JP2017174775A - Lighting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lighting device which can reproduce sparking as if an incandescent clear bulb lights, achieves high light extraction efficiency, and enables improvement of brightness.SOLUTION: A lamp device 10 serving as a lighting device includes: a light-emitting part 28; a light radiation cover 15; and reflection surface parts 40a, 40b. The light radiation cover 15 has a cover body 48, a light guide space 51, and a light extraction part 52. The cover body 48 is transparent and covers the light-emitting part 28. The light guide space 51 is provided at the cover body 48 in a recessed form along an optical axis direction from the light-emitting part 28 while facing the light-emitting part 28. The light extraction part 52 is provided at a tip side of the light guide space 51 and extracts light from the light guide space 51 to the cover body 48 side. The reflection surface parts 40a, 40b are provided in an area located around the light guide space 51 and closer to the light-emitting part 28 side than the light extraction part 52.SELECTED DRAWING: Figure 1

Description

  Embodiments described herein relate generally to a lighting device that emits light.

  Conventionally, there is an incandescent clear light bulb that uses a transparent glass globe and allows the filament to be seen directly. When this incandescent clear light bulb is lit, strong light is emitted from the filament that can be seen directly through the glass globe, so that a glittering feeling can be obtained and a lighting effect can be obtained.

  In addition, there is an illumination device in which a light emitting unit is disposed on one end side of a housing, a transparent cover that covers the light emitting unit is disposed, and a lens facing the light emitting unit is protruded into the cover.

  In an illuminating device using such a lens, it is difficult to reproduce the glittering feeling that an incandescent clear light bulb is lit.

  Furthermore, since the lens may be deteriorated by heat generated by the light emitting unit, it is necessary to separate the lens from the light emitting unit and provide a gap between the light emitting unit and the lens. By providing a gap between the light emitting part and the lens, the light emitted from the light emitting part leaks from the gap, the light extraction efficiency is lowered, and a desired brightness cannot be obtained.

JP 2011-142060 A

  The problem to be solved by the present invention is to provide an illuminating device that can reproduce the glittering feeling that an incandescent clear light bulb is lit, has high light extraction efficiency, and can improve brightness.

  The illuminating device of embodiment is provided with a light emission part, a light emission cover, and a reflective surface part. The light radiation cover has a cover body, a light guide space, and a light extraction portion. The cover body is transparent and covers the light emitting part. The light guide space is provided in the cover body in a concave shape along the optical axis direction from the light emitting portion while facing the light emitting portion. The light extraction unit is provided on the leading end side of the light guide space, and extracts light from the light guide space to the cover body side. The reflective surface portion is provided closer to the light emitting portion than the light extraction portion around the light guide space.

  According to the present invention, it can be expected to provide a lighting device that reproduces the glittering feeling that an incandescent clear light bulb is lit, has high light extraction efficiency, and has improved brightness.

It is sectional drawing of the lamp device which shows 1st Embodiment. It is a side view of a lamp device same as the above. It is a disassembled perspective view of a lamp device same as the above. It is a perspective view of a cover same as the above. It is sectional drawing of the lamp device which shows 2nd Embodiment.

  Hereinafter, a first embodiment will be described with reference to FIGS. 1 to 4.

  1 to 4 show a lamp device 10 as a lighting device. The lamp device 10 is a light bulb shaped lamp that can be used by being mounted on a socket for an incandescent light bulb for general illumination, and is a relatively small mini-krypton light bulb shaped lamp.

  The lamp device 10 includes a housing 11. On one end side of the housing 11, a heat radiating plate 12, a light emitting module 13, an insulating cover 14, and a light emitting cover 15 are disposed, and a case 16 and a power supply unit 17 are disposed inside the housing 11. In addition, a power feeding unit 18 is disposed on the other end side of the housing 11. The lamp device 10 has an imaginary central axis (lamp axis) extending from the light radiation cover 15 to the power supply unit 18, and the light radiation cover 15 side of the central axis is one end side, and the power supply unit 18 side is the other end. The side.

  The housing 11 is made of, for example, a metal material. For example, the housing 11 is made of aluminum die casting. The casing 11 is formed in a cylindrical shape having a diameter on one end side larger than a diameter on the other end side and a diameter decreasing from the one end side toward the other end side. Inside the housing 11, a hollow portion that opens to one end and the other end is formed. A mounting surface 22 on which the periphery of the heat sink 12 is placed is formed on one end surface of the housing 11, and the insulating cover 14, the light emitting module 13 and the heat sink 12 are integrally fastened to the mounting surface 22. A plurality of fixing screws to be fixed are screwed. An annular mounting edge 23 for mounting the light radiation cover 15 is provided around the mounting surface 22.

  Further, as shown in FIGS. 1 to 3, the heat radiating plate 12 is formed in a substantially disc shape by a metal material such as aluminum. The light emitting module 13 is brought into contact with one end surface of the heat radiating plate 12 so as to be able to conduct heat, and the peripheral portion of the other end surface of the heat radiating plate 12 is placed on the placement surface 22 of the housing 11 so as to be able to conduct heat. An insertion groove through which the fixing screw is inserted is formed in the periphery of the heat sink 12, and a wiring groove through which wiring for electrically connecting the light emitting module 13 and the power supply unit 17 is formed. .

  The light emitting module 13 includes a substrate 27 and a light emitting unit 28 provided on the surface of the substrate 27. In this embodiment, a COB (Chip On Board) module is used. The light emitting module 13 includes a substrate 27, a plurality of light emitting elements (LED chips) 29 mounted on the substrate 27, a frame portion 30 surrounding the light emitting elements 29, and the light emitting elements 29 sealed in the frame portion 30 A phosphor layer 31 filled in such a manner is provided. The fluorescent element 29 and the phosphor layer 31 are configured as the light emitting unit 28. The surface of the light emitting section 28 is circular in appearance.

  The substrate 27 has a flat plate shape, and a wiring pattern for electrically connecting the plurality of light emitting elements 29 is formed on one end surface. The substrate 27 is made of an insulating material or a metal material. When the substrate 27 is made of a metal material, an insulating film is formed on the surface of the substrate 27, and a wiring pattern is formed on the insulating film. In addition, a light emitting unit 28 is disposed at the center of one end surface of the substrate 27, and an electrical component 32 such as a connector or a capacitor is mounted on the periphery of the one end surface of the substrate 27. These electrical components 32 are also electrically connected to the wiring pattern.

  The light emitting unit 28 may be formed of a surface mount type LED package or an organic EL other than the LED.

  The insulating cover 14 is made of a resin material having insulating properties, light impermeability or light diffusing property, and heat resistance. The insulating cover 14 is attached to one end side of the housing 11 and covers the one end side of the housing 11 and the substrate 27 of the light emitting module 13 and the like.

  The insulating cover 14 has a conical cover part 36 whose central side protrudes to one end side. A cylindrical tube portion 37 protruding to the other end side is formed at the center of the cover portion 36, and a circular opening 38 facing the light emitting portion 28 is formed inside the tube portion 37.

  On the inner peripheral surface of the cylindrical portion 37, an inclined surface 39 is formed which expands from the other end side toward the one end side. The inclined surface 39 is formed with a reflecting surface portion 40a that reflects light from the light emitting portion 28 toward the optical axis direction. The reflection surface portion 40a is formed on a surface having a high light reflectance such as a mirror surface or a surface on which a metal film is deposited. Therefore, the insulating cover 14 is also used as the reflector 41 that reflects the light from the light emitting unit 28.

  A plurality of insertion holes 42 through which a plurality of fixing screws are respectively inserted are formed in the peripheral portion of the insulating cover 14.

  On the other end side of the insulating cover 14, a pressing portion 43 is formed which is fitted to the substrate 27 of the light emitting module 13 and pressed to the housing 11 side. Between the surface on the other end side of the insulating cover 14 and the substrate 27, an accommodation space 44 for accommodating the electrical component 32 is formed.

  The light radiation cover 15 includes a cover body 48 formed of a transparent material having a light transmittance of 95% or more, for example. As the transparent material of the cover body 48, resin or glass is used. The cover body 48 may contain a minute amount of a diffusible substance such as a pearl material within a range in which the transparency of the light radiation cover 15 is ensured.

  On the surface of the cover main body 48, a surface portion 49 formed in a hemispherical shape so as to be continuous with one end side of the housing 11 is formed.

  On the surface on the other end side of the cover main body 48, a concave portion 50 is formed along the optical axis direction from the light emitting portion 28 while facing the light emitting portion 28, and a light guide space 51 is formed by the concave portion 50. That is, the cover main body 48 is formed with a concave light guide space 51 that faces the light emitting portion 28 and extends in the optical axis direction from the light emitting portion 28. Light from the light emitting unit 28 enters the light guide space 51.

  The light guide space 51 (recess 50) is formed in a conical shape whose diameter decreases from the other end side toward the one end side.

  A light extraction portion 52 is formed on the front end side (one end side) of the light guide space 51 (recess 50) so that the light guided to the light guide space 51 enters the cover body 48 and is extracted. The light extraction part 52 is located in a substantially central area of the cover main body 48. The light extraction part 52 has a diffusion surface 53 formed on the inner wall surface of the light guide space 51 (recess 50). The diffusion surface 53 includes continuous fine irregularities, discontinuous irregularities, or fine continuous lenses. The light from the light emitting portion 28 guided to the light guide space 51 is made incident on the cover body 48 by the diffusion surface 53.

  An inclined surface 54 that is inclined from the other end side of the light guide space 51 (recess 50) to the periphery of the other end side of the cover body 48 is formed on the surface on the other end side of the cover body 48. The inclined surface 54 is opposed to the surface of the cover portion 36 of the insulating cover 14.

  On the other end side of the cover main body 48, a fixing portion (not shown) is provided so as to be fitted inside the mounting edge portion 23 of the housing 11 and bonded and fixed with, for example, a silicone adhesive.

  A reflection surface portion 40a of the insulating cover 14 (reflector 41) is disposed around the light guide space 51 and closer to the light emitting portion 28 than the light extraction portion 52. The reflection surface portion 40a reflects the light incident from the light emitting portion 28 toward the light extraction portion 52 of the light guide space 51, and increases the light extracted from the light extraction portion 52 and intersects the light axis from the light emission portion 28 in the optical axis direction. To block the light going to the side.

  Further, the reflection surface portion 40b may be provided on the inner wall surface and the inclined surface 53 of the light guide space 51 (recess 50) on the light emitting portion 28 side with respect to the light extraction portion 52. The reflecting surface portion 40b is a surface having a high light reflectance such as a mirror surface or a surface on which a metal film is deposited. The reflection surface portion 40b reflects the light incident from the light emitting portion 28 toward the light extraction portion 52 of the light guide space 51, increases the light extracted from the light extraction portion 52, and radiates outside from the light extraction portion 52 to the outside. Reduce the light emitted.

  The case 16 is formed in a cylindrical shape from a resin material having an insulating property. The case 16 is inserted into the housing 11 from one end side, and the fixing ring 57 is attached to the other end side of the case 16 protruding from the other end side of the housing 11, whereby the case 16 is fixed to the housing 11. A power feeding unit 18 is attached to the other end side of the case 16.

  Further, the power supply unit 17 converts the AC power input from the power supply unit 18 into a predetermined DC power supply and supplies it to the light emitting module 13. The power supply unit 17 includes a power supply board 61 and a plurality of power supply components mounted on the power supply board 61. The power supply substrate 61 is inserted from one end side of the case 16 and is held in the case 16. The pair of input parts of the AC power source of the power source unit 17 is electrically connected to the power feeding unit 18 by wiring, and the pair of output parts of the DC power source of the power source unit 17 is electrically connected to the connector of the light emitting module 13 by wiring. Has been.

  The power supply unit 18 uses a base that can be connected to a socket for a general illumination incandescent bulb such as E17. The power supply unit 18 is not limited to the base, and may be a pair of pins depending on the lamp type.

  The operation of the lamp device 10 according to the first embodiment will be described.

  The lamp device 10 is used by connecting the power feeding portion 18 to a socket for an incandescent light bulb for general illumination of the lighting device.

  When AC power is supplied to the lamp device 10 through the socket, the power supply unit 17 converts the AC power into a predetermined DC power and supplies it to the light emitting module 13. Thereby, light is emitted from the light emitting unit 28 of the light emitting module 13.

  The light emitted from the light emitting unit 28 mainly travels in the optical axis direction, passes through the opening 38 of the insulating cover 14, travels to the light guide space 51 of the light radiation cover 15, and takes out light at the tip of the light guide space 51. It enters the part 52. The light incident on the light extraction part 52 is diffused by the diffusion surface 53, enters the cover body 48, and is emitted from the surface part 49 of the cover body 48 to the illumination space. The light extraction unit 52 serves as a point light source, and intense light is radiated in a wide range from the light extraction unit 52 serving as the point light source.

  Therefore, since the light from the light emitting unit 28 is directly incident on the light extraction unit 52 and is emitted from the surface of the light emission cover 15, the light extraction unit 52 that becomes a point light source with less light loss and improved light extraction efficiency. Strong light is emitted from Therefore, it is easy to obtain a sparkle when looking at the lamp device 10.

  Further, the light guide 28 intersects the optical axis direction from the light emitting portion 28 by the reflecting surface portion 40a of the insulating cover 14 (reflector 41) disposed on the light emitting portion 28 side of the light extraction portion 52 around the light guide space 51. Light directed toward the side is reflected toward the light extraction portion 52 of the light guide space 51 to increase the light extracted from the light extraction portion 52, and toward the side intersecting the optical axis direction from the light emitting portion 28. Block out light.

  Furthermore, when the reflecting surface portion 40b is provided on the light emitting portion 28 side of the light extraction portion 52 on the inner wall surface and the inclined surface 53 of the light guide space 51 (recess 50), the reflecting surface portion 40b allows the light emitting portion 28 or The light that travels laterally from the reflecting surface portion 40a to the direction intersecting the optical axis direction is reflected toward the light extraction portion 52, and the light extracted from the light extraction portion 52 is increased and emitted from other than the light extraction portion 52 to the outside. Reduce the light emitted.

  Therefore, the reflection surface portion 40a, and further the reflection surface portion 40b, reflects light toward the side intersecting the optical axis direction toward the light extraction portion 52, so that light loss is small and light extraction efficiency is improved. Strong light is radiated from the light extraction unit 52 serving as a point light source, and light emitted outside from the light extraction unit 52 is reduced. Therefore, strong light is likely to be emitted only from the light extraction unit 52 serving as a point light source, and a glittering feeling when the lamp device 10 is viewed is more easily obtained.

  As described above, in the lamp device 10 of the present embodiment, it is possible to reproduce the glittering feeling as if the incandescent clear light bulb is lit, and the light extraction efficiency is high, thereby improving the brightness.

  In addition, since the light radiation cover 15 is separated from the light emitting unit 28, deterioration of the light radiation cover 15 due to heat of the light emitting unit 28 can be reduced.

  The shape of the surface portion 49 of the light emitting cover 15 is not limited to a spherical shape, and may be a candle shape that is pointed in the tip direction, or other shapes, for example. Regardless of the shape, the light extraction unit 52 serving as a point light source shines, and a glittering feeling can be reproduced.

  In addition, a cylindrical reflector having a reflective surface portion may be disposed around the light guide space 51 and closer to the light emitting portion 28 than the light extraction portion 52. That is, a cylindrical reflector having a reflective surface portion may be disposed between the light extraction portion 52 and the light emitting portion 28. In this case, since the portion of the light radiation cover 15 can be hollow on the outer peripheral side of the reflector, the amount of material used for the light radiation cover 15 can be reduced, and the lamp device 10 can be reduced in weight.

  Next, FIG. 5 shows a second embodiment. In addition, about the same structure as 1st Embodiment, description of the structure and effect is abbreviate | omitted using the same code | symbol.

  The lamp device 10 of the second embodiment is different from the first embodiment in the shape of the light radiation cover 15.

  A conical recess 70 is formed at the top of the surface 49 of the light emitting cover 15, a surface 71 is formed on the inner surface of the recess 70, and a plurality of surfaces 72 and 73 are formed around the periphery. ing. Therefore, the surface portion 49 of the light radiation cover 15 is formed of a polyhedron.

  A conical protrusion 74 projects from the light extraction portion 52 on the distal end side of the light guide space 51 so as to face the light emitting portion 28. A plurality of surfaces 75 are formed on the peripheral surface of the protrusion 74, and the protrusion 74 is formed of a polyhedron.

  When the lamp device 10 is turned on, light emitted from the light emitting unit 28 in the optical axis direction is incident on the light extraction unit 52, and part of the light is incident on the plurality of surfaces 75 of the protrusion 74. Light incident on the plurality of surfaces 75 of the protrusion 74 travels in the cover main body 48 in a direction corresponding to each surface 75 and is emitted from the plurality of surfaces 71 to 73 of the surface portion 49 of the cover main body 48 to the illumination space. Further, a part of the light incident on the cover main body 48 is emitted after being repeatedly reflected in the cover main body 48.

  Light emitted from the plurality of surfaces 71 to 73 of the surface portion 49 of the cover main body 48 is emitted over a wide range and is also emitted in the direction of the power feeding unit 18.

  In this way, by configuring the light radiation cover 15 with a polyhedron, it is possible to reproduce the glittering feeling and obtain a wide light distribution.

  The lighting device is not limited to the lamp device 10, and may be, for example, a lantern or a flashlight, and may be a pendant or a downlight.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

10 Lamp device as lighting device
15 Light radiation cover
28 Light emitter
40a, 40b Reflective surface
41 Reflector
48 Cover body
51 Light guide space
52 Light extraction part

Claims (3)

A light emitting part;
A transparent cover main body that covers the light emitting section, a light guide space that faces the light emitting section and that is concavely provided in the cover main body along the optical axis direction from the light emitting section, and a distal end side of the light guide space A light emitting cover having a light extraction portion that is provided and extracts light from the light guide space to the cover body side;
A reflective surface provided around the light guide space of the cover and closer to the light emitting part than the light extraction part;
An illumination device comprising: The lighting device according to claim 1, wherein the reflection surface portion is provided on an inner wall surface of the light guide space. The lighting device according to claim 1, further comprising a reflector having the reflection surface portion provided on an inner peripheral surface.

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