JP6560575B2 - lighting equipment - Google Patents

Description

  The present invention relates to a lighting fixture including a light emitting element such as an LED as a light source.

  2. Description of the Related Art In recent years, there has been known a lighting fixture that uses a light emitting element such as an LED as a light source to irradiate a flat irradiation surface such as a signboard (for example, see Patent Document 1). In such a luminaire, a plurality of light sources are used in order to obtain sufficient illuminance.

JP 2008-153154 A

By the way, in order to obtain sufficient illuminance by reducing the number of light sources to be used, it is preferable to use a high output type light source module in which light emitting elements are densely arranged on a substrate to form a planar light emitting portion. it can. There has been a demand for a lighting fixture that efficiently uses light from such a high-power light source module to illuminate an irradiation surface such as a signboard.
The present invention has been made in view of the above-described circumstances, and illumination that efficiently uses light from a high-power light source module in which light-emitting elements are densely arranged on a substrate to form a planar light-emitting portion. The purpose is to provide equipment.

  In order to achieve the above-described object, the present invention provides a lighting apparatus for illuminating an irradiation surface, having an exit opening on the front surface, and aligning the horizontal axis as a reference axis substantially parallel to the reference axis of the irradiation surface. Instrument body, a plurality of light source modules arranged inside the instrument body along the direction of the horizontal axis, and a bowl-shaped reflector in which the light source modules are respectively disposed at the bottom. The light source module has a plurality of light emitting elements arranged so that the left and right ends of a substantially circular region are apexes and a plurality of arcuate curves are connected between the vertices, and the substantially circular region is made of phosphor resin. The light source module is arranged so that the apexes are aligned in the horizontal axis direction.

  Moreover, the present invention may be provided with a lens that expands light emitted from the opening of the reflecting mirror in the direction of the horizontal axis in the lighting fixture.

  Further, the present invention provides the above-described lighting fixture, wherein the fixture main body is installed at one end of the irradiation surface, and the reflecting mirror is installed in a state of irradiating the irradiation surface with light from the light source module. It may have a notch provided obliquely toward the one end as viewed from the optical axis direction.

  Moreover, this invention WHEREIN: The said lighting fixture WHEREIN: The reflective surface of the said reflective mirror may have a paraboloid.

  In the lighting fixture according to the present invention, a diffusion cover that covers the emission opening and diffuses light from the light emitting element may be provided on the front surface of the fixture main body.

  Moreover, this invention WHEREIN: The said diffusion cover may be an embossed glass in the said lighting fixture.

  According to the present invention, there is provided a lighting apparatus for illuminating an irradiation surface, the apparatus main body having an emission opening on the front surface, and being set so that a horizontal axis that is a reference axis is substantially parallel to a reference axis of the irradiation surface. A plurality of light source modules arranged inside the instrument main body along the direction of the horizontal axis, and a bowl-shaped reflecting mirror in which the light source modules are respectively arranged at the bottom, and the light source module is substantially circular It has a plurality of light emitting elements arranged so as to connect each vertex with a plurality of arcuate curves with the left and right ends of the region as vertices, and the substantially circular region is integrally covered with a phosphor resin. Since the light source modules are arranged so that the apexes are aligned in the horizontal axis direction, the light from each light source module can be spread in the same direction as the arrangement direction of the plurality of light source modules, and the light emitting element is placed on the substrate. Densely arranged and planar It can utilize a high-output light source module of forming the optical portion efficiently.

It is a perspective view which shows the lighting fixture of embodiment of this invention from the front side. It is a disassembled perspective view of a lighting fixture. It is a figure which shows the structure of a reflective mirror, (A) is a perspective view, (B) is a top view. It is a perspective view of the lighting fixture which shows the state which attached the reflective mirror. It is a figure which shows the structure of the lighting fixture which has a reflecting mirror, (A) is a schematic diagram which shows the installation form of a lighting fixture, (B) is a figure which shows the light distribution obtained by a lighting fixture. It is a perspective view of the lighting fixture which shows the state which attached the lens. It is a figure which shows the structure of the lighting fixture which has a lens, (A) is a schematic diagram which shows the installation form of a lighting fixture, (B) is a figure which shows the light distribution obtained by a lighting fixture. It is a schematic diagram which shows the structure of LED. It is a figure which shows the characteristic of the light distribution obtained by LED of this embodiment, (A) is a perspective view of a lighting fixture, (B) is a figure which shows the light distribution curve of LED of this embodiment, (C) is conventional. It is a figure which shows the light distribution curve of no LED.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a perspective view of a lighting fixture 1 according to this embodiment. FIG. 2 is an exploded perspective view of the lighting fixture 1. The luminaire 1 is a projector that can be used to illuminate the planar irradiation surface S, and can be used as, for example, signboard illumination. As shown in FIGS. 1 and 2, the lighting fixture 1 includes a fixture main body 10 and is rotatably attached to a predetermined attachment location by an attachment arm 25 provided so as to sandwich the fixture main body 10.

  As shown in FIG. 2, the instrument main body 10 includes a bottomed rectangular box-shaped casing 11 having one side opened, and a light source module 12 provided inside the casing 11. The light source module 12 is a high-power LED in which LED elements 6 as an example of light-emitting elements are densely arranged on an LED substrate 7 to form a planar light-emitting portion. As the light source module 12, a chip-on-board (COB) type LED can be suitably used. According to this configuration, the high-power lighting fixture 1 can be realized with a small number of light source modules 12, and the fixture main body 10 can be downsized. A plurality (two in this embodiment) of light source modules 12 are arranged side by side along the longitudinal direction of the casing 11 (the instrument horizontal axis X direction described later) on the bottom of the casing 11. Furthermore, the housing 11 is provided with a bowl-shaped reflecting mirror 14 that controls the light distribution of the light source module 12. The casing 11 is formed to an appropriate depth in which the reflecting mirror 14 is accommodated. The light source module 12 is disposed on the bottom 15 of the reflecting mirror 14 and is disposed with the light emitting surface 12 </ b> A facing the opening 15 </ b> A of the bottom 15 of the reflecting mirror 14. In addition, a shielding plate 39 is provided inside the housing 11 between the bottom surface 20 of the housing 11 and the emission opening 13 so as to be substantially parallel to the bottom surface 20. The shielding plate 39 is provided so that the structure inside the housing 11 cannot be seen from the outside through a front cover 40 described later. The shielding plate 39 is provided with an appropriately sized hole 39A into which the bottom 15 of the reflecting mirror 14 is inserted. In addition, the shielding plate 39 is formed with a locking hole 39B in which the claw portion 19 provided at the tip of the pair of fixed legs of the reflecting mirror 14 is locked.

  The casing 11 is made of a material having excellent thermal conductivity, and can be made of, for example, aluminum die cast. Further, a light source attachment portion 21 to which the light source module 12 is attached is integrally formed on the bottom surface 20 of the housing 11 in the housing 11. A plurality of radiating fins (not shown) for radiating heat generated from the light source module 12 are provided on the back surface of the housing 11. The heat from the light source module 12 is transferred to the light source mounting portion 21, further transferred from the light source mounting portion 21 to the heat radiation fin via the bottom surface 20, and radiated to the outside. In addition, a back guard 50 is attached to the back surface 30 of the housing 11 so as to surround the periphery of the radiation fins (not shown). The back guard 50 can be made of resin, protects the structure provided on the back surface of the housing 11, and prevents the fingers from coming into contact with the heat radiating fins and the charging part on the back surface 30 of the housing 11. The back guard 50 is provided with a plurality of slits 51. The slit 51 is formed in a size that prevents a finger from entering the back guard 50 through the slit 51. Further, the heat of the radiating fin is radiated to the outside of the back guard 50 through the slit 51.

The housing 11 has a front opening 11B on the front surface 11A located in front of the light emitting surface 12A of the light source module 12. A front cover 40 that covers the front opening 11 </ b> B is provided on the front surface 11 </ b> A of the housing 11. The front cover 40 is a diffusion cover that diffuses light from the light source module 12, and glass having light diffusibility such as tempered embossed glass can be suitably used for the front cover 40. The front cover 40 is fixed to the front surface of the housing 11 in a watertight manner, for example, by adhesion.
The front cover 40 is further pressed against the casing 11 by a frame-shaped cover presser 41 from the outside direction of the casing 11. The opening of the cover presser 41 constitutes the emission opening 13 of the lighting fixture 1, and light from the light source module 12 is emitted from the emission opening 13 to the outside of the housing 11. The cover presser 41 is formed of a resin material, and is fixed to the front surface 11A of the housing 11 in a watertight manner, for example, by adhesion, and is fixed by a fixing tool such as a screw. The cover presser 41 may have a sealing material such as waterproof packing between the front surface 11A of the housing 11 and be fixed by a fixture. According to this configuration, even if the adhesion between the front cover 40 and the cover presser 41 and the front surface 11A of the housing 11 is weakened, the front cover 40 can be prevented from dropping or being flooded into the housing 11. Can do.

  A lens 22 for spreading light emitted from the opening 24 in a predetermined direction can be attached to the opening 24 of the reflecting mirror 14. The reflecting surface 16 of the reflecting mirror 14 has a parabolic surface, and the lens 22 is formed in a substantially circular shape centering on the rotation axis of the parabolic reflecting surface 16. The lens 22 is fixed to a flange portion 23 provided at the periphery of the opening 24 of the reflecting mirror 14. In addition, although illustration is abbreviate | omitted, the structure provided integrally with the front cover 40 may be sufficient as the lens 22 in the position through which the light radiate | emitted from the opening part 24 of the reflective mirror 14 passes. The lens 22 may be supported by an arm extending from the housing 11.

  As shown in FIGS. 2 and 3, the reflecting mirror 14 has a notch 17 at a part of the periphery. As shown in FIG. 3A, the cutout portion 17 is formed by cutting out a range of a predetermined angle or more (for example, 30 ° or more) from the optical axis L direction of the light source module 12. With this cutout portion 17, light of a predetermined angle or more from the light axis L direction out of the light from the light source module 12 is directly emitted from the cutout portion 17 without entering the reflection surface 16 of the reflecting mirror 14. It is configured. The angle range from the optical axis L direction where the notch 17 is provided is the light that is reflected by the inner surface of the housing 11 when the light from the light source module 12 is directly emitted without being reflected by the reflecting mirror 14. And can be set appropriately depending on the size and shape of the housing 11 and the size of the light emitting surface 12A of the light source module 12. That is, the notch 17 is provided up to a height range in the optical axis L direction in which light emitted from the light source module 12 through the notch 17 is directly emitted from the exit opening 13 of the housing 11. .

  Further, as shown in FIG. 3 (B), the notch 17 has a notch in the range of 40 ° to 60 ° with the notch center α being 15 ° to 35 ° from the horizontal axis x of the reflector passing through the optical axis L. It is formed with a notch width β. Further, the notch 17 is provided at two positions symmetrical to the reflecting mirror vertical axis y passing through the optical axis L and orthogonal to the reflecting mirror horizontal axis x. In addition, when the reflecting mirror 14 has the parabolic reflecting surface 16 like this embodiment, it cannot be overemphasized that the optical axis L passes on the same line as the rotation center O of the reflecting surface 16. FIG.

  The light source module 12 and the reflecting mirror 14 are disposed inside the housing 11 so that the light emitted from the notch 17 does not enter the outer peripheral surface or the reflecting surface 16 of the adjacent reflecting mirror 14 and is blocked. Are arranged side by side along the instrument horizontal axis X direction at appropriate intervals.

  The reflecting mirror 14 has a pair of fixed legs 18 and 18 provided at positions avoiding the notch 17. The fixed leg 18 is formed to have a height dimension substantially the same as the height dimension of the reflecting mirror 14 extending in the optical axis L direction, and a claw portion 19 is provided at the lower end. The reflecting mirror 14 is attached by elastically deforming the fixed leg 18, inserting the lower end into the locking hole 39 </ b> B, and hooking the claw portion 19 into the locking hole 39 </ b> B of the shielding plate 39 from the inside.

  As shown in FIG. 4, the reflecting mirror 14 is arranged such that the reflecting mirror horizontal axis x is substantially parallel to the fixture horizontal axis X of the lighting fixture 1. The reflector horizontal axis x and the instrument horizontal axis X may be arranged on the same line. In FIG. 4, the front cover 40 is not shown in order to clearly show the installation configuration of the reflecting mirror 14. However, in the actual use state, the front cover 40 is provided on the front surface 11 </ b> A of the housing 11. It has been. In this embodiment, the luminaire 1 is installed so as to illuminate a substantially rectangular planar irradiation surface S (see FIGS. 5A and 7A), and one end (upper and lower ends) of the irradiation surface S. The illumination surface S is entirely illuminated from the 60 side. An instrument horizontal axis X extending along the arrangement direction of the light source modules 12 is a reference axis when the lighting fixture 1 is installed. The lighting fixture 1 is substantially the same as the irradiation reference axis W of the irradiation surface S. Installed in parallel. As shown in FIGS. 5 (A) and 7 (A), the irradiation surface S has a substantially rectangular planar shape, and when the luminaire 1 is installed and used at the upper end of the irradiation surface S, the irradiation reference is used. The axis W is defined as extending in a direction along the upper edge of the irradiation surface S. In addition, when irradiating the irradiation surface S with one lighting fixture 1, the irradiation surface S can be efficiently illuminated by installing and using the lighting fixture 1 in the approximate center of the edge to install. . In addition, it cannot be overemphasized that according to the magnitude | size of the irradiation surface S, the some lighting fixture 1 can be arranged and used side by side.

  The lighting fixture 1 is installed so that the cutout portion 17 of the reflecting mirror 14 faces the one end portion 60 of the irradiation surface S on which the lighting fixture 1 is installed. That is, when the luminaire 1 is provided at the upper end portion of the irradiation surface S, the cutout portion 17 of the reflecting mirror 14 is disposed so as to be located obliquely upward as viewed from the optical axis L direction. When provided at the lower end portion of the irradiation surface S, the cutout portion 17 of the reflecting mirror 14 is disposed so as to be located obliquely downward as viewed from the optical axis L direction. Similarly, when the lighting fixture 1 is provided at the left end portion of the irradiation surface S, the cutout portion 17 of the reflecting mirror 14 is disposed so as to be obliquely leftward when viewed from the optical axis L direction. Is provided at the right end portion of the irradiation surface S, the notch portion 17 of the reflecting mirror 14 is disposed so as to be positioned obliquely to the right when viewed from the optical axis L direction.

  The lighting fixture 1 is configured to control the light from the light source module 12 with a single reflecting mirror 14 as shown in FIG. 4, or the light from the light source module 12 with the reflecting mirror 14 as shown in FIG. It can be set as the structure controlled by the combination with the lens 22. FIG. The configuration in which the light from the light source module 12 is controlled by the reflecting mirror 14 alone can be suitably used when illuminating a vertically long irradiation surface S such as a vertically long signboard as shown in FIG. FIG. 5A shows a state in which one lighting fixture 1 is installed at the center of the upper end of a signboard having a width of 4 m and a height of 6 m. FIG. 5B shows the light distribution of the lighting fixture 1 in the installation state of FIG.

  In the installed state shown in FIG. 5A, the reflecting mirror 14 of the luminaire 1 has the notch 17 positioned obliquely upward as viewed from the optical axis L direction as described above. Since the two notches 17 are provided at symmetrical positions, a part of the light from the light source module 12 is directed from the luminaire 1 to the upper corners of the irradiation surface S via the notches 17. Radiated. When the reflecting mirror 14 does not have the notch portion 17, the light from the light source module 12 becomes a light beam line substantially parallel to the central axis of the parabolic reflecting surface, and the illuminance at the upper corners of the irradiation surface S Cannot be secured. However, according to this embodiment, since the notch part 17 is provided so that it may face in the direction of the one end part 60 of the irradiation surface S in which the lighting fixture 1 was installed, it is in the both corners of the said one end part 60 of the irradiation surface S. The brightness can be ensured.

  FIG. 6 shows the luminaire 1 configured to control the light from the light source module 12 by a combination of the reflecting mirror 14 and the lens 22. In FIG. 6, the front cover 40 is not shown in order to clearly show the installation configuration of the reflecting mirror 14 and the lens 22, but in actual use, the front surface 11 </ b> A of the housing 11 has a front surface. A cover 40 is provided. As described above, the lens 22 is provided in the opening 24 of the reflecting mirror 14, and is configured to spread light from the light source module 12 emitted through the opening 24 in the instrument horizontal axis X direction. . Among the light emitted from the light source module 12, the light emitted from the light source module 12 and the reflected light reflected by the reflecting surface 16 of the reflecting mirror 14 are directly emitted from the light source module 12 and substantially parallel to the optical axis L. And included light.

  The configuration in which the light from the light source module 12 is controlled by the combination of the reflecting mirror 14 and the lens 22 can be suitably used when illuminating a horizontally long irradiation surface S such as a horizontally long signboard as shown in FIG. . FIG. 7A shows a state in which one lighting fixture 1 is installed at the center of the upper end of a signboard having a width of 4 m and a height of 3 m. FIG. 7B shows the light distribution of the luminaire 1 in the installed state of FIG. As described above, the reflecting mirror 14 that converts the light from the light source module 12 into parallel light parallel to the optical axis L, and the lens that expands the light emitted through the opening 24 of the reflecting mirror 14 in the instrument horizontal axis X direction. 22 can be used to efficiently illuminate the horizontally elongated irradiation surface S using the light from the light source module 12 without waste.

  In the installation state shown in FIG. 7A, the reflecting mirror 14 of the luminaire 1 has the cutout portion 17 positioned obliquely upward as viewed from the optical axis L direction as described above. Since the two notches 17 are provided at symmetrical positions, a part of the light from the light source module 12 is directed from the luminaire 1 to the upper corners of the irradiation surface S via the notches 17. Radiated. Thereby, the direct light radiate | emitted from the notch part 17 in the direction of the both corners of the one end part 60 of the irradiation surface S in which the lighting fixture 1 was installed is radiated | emitted, and the brightness in the both corners of the said one end part 60 is made. Can be secured.

  By the way, the light source module 12 is a high-brightness and high-output module having a COB (chip on board) structure in which a large number of LED elements 6 are densely arranged on the LED substrate 7 to form a light emitting surface 12A having a substantially circular shape in plan view. However, the inventors have found that the light distribution from the light source module 12 changes depending on the arrangement direction of the LED elements 6 in the light source module 12. In recent years, in order to densely arrange a larger number of LED elements 6 on the LED substrate 7, within the substantially circular region (circular region 8), the opposite ends on the outer periphery are set as vertices V, and between the vertices V There is known a COB type LED in which a plurality of LED elements 6 are arranged so as to be connected by a plurality of arcuate curves (for example, arcuate curves such as a plurality of meridians connecting the north and south poles of the earth). When the inventors use such a COB type LED as the light source module 12, as shown in FIG. 8, each vertex V of the arcuate curve in which the LED elements 6 are arranged is set as the horizontal axis of the lighting fixture 1. It was discovered that the light distribution spreads in the left-right direction by arranging the light source module 12 so as to be positioned in the X direction.

  FIG. 9 is a diagram illustrating a difference in light distribution of the light source module 12 due to a difference in the arrangement direction of the LED elements 6. 9A shows the horizontal angle φ and the vertical angle θ used in FIGS. 9B and 9C. FIG. 9B shows the light source module 12 along with the LED element 6. FIG. 9C shows the light distribution when the vertices of the arranged arcuate curves are positioned in the horizontal direction. FIG. 9C shows the light source module 12 and the vertices of the arcuate curve along which the LED elements 6 are arranged. The light distribution in the case of being arranged so as to be positioned in the vertical direction is shown. As shown in FIGS. 9B and 9C, when the light source module 12 is arranged so that each vertex of the arc-shaped curve in which the LED elements 6 are arranged is positioned in the lateral direction, 0 ° and The luminous intensity of the horizontal plane φ of 180 ° is higher than when the light source module 12 is arranged so that each vertex of the arc-shaped curve in which the LED elements 6 are arranged is positioned in the vertical direction. That is, when the light source module 12 is arranged so that each vertex of the arc-shaped curve in which the LED elements 6 are arranged is positioned in the horizontal direction, it can be seen that a lot of light is emitted in the horizontal direction. .

  As described above, light from the light source module 12 is directly emitted from the cutout portion 17 of the reflecting mirror 14 through the cutout portion 17. The light source module 12 is arranged along the LED elements 6. By arranging each vertex of the arcuate curve so as to be positioned in the direction of the horizontal axis X of the lighting fixture 1, the light from the light source module 12 is efficiently spread in the left-right direction, and the irradiation surface on which the lighting fixture 1 is installed Both corners of one end 60 of S can be illuminated. Further, when the light from the light source module 12 is expanded in the instrument horizontal axis X direction by the lens 22 provided in the opening 24 of the reflective mirror 14, the amount of light reflected from the reflective mirror horizontal axis x direction increases. Therefore, the entire horizontally long irradiation surface S can be efficiently illuminated.

As described above, according to the present embodiment, the illuminating device 1 illuminates the irradiation surface S, has the emission opening 13 on the front surface 11A, and irradiates the irradiation surface S with the device horizontal axis X that is the reference axis. The instrument main body 10 installed so as to be substantially parallel to the reference axis W, the plurality of light source modules 12 arranged inside the instrument main body 10 along the direction of the instrument horizontal axis X, and the light source modules 12 are respectively provided on the bottom 15. The light source module 12 includes a plurality of LEDs arranged in such a manner that the left and right ends of the substantially circular region 8 are apexes and the apexes are connected by a plurality of arc-shaped curves. The element 11 is provided, and the substantially circular region 8 is integrally covered with a phosphor resin, and the light source module 12 is arranged so that the vertex V is aligned in the direction of the instrument horizontal axis X.
According to this configuration, since the light from each light source module 12 can be spread in the same direction as the arrangement direction of the plurality of light source modules 12, the light from the light source modules 12 can be used efficiently.

  Further, according to the present embodiment, the lens 22 that spreads the light emitted from the opening 24 of the reflecting mirror 14 in the direction of the instrument horizontal axis X is provided. According to this configuration, the light from each light source module 12 can be spread by the lens 22 in the same direction as the arrangement direction of the plurality of light source modules 12, and the light from the light source modules 12 can be used efficiently. .

  Moreover, according to this embodiment, the instrument main body 10 is installed in the one end part 60 of the irradiation surface S, and the reflective mirror 14 of the light source module 12 is the installation state which irradiates the light from the light source module 12 to the irradiation surface S. It has the notch part 17 provided diagonally toward the direction of the one end part 60 seeing from the optical axis L direction. According to this configuration, a part of the light that spreads in the direction of the instrument horizontal axis X due to the arrangement of the LED elements 6 of the light source module 12 can be irradiated obliquely from the notch portion 17 directly toward the one end portion 60. It is possible to prevent the amount of light from dropping at both corners of the one end 60.

  In addition, according to the present embodiment, the reflecting surface 16 of the reflecting mirror 14 has a parabolic surface. Therefore, the light from the light source module 12 is converted into parallel light parallel to the optical axis L by changing the light from the light source module 12. The utilization efficiency of can be improved.

Further, according to the present embodiment, the front cover 40 that covers the emission opening 13 and diffuses the light from the light source module 12 is provided on the front surface 11 </ b> A of the instrument body 10. According to this configuration, the light emitted from the emission opening 13 can be diffused and the entire irradiation surface S can be efficiently illuminated.
Moreover, according to this embodiment, since the front cover 40 is stamped glass, the handleability of the front cover 40 can be improved, and the light emitted from the emission opening 13 can be diffused efficiently.

The above-described embodiment is merely an aspect of the present invention, and can be arbitrarily modified and applied without departing from the spirit of the present invention.
For example, in the embodiment described above, the luminaire 1 is configured to have a rectangular shape including the box-shaped housing 11, but the shape of the luminaire is not limited to a rectangle, and is formed in, for example, a circular shape or a polygonal shape. May be.

1 Lighting fixture 6 LED element (light emitting element)
7 LED substrate 8 Circular area 10 Instrument body 11 Housing 11A Front surface 12 Light source module 12A Light emitting surface 13 Outgoing aperture 14 Reflecting mirror 15 Bottom 16 Reflecting surface (parabolic reflecting surface)
17 Notch 22 Lens 24 Opening 40 Front Cover 60 One End L Optical Axis S Irradiation Surface V Vertex W Irradiation Reference Axis (Reference Axis)
X Instrument horizontal axis (horizontal axis, reference axis)

Claims (6)

A lighting fixture for illuminating the irradiated surface,
An instrument body that has an exit opening on the front surface and is set so that the horizontal axis that is the reference axis is substantially parallel to the reference axis of the irradiation surface;
A plurality of light source modules arranged inside the instrument body along the direction of the horizontal axis;
A bowl-shaped reflecting mirror disposed on the bottom of each of the light source modules,
The light source module includes a plurality of light emitting elements arranged so that the left and right ends of a substantially circular area are apexes and a plurality of arcuate curves are connected between the apexes, and the substantially circular area is made of phosphor resin. It ’s covered together,
The lighting device, wherein the light source modules are arranged so that the apexes are aligned in the horizontal axis direction.   The lighting fixture according to claim 1, further comprising a lens that spreads light emitted from the opening of the reflecting mirror in the direction of the horizontal axis. The instrument body is installed at one end of the irradiation surface,
The reflecting mirror has a cutout portion provided obliquely toward the one end portion when viewed from the optical axis direction of the light source module in an installation state in which the light from the light source module is irradiated onto the irradiation surface. The lighting fixture according to claim 1 or 2, wherein   The lighting apparatus according to claim 1, wherein the reflecting surface of the reflecting mirror has a parabolic surface.   The lighting fixture according to claim 1, wherein a diffusion cover that covers the emission opening and diffuses light from the light source module is provided on a front surface of the fixture main body. The lighting apparatus according to claim 5, wherein the diffusion cover is a stamped glass.