JP6642799B2 - Lamp device - Google Patents

Description

  Embodiments of the present invention relate to a lamp device using a light guide.

  Conventionally, there is an incandescent clear light bulb using a transparent glass glove and a filament being directly visible. When the incandescent clear light bulb is turned on, strong light is emitted from the filament which is directly visible through the glass globe, so that a glittering feeling is obtained and a lighting effect is obtained.

  In addition, a lamp device in which a light emitting unit is provided on one end side of the housing, a transparent globe covering the light emitting unit is provided, and a light guide opposing the light emitting unit is protruded into the glove. is there.

  In the case of this lamp device, if the one end side of the housing or the other end side of the light guide is visible through the transparent globe, the appearance is not preferable, and if anything other than the light guide shines, it is difficult to reproduce the glittering feeling. .

JP 2014-35790 A

  The problem to be solved by the present invention is to provide a lamp device which has a good appearance and can reproduce a glittering feeling as if an incandescent clear light bulb is lit.

The lamp device according to the embodiment includes a housing, a light emitting unit, a globe, a light guide, a cover, and a power supply unit. The light emitting unit is provided on one end side of the housing. The glove is provided on one end side of the housing so as to cover the light emitting unit. The light guide has one end protruding into the glove and the other end facing the light emitting unit. The cover has a cover that covers one end of the housing and the other end of the light guide. A mirror surface is provided on the surface of the cover portion as a mirror-like reflective surface, and the reflective surface extends along a virtual line extending from the center of one end of the light guide to a peripheral portion on one end side of the housing, and a gap between the virtual line and the virtual line is 0 mm or more and 3 mm. It is provided so as to be less. The power supply unit is provided on the other end side of the housing.

  ADVANTAGE OF THE INVENTION According to this invention, it can be expected that the appearance is good and a glittering feeling as if the incandescent clear light bulb is lit is reproduced.

It is sectional drawing of the lamp apparatus which shows one Embodiment. It is a side view of a lamp apparatus same as the above. It is a perspective view of a lamp apparatus same as the above. FIG. 3 is a perspective view of a light guide and a cover of the lamp device. FIG. 3 is a perspective view of the light guide and the cover in an exploded state. 3 is a graph showing a relationship between an angle of a side surface of a light guide column of the light guide and light extraction efficiency from the light guide.

  Hereinafter, an embodiment will be described with reference to FIGS. 1 to 6.

  1 to 3 show a lamp device 10. 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 lighting, and is a relatively small mini krypton light bulb shaped lamp.

  The lamp device 10 includes a housing 11. A heat sink 12, a light emitting module 13, a light guide 14, a cover 15, and a globe 16 are provided on one end of the housing 11, and a case 17 and a power supply unit 18 are provided inside the housing 11. In addition, a power supply unit 19 is disposed on the other end side of the housing 11. Note that the lamp device 10 has a virtual central axis (ramp axis) from the globe 16 to the power supply unit 19, and the globe 16 side of the central axis is called one end side, and the power supply unit 19 side is called the other end side.

  The housing 11 is formed of a metal material. For example, the housing 11 is made of aluminum die-cast. The housing 11 is formed in a cylindrical shape in which the diameter at one end is larger than the diameter at the other end, and the diameter decreases from one end to the other end. Inside the housing 11, a hollow portion that is open at one end and the other end is formed. A mounting surface 22 on which the peripheral portion of the heat radiating plate 12 is mounted is formed on one end surface of the housing 11, and the cover 15, the light emitting module 13 and the heat radiating plate 12 are integrally fastened and fixed to the mounting surface 22 together. Screw holes 24 into which a plurality of screws 23 are screwed. An annular protruding portion 25 protrudes from the periphery of the mounting surface 22, and an annular mounting edge 26 protrudes from the inner periphery of the distal end of the protruding portion 25.

  Further, the heat radiating plate 12 is formed in a substantially disc shape with a metal material such as aluminum. The light emitting module 13 is in 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 placing surface 22 of the housing 11 and is in contact with being able to conduct heat. An insertion groove 29 through which the screw 23 is inserted is formed in a peripheral portion of the heat radiating plate 12, and a wiring groove (not shown) through which wiring for electrically connecting the light emitting module 13 and the power supply unit 18 is passed. Are formed.

  Further, the light emitting module 13 has a substrate 33 and a light emitting unit 34 provided on the surface of the substrate 33. In this embodiment, a COB (Chip On Board) module is used. The COB module includes a substrate 33, a plurality of light emitting elements (LED chips) 35 mounted on the substrate 33, a frame 36 surrounding the light emitting elements 35, and a light emitting element 35 sealed in the frame 36. Phosphor layer 37 filled as described above. Further, the surface of the phosphor layer 37 is configured as the light emitting section 34. The light emitting section 34 is formed in a square or a circle.

  The substrate 33 has a flat plate shape, and a wiring pattern for electrically connecting the plurality of light emitting elements 35 is formed on one end surface. The substrate 33 is formed of an insulating material or a metal material. When the substrate 33 is made of a metal material, an insulating film is formed on the surface of the substrate 33, and a wiring pattern is formed on the insulating film. An insertion groove 38 through which the screw 23 is inserted is formed in a peripheral portion of the substrate 33. In addition, a light emitting unit 34 is provided at the center of one end surface of the board 33, and an electric component 39 such as a connector is provided around the one end face of the board 33, for example. This electric component 39 is electrically connected to the wiring pattern.

  The light emitting unit 34 may be configured by a surface-mount type LED package or an organic EL other than the LED, for example.

  Further, as shown in FIGS. 1 to 5, the light guide 14 is formed of a rubber material such as silicone rubber which is transparent, has heat resistance, and has elasticity and flexibility.

  The light guide 14 includes a light guide column 41 having a columnar shape. One end (hereinafter, also referred to as a tip) of the light guide column 41 projects into the globe 16, the other end of the light guide column 41 is fixed to the cover 15, and the other end surface of the light guide column 41 They face each other with a gap.

  On the other end surface of the light guide column 41, an incident surface 42 on which light emitted from the light emitting unit 34 enters the light guide column 41 is formed.

  A concave portion 43 is formed on the distal end surface of the light guide column 41, and a prism 44 is formed on the surface of the concave portion 43. A light radiating portion 45 that emits light that enters from the incident surface 42 and is guided inside the light guide column 41 to the outside of the light guide column 41 is formed on the tip end side of the light guide column 41. In the light emitting portion 45, a part of the light guided in the light guide column 41 is reflected by the prism 44 and emitted from the peripheral surface of the light guide column 41, and a part of the light guided in the light guide column 41. Is transmitted through the prism 44 and emitted from the front end surface of the light guide column 41. Therefore, the light emitting portion 45 is configured on the tip side of the light guide column 41 in which the concave portion 43 and the prism 44 are provided, and from the light emitting portion 45, the side crossing the axial direction of the light guide column 41, the light guide column. Light is emitted in a wide direction including the tip direction, which is one end direction of 41, and the rearward direction from the light guide column 41 to the side of the housing 11. The light emitted from the light emitting portion 45 of the light guide column 41 reproduces a glittering feeling as if the incandescent clear light bulb were lit. Glitter is used to mean "the light looks beautiful and shimmering."

Further, the diameter d1 of the light emitting portion 45 of Shirubekohashira 41 is preferably thin in order to reproduce can Rameki feeling, such as in the range of 4~9mm is preferred. Note that the entire area of the light emitting section 45 is formed with the same diameter d1.

  The diameter d2 of the incident surface 42 of the light guide column 41 is larger than the diameter of the light emitting unit 34 in order to improve the incident light rate of the light from the light emitting unit 34 and to cope with an increase in the area of the light emitting unit 34 due to the high output. Is preferably larger than the diameter d1 of the light emitting portion 45. That is, the light guide column 41 is formed in a conical shape in which the diameter d2 at the other end is larger than the diameter d1 at the one end. The side surface of the light guide column 41 is inclined such that the angle θ with respect to the central axis (optical axis) z of the light guide column 41 is in the range of 8 ° to 22 °.

  A flange-shaped edge 46 is provided to protrude around the other end of the light guide column 41, that is, around the region of the incident surface.

  Further, the tip of the light guide column 41 projects into a central region in the globe 16 in the axial direction. The axial central region in the globe 16 includes the axial center in the globe 16 and the vicinity of the center.

  The concave portion 43 of the light guide column 41 is formed such that the depth from the tip of the light guide column 41 is the largest at the center of the concave portion 43.

  The prism 44 is formed radially outward (in the circumferential direction) from the central axis z of the light guide column 41. Specifically, the prisms 44 are formed in a triangular cross section having a ridge line 44a and valleys 44b on both sides, are arranged in a plurality along the circumferential direction of the light guide column 41, and are each radially arranged from the central axis z of the light guide column 41. It is provided in.

  The cover 15 is formed of, for example, a resin material having an insulating property and a light shielding property. The cover 15 has a conical cover (light-shielding portion) 48 whose central top protrudes toward one end, is attached to one end of the housing 11, and has one end of the housing 11, the light-emitting module 13, And the other end of the light guide 14 and the like.

  In the center of the cover 48, an insertion hole 49 through which the light guide 14 is inserted is formed, and at the other end of the center of the cover 48, the light guide 14 inserted through the insertion hole 49 is formed. A fixing portion 50 for fixing the other end is provided.

  The fixing portion 50 includes a protrusion 51 having a substantially L-shaped cross section, protruding from the edge of the insertion hole 49 of the cover portion 48 toward the other end, and the other end of the light guide column 41 provided between the inside of the protrusion 51. Has a groove 52 in which the edge 46 is fitted.

  The protrusions 51 are provided in a pair, and are disposed symmetrically with respect to the insertion hole 49 so as to face each other such that the tips 51a approach each other. An opening diameter d3, which is a distance between the distal ends 51a of the protrusions 51, is provided to be larger than the diameter d2 of the incident surface 42 of the light guide column 41 and smaller than the diameter d4 of the edge 46. The protrusion 51 may be provided over the entire circumference of the insertion hole 49.

  The groove 52 is formed on inner surfaces of the pair of protrusions 51 facing each other. The width of the groove 52 in the direction corresponding to the axial direction of the light guide column 41 is formed to be approximately the same as the thickness of the edge 46, and the opening diameter, which is the distance between the grooves 52 facing each other, is approximately the same as the diameter d4 of the edge 46. Is provided.

  The edge 46 can be fitted into the groove 52 by utilizing the elastic deformation of the light guide 14 while pushing the distal end of the light guide 41 into the insertion hole 49 from the other end of the cover 48. The light guide 14 is positioned and fixed to the cover 15 with the edge 46 fitted in the groove 52. Note that the light guide 14 and the cover 15 may be adhered to each other with an adhesive to secure the fixing.

  A plurality of mounting holes 53 into which the screws 23 are inserted are formed in the periphery of the cover 15. At the other end of the cover 15, a contact portion 54 that contacts the substrate 33 of the light emitting module 13 is formed.

  Further, a surface, which is a surface on one end side of the cover portion 48, is formed on the reflection surface 55. The reflecting surface 55 is formed in a mirror surface by, for example, vapor deposition of a metal film. When the reflection surface 55 draws an imaginary line 56 extending from the center of one end of the light guide 14, that is, the center of the concave portion 43, to the peripheral edge on one end side of the housing 11, that is, the corner on the inner peripheral side of the mounting edge 26, It is provided along the virtual line 56. In the present embodiment, the reflection surface 55 is parallel to the virtual line 56. The reflection surface 55 provided along the imaginary line 56 is not limited to being parallel to the imaginary line 56, and includes a surface having a slight inclination or curvature with respect to the imaginary line 56. The reflection surface 55 is disposed on the virtual line 56 or on the other end side of the virtual line 56. The gap s between the reflection surface 55 and the virtual line 56 is preferably 0 mm or more and 3 mm or less.

  The globe 16 is formed of a transparent material having a light transmittance of 95% or more. Resin or glass is used as the transparent material. The globe 16 is formed in a hollow hemispherical shape, and the other end is opened. On the other end of the globe 16, the glove 16 has a fitting portion 58 that is fitted inside the mounting edge portion 26 of the housing 11, and a plurality of locking hooks that are hooked on the mounting edge portion 26. Claws (not shown) are protruded. The globe 16 is fixed to the housing 11 by, for example, a silicone adhesive. The light radiating portion 45 at the tip of the light guide 14 is arranged in the central region of the globe 16 in the axial direction.

  The case 17 is formed in a cylindrical shape from a resin material having an insulating property. The case 17 is inserted into the case 11 from one end, and the case 17 is fixed to the case 11 by attaching a fixing ring 61 to the other end of the case 17 projecting from the other end of the case 11. A power supply unit 19 is attached to the other end of the case 17. A pair of substrate holding portions 62 are formed at two opposing locations in the case 17 along the central axis.

  Further, the power supply unit 18 converts the AC power input from the power supply unit 19 into a predetermined DC power and supplies the DC power to the light emitting element 35 of the light emitting module 13. The power supply unit 18 has a power supply board 65 and a plurality of electronic components (not shown) mounted on the power supply board 65. The power supply board 65 is inserted between the pair of board holding portions 62 from one end side of the case 17 and held by the case 17. The pair of input portions of the AC power supply of the power supply unit 18 are electrically connected to the power supply unit 19 by wiring, and the pair of output units of the DC power supply of the power supply unit 18 are electrically connected to the connector of the light emitting module 13 by wiring. Have been.

  The power supply unit 19 uses a base that can be connected to a socket for a general lighting incandescent lamp such as E17. Note that the power supply unit 19 is not limited to the base, and may be a pair of pins depending on the type of lamp.

  Then, the operation of the lamp device 10 of the present embodiment will be described.

  At the time of assembling the lamp device 10, the case 17 and the power supply unit 18 are incorporated in the housing 11, and the heat sink 12 and the light emitting module 13 are arranged on one end side of the housing 11, and the connector of the power supply unit 18 and the light emitting module 13 Are connected by wiring.

  Thereafter, the cover 15 to which the light guide 14 is fixed in advance is put on the light emitting module 13, and the screw 23 is inserted through the mounting hole 53 of the cover 15, the insertion groove 38 of the substrate 33 of the light emitting module 13, and the insertion groove 29 of the heat sink 12. By screwing into the screw hole 24 of the housing 11, the cover 15, the substrate 33 of the light emitting module 13 and the radiator plate 12 are fastened together and fixed to the housing 11, and the substrate 33 and the radiator plate 12 are thermally connected to the housing 11. To join.

  By fixing the cover 15 to the housing 11, the incident surface 42 of the light guide 14 fixed to the cover 15 is positioned and arranged at a predetermined position facing the light emitting unit 34. In the assembled state, there is a slight gap between the incident surface 42 of the light guide 14 and the light emitting unit 34, and the light emitting unit 34 is located in a region facing the incident surface 42 of the light guide 14. Becomes

  The lamp device 10 is used by connecting the power supply unit 19 to a socket for an incandescent light bulb for general lighting of the lighting device.

  When the AC power is supplied to the lamp device 10 through the socket, the power supply unit 18 converts the AC power into a predetermined DC power and supplies it to the light emitting element 35. As a result, the light emitting element 35 emits light, and light is emitted from the light emitting unit 34.

  The light emitted from the light emitting unit 34 enters the light guide column 41 from the incident surface 42, and is guided inside the light guide column 41 toward the light emitting unit 45. A part of the light guided to the light emitting part 45 is reflected by the prism 44 and emitted from the peripheral surface of the light guiding column 41, and a part of the light guided to the light emitting part 45 passes through the prism 44. Then, the light is radiated from the front end face of the light guide column 41. Therefore, from the light emitting portion 45 of the light guide column 41, the tip direction of the light guide column 41, the lateral direction crossing the axial direction of the light guide column 41, and the rearward direction from the light guide column 41 toward the side of the housing 11 are shown. Light is emitted in a wide direction including the direction. The light emitted from the light emitting portion 45 of the light guide column 41 passes through the globe 16 and irradiates the illumination space.

  The light reflected by the prism 44 is reflected by the light incident on the surface of the prism 44 as it is radiated from the peripheral surface of the light guide column 41 or the light incident on one surface of the prism 44 reflected by the other surface. Radiated from the circumference of 41.

  By the way, when the prism 44 is not provided on the surface of the concave portion 43 of the light guiding column 41 and the concave portion 43 is formed as an arc-shaped concave surface or a conical concave surface and an aluminum vapor deposition film is formed on the surface of the concave portion 43, the tip of the light guiding column 41 Although the part looks shiny and can reproduce a glittering feeling, the reflectance of the aluminum vapor-deposited film is about 85 to 88%, the reflection loss is large, and the efficiency of the lamp device 10 may be low.

  On the other hand, by providing the prism 44 on the surface of the concave portion 43 of the light guide column 41, light can be reflected even without the aluminum vapor deposition film, and the reflection loss by the prism 44 is smaller than the reflection loss by the aluminum vapor deposition film. And the efficiency of the lamp device 10 can be increased. Moreover, since the light guide 14 includes the plurality of prisms 44, the glitter can be reproduced regardless of the globe 16 of the lamp device 10 from any direction.

  As described above, the lamp device 10 of the present embodiment can reproduce a glittering feeling as if the incandescent clear light bulb is lit.

  When the diameter d1 of the light emitting portion 45 of the light guide column 41 is 4 to 9 mm, the light extraction efficiency is high, and the glittering feeling can be reproduced. That is, if the diameter d1 of the light guide 14 is smaller than 4 mm, the area of the incident surface 42 is correspondingly reduced, so that light from the light emitting portion 34 is hardly incident on the incident surface 42, and the light from the light emitting portion 45 If the diameter d1 of the light radiating portion 45 of the light guide column 41 is larger than 9 mm, the light radiating portion 45 becomes large and the glittering feeling is reduced.

  The diameter d2 of the other end side of the light guide column 41 is larger than the diameter d1 of the one end side, and the side surface of the light guide column 41 has an angle θ of 8 ° to 22 ° with respect to the central axis (optical axis) z of the light guide column 41. , It is possible to reproduce a bright and sparkling feeling.

  Here, the light emitting portion 34 is a square having a side of 6.2 mm, the outer diameter d1 of the light emitting portion 45 of the light guide column 41 is 7 mm, the axial length of the light guide column 41 is 7.8 mm, and the angle θ is FIG. 6 shows the measurement results of the light extraction efficiency of the light extracted from the light emitting portion 45 of the light guide column 41. As a result, high efficiency was obtained when the angle θ was in the range of 8 ° to 22 °. If the angle θ is smaller than 8 °, the area of the incident surface 42 cannot be made sufficiently large, so that the efficiency of incidence on the light guide column 41 decreases, whereby the efficiency of extracting light radiated from the light emitting unit 45 decreases. descend. When the angle θ is larger than 22 °, the angle of incidence when light guided inside the light guide column 41 is incident on the interface with the surface of the light guide column 41 becomes small, and the light is reflected at the interface. The light that is radiated from the light emitting portion 45 is reduced because the light that is radiated from the light emitting portion 45 is reduced. Decrease. Therefore, by setting the angle θ in the range of 8 ° to 22 °, the efficiency of incidence on the incident surface 42 and the efficiency of light guide are increased, and the efficiency of extracting light emitted from the light emitting section 45 is increased.

  Further, since the cover portion 48 of the cover 15 covers one end of the housing 11 and the other end of the light guide 14, even when the transparent glove 16 is used, the appearance is good, and the light emitting portion 34 and the light guide Light that leaks outside from between the body 14 is blocked, and only the light radiating portion 45 of the light guide column 41 is illuminated, so that a glittering feeling can be reproduced.

  Further, a surface which is a surface on one end side of the cover portion 48 is formed on a mirror-like reflecting surface 55. This reflection surface 55 is formed by drawing an imaginary line 56 extending from the center of one end of the light guide 14, that is, the center of the concave portion 43, to the peripheral edge on one end side of the housing 11, that is, the corner on the inner peripheral side of the mounting edge 26. , Along the virtual line 56. Therefore, of the light emitted from the light emitting portion 45 of the light guide column 41, the light directed to the reflecting surface 55 of the cover 15 is reflected by the reflecting surface 55 and enters the inside of one end side of the housing 11, and the globe It becomes difficult to emit out of the 16. Thereby, it is possible to prevent the cover 15 from appearing to be shining, to illuminate only the light emitting portion 45 of the light guide column 41, and to reproduce a glittering feeling.

  Further, the gap s between the virtual line 56 and the reflecting surface 55 is preferably 0 mm or more and 3 mm or less. If the gap s is smaller than 0 mm, that is, if the reflection surface 55 protrudes to one end side from the imaginary line 56, the light reflected by the reflection surface 55 is emitted to the outside of the globe 16, and the cover 15 shines depending on the viewing direction. I can see On the other hand, if the gap s is larger than 3 mm, light loss increases, and the size of the lamp device 10 increases.

  In addition, the cover 15 fixes the other end of the light guide 14 inserted into the insertion hole 49 with the fixing portion 50, so that the other end of the light guide 14 facing the light emitting portion 34 is positioned, and the light emitting portion is positioned. The positional relationship between 34 and the other end of the light guide 14 can be made constant. Accordingly, the efficiency of incidence from the light emitting section 34 to the light guide 14 is high, and the state can be maintained, and the light output radiated from the light emitting section 45 of the light guide 14 can be stabilized.

  Further, the edge 46 can be fitted into the groove 52 by utilizing the elastic deformation of the light guide 14 while pushing the distal end of the light guide 41 into the insertion hole 49 from the other end of the cover 48. Can be improved.

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

10 Lamp unit
11 housing
14 Light guide
15 Cover
16 gloves
19 Power supply
34 Light emitting section
48 Cover
55 Reflective surface
56 virtual lines

Claims (1)

A housing;
A light emitting unit provided on one end side of the housing;
A glove provided on one end side of the housing to cover the light emitting unit;
A light guide having one end protruding into the glove and the other end disposed opposite the light emitting unit;
The housing one end of and a cover portion covering the other end side of the light guide, provided on the reflecting surface of the mirror surface to the surface of the cover portion, and said reflective surface of one end of the light guide A cover provided along an imaginary line extending from the center to the peripheral edge on one end side of the housing so that a gap between the imaginary line is 0 mm or more and 3 mm or less ;
A power supply unit provided on the other end side of the housing;
A lamp device comprising:

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