JP2020167124A - Luminaire - Google Patents

Abstract

To provide a luminaire that can be made compact and lightweight.SOLUTION: A luminaire comprises a heat radiator 21, a first optical component 16, a second optical component 17, and a press member 68. The heat radiator 21 has a light source. The first optical component 16 has a first fitting part 53, and is arranged in an optical-axis direction of the light source. The second optical component 17 has a second fitting part 61 overlapping with the first fitting part 53 of the first optical component 16, and is different in material from the first optical component 16 and arranged in the optical axis direction of the light source with respect to the first optical component 16. The press member 68 presses the second fitting part 61 of the second optical component 17, overlapping with the first fitting part 53 of the first optical component 16, elastically against the heat radiator 21.SELECTED DRAWING: Figure 4

Description

An embodiment of the present invention relates to a lighting device using two optical components made of different materials.

Conventionally, in a lighting device, two optical components such as a reflector and a diffuser may be arranged in the optical axis direction of a light source. In this case, in order to reduce the size of the lighting device and improve the assembling property, the two optical components are integrally attached to the fixture body with screws.

However, if the materials of the two optical components are different, abnormal noise may be generated when the temperature rises or falls as the temperature rises or falls due to the difference in the coefficient of thermal expansion of each material.

Therefore, it is desired that even a lighting device using two optical components made of different materials can be miniaturized and assembled without generating abnormal noise.

Japanese Unexamined Patent Publication No. 2016-181435

The present invention is to provide a lighting device that can be made smaller and lighter.

The lighting device of the embodiment includes an instrument body, a first optical component, a second optical component, and a pressing member. The instrument body has a light source. The first optical component has a first mounting portion and is arranged in the optical axis direction of the light source. The second optical component has a second mounting portion that overlaps with the first mounting portion of the first optical component, is made of a different material from the first optical component, and has an optical axis of a light source rather than the first optical component. Arranged in the direction. The pressing member elastically presses the second mounting portion of the second optical component that overlaps the first mounting portion of the first optical component against the instrument body.

According to the lighting device of the embodiment, miniaturization and weight reduction can be expected.

It is a perspective view of the lighting apparatus which shows the 1st Embodiment. It is the perspective view of the disassembled state of the lighting apparatus as above. It is the perspective view of the disassembled state of the lighting apparatus as above. It is a perspective view of the same lighting apparatus. It is a bottom view of the same lighting device. It is a top view of the fixture main body of the 2nd lighting apparatus.

Hereinafter, the first embodiment will be described with reference to FIGS. 1 to 5.

The lighting device 10 is, for example, an embedded lighting device such as a downlight that is embedded and installed in an embedded hole provided in a ceiling plate.

The lighting device 10 includes a lamp body 11 and a power supply unit connected to the lamp body 11 by a connecting line to supply lighting power.

The lamp body 11 includes a housing 14, a light source 15 attached to the housing 14, a first optical component 16 arranged in the housing 14 along the optical axis direction of the light source 15, and a second optical. It includes a component 17 and a third optical component 18, and the like.

The housing 14 includes a radiator 21 as an instrument main body and a decorative frame 22 attached to the lower surface of the radiator 21.

The radiator 21 is made of metal and includes a disc-shaped heat radiating plate portion 25 and a plurality of radiating fins 26 projecting from the upper surface of the heat radiating plate portion 25. A mounting surface 25a is provided on the lower surface of the heat radiating plate portion 25, and a light source mounting surface portion 27 for mounting the light source 15 is provided in the center of the mounting surface 25a. On the mounting surface 25a, a plurality of bosses 29 are projected from a position where a wiring path 28 having a predetermined width is provided between the mounting surface 25a and the position where the light source 15 is mounted. For example, two bosses 29 are provided at symmetrical positions in the circumferential direction, but three or more bosses 29 may be provided.

A plurality of mounting grooves 30 for screwing the decorative frame 22 are provided on the peripheral edge of the heat radiating plate portion 25. Further, a wiring groove 31 for wiring a connection line to and from the power supply unit is provided in the peripheral portion of the heat radiation plate portion 25. The wiring groove 31 is arranged between the adjacent heat radiation fins 26.

The heat radiating fin 26 has a first fin portion 26a protruding in the radial direction passing through the center of the heat radiating plate portion 25, and a plurality of second fin portions 26b protruding in a direction intersecting the first fin portion 26a. are doing. A wiring groove 31 is provided between the adjacent second fin portions 26b, and a holding plate 32 for holding the connecting wire is attached to the upper surface of the second fin portions 26b.

Further, the decorative frame 22 has a cylindrically formed tubular portion 34 and a flange-shaped decorative frame portion 35 projecting outward from the lower end of the tubular portion 34. On the upper side of the outer peripheral surface of the tubular portion 34, a plurality of boss portions 36 to be screwed through the mounting groove 30 of the radiator 21 are provided. A plurality of spring mounting portions 37 are provided on the lower side of the outer peripheral surface of the tubular portion 34. A mounting spring 38 for mounting on the ceiling plate is mounted on each spring mounting portion 37. Further, a plurality of mounting holes 39 for mounting the third optical component 18 are provided on the outer peripheral surface of the tubular portion 34.

A light emitting module 41 is used as the light source 15. The light emitting module 41 includes a substrate and a light emitting element mounted on the substrate. As the light emitting module 41, for example, a COB (Chip on board) module in which a plurality of LED chips are mounted on a substrate and sealed with a phosphor layer is used, and circular light emission that emits light to the surface of the phosphor layer. It has a part 42. The light emitting module 41 is attached to a polygonal substrate 43 such as an octagon, and is attached to the light source attachment surface 27 of the radiator 21 by the substrate 43. The substrate 43 is made of a metal plate such as aluminum having good thermal conductivity. The substrate 43 has a light source mounting surface portion of the radiator 21 so that the central portion of the polygonal side faces each boss 29 of the radiator 21 and a wiring path 28 having a predetermined width is provided between the substrate 43 and each boss 29. It is attached to 27.

The light emitting module 41 is held by the holder 44 and is attached to the light source mounting surface portion 27 of the radiator 21. The holder 44 has an insulating annular holder main body 45 having an opening in which the light emitting portion 42 faces and allows light to pass through, and a terminal structure arranged in the holder main body 45. The terminal structure is electrically connected to the light emitting module 41 while the holder 44 holds the light emitting module 41, and is electrically connected to the connection line A inserted from the connection hole 46 provided on the outer peripheral surface of the holder 44. The light emitting module 41 and the connection line A are electrically connected. The connection holes 46 are provided at symmetrical positions in the circumferential direction of the holder body 45, and the connection lines A are inserted and connected to the center of the holder body 45 from opposite directions. At least a part of the power line A is drawn to the lower surface side of the radiator 21 through the wiring groove 31 of the radiator 21, is wired in the wiring path 28 between the boss 29 and the board 43 and the holder 44, and is connected to the holder 44. Has been done.

The holder 44 is attached to the radiator 21 by being pressed against the radiator 21 by a plurality of mounting plates 48 fixed to the radiator 21 by a plurality of screws 47. Therefore, the light emitting module 41 is pressed against the radiator 21 via the substrate 43, and the light emitting module 41 is thermally connected to the radiator 21.

The first optical component 16 is a reflector 51 that reflects light emitted from the light emitting unit 42 in a predetermined light irradiation direction. The reflector 51 is made of metal, for example, and has a conical cylindrical reflecting surface portion 52 that expands toward the front in the light irradiation direction, and a flange-shaped first mounting portion 53 around the front end of the reflecting surface portion 52. Is provided. The inner surface of the reflective surface portion 52 is formed on a reflective surface having a high reflectance, for example, a mirror surface.

The first mounting portion 53 is provided with a mounting groove 54 and a notch groove 55 as a set at symmetrical positions in the circumferential direction. Each mounting groove 54 is provided corresponding to the position of each boss 29 of the radiator 21, and the male screw portion of the screw 56 screwed to each boss 29 can be inserted. Each notch groove 55 is provided long in a slit shape along the radial direction of the first mounting portion 53. The mounting groove 54 and the notch groove 55 are open to communicate with each other on the outer periphery of the first mounting portion 53. Further, the first mounting portion 53 is provided with a positioning hole 57 for positioning the second optical component 17 at a symmetrical position in the circumferential direction intersecting the mounting groove 54 and the notch groove 55.

The second optical component 17 is a diffuser plate 60 having both light transmittance and light diffusivity. The diffuser plate 60 is made of, for example, a resin whose material is different from that of the first optical component 16, and is formed in a disk shape. A second mounting portion 61 that overlaps the first mounting portion 53 of the reflector 51 is provided at the peripheral portion of the diffuser plate 60. The first mounting portion 53 of the reflector 51 and the second mounting portion 61 of the diffuser plate 60 are formed to have the same diameter. The second optical component 17 may be a transparent translucent plate.

The second mounting portion 61 is provided with cutout portions 62 at symmetrical positions in the circumferential direction. An engaging portion 63 is provided on one edge in the circumferential direction facing the notch 62. The engaging portion 63 is formed of a thin-walled portion that reduces the thickness of the diffusion plate 60, and an engaging groove 64 is formed on the front surface side. Further, on the back surface side of the second mounting portion 61, a positioning projection 65 to be inserted into the positioning hole 57 of the first mounting portion 53 of the reflector 51 is provided so as to project. Then, in the positioning state in which the positioning protrusion 65 is inserted into the positioning hole 57 of the first mounting portion 53 of the reflector 51, the notch portion 62 is the mounting groove 54 and the notch groove of the first mounting portion 53 of the reflector 51. It is arranged so as to communicate with 55, and the engaging portion 63 is arranged in one of the circumferential directions of the mounting groove 54 of the first mounting portion 53 of the reflector 51.

Further, for mounting the diffuser plate 60, a pressing member 68 that elastically presses the second mounting portion 61 of the diffuser plate 60 that overlaps the first mounting portion 53 of the reflector 51 against the radiator 21 is used. .. The pressing member 68 is made of an elongated metal plate, for example. The pressing member 68 is provided on one end side in the longitudinal direction and is fixed to the boss 29 of the radiator 21, and is provided on the other end side in the longitudinal direction on the front side of the second mounting portion 61 of the diffuser plate 60. It has an abutting portion 70 to be abutted, and a bent portion 71 provided between the fixing portion 69 and the abutting portion 70. The fixing portion 69 is provided with a mounting hole 72 through which the male screw portion of the screw 56 is inserted. The mounting hole 72 is open to communicate with the side portion of the fixing portion 69 intersecting in the longitudinal direction.

The fixing portion 69 of the pressing member 68 is arranged between the back surface side of the first mounting portion 53 of the reflector 51 and the boss 29 of the radiator 21, and the mounting groove 54 of the first mounting portion 53 of the reflector 51. And the male screw portion of the screw 56 that inserts the mounting hole 72 of the fixing portion 69 of the pressing member 68 is screwed to the boss 29, so that the boss 29 of the radiator 21 is integrated with the first mounting portion 53 of the reflector 51. It is fixed to. The head of the screw 56 is arranged in the notch 62 of the second mounting portion 61 of the diffuser plate 60 and does not interfere with the diffuser plate 60.

The bent portion 71 of the pressing member 68 is inserted into the notch groove 55 of the first mounting portion 53 of the reflector 51, and projects from the back side to the front side of the first mounting portion 53 of the reflector 51.

The contact portion 70 of the pressing member 68 is brought into contact with the front surface side of the second mounting portion 61 of the diffuser plate 60 superposed on the first mounting portion 53 of the reflector 51, and the second mounting portion of the diffuser plate 60 is mounted. The portion 61 is elastically pressed against the first mounting portion 53 of the reflector 51 on the radiator 21 side. The contact portion 70 of the pressing member 68 is engaged with the engaging portion 63 of the second mounting portion 61 of the diffuser plate 60, and is housed in the engaging groove 64.

The pressing member 68 is arranged so that the longitudinal direction extending from the fixing portion 69 on one end side to the abutting portion 70 on the other end side is in the circumferential direction centered on the optical axis of the light source 15. The pressing member 68 is rotatable around the screw 56 with the screw 56 loosened so that the bent portion 71 can advance and retreat into the notch groove 55 of the first mounting portion 53 of the reflector 51. The contact portion 70 can be engaged with and disengaged from the front side (engagement portion 63) of the diffuser plate 60.

The third optical component 18 is a reflector 74 that reflects the light emitted from the light emitting unit 42 in a predetermined light irradiation direction. The reflector 74 is made of metal, for example, and has a conical cylindrical reflecting surface portion 75 that expands toward the front in the light irradiation direction, and a flange portion 76 provided around the front end and the rear end of the reflecting surface portion 75. , 77. The reflecting surface portion 75 is formed so as to be continuous with the reflecting surface portion 52 of the reflector 51, and the inner surface of the reflecting surface portion 75 is formed on a reflecting surface having a high reflectance, for example, a mirror surface. The flange portion 76 on the front end side is fitted and arranged on the lower surface side of the decorative frame 22.

A reflector mounting spring 78 for attaching the reflector 74 to the decorative frame 22 is attached to the flange portion 77 on the upper end side, which is the rear end of the reflector 74. The reflector mounting spring 78 is made of metal and has an annular mounting portion 79 and a plurality of mounting piece portions 80 that elastically project from the outer periphery of the mounting portion 79. The mounting portion 79 is fixed to the first mounting portion 53 by a fixture 81 such as a rivet. The mounting piece portion 80 can be elastically engaged with and disengaged from the mounting hole 39 of the decorative frame 22, and the reflector 74 is supported by the decorative frame 22 in the engaged state.

Further, the power supply unit converts, for example, an AC power supply into a predetermined DC power supply and supplies the AC power supply to the light emitting module 41 through the connection line A.

Then, in the lighting device 10 configured in this way, by supplying power to the light emitting module 41 from the power supply unit, the light emitting module 41 is turned on and light is radiated from the light emitting unit 42. The light emitted from the light emitting unit 42 passes through the reflector 51, passes through the diffuser plate 60, passes through the reflector 74, and irradiates the illumination space. The light distribution is controlled by these reflectors 51 and 74, and the light is diffused by the diffuser plate 60 to reduce light unevenness.

The heat generated when the light emitting module 41 emits light is transferred from the light emitting module 41 to the radiator 21 through the substrate 43, and is dissipated from the radiator 21 into the air.

Further, the reflector 51 and the diffuser plate 60 are attached to the boss 29 of the radiator 21 by a screw 56 and a pressing member 68.

The male screw portion of the screw 56 is screwed to the boss 29 through the mounting groove 54 of the first mounting portion 53 of the reflector 51 and the mounting hole 72 of the fixing portion 69 of the pressing member 68, and the first of the reflector 51. The mounting portion 53 and the fixing portion 69 of the pressing member 68 are integrally tightened and fixed to the boss 29 of the radiator 21. The head of the screw 56 is arranged in the notch 62 of the second mounting portion 61 of the diffuser plate 60 and does not interfere with the diffuser plate 60.

The screw 56, the first mounting portion 53 of the reflector 51, the fixing portion 69 of the pressing member 68, and the boss 29 of the radiator 21 are all made of metal, and the difference in thermal expansion between them is small. Even if the first mounting portion 53 of 51 and the fixing portion 69 of the pressing member 68 are tightened and fixed to the boss 29 of the radiator 21, abnormal noise may be generated due to temperature changes due to lighting and extinguishing of the light emitting module 41. Is low.

Further, the contact portion 70 of the pressing member 68 is brought into contact with the front surface side of the second mounting portion 61 of the diffuser plate 60 superimposed on the first mounting portion 53 of the reflector 51, and the second mounting portion 60 of the diffuser plate 60 is contacted. The mounting portion 61 of the above is elastically pressed toward the first mounting portion 53 of the reflector 51 on the radiator 21 side.

The first mounting portion 53 of the reflector 51 and the second mounting portion 61 of the diffuser plate 60, which overlap each other, are made of different materials and have a large difference in thermal expansion, but they are not screwed together. Since it is only elastically pressed by the pressing member 68, it is unlikely that an abnormal noise will be generated due to a temperature change caused by turning on and off the light emitting module 41.

In the lighting device 10 configured in this way, the two optical components of the reflector 51 and the diffuser plate 60 can be attached to the radiator 21 by using the pressing member 68, and the size and weight can be reduced.

Moreover, since the pressing member 68 only elastically presses the second mounting portion 61 of the diffuser plate 60 that overlaps the first mounting portion 53 of the reflector 51 against the radiator 21, the light emitting module 41 is lit. It is also possible to reduce the generation of abnormal noise due to temperature changes caused by turning off the lights.

Further, since the pressing member 68 is arranged in the longitudinal direction from the fixed portion 69 on one end side to the abutting portion 70 on the other end side in the circumferential direction centered on the optical axis of the light source 15, the diffuser plate 60 It prevents interference with the light that passes through the light and enables miniaturization.

Further, since the boss 29 is projected from the position where the wiring path 28 is opened between the mounting surface 25a of the radiator 21 and the position where the light source 15 is mounted, the reflector 51 and the reflector 51 are used by using the boss 29. The diffuser plate 60 can be attached, and the wiring path 28 can be used for wiring the connection line A and can be held so as to regulate the movement of the connection line A.

Further, the substrate 43 on which the light emitting module 41 is mounted is polygonal, and the central portion of the side of the polygon faces the boss 29, so that the size can be reduced while providing the wiring path 28 having a predetermined width.

Next, FIG. 6 shows a second embodiment.

The wiring groove 31 of the radiator 21 is provided at a position deviated from the center of the radiator fin 26 of the radiator 21 in the direction along the first radiation fin 26a. With this configuration, the wiring groove 31 can be moved away from the center where the temperature of the radiator 21 is highest, the deterioration of the heat dissipation property of the radiator 21 due to the wiring groove 31 can be suppressed, and a part of the second heat dissipation fin 26b is cut off. Even if it is missing, the relatively large second heat radiating fin 26b on the center side is left as it is, and the second heat radiating fin 26b that is smaller than the center deviated from the center is cut out so that the radiator 21 by the wiring groove 31 It is possible to suppress a decrease in heat dissipation.

The mounting structure using the pressing member 68 of the first optical component 16 and the second optical component 17 of the present embodiment is not limited to the embedded lighting device, but also to other lighting devices such as spotlights. Can be applied.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

10 Lighting equipment
15 light source
16 First optical component
17 Second optical component
21 Radiator as the main body of the appliance
25a mounting surface
28 Wiring route
29 boss
53 First mounting part
61 Second mounting part
68 Pressing member

Claims (3)

With the main body of the fixture that has a light source;
With a first optical component having a first mounting portion and arranged in the optical axis direction of the light source;
It has a second mounting portion that overlaps with the first mounting portion of the first optical component, is made of a different material from the first optical component, and is in the optical axis direction of the light source than the first optical component. With the second optical component to be placed;
With a pressing member that elastically presses the second mounting portion of the second optical component against the instrument body, which overlaps the first mounting portion of the first optical component;
A lighting device characterized by comprising. One end side of the pressing member is fixed to the instrument body, the other end side is in contact with the second mounting portion of the second optical component, and the direction extending from one end side to the other end side is the optical axis of the light source. The lighting device according to claim 1, wherein the lighting device is oriented in the circumferential direction centered on the above. The instrument body is characterized by having a mounting surface on which the light source is mounted and a boss on which the pressing member is mounted so as to project from a position where a wiring path is provided between the mounting surface and the position where the light source is mounted. The lighting device according to claim 1 or 2.

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