring shape extending along the element group consisting of the light emitting elements 22 consists; and the section located inside the ring 142 having a circular plate-like shape and the outer periphery of the ring portion 141 is surrounded. The ring section 141 and the section located within the ring 142 form a single body.

The ring section 141 includes: a section facing the element group 144 , a first light scattering section 145 and the second light scattering section 146 , The first light scattering section 145 and the second light scattering section 146 form an inner reflective section. The section facing the element group 144 has a ring shape and overlaps with the element group consisting of the light emitting elements 22 consists. The first light scattering section 145 is located inside the ring, passing through the element group facing section 144 is formed, has a ring shape and extends along the element group facing portion 144 , The second light scattering section 146 is inside the ring passing through the first light scattering section 145 is formed, has a ring shape and extends along the first light scattering portion 145 ,

In 17 is an area indicated by reference W141, the ring portion 141 and an area indicated by reference character W142 is the portion located inside the ring 142 , In 18 is an area indicated by reference W144, the section facing the element group 144 That is, an area indicated by reference W145 is the light diffusing section 145 and an area indicated by reference W146 is the second light diffusing section 146 ,

It should be noted that the light guide member according to the present invention need not have a circular plate-like shape and may have any other shape. For example, the light guide member according to the present invention may have a polygonal plate-like shape, such as a rectangular plate-like shape, a hexagonal plate-like shape, or an octagonal plate-like shape. Moreover, each of the ring portion, the inside ring portion, the outside ring portion, the element group facing portion, the first light diffusing portion, the second light diffusing portion, the third light diffusing portion, and the fourth light diffusing portion may have any shape corresponding to the shape of Light guide element corresponds. Moreover, the element arrangement, the substrate shape, etc., may be changed according to the shape of the light guide member.

A forward facing surface 141 of the ring section 141 is light-reflecting to light that enters the ring section 141 enters, from the reverse direction towards the portion located within the ring 142 to reflect. It should be noted that the light here originally by the light emission elements 22 is produced. Moreover, the forward facing surface points 141 of the ring section 141 in a vertical cross section of the light guide plate 140 substantially the shape of an arc bulged in the forward direction.

Moreover, the forward facing surface became 141 of the ring section 141 subjected to a light scattering treatment. In particular, a forward-facing surface of the first light-scattering portion 145 ie a first light scattering area 145a , with depressions 145c provided and a forward facing surface of the second light scattering section 146 ie a second light scattering area 146a , is with depressions 146c Mistake. Due to the light scattering treatment, light becomes the forward facing surface 141 from the ring section 141 achieved, not completely reflected. Instead, part of the light passes through the pits 145c and 146c scattered and to the outside of the light guide plate 140 emitted. It should be noted that a forward facing surface 144a of the element group facing portion 144 not provided with depressions. Moreover, the depressions point 145e . 146c all substantially in the form of hemispheres and all of the same size.

When comparing the first light scattering section 145 with the second light scattering section 146 it can be seen that the first light scattering area 145a and the second light scattering area 146a subjected to different light scattering treatments. In particular, the number of pits per unit area in the second light scattering area 146a higher than in the first light scattering area 145a (Comparison of the wells 145c and depressions 146c ). Thus, a larger amount of light from the second light scattering section 146 emitted as from the first light scattering section 145 ,

Part of a rearward surface 141b of the ring section 141 serves as a light entrance surface through which light from the light emitting elements 22 in the light guide element 140 entry. A backward surface 144b of the element group facing portion 144 corresponds to this light entry surface. The backward surface 144b of the element group facing portion 144 has a ring shape that overlaps the element group consisting of the light emitting elements 22 consists. Moreover, it should be mentioned that within the element recording groove 160 the entirety of the rearward surface 141b of the ring section 141 as a light entrance surface works, via the light that is on the element attachment surface 121 of the substrate 121 is reflected in the ring section 141 entry.

The section located inside the ring 142 has substantially the same structure as the portion located inside the ring 42 according to embodiment 1.

(Scattering cover)

The scattering coverage 150 includes: a main body portion 151 which has a dome-like shape and the Liehtführungsplatte 140 covers; and a side wall portion 152 arising from a circumferential rim portion of the main body portion 151 extends in the reverse direction. The sidewall section 152 is on the sidewall portion 114 of the main body 111 of the housing 110 attached. The main body section 151 was subjected to light scattering treatment. So will the light coming from the light guide plate 140 is emitted, scattered light when it is the main body portion 151 crosses.

(Effect of Reflecting Element to Reduce Luminance Nonuniformity)

The present embodiment is similar to Embodiment 1 in that the groove width of the element receiving groove is 160 in areas where the light emission elements 22 are not present (areas that are the spaces between the light emitting elements 22 correspond) is relatively small. Moreover, in the present embodiment, the combination of each of the outer circumferential surface is 33a of the inner reflective element 30a and the element mounting surface 121 of the substrate 121 that the element shots groove 160 forms, light-reflecting. Moreover, an angle θ1 passing through the outer circumferential surface 33a of the inner reflective element 30a and the element attachment surface 121 of the substrate 121 is formed, pointed. Thus, in the present embodiment, effects similar to those achieved in Embodiment 1 are achieved.

(Effect of the combination of reflective element and light guide plate to reduce the unevenness of luminance)

The present embodiment is similar to Embodiment 1 in that it has the forward surface 141 of the ring section 141 was subjected to a light scattering treatment, the luminance of the ring portion 141 is higher than a conventional lighting device and thus the unevenness in the luminance is reduced. In addition, a larger amount of light from the second light scattering section 146 extending relatively far from the section facing the element group 144 is emitted as emitted from the first light scattering section 145 that is relatively close to the section facing the element group 144 lies. So, the difference in luminance between the areas becomes 63 that are relatively close to the light emitting elements 22 cherish, and the areas 64 that are relatively far from the light-emitting elements 22 are removed, eliminated and the unevenness of the luminance is reduced.

The lighting device 100 According to the present embodiment, the combination of the inner reflective element comprises 30a and the light guide plate 40 , This is how the lighting device achieves 1 both the effect of reducing the unevenness of the luminance of the reflective element and the effect of reducing the unevenness of the luminance of the light guide plate. It should be noted that the lighting device according to the present invention may or may not include the light guide plate as long as it includes the reflective element to achieve the effect of reducing the unevenness of the luminance of the reflective element. As such, the lighting device according to the present invention may comprise a light guide plate having a conventional structure.

<Modifications>

Hereinafter, modifications of the lighting apparatus according to the present invention will be described. 19 FIG. 12 is a cross-sectional view for explaining a light guide plate and a reflective member according to the modifications. FIG.

(Reflective element)

In Embodiment 1, the angle θ1 passing through the element attachment surface 21a of the substrate 21 and the outer circumferential surface 33a of the inner reflective element 30a is formed. pointed. Meanwhile, the angle θ1 may be a right angle or an obtuse angle, as in FIG 19 illustrating an angle θ1 passing through the element attachment surface 21a of the substrate 21 and an outer circumferential surface 233a an inner reflective element 230a is formed. Moreover, in Embodiment 1, the angle θ2 passing through the element attachment surface is 21a of the substrate 21 and the inner circumferential surface 33b the outer reflective element 30b is formed, a sharp angle. Meanwhile, the angle θ2 may be a right angle or an obtuse angle, as in FIG 19 illustrating an angle θ2 passing through the element attachment surface 21a of the substrate 21 and an inner circumferential surface 233b an outer reflective element 230a is formed.

(Light guide plate)

As for the light guide plate according to the present invention, the light scattering treatment relating to the ring portion 41 is performed, different from that performed in Embodiment 1. For example, the ring section 41 as a result of the light scattering treatment with bulges and not be provided with depressions or may be provided as well as recesses as a result of the light scattering treatment with recesses.

In the light guide plate 40 According to Embodiment 1, various light scattering treatments are performed to change the number of pits per unit area of the forward facing apex 41a of the ring section 41 (wells 45c . 46c . 47c . 48c ) to be provided. However, the various light scattering treatments need not be those which differ in the resulting number of pits formed.

For example, they differ in a light guide plate 240 , in the 19 as a result of performing various light scattering treatments, the pits are illustrated 245c . 246c . 247c . 248c in terms of size, while the pits 245c . 246c . 247c . 248c be provided with the same number per unit area. In other words, the different light scattering treatments cause the pits 245c . 246c . 247c . 248c Occupy areas of different sizes. So differs in different areas of the forward facing surface 41a of the ring section 41 the surface of areas having the function of reflecting light as a result of performing various light scattering treatments.

In particular, the number of wells 245c , the per unit area in a first light scattering area 245a be provided the same as the number of wells 246c , the per unit area in a second light scattering area 246a to be provided. The wells 245c are smaller than the wells 246c , So the sum of the surfaces of areas of the first light scattering area 245a having the function of reflecting light smaller than the sum of the surfaces of areas of the second light scattering area 246a having the function of reflecting light. Thus, a larger amount of light from the second light scattering section 246 emitted as from the first light scattering section 245 ,

Moreover, because the pits 245c smaller than the wells 246c , the light scattering function of the pits 245c less than that of the wells 246c , As such, also due to this difference in the light scattering function, a larger amount of light from the first light scattering section 246 as of the second light scattering section 245 emitted.

Similarly, the number of wells is 247c , the per unit area in a third light scattering area 247a be provided the same as the number of wells 248c , the per unit area in a fourth light scattering area 248a to be provided. The wells 247c are smaller than the wells 248c , Thus, a larger amount of light from the fourth light scattering section 248 emitted as from the third light scattering section 247 ,

It should be noted that the size of the wells 245c . 246c . 247c and 248c can be changed according to the following mathematical expression: Dr = k1 × R ^ n / cos (m × θ) + k2 (Math 1)

In Math 1, Dr denotes a radius of a pit, R denotes the pitch of the pit from a light emitting element, θ denotes a shift angle of the pit from an optical axis of the light emitting element (see FIG 19 ), and each of k1, k2, n, and m denotes a fixed number.

The amount of energy coming from the wells 245c . 246c . 247c . 248c can be discharged by changing the sizes of the wells 245c . 246c . 247c . 248c changed according to Math 1. Alternatively, the number of pits per unit area may be changed according to Math 1 while providing each pit with the same size.

The provision of the wells 45c . 46c . 47c . 48c As previously described, it also eliminates the luminance difference between areas relatively close to the light emitting elements 22 lie, and areas that are relatively far from the light-emitting elements 22 are removed, and reduces the unevenness of the luminance.

Moreover, in Embodiment 1, two different light scattering treatments with respect to the area between the element group facing portion 44 and the section located inside the ring 42 made what the first light scattering section 45 and the second light scattering section 46 results. However, there may be two or more different light scattering treatments with respect to the area between the element group facing portion 44 and the section located inside the ring 42 be performed. Moreover, it may be that the light scattering processing is not performed stepwise as described above, and instead may be performed to form a step such that the larger the distance from the element group facing portion, the more the light is scattered 44 is. This similarly applies to the area between the section facing the element group 44 and the section outside the ring 43 ,

(Miscellaneous)

In the foregoing, a description will be given of the structure of the lighting device according to the present invention based on embodiments and modifications thereof. However, such embodiments and modifications are non-limiting examples, and the present invention is not limited to the described embodiments and modifications. For example, parts of the embodiments and modifications may be combined as required. Moreover, the materials, numerical values, etc. described in the embodiments are merely examples of materials, numerical values, etc., which are preferable, and are non-limiting examples. In addition, various structural changes may be made without departing from the spirit and scope of the present invention.

The lighting device according to the present invention is widely applicable to various types of lighting including ceiling lights, ceiling lights and backlights.

LIST OF REFERENCE NUMBERS

1, 100

lighting device

21, 121

substratum

21a, 121a

Element mounting surface

22

Light emitting element

30

Reflecting element

30a, 230a

Inner reflective element

30b, 230b

Exterior reflective element

31a, 32a

Light-reflecting surface of the inner reflective element

32b, 32b

Light-reflecting surface of the outer reflective element

33a, 233a

Inner circumferential surface of the inner reflective element

33b, 233b

Inner umlautende surface of the outer reflective element

40, 140, 240

Light guide plate

41, 141

ring section

42, 142

section located within the ring

43, 143

Outside the ring located section

44, 144

Element group facing section

44b, 144b

Light entry surface

45, 145, 245

First light scattering section (inner reflecting section)

45a, 145a, 245a

First light scattering section

46, 146, 246

Second light scattering section (inner reflecting section)

46a, 146a, 246a

Second light scattering section

47a, 147a, 247a

Third light scattering section

48a, 148a, 248a

Fourth light scattering section

45c, 46c, 47c, 48c, 145c, 146c, 245c, 246c, 247c, 248c

deepening

47, 247

Third light scattering section (outer reflecting section)

48, 248

Fourth Light Scattering Section (Outer Reflecting Section)

60, 160

Element receiving groove (groove section)

Claims (5)

A lighting device, comprising: a light guide plate; a plurality of light emitting elements; and a reflective element. wherein the light emitting elements are arranged in a rearward direction from the light guide plate, arranged so that adjacent ones are spaced from each other, are arranged to form an annular group of elements, each facing a main light emission direction thereof facing the light guide plate, and the reflective element having light-reflecting surface and is disposed in the vicinity of the guide member with the light-reflecting surface facing a part of a rear surface of the light guide plate, wherein the reflective element, when viewed from a direction perpendicular to the rearward surface of the light guide plate, does not overlap with an annular groove portion which receives the annular element group, and a groove width of the groove portion at portions corresponding to the spaces between the adjacent ones of the light emitting elements is larger than at portions corresponding to the light emitting elements. A lighting device according to claim 1, wherein: the light guide plate has a light entrance surface through which light emitted from the light emission elements enters the light guide plate, and comprising: a ring portion having a ring shape and overlapping with the ring-shaped element group; a portion located within the ring that is continuous with the ring portion and located within the ring portion; and an out-of-ring portion that is continuous with the ring portion and that is outside the ring portion, the reflecting member includes an inner reflecting member disposed in the rearward direction from the portion located inside the ring and an outer reflecting member disposed in the rearward direction from the portion located outside the ring, and an outer circumferential surface of the inner reflective member forms an inner circumferential surface of the groove portion, and an inner circumferential surface of the outer reflective member forms an outer circumferential surface of the groove portion. A lighting device according to claim 1, wherein: each of the outer circumferential surface of the inner reflective element and the inner circumferential surface of the outer reflective element is light-reflecting. A lighting device according to claim 1, wherein: the light emitting elements are disposed on an element mounting surface of a substrate, the element mounting surface being light reflecting, and the element attachment surface forms a bottom surface of the groove portion. A lighting device according to claim 4, wherein: an acute angle is formed between the element attachment surface and the outer circumferential surface of the inner reflective element, and an acute angle is formed between the element attachment surface and the inner circumferential surface of the outer reflective element.

Images