DE112013005914T5 - lighting device - Google Patents

Abstract

A lighting apparatus comprises: a mounting substrate on which a light-emitting element is mounted on an upper surface thereof; a light guide plate; and a plate-like member provided between the mounting substrate and the lightguide plate and having an opening to at least partially expose the light-emitting element. The light guide plate has a light incident portion disposed above the opening and on which the output light beam of the light emitting element is incident, and has: an element facing surface facing the light emitting element; and an inclined surface whose inclination angle to the upper surface gradually decreases with the distance from the element-facing surface in a first direction parallel to the upper surface. The plate-like member has a peripheral end surrounding the opening and having a pair of portions facing each other with the opening therebetween in the first direction and overlapping the element-facing surface in the plan view of the light guide plate.

Description

[Technical area]

The present invention relates to a lighting device comprising a light-emitting element such as an LED (Light Emitting Diode) as a light source. More particularly, the present invention relates to a technology for reducing luminance unevenness in a lighting device in which surface emission is performed by using a light guide plate.

[State of the art]

For example, a lighting device 900 which is in a sectional view in 16 has been developed as a surface emitting lighting device using a light guide plate. The lighting device 900 includes a plurality of light-emitting elements 922 , a reflection member 945 and a light guide plate 940 , The reflection member 945 and the light guide plate 940 are each formed in a disk shape in which a direction perpendicular to a paper surface of 16 is set to a direction of a flat surface of the disk shape. The light guide plate 940 has a light incident part 941 on top of the light-emitting elements 922 surrounds from above. The light-emitting elements 922 are spaced around the circumference while main output directions of the light-emitting elements 922 towards the light guide plate 940 are aligned. The lighting device 900 includes a power supply unit (not shown) that houses each light-emitting element 922 powered. When operating the lighting device 900 fall output light beams of the light-emitting elements 922 on an incident surface 944 a light incident part 941 one. The incident light rays are from the inclined surface 941a reflected on an upper surface of the light incident part 941 and the incident light rays become an inner light conductor part 942 directed, located inside the light incident part 941 located, and an outer light guide part 943 which is outside at the light incident part 941 located. Then, the light beams become uniform illumination light beams of light output surfaces 942a and 943a issued, which are the upper surfaces of the inner light guide part 942 or the outer light guide part 943 are.

[List of Citations]

[Patent Literature]

[Patent Literature 1]

• Japanese Patent Application Publication No. 2012-104476

Summary of the Invention

[Technical task]

For example, it is also conceivable to use a light guide plate in the surface emitting illumination device 940x to use a light incidence part 946X having, in a partial sectional view ( 17 (a) ) of a lighting device 910 is shown. The light incident part 946X has an element-facing surface 947x , inclined surfaces 948x and 949X and side panel parts 950x and 951X on, facing the inclined surfaces 948x respectively. 949X are located. The surface facing the element 947x is in an opening of a reflection member 945X arranged around a light-emitting element 922 is provided, and is an output surface of the light-emitting element 922 facing. In the inclined areas 948x and 949X takes an inclination angle with respect to an upper surface (an XY plane in FIG 17 ) of a mounting substrate gradually with the distance from the element-facing surface 947x on an upper surface of the lightguide plate 940x from. When operating the lighting device 910 fall output light beams of the light-emitting element 922 comprising light rays L ₉ to L ₁₂ , on the surface facing the element 947x one. Then, the incident rays of light are respectively regularly efficiently adjacent to the inclined surface 948x or 949X reflected and to the entire light guide plate 940x directed. Light rays coming from the reflection member 945X be reflected, without on the element-facing surface 947x to fall in each case fall on the Lichteinfallsteil 946X from the side surface part 950x or 951X like a ray of light L ₁₃ in 17 (a) one.

In the lighting device 910 is a strictly positional relationship between the light-emitting element 922 and the light guide plate 940x required. However, a postion misalignment error (hereinafter referred to as "chip misalignment") may be generated in which a mounting position of the light-emitting element 922 deviates from a target position.

When the chip misalignment is generated, a relative position also deviates between the light-emitting element 922 and the light incident part 946X as in a partial sectional view of 17 (b) shown. Consequently, an amount of light beam of the light-emitting element decreases 922 directly on the side surface part 950x or 951X ( 951X in 17 (b) ) incident, without on the surface facing the element 947x to invade and from the reflection member 945X to be reflected and then to the inclined surface 949X with a relatively small angle of incidence, in a direction to (a Y direction in 17 (b) ) in which the chip misalignment is generated. The incident light beam can be output to the outside, passing through the inclined surface 949X migrates to become a direct light beam of high luminance L14. Looking at the lighting device 910 from the outside, the luminance in a region where the chip misalignment is generated is higher than the luminance in other regions. This leads to the problem that a luminance unevenness is generated. Although light rays L ₁₃ and L ₁₅ are present, which are output to the outside after being reflected by the reflection member 945X have been reflected ( 17 (a) and 17 (b) ), the light beams L ₁₃ and L _{15 are} partially diffusely reflected (not shown) while being reflected by the reflection member 945X reflected, and the ratio of the light beam output to the outside decreases. Therefore, the light beams L ₁₃ and L ₁₅ hardly cause the problem.

The present invention has been made in view of the problem described above. An object of the present invention is to provide a lighting device that can restrict the generation of luminance unevenness even when a chip misalignment is generated in the lighting device, comprising a light guide plate whose light incident portion has an inclined surface.

[Technical solution]

In order to achieve the above-mentioned object, an aspect of the present invention provides a lighting apparatus comprising: a mounting substrate on which at least one light-emitting element is mounted on an upper surface thereof; a light guide plate covering the upper surface of the mounting substrate to guide an output light beam of the light emitting element; and a plate-like member provided between the mounting substrate and the lightguide plate and having an opening penetrating in a thickness direction to expose at least a part of the light-emitting element, the lightguide plate having a light-incident part disposed above the opening, and on which the output light beam of the light-emitting element is incident, the light-incident part has: an element-facing surface facing the light-emitting element; and, on one side of an upper surface of the lightguide plate, an inclined surface whose inclination angle with respect to the upper surface of the mounting substrate gradually decreases with the distance from the element-facing surface in a first direction, the first direction being parallel to the upper surface of the Mounting substrate is, the plate-like member has a peripheral end surrounding the opening, and the peripheral end of the plate-like member has a pair of portions facing each other with the opening therebetween in the first direction and in a plan view of the light guide plate Overlap element-facing surface.

According to another aspect of the present invention, the plate-like member has a recessed part in an upper surface of the plate-like member, and the recessed part has the opening therein, and the light-incident part has a protruding part protruding toward the opening, and protruding part is inserted in the recessed part.

According to still another aspect of the present invention, the plate-like member has a pair of side walls that are upstanding from the pair of sections in the recessed part, wherein one of the side walls is arranged on a straight line corresponding to one of the pairs of sections and one end of the element-facing surface that is proximate to the one portion in a section along a virtual surface connects, wherein the virtual surface is perpendicular to the upper surface of the mounting substrate and passes through the pair of sections.

According to still another aspect of the present invention, there is a clearance between each of the side walls and the element-facing surface in the first direction.

According to still another aspect of the present invention, the plate-like member is a reflection member that reflects the light beam of the light-emitting element.

Moreover, according to still another aspect of the present invention, the light incident portion has an inclined surface on the upper surface side of the light guide plate, the inclination angle of which with respect to the upper surface of the mounting substrate gradually decreases with the distance from the element-facing surface in one direction, which is opposite to the first direction.

According to still another aspect of the present invention, the opening comprises: a first opening part provided between the pair of sections; and a second opening part connected to the first opening part in a second direction and having a larger maximum diameter in a direction parallel to the first direction than the first opening part, the second direction being the first direction cuts in parallel with the upper surface of the mounting substrate and the Lichteinfallsteil is disposed over the first opening part.

According to still another aspect of the present invention, the second direction is a direction perpendicular to the first direction, and the second opening part is provided in pairs facing each other with the first opening part interposed therebetween.

According to still another aspect of the present invention, the light-emitting element is multi-mounted with gaps, and the second opening part is provided above a gap between each juxtaposed two of the light-emitting elements.

According to still another aspect of the present invention, the plurality of light-emitting elements are circumferentially mounted on the upper surface of the mounting substrate, and the light-incident portion is formed throughout so as to couple portions over the plurality of light-emitting elements.

According to still another aspect of the present invention, the light guide plate has a disc shape and has an inner light guide part located inside the light incident part and an outer light guide part located outside the light incident part.

According to a still further aspect of the present invention, the inner optical fiber part is equal to the outer optical fiber part at the height of a top side major surface of the upper surface of the mounting substrate, and the inner optical fiber part is equal in thickness to the outer optical fiber part.

According to still another aspect of the present invention, the plate-like member and the light guide plate are respectively molded by injection molding.

According to still another aspect of the present invention, the light-emitting element is an LED element.

In addition, according to still another aspect of the present invention, the lighting device includes a power supply device that powers the light-emitting element.

[Advantageous Effects of Invention]

In the lighting apparatus, according to one aspect of the present invention, in operating the lighting apparatus, when the output light beam from the light-emitting element travels through the opening of the plate-like member, the output light beam is partially blocked by at least one of pairs of portions of the peripheral end of the plate-like member, whose gap is narrower than the width of the element-facing surface of the light incident part in the first direction.

Therefore, even if the chip misalignment is generated in the first direction, an output high-intensity light beam of the light-emitting element incident on the light guide plate without being reflected by the plate-like member can be prevented from permeating the inclined surface. which has a small inclination angle to be output to the outside as a direct light beam having a high luminance.

Consequently, it is possible to provide a lighting apparatus comprising a light guide plate whose light incident portion has an inclined surface in which even if a chip misalignment is generated, the generation of luminance unevenness is limited.

[Brief Description of the Drawings]

1 FIG. 16 is a partial sectional view showing a configuration and an installation example of a lighting device. FIG 100 according to a first embodiment shows.

2 is a view showing a configuration of the appearance and an internal configuration of a lighting fixture 1 shows.

3 is an exploded view (assembly drawing) showing an internal configuration of the lighting fixture 1 shows.

4 is a partial sectional perspective view showing the internal configuration of the lighting fixture 1 shows.

5 is a partial sectional perspective view showing an internal configuration of a reflection member 30 shows.

6 (a) is a plan view showing the configuration of the reflection member 30 shows when the reflection member 30 from a diffusion cover 50 is considered, and 6 (b) is a bottom view showing the configuration of the reflection member 30 , seen from a base plate 10 , represents.

7 is a partial sectional view showing a configuration around a Lichteinfallsteil 42 shows.

8th is a partial sectional view of a neighborhood of the light incident part 42 receiving an output light beam of a light-emitting element 22 shows in which a chip misalignment is generated.

9 (a) is a partial sectional view showing the output light beam of the normal light-emitting element 22 (without chip misalignment) in the vicinity of the light incident part 42 shows, and 9 (b) FIG. 12 is a partial sectional view showing an angle θ ₁ of output light beams L ₁ and L ₂ and an angle θ ₂ of output light beams L ₂ and L ₄ .

10 FIG. 11 is a comparative example showing data of a luminance unevenness pattern and illuminance distribution when the chip misalignment is generated. FIG.

11 Fig. 12 exemplifies data of the pattern of the luminance unevenness and the illuminance distribution when the chip misalignment is generated.

12 (a) shows as a comparative example a luminance pattern in which the luminance unevenness is generated, and 12 (b) Fig. 15 is a photograph showing the state of actual emission in the comparative example.

13 (a) shows by way of example a schematic luminance pattern, and 13 (b) is a photograph showing the state of the actual emission in the example.

14 (a) FIG. 16 is a view showing a configuration of an opening according to a second embodiment of the present invention; FIG. 14 (b) FIG. 14 is a view showing a configuration of an opening according to a third embodiment; FIG. 14 (e) FIG. 16 is a view showing a configuration of an opening according to a fourth embodiment; and FIG 14 (d) FIG. 14 is a view showing a configuration of an opening according to a fifth embodiment. FIG.

15 FIG. 12 is a partial sectional view showing a configuration of a light incident part. FIG 42A according to a sixth embodiment of the present invention in the vicinity of the light incident part 42A shows.

16 FIG. 10 is a sectional view showing a configuration of a conventional lighting apparatus. FIG 900 shows.

17 (a) Fig. 13 is a partial sectional view showing a vicinity of a light incident part 946X in a lighting device 910 shows. and 17 (b) is a partial sectional view, which is a problem of the lighting device 910 in the neighborhood of the light incident part 946X shows.

[Description of the Embodiments]

Hereinafter, a lighting device according to an exemplary embodiment of the present invention will be described with reference to the drawings.

<First Embodiment>

(Configuration of the lighting device 100 )

In a sectional view ( 1 ), which is a configuration and an installation example of a lighting device 100 shows, includes the lighting device 100 (hereinafter referred to as "device 100 "Denotes) a lighting fixture 1 , a locking member 3 , which has a leaf spring shape, and a power supply unit 4 which is used to light the lighting fixture 1 to illuminate. The lighting fixture 1 is about a leader 23 electrically to the power supply unit 4 connected. The locking member 3 is on the lighting fixture 1 attached. In the first embodiment, a spotlight embedded in a ceiling becomes the device 100 used.

When installing the device 100 becomes the power supply unit 4 through a through hole 2a that in the ceiling 2 was made, on a back 2 B a blanket 2 placed. The lighting fixture 1 is arranged such that it partially in the through hole 2a is housed. Here is the locking member 3 in the circumference of the through hole 2a locked. Therefore, the lighting device 100 in the ceiling 2 be installed.

In a view ( 2 ), which is a design of the appearance and an internal configuration of the lighting fixture 1 shows is the configuration of the appearance of the lighting fixture 1 mainly with a base plate 10 and a diffusion cover 50 built. The leader 23 extends outside of a locking projection 16 the base plate 10 ,

A dotted line in 2 gives a position of a mounting substrate 20 on that in the lighting fixture 1 is involved. In the lighting fixture 1 is a plurality of light-emitting elements 22 on a surface of the mounting substrate 20 (Substrate body 21 ) assembled. Hereinafter, the one surface of the mounting substrate 20 on which the light-emitting elements 22 are mounted, referred to as upper surface, the other surface, the opposite upper surface is referred to as lower surface. A direction that extends from the bottom surface to the top surface while perpendicular to the mounting substrate 20 is referred to as an upward direction, and a direction opposite to the upward direction is referred to as a downward direction. An XY plane in the drawings is a plane parallel to the upper surface of the mounting substrate 20 and a Z direction in the drawings indicates the upward direction.

(Configuration of the lighting device 1 )

In an exploded view ( 3 ), which is the internal configuration of the lighting fixture 1 illustrates, includes the lighting fixture 1 (hereinafter referred to as "body 1 "Designates) the base plate 10 , the mounting substrate 2 , a reflection member 30 , a light guide plate 40 and the diffusion cover 50 , The body 1 has a total of a disc shape. Respective outer peripheral shapes of the base plate 10 , the mounting substrate 20 , the reflection member 30 , the light guide plate 40 and the diffusion cover 50 are each in a circular shape according to the overall shape of the lighting fixture 1 educated.

[Baseplate 10 ]

The base plate 10 consists of a material that has excellent radiation properties, such as a metallic material such as an aluminum injection molding material. The base plate 10 has a body part 11 on, which has a raised floor structure, which is deep to the central part and flat to the peripheral part, and a flange 12 which is upright around the body part 11 is provided ( 3 ). The locking projection 16 is in the flange 12 intended.

Towards the perimeter of the middle of the body part 11 indicates the body part 11 a writing-shaped inner lower part 13 , a side wall part 14 which is upright on the circumference of the inner lower part 13 is provided, and a cyclic outer lower part 15 on, around the sidewall part 14 is provided.

The mounting substrate 20 and the reflection member 30 are sequential on the inner base 13 laminated. An outer light guide part 43 the light guide plate 40 is on the outer base 15 placed.

The flange 12 is with a side wall part 52 the diffusion cover 50 by using, for example, an adhesive or a sealing member adjacent to an apex in the upward direction (Z direction).

[Mounting substrate 20 ]

The mounting substrate 20 has the cyclic substrate body 21 , the plurality of light-emitting elements 22 placed on the upper surface (the surface facing the reflection member 30 from 3 facing) of the substrate body 21 are mounted, and the conductor 23 on.

For example, the substrate body 21 a double-layer structure in which an insulating layer of a ceramic material or a thermally conductive resin and a metal layer of aluminum are laminated. A conductor pattern (not shown) is on the upper surface of the substrate body 21 formed around the light-emitting elements 22 and the leader 23 to connect electrically. An outer diameter of the substrate body 21 is substantially equal to an inner diameter of the side wall part 14 ,

For example, an LED element becomes a light-emitting element 22 used. As in a partial sectional view ( 7 ) a configuration of environments of a light incident part 42 shown has the light-emitting element 22 an elementary body 220 and an element capsule 221 on, in which the element body 220 as a specific configuration is to accommodate. The light-emitting elements 22 are circumferentially spaced at the top surface of the substrate body 21 mounted so that a main output direction is aligned toward the upward direction (Z direction). In the mounting substrate 20 For example, a total of eighteen light-emitting elements 22 with the active side up on the conductor structure using COB (Chip On Board) technology.

Hereinafter, a direction along a circumference of the light-emitting elements 22 is formed, referred to as a circumferential direction, a direction of the light-emitting elements 22 is directed toward a center of the circumference, is referred to as a center direction, and a direction opposite to the center direction is referred to as a reverse center direction.

The upper surface of the substrate body 21 has light reflection characteristics for reflecting the output light beam of the light-emitting elements 22 to the light guide plate 40 (hereinafter referred to as "reflection properties").

The wiring 23 is used to light emitting element 22 with power from the power supply unit 4 to supply. Respective ends of the wiring 23 are electrically connected to the Conductor structure of the substrate body 21 and the power supply unit 4 connected.

[Reflecting member 30 ]

The reflection member 30 is a plate-like member provided to receive the light beam emitted from the light-emitting element 22 is emitted, and the light beam coming out of the light guide plate 40 escapes, effectively to the light guide plate 40 to reflect. In the body 1 is the reflection member 30 between the mounting substrate 20 and the light guide plate 40 intended. The reflection member 30 consists of a material with good reflection properties. Examples of such materials include a high-reflectance polybutylene terephthalate (PBT) resin, a high-reflectance polycarbonate (PC) resin, a high-reflectance nylon resin, and a high-reflectance foam resin. The reflection member 30 can be manufactured with high accuracy by injection molding of the resin materials. The reflection member 30 should have the reflective properties at least on its surface.

As in a perspective partial sectional view ( 4 ) of the body 1 , a perspective partial sectional view ( 5 ) of the reflection member 30 and a plan view ( 6 (a) ) and a bottom view ( 6 (b) ) of the reflection member 30 shown has the reflection member 30 from the center to the outside an inner reflection part 31 , a recessed part 32 and an outer reflection part 33 on. The outer diameter of the reflection member 30 is substantially equal to the inner diameter of the side wall part 14 , The inner reflection part 31 and the outer reflection part 33 have upper surface 310 respectively. 320 on ( 5 ).

The inner reflection part 31 (outer reflection part 33 ) is provided at the position inside (outside) of the position where the light-emitting element 22 on the mounting substrate 20 is mounted ( 4 ). The inner reflection part 31 (outer reflection part 33 ) is used to turn the light beam coming from the light guide plate 40 escapes, to the light guide plate 40 on the upper surface 310 ( 320 ) to reflect.

The recessed part 32 is provided in a region including a portion above the position where the light-emitting element 22 on the mounting substrate 20 is mounted. A cyclic area of a constant width on the upper surface (the area of the light guide plate 40 facing) of the reflection member 30 is recessed in a thickness direction (a reverse direction to the Z direction) to the recessed part 32 to build ( 5 ). Accordingly, the recessed part 32 formed in the circumferential direction.

The recessed part 32 points in, as in the 5 . 6 (a) , and 6 (b) shown, a plurality of openings 34 on, which is the reflection member 30 in the thickness direction with constant gaps in the circumferential direction. The reflection member 30 here has a peripheral end 344 on, that's the opening 34 surrounds.

The opening 34 know a first opening part 340 and a pair of second opening parts 341 on that with the first opening part 340 keep in touch. In an opening 34 is the first opening part 340 with the pair of second opening parts 341 in the circumferential direction in connection. In a direction parallel to the center direction, a maximum diameter of each of the second opening parts 341 larger than a maximum diameter of the first opening part 340 ( 5 (a) ). Accordingly, the opening 34 a gourd-shaped perimeter in which the opening 34 in the first opening part 340 having the smaller diameter while the opening 34 the larger diameter in the pair of second opening parts 341 having.

The first opening part 340 is located so that at least part of the position at which the light-emitting element 22 is mounted, exposed. That is, in a plan view of the plate-like member 30 have the light-emitting element 22 and the first opening part 340 a positional relationship in which at least a part of the light-emitting element 22 from the first opening part 340 is looked at ( 7 and 8th ). In the reflection member 30 is a pair of sections 342A and 343A in the peripheral end 344 (please refer 6 (a) and 6 (b) ) each other with the first opening part 340 between them in the direction parallel to the center direction with a relatively narrow gap W ₂ , and is close to each other. This is because in the first opening part 340 an amount of output light beam of the light-emitting element 22 is properly controlled so that it is not overly elevated. In the recessed part 32 stand the side walls 342 and 343 from the pair of sections 342A respectively. 343A upwards, the first opening part 340 in between, is the output light beam of the light-emitting element 22 to reflect. As in 7 shown, have the side walls 342 and 343 each having a curved surface having a recessed shape. Therefore, in the reverse center direction (center direction), a space of the recessed part is 32 between each of the side walls 342 and 343 and a surface facing the element 420 (described later) of the light guide plate 40 available. The side walls 342 and 343 are each formed to have a sectional shape of the curved surface of R = about 0.2 in the section (for example, the section 7 in figure) in which the body 1 along a virtual plane which is perpendicular to the upper surface of the mounting substrate and through the pair of sections 342A and 343A runs.

The second opening parts 341 are provided to the output light beam of the light-emitting element 22 efficiently dissipate to an area farther from the light-emitting element 22 is removed. The diameter of each of the second opening parts 341 in the direction parallel to the center direction is set to be spaced from the first opening part 340 increases ( 5 (a) ).

As in 6 (b) shown has the reflection member 30 a flat surface according to the upper surface of the substrate body 21 of the mounting substrate 20 on.

[Light guide plate 40 ]

The light guide plate 40 dissipates the output light beam of the light-emitting element 22 in the center direction or the reverse direction, and generates surface emission at the diffusion cover 50 (Z-direction). The light guide plate 40 is above the reflection member 30 arranged. The light guide plate 40 consists of a material that has a translucent material. Examples of such a material include an acrylic resin, a polycarbonate resin, a polystyrene resin and glass. The light guide plate 40 can be made with high accuracy by making the materials similar to the reflection member 30 be injection molded. Accordingly, the position misalignment error can be negligible in an arrangement relationship between the reflection member 30 and the light guide plate 40 be reduced. The light guide plate 40 has from the center to the outside an inner light guide part 41 , a light incident part 42 and an outer light guide part 43 on ( 3 ). An outer diameter of the light guide plate 40 is substantially equal to an inner diameter of the flange 12 , In the light guide plate 40 for example, the inner light guide part is the same 41 the outer light guide part 43 at the height of a top surface of the upper surface of the substrate body 21 of the mounting substrate 20 ( 4 ). The inner light guide part 41 and the outer light guide part 43 are set to have an identical thickness.

The inner light guide part 41 (outer light guide part 43 ) conducts and disperses the light beam of the light-emitting element 22 on the light guide plate 40 incident, from the light incident part 42 to the inside (outside) of the position where the light-emitting element 22 is mounted.

The light incident part 42 is over the opening 34 arranged to cause the output light beam of the light-emitting element 22 on the light guide plate 40 through the opening 34 is incident, and to scatter the output light beam in the center direction or reverse center direction. In the body 1 is the light incident part 42 consistently formed so that sections over the light-emitting elements 22 coupled, and has a protruding part leading to the opening 34 protrudes and in the recessed part 32 of the reflection member 30 is used ( 4 ). As in 7 shown, the light incident part 42 a surface facing the element 420 , a pair of inclined surfaces 422A and 422B and a limit 423 on that between the inclined surfaces 422A and 422B are provided as a specific configuration. As in 4 and 7 shown, the light incident part 42 an essential V-shape in section with a constant thickness as a whole shape. Side surface portions 424A and 424B , each having an inclined surface similar to those of the inclined surfaces 422A and 422B have, are. at both ends of the element facing surface 420 provided in the direction parallel to the center direction so as to face the inclined surfaces 422A respectively. 422B lie ( 7 ).

At a front end leading to the opening 34 protrudes, is the surface facing the element 420 near the light-emitting element 22 arranged and arranged so that they are the upper surface of the light-emitting element 22 is facing. For example, the surface facing the element 420 a flat shape. The surface facing the element 420 has light incidence ends 420A and 420B on, located at both ends of the element facing surface 420 over a width W ₁ in the direction parallel to the center direction ( 7 ).

The pair of inclined. surfaces 422A and 422B is on the upper surface of the light guide plate 40 intended. In particular, the inclined surfaces 422A and 422B respective angles of inclination with respect to the upper surface of the mounting substrate 20 that gradually and evenly with the distance from the surface facing the element 420 become smaller in the reverse direction and the center direction, respectively. That is, one of the center direction and the reverse center direction corresponds to a viewpoint of the first direction of the first embodiment, and the other of the center and reverse direction corresponds to a viewpoint of the direction opposite to the first direction. The circumferential direction intersects the center direction and the reverse center direction and corresponds to a viewpoint of the second direction in the first embodiment. The inclined surfaces 422A and 422B are essentially symmetrical with respect to the straight line passing through the boundary 423 in a vertical (Z-axis) direction. Because the inclined surfaces 422A and 422B the inclination angles as described above can be an incident light beam in the upward direction (Z direction) of the element-facing surface 420 occurs regularly from the area of the inclined surface 422A or 422E be reflected and efficient in the light guide plate 40 in the middle or reverse direction.

The limit 423 is a micro-area between the inclined surfaces 422A and 422B is provided in accordance with a portion above the position at which the light-emitting element 22 is mounted. In the light guide plate 40 is the limit 423 shaped so that it has the smallest possible size. Therefore, when operating the device 100 the output light beam of the light-emitting element 22 adapted so that the output light beam difficult to limit 423 penetrates to become a direct beam of light.

One of the features of the device 100 is it that at the peripheral end 344 of the plate-like member 30 the pair of sections 342A and 343A facing each other, wherein the first opening part 340 between them in the direction parallel to the center direction, and the surface facing the element 420 in a plan view of the light guide plate 40 overlaps ( 6 to 8th ). In the direction parallel to the center direction, the width W here is between the light incident ends 420A and 420B the surface facing the element 420 set larger than a gap W ₂ between the pair of sections 342A and 343A , In the direction parallel to the center direction is the pair of sections 342A and 343A inside the light incidence ends 420A respectively. 420B , That means in the body 1 is the section above the first opening part 340 completely with the element facing surface 420 covered.

The side walls 342 and 343 are each arranged on a straight line, which is a corresponding one of the pair of sections 342A and 343A and a corresponding one of the light incident ends 420A and 420B in a section along a virtual plane (for example, a section in 9 (a) ) connecting at right angles to the upper surface of the mounting substrate 20 is and through the pair of sections 342A and 343A runs (see output light beams L ₂ and L ₄ in 9 (a) ).

[Diffusion cover 50 ]

The diffusion cover 50 is provided so that the luminance distribution has the uniform area emission caused by further scattering the output light beam from the lightguide plate 40 is obtained. The diffusion cover 50 consists of a permeable material such as silicone resin, acrylic resin, polycarbonate resin and glass.

The diffusion cover 50 has a body part 51 on top of the light guide plate 40 and the side wall part 52 covering that around a perimeter of the body part 51 ( 3 ) are provided as a specific configuration.

A light scattering treatment is applied to the body part 51 performed to the light beam coming from the light guide plate 40 is spent scattering. A treatment for finely forming irregularities on the surface of the body part 51 , the light guide plate 40 may be cited as an example of the light scattering treatment.

(Operation of the device 100 )

Hereinafter, an operation of the device 100 described having the aforementioned configuration. When the device 100 is turned on, power is from the power supply unit 4 for the light-emitting element 22 delivered by the wiring 23 connected to a commercially available power source. For this purpose, each of the light-emitting elements emits 22 an output light beam.

The output light beams of the light-emitting element 22 fall onto the light guide plate 40 from the light incident part 42 through the first opening part 340 and the second opening parts 341 of the reflection member 30 one. The normal reflection of the incident light beam is in the light guide plate 40 is repeated, and then the incident light beam is scattered in the central or reverse direction, namely, in the inner light guide portion 41 or the outer light guide part 43 , The light beam coming from the light guide plate 40 escapes downwards, from the upper surface 310 or 320 ( 5 ) of the reflection member 30 reflects and falls on the light guide plate 40 one. The output light beam of the light-emitting. Elements 22 from the light guide plate 40 is scattered, is from the upper surface of the light guide plate 40 issued and falls on the diffusion cover 50 one. The incident light beam gets farther from the body part 51 the diffusion cover 50 scattered on which a light scattering treatment is carried out. The scattered light beam is finally output to the outside as an illumination light beam.

(By the device 100 achieved effects)

The following effects are in the operation of the device 100 expected:

[1] Effect against chip misalignment of the light-emitting element 22

(i) Specific effect

8th FIG. 12 is a sectional view showing the effect obtained when the chip misalignment of the light-emitting element. FIG 22 in the device 100 in the center direction (in this case, the Y direction) is generated.

Usually, the chip misalignment is generated when the light-emitting element 22 on the substrate body 21 of the mounting substrate 20 is mounted. In a current assembly technique, in which case the light emitting element 22 has an overall length of about 1.5 mm in a certain direction, the chip misalignment may be generated in a range of about ± 0.4 mm in the specific direction.

When the chip misalignment is generated, a relative position of the light-emitting element deviates 22 in relation to the light incident part 42 towards the direction of chip misalignment. This increases an amount of high-intensity output light beam of the light-emitting element 22 pointing to the light guide plate 42 and falls to an area of the inclined surface 422A or 422B progresses at which the angle of inclination with respect to the upper surface of the mounting substrate 20 is relatively small (area farther from the surface facing the element 420 is removed). The output light beam falls on the light guide plate 42 on, without on the surface facing the element 420 invade and from either the sidewall 342 or 343 to be reflected. 8th Fig. 10 illustrates a state in which the output light beam of the light-emitting element 22 (indicated by dotted line) towards the inclined surface 4228 is emitted in which the chip misalignment is generated in the center direction.

When an output light beam L _{8 of} high intensity on the inclined surface 422B along a dotted line in 8th incident, without on the element-facing surface 420 invade and from either the sidewall 342 or 343 To be reflected, the output light beam L ₈ can be output to the outside as a direct light beam of high luminance, which is the inclined surface 422B penetrates. This is because the angle of incidence with respect to the inclined surface 422B is small. As a result, the luminance unevenness possibly becomes on the light emission surface of the body 1 generated.

On the other hand, the output light beam L _{8 of} the light-emitting element becomes 22 in the body 1 from the section 343A blocks the surface facing the element 420 in the peripheral end 344 in the plan view of the light guide plate 40 overlaps ( 7 and 8th ). Accordingly, even if the chip misalignment of the emitting element 22 is generated in the center direction, the output light beam of high intensity L ₈ , which is not on the element-facing surface 420 and not either from the sidewall 342 or 343 is reflected, hindered, the inclined surface 422B to reach. Accordingly, it can be prevented that the output light beam L _8, the inclined surface 422B penetrates to be output to the outside as a direct light beam of high luminance.

Although not in 8th 1, even if the chip misalignment is generated in the reverse-direction direction (in this case the reverse direction to the Y-direction), the output light beam emitted from the light-emitting element 22 to the outside of the element facing surface 420 is emitted from the section 342A blocked. Therefore, the similar effect is achieved.

In the body 1 For example, the generation of the respective direct light beam of high luminance, which is the inclined surface 422A or 422B penetrates to be output to the outside, even if the chip misalignment of the light-emitting element 22 in the central or reverse direction (the Y direction or the direction of return to the Y direction in FIG 7 and 8th ), namely, in the first direction or the direction opposite to the first direction.

Although not in 8th sometimes the respective light rays coming from the sidewalls fall 342 and 343 be reflected on the light guide plate 40 from a different area than the surface facing the element 420 and penetrate the light guide plate 40 to be output to the outside (see a light beam L ₁₃ in FIG 17 (a) and a light beam L ₁₅ in 17 (b) ). Because such rays of light partly from the side walls 342 and 343 however, this reduces a ratio of the light beams output to the outside to weaken the intensity of the light beams, and accordingly, luminance unevenness is hardly generated.

Even if the chip misalignment is generated, the output light rays (including L ₅ , L _6, and L ₇₎ fall in 8th ) of the light-emitting element 22 not at least from either one of the pair of sections 342A and 343A be blocked properly on the light guide plate 40 from the environment of the light incident part 42 through the first opening part 340 and become the inner light guide part 41 and the outer light guide part 43 directed to contribute to the light emission. Consequently, the device can 100 which limits the generation of luminance unevenness to achieve uniform area emission.

(ii) Performance Confirmation Test

An example of the device 100 was actually made, and a performance confirmation test was conducted on the luminance unevenness pattern and the illuminance distribution, and the chip misalignment was intentionally generated at constant intervals.

A comparative example was made for the purpose of comparison with the example. In a plan view of the light guide plate 940x points, as in the lighting device 910 from 17 (a) For example, the comparative example illustrates the configuration in which ends facing each other so that the opening of the reflection member 954x which is the light-emitting element 922 surrounds, is present between the ends, not the surface facing the element 947x overlap. Other configurations of the comparative example are identical to those of the example.

The following two cases relate to the chip misalignment of the example and the comparative example. One is a case where the mounting position of the light-emitting element deviates from a reference position in the center direction by a chip misalignment amount of -0.1 mm, -0.3 mm, or -0.5 mm. The other is a case where the mounting position of the light emitting element deviates from the reference position in the reverse center direction by a chip misalignment amount of +0.1 mm, +0.3 mm, or +0.5 mm. The chip misregistration amounts of the example and the comparative example were set equal for all the light emitting elements on the mounting substrate. The devices of Example and Comparative Example were operated under identical conditions. 10 and 11 illustrate results of the performance confirmation tests.

10 and 11 illustrate luminance unevenness patterns and illuminance distributions in the comparative example and the example when the chip misalignment is generated. In 10 and 11 For example, the luminance unevenness pattern is illustrated by photographs in which the light emission surface of the device is photographed from above. The illuminance distribution is shown by a relative intensity distribution with respect to a distance from the center of the light emitting surface of the device.

As apparent from the results of the performance confirmation tests, in the comparative example, the illuminance distribution became inconsistent as the amount of misalignment increased, in both cases where the chip misalignment in the center and inversion direction with respect to the reference position was generated, as in FIG 10 shown. The inconsistency of the illuminance distribution means that the luminance unevenness in the area emission can be generated. As the amount of misalignment increased, an unnecessary high luminance peak in the illuminance distribution appeared to be easily generated (see, for example, chip misalignment data of -0.5 mm or +0.5 mm). When the light emission surface of the device of the comparative example was viewed from above, generation of the chip misalignment largely changed the light emission region. It was confirmed that, as the amount of misregistration increased, the central area of the light emitting area was decreased and the luminance was absent. It was further confirmed that, as the amount of misregistration increased, an annular area of high luminance was generated over the vicinity of the mounting substrate, and the luminance unevenness became conspicuous. At the light emission surface, the position of the luminance unevenness of the high luminance is matched with the peak position of the illuminance distribution.

In contrast, it was confirmed that the example in both cases where the chip misalignment was generated in the inner and outer directions of the mounting substrate with respect to the reference position, in terms of luminance unevenness, which was generated in the illuminance distribution smaller was as the comparative example. When viewed from the top of the light emission surface of the device, the change in a light emission region associated with the amount of chip misalignment was properly restricted. With extremely increasing the chip misalignment, although a slight luminance unevenness observed, a dramatically uniform area emission was provided as compared with the comparative example.

Consequently, a superiority of the example over the comparative example can be confirmed.

[2] Effect of the first opening part 340

In the device 100 becomes when the output light beam of the light-emitting element 22 through the first opening part 340 migrates the output light beam partially from at least one of the two pairs of sections 342A and 343A blocked, which have between them the narrow gap W ₂ ( 7 ). Thereby, the amount of output light beam passing through the first opening part 340 from the mounting position of the light-emitting element 22 wanders, so controlled that it does not become excessive.

Accordingly, when the body 1 from the top, the amount of output light beam is properly in the neighborhood above the light-emitting element 22 controlled. This restricts the unevenness of the luminance distribution between the region corresponding to the mounting position of the light-emitting element 22 and the region corresponding to other positions on the upper surface of the diffusion cover 50 , which contributes to the provision of excellent area emission.

[3] Effects of sidewalls 342 and 343 , Sections 342A and 343A , and light incidence ends 420A and 420B

In the device 100 All output light beams of the light-emitting element 22 that is between the light incidence end 420A ( 420B ) and the section 342A ( 343A ) (hereafter referred to as "traveling light beam"), respectively, from the surface of the sidewall 342 ( 343 ) of the reflection member 30 Reflects and falls on the light incidence part 42 the light guide plate 40 one ( 9 (a) ). An effect achieved here will be described below with reference to the sectional partial view (FIG. 9 (a) ) of the neighborhood of the light incident part 42 and the enlarged sectional view ( 9 (b) ) of the light-emitting element 22 described.

An angle θ ₁ in 9 (b) is an angle of the output light beam L ₁ (L ₃ ) from a certain position of the light-emitting element 22 is output upward in the reverse direction, namely, in the opposite Y direction (the center direction, the Y direction in FIG 9 (b) ) and is in contact with the light incident end 420A ( 420B ) with respect to the reverse-direction (center) direction. That is, the traveling light beam output from the position in the reverse center direction (the center direction) has an angle of θ ₁ or less. An angle θ ₂ is an angle of the output light beam L ₂ (L ₄ ) emitted from the light-emitting element 22 is output upward in the reverse direction, namely, in the opposite Y direction (the center direction, the Y direction in FIG 9 (b) ) and is in contact with the section 342A ( 343A ) and the light incident end 420A ( 420B ) with respect to the reverse-direction (center) direction.

Here, the angle of the passing light beam output in the reverse center direction (the center direction) is restricted to θ ₂ or less at the position where θ _{1 is} larger than θ ₂ . This is because the output light beam of the light-emitting element 22 from the section 342A ( 343A ) or on the surface facing the element 420 occurs when the angle is greater than θ ₂ .

In the body 1 are the side walls 342 and 343 each arranged on a straight line, which is a corresponding one of the pair of sections 342A and 343A and a corresponding one of the light incident ends 420A and 420B that connects to the corresponding one of the pair of sections 342A and 343A in a section along a virtual plane perpendicular to the upper surface of the mounting substrate 20 is and through the pair of sections 342A and 343A runs (for example, a cut in 9 (a) ).

Therefore, the passing light rays each hit the surface of the sidewall 342 or 343 and fall onto the light guide plate 40 as the reflected light beam. The emitted light beam coming from the side wall 342 or 343 is reflected with a sufficiently large angle of incidence on the neighborhood of the inclined surface 422A or 422B ( 9 (a) ) one. Accordingly, the output light beams L ₁ to L _{4 are} respectively regularly from the neighborhoods of the inclined surface 422A or 422B reflected and good to the entire light guide plate 40 directed.

With such an ingenious embodiment, it is possible to prevent the light rays from passing through the vicinity of the inclined surface 422A or 422B penetrate to be discharged to the outside as a direct light beam having a large amount of light.

As in 8th even if there is little chip misalignment in the light-emitting element 22 is generated, passing light beams each with a sufficiently large angle of incidence on the inclined surface 422A or 422B as the output light beams L ₅ , L ₆ and L ₇ a. Accordingly, the aforementioned effect is achieved even if the chip misalignment is generated.

[4] Effect of the combined use of the first opening part 340 and second opening part 341

In the device 100 is the maximum diameter of each of the second opening parts in the direction parallel to the center direction 341 larger than a maximum diameter of the first opening part 340 , For this reason, the amount of emitted light beam passing through the second opening parts 341 migrates compared to the amount emitted light beam through the first opening part 340 migrates, be relatively enriched.

Consequently, the output light beam is each of the light-emitting elements 22 evenly along the cyclic recessed part 32 scattered. Looking at the diffusion cover 50 of the body 1 from the outside, it is possible to mix the high-luminance light-emitting area according to the mounting position of the light-emitting element 22 and the low-luminance light-emitting region corresponding to the position where the light-emitting element 22 not mounted, to prevent. Therefore, the generation of the luminance unevenness can be restricted to produce the uniform area emission.

12 (a) FIG. 12 is a schematic plan view during operation of the surface emitting illumination device. FIG 910 (shown in 17 (a) and 17 (b) ) of the comparative example. 12 (b) Fig. 10 is a plan view showing a photograph in which the state of the light emission surface during operation of the device 910 photographed from above.

As in 12 (a) is the amount of output light beam of the light-emitting element 922 in the vicinity of the mounting position of the light-emitting element 922 between the inner reflection part 945Xb and the outer reflection part 945Xa of the reflection member 945X relatively large. For this reason, as in an enlarged view of 12 (a) shown, a light emitting region D ₂ , which has a relatively high luminance, in addition to the mounting position of the light-emitting element 922 available. On the other hand, light emitting regions D ₁ and D _{3 are present} near the light emitting region D ₂ . In the light emission regions D ₁ and D ₃ , the amount of output light beam of the light-emitting element 922 not present, so that a relatively low luminance is exhibited. In the lighting device 910 appear because the majority of light-emitting elements 922 is arranged with gaps around the circumference, the light emission regions D ₁ to D ₃ repeated in the circumferential direction on the outer surface of the diffusion cover 50X according to the mounting position of the light-emitting elements 922 , Accordingly, when the lighting device 910 is operated, the luminance unevenness possibly generated in the circumferential direction in the light emitting surface, as in 12 (b) shown.

13 (a) is a schematic plan view showing the device 100 during operation of the device 100 shows. 13 (b) Fig. 10 is a plan view showing a photograph in which the state of the light emission surface during operation of the device 100 photographed from above.

As in 13 (a) As shown, the amount of output light beam becomes close to the mounting position of the light-emitting element 22 between the inner light guide part 41 and the outer light guide part 43 the light guide plate 40 from the first opening part 340 controlled, which has the small opening diameter. On the other hand, a large amount of output light beam of the light-emitting element travels 22 through each of the second opening parts 341 having the large opening diameter and with the first opening part 340 communicates. Consequently, the luminance distributions are in the upper surface of the diffusion cover 50 as in an enlarged view of 13 (a) shown in a light emission region C ₂ , the first opening part 340 and light emission regions C ₁ and C ₃ corresponding to the respective second opening portions 341 correspond, homogenized. Accordingly, in the case where the device 100 is actually operated, substantially uniform area emission is obtained in the light emission area, as in 13 (b) shown.

Other Embodiments

Hereinafter, other embodiments of the present invention will be described with reference to FIG 14 (a) to 14 (d) mainly highlighting differences between the other embodiments of the present invention and the first embodiment. Hereinafter, the simple description of the opening diameter means the opening diameter in the direction perpendicular to the connecting direction of the first and second opening parts (a distance between the peripheral ends).

14 (a) is a view that is a shape of an opening 34A shows, which is provided in a reflection member according to a second embodiment. The opening 34A has a structure substantially similar to the structure of the opening of the first embodiment. The opening 34A has a feature in which a peripheral end is formed that divides a pair of second openings 341A surrounds, each with the first opening part 340A are connected in one direction (a horizontal direction in the paper surface of 14 (a) ).

The effect of that of the opening 34 of the reflection member 30 similar to the first embodiment may also be from the opening 34A of the second embodiment. The opening 34A has a configuration in which the opening diameter of each of the second opening parts 341A gradually with the distance from the first opening part 340A decreases, so that a larger amount of emitted light beam can be secured and smoothly in the respective areas of the second opening parts 341A farther away from the first opening part 340A can be issued.

14 (b) is a view that is a shape of an opening 34B shows, which is provided in a reflection member according to a third embodiment. A pair of peripheral ends facing each other with a first opening part 340B in between, is around the opening 34B exists, and is respectively parallel to a direction (the horizontal direction in the paper surface of 14 (b) ). The opening 34B also has a pair of right-angled second opening parts 341B on, each with the first opening part 340B keep in touch.

The effect similar to that of the first embodiment can also be obtained from the opening 34B of the third embodiment. In the opening 34B takes the opening diameter of each of the second opening parts 341B quickly with the distance from the first opening part 340B to. Therefore, a ratio of the amount of output light beam from each of the second opening parts 341B to the amount of output light beam from the first opening part 340B be secured relatively far.

14 (c) is a view that is a shape of an opening 34C shows, which is provided in a reflection member according to a fourth embodiment. The opening 34C has a structure substantially similar to the structure of the opening of the third embodiment. The opening 34C has a feature in which a peripheral end that divides a pair of second opening 341C surrounds, each with the first opening part 340C are connected, is formed circular.

The effect similar to that of the third embodiment can also be obtained from the opening 34C of the fourth embodiment. Because the peripheral end, that the second opening parts 341C surrounds, has no corner portion, have the output light beams from the second opening portions 341C excellent uniformity.

14 (d) is a view that is a shape of an opening 34D shows, which is provided in a reflection member according to a fifth embodiment. The opening 34D has a structure substantially similar to the structure of the opening of the third embodiment. The opening 34D have a feature in which a pair of second opening parts 341D , each with a first opening part 340D are each formed in a shape such that they have an opening diameter, the stepwise with the distance from the first opening part 340D increases.

The effect similar to that of the third embodiment can also be obtained from the opening 34D of the fifth embodiment. The amount of output light beam from each of the second opening parts 341D can by properly adjusting the opening diameter of each of the second opening parts 341D gradually be fine adjusted.

Although only one opening in each of the 14 (a) to 14 (d) is indicated, a plurality of openings may be provided in the reflection member of each of the aforementioned embodiments. A mixture of a plurality of types of the apertures previously described, including the aperture 34 , may be provided in a reflection member.

15 FIG. 12 is a partial sectional view showing a configuration of a light incident part. FIG 42A in a body 1 according to a sixth embodiment and the environment of the light incident part 42 shows. The body 1A is different from the body 1 in that a surface facing the element 420C formed in a slightly curved shape, which is in the light guide plate 40A protrudes downwards.

The similar effect as in the first embodiment may also be in the body 1A expected to have the above-mentioned configuration. In addition, the surface facing the element has 420C in section, the curved shape so that the angle of incidence can be increased when the output light beam of the light-emitting element 22 on the surface facing the element 420C meets. Therefore, the amount of light beam increases from that of the element facing surface 420C is reflected, and the amount of light beam coming from the sidewall 342 or 343 is reflected and onto the light guide plate 40A comes in, increases. Consequently, the amount of light beam that is emitted by the entire lightguide plate can increase 40A is directed.

<Other aspects>

The lighting apparatus related to the present invention is not limited to a ceiling light embedded in a ceiling. The lighting apparatus relating to the present invention can be widely used in lighting such as a spotlight, a tail lamp and a ceiling light installed by other installation methods.

In the present invention, the locking member 3 not necessarily provided. The lighting fixture 1 Can get under the ceiling Use a screw, a rivet, an adhesive or the like may be attached.

In the device 100 are the power supply unit 4 and the lighting fixture 1 for example, configured separately. However, the present invention is not limited to the configuration. That is, the lighting device related to the present invention may have the configuration in which the lighting fixture 1 the power supply unit 4 has in itself.

The light-emitting element relating to the present invention may be, for example, an LD (laser diode) or an EL element (electroluminescent element). The light-emitting element relating to the present invention may also be an SMD (Surface Mount Device) type.

In the lighting device related to the present invention, the diffusion cover is not necessarily provided.

In the aforementioned embodiments, the reflection member is 30 poured as a piece. Alternatively, in the present invention, the adjacent openings 34 be connected to each other. In this case, the reflection member 30 in the inner reflection part 31 and the outer reflection part 33 to be grouped.

In the reflection member relating to the present invention, the recessed part is not necessarily provided, and the light incident part may alternatively be disposed at the position corresponding to the opening of the reflection member. However, since the total thickness of the reflection member and the light guide plate can be reduced by inserting the light incident part into the recessed part, the recessed part contributes to the compact illumination device.

In the lightguide plate, the surface facing the reflection member may be formed in a flat shape, or a plurality of microlenses may be provided to change a reflection property of the light beam traveling through the lightguide plate. Therefore, a photoconductive effect of the light guide plate can be improved.

In the aforementioned embodiments, the reflection member is 30 as an example of the plate-like member extending over the mounting substrate 20 located. However, in the present invention, the configuration of the plate-like member is not limited to the reflection member. That is, the plate-like member may not have the reflective properties.

In the aforementioned embodiments, the body is formed in the disc shape. However, the shape of the body is not limited to the disc shape. For example, the mounting substrate may be constructed by arranging the plurality of light emitting elements in an elongated substrate body. In this case, the base plate, the reflective member, the light guide plate, and the light guide cover are formed in the elongated shape similar to the mounting substrate.

Therefore, the body may be formed in an elongated shape. In the aforementioned embodiments, for example, either one of the first direction and the direction opposite to the first direction is set to one of the middle and reverse direction, and the other of the first direction or the reverse direction is to the other one of the middle direction Reverse center direction set. However, the first direction is not limited to one, the middle or reverse direction. The first direction is the direction in which the inclination angle of the inclined surface with respect to the upper surface of the mounting substrate gradually decreases from the element-facing surface (and the light-emitting element facing the element-facing surface) and the first direction is determined according to the shape of the light guide plate. The body 1 For example, it may have the structure in which the first direction is set to one of the central and reverse direction, with an inclined surface provided only in the first direction. In addition, the body in an oblong shape may have, for example, the structure in which the first direction is set to the direction intersecting the longitudinal direction of the body. In addition, the first direction may be set, for example, in all directions parallel to the upper surface of the mounting substrate of the light-emitting element.

For example, in the aforementioned embodiments, the second direction is set to the circumferential direction. However, the second direction is not limited to the circumferential direction. The second direction may be set in any direction in which the first opening part and each of the second opening parts are connected to each other, the direction intersecting the first direction parallel to the upper surface of the mounting substrate. For example, the second direction in the body 1 be set in a direction that intersects the first direction at an angle greater than 0 ° and less than 90 °.

LIST OF REFERENCE NUMBERS

1, 1A

lighting

2

blanket

4

circuit unit

10

baseplate

20

mounting substrate

21

substrate body

22

Light-emitting element

30, 945, 945X

reflecting member

31

Inner reflection member

32

Spare part

33

Extra reflection member

34, 34A to 34D

opening

40, 40A, 940, 940X

Light guide plate

41

Inner light guide part

42, 42A, 941, 946X

Light incidence part

43

Outer light guide part

50, 50X

diffusion cover

51

body part

100, 900, 910

lighting device

220

member body

221

element capsule

310, 320

Upper surface of the reflection member

340, 340A to 340D

First opening part

341, 341A to 341D

Second opening part

342, 343

Side wall

342A, 343A

Pair of sections

344

Peripheral end

420, 420C, 947X

Surface facing the element

420A, 420B

Light Incident

422A, 422B, 941a, 948X, 949X

inclined surface

423

limit

424A, 424B, 950X, 951X

Side surface portion

Claims (15)

Lighting device comprising: a mounting substrate on which at least one light-emitting element is mounted on an upper surface thereof; a light guide plate covering the upper surface of the mounting substrate to guide an output light beam of the light emitting element; and a plate-like member provided between the mounting substrate and the lightguide plate and having an opening penetrating in a thickness direction to expose at least a part of the light-emitting element, wherein the light guide plate has a light incident part which is disposed above the opening and on which the output light beam of the light emitting element is incident, the light incident part comprises: an element-facing surface facing the light-emitting element; and, on one side of an upper surface of the light guide plate, an inclined surface whose inclination angle with respect to the upper surface of the mounting substrate gradually decreases with the distance from the element-facing surface in a first direction, the first direction being parallel to the upper surface the mounting substrate is, the plate-like member has a peripheral end surrounding the opening, and the peripheral end of the plate-like member is a pair of. Having portions facing each other with the opening therebetween in the first direction, and overlap the element-facing surface in a plan view of the light guide plate. Lighting device according to claim 1, wherein the plate-like member has a recessed part in an upper surface of the plate-like member, and the recessed part has the opening therein, and the light incident part has a protruding part protruding toward the opening, and the protruding part is inserted into the recessed part. Lighting device according to claim 2, wherein the plate-like member has a pair of side walls which are upstanding from the pair of portions in the recessed part, and one of the sidewalls is disposed on a straight line connecting one of the pair of sections and an end of the element-facing surface that is proximate to the one section in a section along a virtual surface, the virtual surface being perpendicular to the upper surface of the surface Mounting substrate is and passes through the pair of sections. The lighting apparatus according to claim 3, wherein there is a gap between each of the side walls and the element-facing surface in the first direction. The lighting apparatus according to any one of claims 1 to 4, wherein the plate-like member is a reflection member that reflects the light beam of the light-emitting element. The lighting apparatus according to any one of claims 1 to 5, wherein the light incident portion further has on the side of the upper surface of the light guide plate an inclined surface whose inclination angle with respect to the upper surface of the mounting substrate gradually decreases with the distance from the element-facing surface in one direction which is opposite to the first direction. Lighting device according to one of claims 1 to 6, wherein the opening comprises: a first opening part provided between the pair of sections; and a second opening part connected to the first opening part in a second direction and having a larger maximum diameter in a direction parallel to the first direction than the first opening part, the second direction intersecting the first direction parallel to the upper surface of the mounting substrate and the light incident part is disposed above the first opening part. The lighting apparatus according to claim 7, wherein the second direction is a direction perpendicular to the first direction, and the second opening part is provided in pairs facing each other with the first opening part interposed therebetween. Lighting device according to claim 7 or 8, wherein the light-emitting element is mounted several times with gaps and the second opening part is provided above a gap between each adjacent two of the light-emitting elements. Lighting device according to claim 9, wherein the plurality of light-emitting elements are mounted circumferentially on the upper surface of the mounting substrate and the light incident part is continuously formed, so that portions are coupled over the plurality of light emitting elements. The lighting device according to claim 10, wherein the light guide plate has a disk shape and has an inner light guide part located inside the light incident part, and an outer light guide part that is outside the light incident part. Lighting device according to claim 11, wherein the inner light guide part is similar to the outer light guide part at the height of a top side major surface of the upper surface of the mounting substrate and the inner light guide part is equal in thickness to the outer light guide part. A lighting device according to any one of claims 1 to 12, wherein the plate-like member and the light guide plate are each molded by injection molding. Lighting device according to one of claims 1 to 13, wherein the light-emitting element is an LED element. The lighting device according to any one of claims 1 to 14, further comprising a power supply device that powers the light-emitting element.

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