JP2017084446A - Illuminating device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an illuminating device that improves light extraction efficiency while securing dielectric strength voltage between a light source and a reflecting mirror.SOLUTION: An illuminating device 10 comprises a light source 15, a cylindrical reflecting mirror 18, and a light guide pole 20. The reflecting mirror 18 comprises an incident opening 30 on which light from the light source 15 is incident, on one side. The reflecting mirror 18 comprises an emitting opening 31 from which light is emitted, on another side. The reflecting mirror 18 is arranged via a gap 19 between the one side and the light source 15. The light guide pole 20 has an insulating property, and is at least partially interposed in the gap 19 between the light source 15 and the one side of the reflecting mirror 18. The light guide pole 20 guides light from the light source 15 to the incident opening 30 of the reflecting mirror 18.SELECTED DRAWING: Figure 1

Description

  Embodiments of the present invention relate to an illuminating device including a condenser disposed through a gap between one end side including an entrance opening and a light source.

  Conventionally, for example, there is a spotlight as a lighting device for production in a stage or a television studio. In recent years, such spotlights have been replaced with LED (Light Emitting Diode) lamps as light sources instead of conventional halogen lamps from the viewpoint of energy saving and life.

  The spotlight is provided with a condensing member such as a reflecting mirror in the vicinity of a light source such as a COB (Chip On Board) module. At this time, it is necessary to provide an insulating space of about 3 to 4 mm between the conductive portion of the light source and the reflecting mirror in order to ensure the withstand voltage. In this case, it is desired that light from the light source does not leak to the outside of the reflecting mirror through the insulating space and the light extraction efficiency is not lowered.

Japanese Patent Application Laid-Open No. 2015-95337

  Problem to be solved by the invention is providing the illuminating device which improved the light extraction efficiency, ensuring the insulation proof pressure between a light source and a collector.

  The illuminating device of embodiment has a light source, a cylindrical collector, and a light guide part. The concentrator includes an incident aperture through which light from the light source is incident on one end side. The concentrator also includes an exit opening through which light exits on the other end side. And a concentrator is arrange | positioned through a clearance gap between one end side and a light source. The light guide has an insulating property, and at least a part of the light guide is interposed in the gap between the light source and the one end side of the light collector. And a light guide part guides the light from a light source to the entrance opening of a collector.

  According to the present invention, the insulating light guide having at least a part interposed in the gap between the light source and the one end side of the collector, while ensuring the withstand voltage, the one end side of the light source and the collector It can be expected that the light extraction efficiency is improved by suppressing light leakage from the gap between the two.

It is sectional drawing of the illuminating device which shows 1st Embodiment. It is a perspective view which shows the light source and light guide part of an illuminating device same as the above. It is sectional drawing of the illuminating device which shows 2nd Embodiment. It is a perspective view which shows the light source and light guide part of an illuminating device same as the above. It is sectional drawing of the illuminating device which shows 3rd Embodiment. It is a perspective view which shows the light source and light guide part of an illuminating device same as the above.

  Hereinafter, a first embodiment will be described with reference to FIGS. 1 and 2.

  FIG. 1 shows a configuration of a spotlight used as a lighting device 10 in, for example, a studio or a stage. In the illumination device 10, a light source unit 12 is disposed in a cylindrical housing (not shown) with the optical axis z as the center. In addition, a lens may be disposed in front of the light source unit 12 in the housing, or an adjustment mechanism that adjusts the irradiation angle by moving the lens in the optical axis direction may be disposed.

  The casing is made of, for example, metal, and an opening for projecting light having a predetermined irradiation angle emitted from the light source unit 12 and collected by the lens is formed on the front surface. The light source unit 12 may be disposed at the rear of the housing, and vents may be formed on the upper surface, the lower surface, the back surface, and both side surfaces of the rear portion. Each vent may be covered with a net having air permeability.

  The light source unit 12 includes a light source 15, a heat spreader 16 and a radiator 17 disposed on the rear side of the light source 15, a reflector 18 that is a condenser disposed between the light source 15 and the lens, and a reflection with the light source 15. A light guide column 20 as a light guide unit disposed in a gap 19 between the mirror 18 and the like is provided. In the light source unit 12, a light shielding plate may be disposed on the front side of the radiator 17, or a light diffusing unit may be disposed between the reflecting mirror 18 and the lens.

  The light source 15 includes, for example, a flat substrate 22 and a plurality of light emitting elements 23 mounted on the front surface of the substrate 22, and a planar light emitting surface 24 that emits light is formed. For example, in the light source 15, a plurality of LED elements as the light emitting elements 23 are mounted on the front surface of the flat substrate 22, and the plurality of LED elements are integrally covered with a transparent sealing resin 25 containing a phosphor. It is composed of COB (Chip On Board) modules. The periphery of the sealing resin 25 is surrounded by, for example, an annular bank (bank) 26 protruding from the front surface of the substrate 22. The light emitting surface 24 is constituted by the front surface of the sealing resin 25 surrounded by the bank portion 26, and is formed in a circular outer shape. A blue LED element that emits blue light is used as the LED element, and a yellow phosphor that emits yellow light when excited by blue light is used as the phosphor. As the phosphor, an orange light emitter that emits orange light in addition to yellow light may be used.

  The heat spreader 16 diffuses heat generated from the light source 15 (light emitting element 23), and is formed of a metal material such as aluminum, for example, and is formed in a flat plate shape that attaches the substrate 22 of the light source 15 so that heat conduction is possible. Yes.

  The radiator 17 is provided with a base 27 made of metal such as copper for attaching the heat spreader 16 so as to be able to conduct heat, and a flat plate formed of a metal material such as aluminum disposed on the rear side of the base 27. A plurality of heat radiation fins 28 are provided. Note that the charging part of the light source 15 and the radiator 17 side are electrically insulated.

  The plurality of radiating fins 28 are arranged in parallel in a state where they are erected in the vertical direction and spaced apart from each other in the horizontal direction (left and right direction as viewed from the optical axis z side). For example, one end of a plurality of heat pipes (not shown) is attached to the base 27 along the horizontal direction, and the other end of each heat pipe passes through the side of the radiator 17 and penetrates the plurality of radiating fins 28. In addition, the plurality of heat radiation fins 28 are connected to be able to conduct heat.

  The radiator 17 is attached to the housing. Corresponding to the top, bottom, and back of the heatsink 17 are the vents on the top, bottom, and back of the housing, and it corresponds to the parts of multiple heat pipes that pass through both sides of the heatsink 17. In addition, vents on both sides of the housing are arranged, good air permeability to the radiator 17 is obtained, and high heat dissipation performance is ensured.

  The reflecting mirror 18 is made of, for example, metal, is formed in a cylindrical shape centered on the optical axis z, and is opened in the optical axis direction. That is, the reflecting mirror 18 has a cylindrical shape, and a circular incident opening 30 into which light emitted from the light emitting surface 24 is incident is formed on the rear side which is one end side, and light which is incident on the front side which is the other end side is formed. A circular exit opening 31 that exits toward the lens is formed. Further, on the inner surface of the reflecting mirror 18, a reflecting surface 33 having a hyperbolic rotationally symmetric shape about the optical axis z is formed. Further, a flange portion 35 is formed around the front side of the reflecting mirror 18. The reflecting mirror 18 radiates heat so that a gap 19 is formed between the incident opening 30 side, which is one end side, and the light source 15 (light emitting surface 24) by, for example, mounting means (not shown) using the flange portion 35. It is attached to the vessel 17.

  Here, the gap 19 between the reflecting mirror 18 and the light source 15 (light emitting surface 24) is supplied with, for example, the reflecting mirror 18 which is supported by a metal member on the ground potential radiator 17 and becomes the ground potential and the lighting power is supplied. In order to ensure a predetermined spatial insulation distance between the light emitting surface 24 of the light source 15 having a charged part or to reflect the voltage pole side and 0V pole side of a predetermined DC power source supplied to the light source 15 This is necessary to secure a predetermined space insulation distance so as not to be short-circuited by 18.

  In the present embodiment, the reflecting mirror 18 has a larger inner diameter of the emission opening 31 than an inner diameter of the incident opening 30, and an outer diameter of the light emitting surface 24 larger than the inner diameter of the incident opening 30. The outer shape of the light emitting surface 24 is larger than that of the incident aperture 30 when viewed from the exit aperture 31 side (optical axis direction). As a result, a region where the non-light emitting portion is reflected on the reflecting surface 33 through the gap 19 is not generated, and when this region is viewed from the optical axis direction, it appears as a shadow in the virtual image and a striped pattern does not occur. It is possible to prevent luminance unevenness from occurring.

  The light shielding plate prevents light that does not enter the lens from coming out of the reflecting mirror 18 from leaking from the vent of the housing that houses the radiator 17.

  The light diffusing means is formed larger than the exit opening 31 of the reflecting mirror 18, and the light emitted from the exit opening 31 enters, diffuses and transmits. For the light diffusing means, for example, a diffusing plate, a fly-eye lens or the like is used. In addition, although it is preferable to use a light-diffusion means, it is not essential.

  The lens receives the light emitted from the reflecting mirror 18, collects the light, and projects the light forward from the opening of the housing. As the lens, a Fresnel lens is used in this embodiment, but a convex lens or the like may be used. When the light diffusing means is used, the light emitted from the reflecting mirror 18 and transmitted through the light diffusing means enters the lens.

  The light guide column 20 secures a dielectric strength between the light source 15 and the reflecting mirror 18 and guides the light emitted from the light source 15 (light emitting element 23) to the incident opening 30 of the reflecting mirror 18 to make it incident. . The light guide column 20 is formed of a member such as an insulating and translucent synthetic resin or glass. The light guide column 20 is formed in, for example, a cylindrical shape (FIG. 2), and has an outer diameter larger than the opening diameter of the incident aperture 30 of the reflecting mirror 18 and one end portion (rear end portion) of the reflecting mirror 18. It is almost the same as the outer diameter. The light guide column 20 is flat, that is, has a cylindrical shape whose thickness (axial dimension) is smaller than the diameter dimension, and one end side (rear end side) is a flat incident surface 40 and the other end side (front end side) ) Is a flat emission surface 41. The light guide column 20 has an incident surface 40 in close contact with the light source 15 (light emitting surface 24) so as to fill a gap 19 between the light source 15 (light emitting surface 24) and the reflecting mirror 18, and is attached to one end of the reflecting mirror 18. Thus, the emission surface 41 is arranged in close contact. The light emitting surface 24 and the incident surface 40 may not necessarily be in close contact with each other as long as the incident loss is small. For example, a slight gap may be generated between the light emitting surface 24 and the incident surface 40 when the incident surface 40 is in contact with the bank portion 26. Further, a reflective layer 43 is provided on the outer peripheral surface which is the side surface of the light guide column 20. The reflection layer 43 is formed by, for example, applying a highly reflective material such as a white synthetic resin to the outer peripheral surface of the light guide column 20, and the light incident on the light guide column 20 is incident on the side of the light guide column 20. It is configured not to leak, that is, to reflect light completely or substantially completely.

  When the lighting device 10 is turned on, when the light source 15 (light emitting element 23) is turned on, the light from the light emitting element 23 and the light from the phosphor contained in the sealing resin 25 excited by this light are mixed. The light is emitted from the light emitting surface 24. Since the incident surface 40 of the light guide column 20 is in close contact with the light emitting surface 24, almost all light from the light emitting surface 24 enters the light guide column 20. Of the light incident on the light guide column 20, the light directed toward the outer peripheral surface of the light guide column 20 is reflected by the reflective layer 43, so that almost all of the light incident on the light guide column 20 is emitted from the emission surface 41. The light enters the reflecting mirror 18 from the entrance opening 30 of the reflecting mirror 18 facing the exit surface 41 and is reflected directly or by the reflecting surface 33 and exits from the exit opening 31.

  Therefore, the insulating light guide column 20 having at least a part interposed in the gap 19 between the light source 15 and the one end side of the reflecting mirror 18, while ensuring the withstand voltage as compared with the case where only the gap 19 is provided, the light source Light leakage from the gap 19 between 15 and one end side of the reflecting mirror 18 can be suppressed, and the light extraction efficiency can be improved. For example, in a conventional lighting device in which an insulating space of about 3 to 4 mm is provided between the light source 15 and the reflecting mirror 18, 30 to 35% of light leaks and becomes a loss due to the insulating space. The optical column 20 can reduce the loss as much as possible.

  In particular, in the present embodiment, the outer diameter of the light emitting surface 24 of the light source 15 is made larger than the inner diameter of the incident aperture 30 of the reflecting mirror 18 in order to suppress uneven brightness, thereby increasing leakage light from the gap 19. Therefore, by guiding the light from the light source 15 to the incident opening 30 of the reflecting mirror 18 by the light guide column 20, the leakage light from the gap 19 can be more effectively suppressed.

  The heat generated by the light source 15 is diffused by the heat spreader 16 and further transmitted from the base 27 of the radiator 17 to the plurality of radiation fins 28 via the plurality of heat pipes. The radiator 17 is arranged in the housing, and the vents on the upper surface, the lower surface, and the rear surface of the housing are arranged corresponding to the upper surface, the lower surface, and the rear surface of the radiator 17, and both sides of the radiator 17 are disposed. Corresponding to the portions of the plurality of heat pipes that pass through the portion, the vents on both sides of the housing are arranged, good air permeability to the heat radiating fins 28 of the radiator 17 is obtained, and high heat radiating performance is obtained.

  Next, a second embodiment will be described with reference to FIGS. In addition, about the structure and effect | action similar to the said 1st Embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted.

  In the second embodiment shown in FIG. 3 and FIG. 4, the light guide column 20 of the first embodiment is divided into a support part 45 and an insertion part 46.

  The support portion 45 is a portion that supports one end side of the reflecting mirror 18. The support portion 45 is formed in, for example, a cylindrical shape, and has an outer diameter larger than the opening diameter of the incident opening 30 of the reflecting mirror 18 and the outer diameter of one end portion (rear end portion) of the reflecting mirror 18. . The support portion 45 is flat, that is, has a cylindrical shape with a thickness (axial dimension) smaller than the diameter dimension, and one end side (rear end side) is a flat incident surface 48 and the other end side (front end side). ) Is a flat support surface 49. In addition, the support portion 45 has an incident surface 48 in close contact with the light source 15 (light emitting surface 24) so as to fill a gap 19 between the light source 15 (light emitting surface 24) and the reflecting mirror 18, and is attached to one end of the reflecting mirror 18. Thus, the support surface 49 is disposed in close contact. Further, a holding portion 50 for holding at least a part of the outer peripheral surface of one end portion of the reflecting mirror 18 is projected from the outer edge portion of the support surface 49 of the support portion 45. A reflective layer 43 is provided on the outer peripheral surface which is the side surface of the support portion 45.

  The holding part 50 is inclined so that the inner side facing the outer peripheral surface of one end of the reflecting mirror 18 gradually expands along the outer peripheral surface of the reflecting mirror 18 toward the front. For this reason, the holding part 50 is provided so that the thickness gradually decreases from the rear side to the front side.

  On the other hand, the insertion portion 46 is a portion inserted into the reflecting mirror 18. The insertion portion 46 is formed in a cylindrical shape, and the outer shape, that is, the outer peripheral surface 51 is formed in a hyperbolic rotationally symmetric shape around the optical axis z, and the outer peripheral surface 51 is in close contact with the reflecting surface 33 without a substantial gap. . The insertion portion 46 has a flat supported surface 52 whose one end side (rear end side) is in close contact with the support surface 49 of the support portion 45, and the other end side (front end side) that emits light. 53. The outer peripheral surface 51 of the insertion portion 46 is arranged at an interval on the optical axis z side with respect to the holding portion 50 of the support portion 45, and one end portion of the reflecting mirror 18 is interposed between the holding portion 50 and the holding portion 50. A holding groove 54 to be fitted and held is formed.

  When the lighting device 10 is assembled, the insertion portion 46 is inserted into the reflecting mirror 18 from the exit opening 31 of the reflecting mirror 18, and the supported surface 52 is substantially flush with the incident opening 30 of the reflecting mirror 18. In this state, the outer peripheral surface 51 of the insertion portion 46 is in close contact with the reflecting surface 33 on one end side of the reflecting mirror 18. Then, the reflecting mirror 18 in which the insertion portion 46 is inserted is overlaid on the support surface 49 of the support portion 45 in which the incident surface 48 is in close contact with the light emitting surface 24 of the light source 15, and the supported surface 52 and support portion of the insertion portion 46 The light guide column 20 is formed by the insertion portion 46 and the support portion 45 by bonding the support surface 49 of the 45. In this state, one end of the reflecting mirror 18 is fitted in the holding groove 54 and held by the light guide column 20.

  When the lighting device 10 is turned on, when the light source 15 (light emitting element 23) is turned on and emitted from the light emitting surface 24, substantially all light enters the light guide column 20 from the incident surface 48 that is in close contact with the light emitting surface 24. Of the light incident on the light guide column 20, the light directed toward the outer peripheral surface of the light guide column 20 (supporting portion 45) is reflected by the reflective layer 43, and substantially all enters the insertion portion 46 from the incident opening 30 of the reflecting mirror 18. Then, the light is emitted from the emission surface 53 and the outer peripheral surface 51 of the insertion portion 46 and is reflected from the reflection surface 33 directly or emitted from the emission opening 31.

  As described above, the light guide column 20 has the insertion portion 46 provided with the outer peripheral surface 51 along the reflection surface 33 which is the inner surface of the reflection mirror 18 attached to the inside of the reflection mirror 18, so that light leakage from the gap 19 is suppressed. Thus, the light incident on the light guide column 20 from the light source 15 can be more efficiently incident on the incident aperture 30 of the reflecting mirror 18, and can be more efficiently guided to the reflecting surface 33 of the reflecting mirror 18. Can be optically controlled.

  Further, the light guide column 20 is divided into a support portion 45 that supports one end side of the reflecting mirror 18 and an insertion portion 46 that is attached to the inside of the reflecting mirror 18, and the support portion 45 and the insertion portion 46 are fixed integrally. Thus, the holding structure (holding groove 54) that holds one end of the reflecting mirror 18 can be easily configured between the support portion 45 and the insertion portion 46. In addition, a protruding portion is formed by protruding a part of the insertion portion 46 from the incident opening 30 of the reflecting mirror 18, and a concave portion that accommodates the protruding portion is formed in the support portion 45, and the protruding portion and the concave portion are formed. May be engaged.

  Next, a third embodiment will be described with reference to FIGS. In addition, about the structure and effect | action similar to said each embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted.

  In the third embodiment, a light guide portion 56 is integrally formed in the sealing resin 25 of the light source 15 instead of the light guide column 20 of each of the above embodiments.

  The sealing resin 25 is integrally formed of an insulating synthetic resin, and includes a sealing portion 57 positioned in the bank portion 26, an insulating portion 58 protruding forward from the bank portion 26, and a front side from the insulating portion 58. And a lens-shaped lens part 59 that is inserted into the entrance opening 30 of the reflecting mirror 18.

  The insulating part 58 is a part that ensures a dielectric strength voltage between the light source 15 and the reflecting mirror 18. The insulating portion 58 is formed, for example, in a cylindrical shape, and has an outer diameter larger than the opening diameter of the incident opening 30 of the reflecting mirror 18 and the outer diameter of one end portion (rear end portion) of the reflecting mirror 18. The insulating portion 58 is flat, that is, has a cylindrical shape whose thickness (axial dimension) is smaller than the diameter dimension, and the front end side is a flat support surface 61. Further, a holding portion 63 for holding the outer peripheral surface of one end portion of the reflecting mirror 18 is projected from the outer edge portion of the support surface 61 of the insulating portion 58. The insulating portion 58 is disposed so that the support surface 61 is in close contact with one end of the reflecting mirror 18 so as to fill a gap 19 between the light source 15 (light emitting surface 24) and the reflecting mirror 18. Note that a reflective layer similar to the reflective layer 43 of each of the above embodiments may be provided on the outer peripheral surface that is the side surface of the insulating portion 58.

  Similar to the holding unit 50 of the second embodiment, the holding unit 63 gradually expands along the outer peripheral surface of the reflecting mirror 18 with the inner side facing the outer peripheral surface of one end of the reflecting mirror 18 facing forward. Inclined to open. For this reason, the holding part 63 is provided so that the thickness gradually decreases from the rear side to the front side.

  The lens portion 59 is a portion that is inserted into the reflecting mirror 18 from the entrance opening 30 of the reflecting mirror 18. The lens portion 59 is formed in a round shape, that is, in a hemispherical shape (dome shape), and an outer peripheral surface 65 serving as the light emitting surface 24 is formed in a rotationally symmetric shape with the optical axis z as a center. Further, the lens portion 59 is disposed at an interval on the optical axis z side with respect to the holding portion 63 of the insulating portion 58, and one end portion of the reflecting mirror 18 is fitted and held between the holding portion 63 and the lens portion 59. The holding groove 66 is formed.

  When the lighting device 10 is assembled, one end of the reflecting mirror 18 is attached to the support surface 61 of the insulating portion 58 so that the lens portion 59 is inserted into the incident opening 30 with respect to the sealing resin 25 of the light source 15. In this state, the reflecting mirror 18 is held by the light source 15 with one end fitting into the holding groove 66.

  When the lighting device 10 is turned on, when the light source 15 (light emitting element 23) is turned on, the light from the light emitting element 23 and the light from the phosphor contained in the sealing resin 25 excited by this light are mixed, The light is condensed or diffused by the lens unit 59 inserted into the incident aperture 30 of the reflecting mirror 18 and is emitted from the outer peripheral surface 65 which becomes the light emitting surface 24, and is reflected directly from the emitting aperture 31 of the reflecting mirror 18 or by the reflecting surface 33. Is emitted.

  Thus, since the light guide part 56 is provided integrally with the sealing resin 25, a separate member for forming the light guide part is unnecessary, and the manufacturing cost can be suppressed.

  In addition, since the light guide unit 56 includes the lens unit 59 that is inserted into the incident opening 30 of the reflecting mirror 18, the light leakage from the gap 19 is suppressed, and the light from the light source 15 is transmitted to the incident opening of the reflecting mirror 18. It is possible to make the light incident on the light beam 30 more efficiently and optically control the light toward the light incident opening 30 and the reflecting surface 33 of the reflecting mirror 18.

  In each of the above embodiments, the reflecting mirror 18 may be formed of an insulating material instead of a metal material. In this case, a high reflectance can be secured by depositing a metal reflecting film in the region of the reflecting surface 33 of the reflecting mirror 18.

  Further, the lighting device is not limited to a spotlight, and any lighting device can be applied as long as it is an instrument structure including a light source 15 and a reflecting mirror 18.

  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 Lighting equipment
15 Light source
18 Reflector as a collector
19 Clearance
20 Light guide column as light guide
23 Light emitting element
25 Sealing resin
30 Entrance aperture
31 Outgoing aperture
45 Support section
46 Insertion
56 Light guide
59 Lens section

Claims (4)

With a light source;
It is formed in a cylindrical shape having an entrance opening through which light from the light source is incident on one end side and an exit opening through which light is emitted on the other end side, and is disposed with a gap between the one end side and the light source. A concentrator made;
A light guide unit that has an insulating property, and at least a part of the light source is interposed in a gap between the light source and the one end side of the collector, and guides light from the light source to an incident opening of the collector;
An illumination device comprising: The light source is
A light emitting element;
A sealing resin for sealing the light emitting element,
The lighting device according to claim 1, wherein the light guide unit is provided integrally with the sealing resin. The lighting device according to claim 1, wherein the light guide unit includes a lens unit that is formed in a lens shape and is inserted into an incident opening of the condenser. The light guide is
An insert formed along the inner surface of the collector and attached to the interior of the collector;
The illumination device according to any one of claims 1 to 3, further comprising a support portion that is separate from the insertion portion and supports one end side of the condenser.

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