JP6179760B2 - lighting equipment - Google Patents

Description

  Embodiments of the present invention relate to a lighting apparatus used as a projector, for example.

  2. Description of the Related Art Conventionally, for example, there are high-powered luminaires that are used as a projector or a spotlight for illuminating a signboard or the like, or for lighting a building. In recent years, such lighting fixtures include LEDs (light-emitting diodes) as solid-state light-emitting elements as light emitters for the purpose of extending life, saving energy, reducing weight, or reducing the size. Such LED projectors have many designs in which, for example, a large number of surface mount type LEDs and optical lenses are arranged. However, as the output increases, the number of LEDs and lenses increases, and the cost, weight, and instrument area increase. It will increase. In addition, since LEDs have high emission luminance, an afterimage tends to remain in the eye when the number of light sources is large, and the LED feels dazzling. Therefore, in order to solve the problems of a plurality of light sources while using an LED light source module mounted with high density, a configuration including an LED and a reflector that controls light distribution from these LEDs is known. .

JP 2012-9280 A

It is desirable that the light projector be able to vary the light distribution in order to cope with various irradiation objects. However, unlike a cylindrical high intensity discharge (HID) lamp, in the case of a projector using a planar LED, a reflector for obtaining a narrow angle light distribution and a medium angle light distribution or a wide angle light distribution are obtained. The size (length in the optical axis direction) differs greatly from reflector to reflector. In general, when the light distribution angle (beam angle) is narrow, the length of the reflector is lost, and when the light distribution angle (beam angle) is medium, the length of the reflector is short. Therefore, it is not easy to use a common instrument structure while corresponding to these different light distribution angles .

Luminaire embodiment, the instrument body and, at least one light emitting unit including a solid-state light-emitting element and; the calling optical unit surrounds a parabolic shape which is formed in reflector and; cylindrical front and rear ends of which are open in paraboloidal rear opening side formed in and the extension reflector having a reflecting surface that is continuous with the reflector while being joined to the front end portion of the reflector; and provided, said extension and said reflector A light distribution angle can be changed by being attached by joining any one of the reflector inner surface and the outer surface of the reflector at the reflector joint portion of any reflector, and the instrument body has a bottom surface portion to which the light emitting part is attached. When, the side surface portion has a sidewall portion surrounding the, that are formed in a longitudinal shape in the optical axis direction than the height the reflector of the side wall portion.

According to the present invention, while utilizing the structure of the common, it can correspond to different light distribution angle.

It is II sectional drawing of FIG. 6 which shows the lighting fixture of one Embodiment. It is II-II sectional drawing of FIG. 5 which shows a lighting fixture same as the above. The state of using the same lighting equipment for the Nakahiro light distribution is a front view indicating a state of detaching the cover portion. It is a front view which shows the upper body which removed the extension cover from the state which uses a lighting fixture same as the above as an object for narrow angle light distribution. It is a perspective view which shows the state which uses a lighting fixture same as the above as an object for medium and wide angle light distribution. It is a perspective view which shows the state which uses a lighting fixture same as the above as an object for narrow angle light distribution. It is a rear view of the heat radiator which shows a lighting fixture same as the above.

  The configuration of one embodiment will be described below with reference to FIGS.

In FIG. 1 to FIG. 7, reference numeral 11 denotes a projector as a lighting fixture. This projector 11 is a high output of, for example, 1 kW class for irradiating light to an irradiation object such as various signs or buildings. Is. Hereinafter, the front-rear direction is set based on the optical axis direction (irradiation direction).
The projector 11 includes a common main body portion 15 and an adapter portion 16 that can be attached to and detached from the common main body portion 15.

  The common main body 15 includes a radiator 21 that is a housing as an instrument main body, at least one arranged in the radiator 21, in the present embodiment, for example, a plurality of, for example, seven light emitting units 22, and the light emitting units 22 Reflector (reflector) 23 detachably attached to the radiator 21, a mounting arm 24 as a mounting member for attaching the radiator 21 to a mounting portion (not shown) such as a structure, and the light emitting unit 22 And a power supply unit 25 for supplying power. And this common main-body part 15 is the 1st light projector (medium-wide angle light projector which can perform medium-angle light distribution or wide-angle light distribution which is the 1st light distribution angle by attaching the cover part 26 to the heat radiator 21. ).

  The radiator 21 is integrally formed of a lightweight member with excellent heat dissipation, such as aluminum or aluminum die-casting, for example, a hexagonal bottom surface portion 31 and is raised from the periphery of the bottom surface portion 31 to the front side. The side wall portion 32 is provided, and a plurality of radiating fins 34 are provided on the back side of the bottom surface portion 31.

  The bottom surface portion 31 is formed in a flat plate shape, and the light emitting portion 22 is attached and thermally connected. In addition, a wiring hole for wiring a power line (not shown) that electrically connects the power supply unit 25 and the light emitting unit 22 is opened in the bottom surface portion 31 at a position closer to the lower side. On the back side of the wiring hole 35, that is, on the rear side of the bottom surface portion 31, a wiring boss portion 36 is integrally formed. The wiring boss part 36 protrudes from the heat radiation fin 34 on the back side of the bottom part 31 and is connected to the power supply part 25.

  Moreover, the side wall part 32 is formed in a wall shape continuous over the entire circumference of the bottom surface part 31, and includes, for example, six side parts 32a and surrounds the entire periphery of the reflector 23 in a frame shape. Further, the side wall portion 32 is formed in a longer shape in the optical axis direction than the reflector 23. Therefore, the front end portion of the side wall portion 32 (heat radiating body 21) is located in front of the front end portion of the reflector 23. The side wall portion 32 is inclined so as to expand from the rear side in the optical axis direction to the front side, and the front end portion (first) emission when the common main body portion 15 is used as the first projector. An opening 37 is formed. Then, a (first) mounting receiving portion 38 to which the cover portion 26 is fitted is formed at the front end portion of the side wall portion 32 surrounding the entire circumference of the emission opening 37 so as to expand outward in a flange shape. ing. In addition, a (first) mounting seat 39 for mounting and fixing the cover 26 is projected from the outer edge of the mounting receiving portion 38, that is, the front end of each side 32a of the side wall 32. Yes. The mounting seats 39 are respectively provided with screw holes 39a for fixing and fixing screws or the like, not shown, for fixing the cover 26. The attachment receiving portion 38 and the attachment seat portion 39 constitute an attachment portion 40 for attaching the cover portion 26 to the radiator 21 (common main body portion 15).

  Further, each radiating fin 34 is continuous in the longitudinal direction on the back surface of the entire bottom surface portion 31 excluding the wiring boss portion 36 and the position below the wiring boss portion 36, that is, along the direction intersecting (orthogonal) with the optical axis direction. And are spaced apart from each other at a predetermined interval (for example, an interval of about 6 to 10 mm) in the width direction. Accordingly, a passage portion 44 through which air passes is formed between the radiation fins 34, 34, respectively. Further, these radiation fins 34 are opposed to the power supply unit 25 while being separated in the optical axis direction by connecting the wiring boss 36 to the power supply unit 25. Therefore, a space portion 45 communicating with each passage portion 44 is formed between each radiation fin 34 and the power source portion 25.

  Each light emitting unit 22 uses, for example, an LED element 22a as a solid light emitting element (semiconductor light emitting element) as a light source. In the present embodiment, a COB (Chip On Board) system in which a plurality of LED elements 22a are mounted on a circular substrate 22b is employed. That is, each light emitting unit 22 is a phosphor layer that is a transparent resin such as a silicone resin in which a plurality of LED elements 22a mounted on a substrate 22b are electrically connected in series by wire bonding and phosphor is mixed therein. A plurality of LED elements 22a are integrally covered and sealed. Note that a light distribution lens may be disposed in the light emitting unit 22. Further, as the light emitting unit 22, a method of mounting a plurality of SMD (Surface Mount Device) packages with connection terminals on which LED elements 22a are mounted on a substrate may be used.

  Each reflector 23 can also be called a medium-wide-angle mirror, has a cylindrical shape with both front and rear ends opened, and is formed in a parabolic shape that gradually increases in diameter from the rear side to the front side. That is, the reflecting surface is mirror-like. Further, on each light emitting portion 22 side of the reflector 23, a flange portion 23a that is a positioning portion as a reflector mounting portion is protruded in a bowl shape over the entire circumference. It is fixed with screws using screws that are not fixed members.

  The mounting arm 24 is for mounting and fixing the projector 11 (common main body portion 15) at a predetermined angle at a predetermined mounting position, and is integrally formed by a member having rigidity such as metal, for example, and a pair of arm portions. 24a, 24a and the connection part 24b which connects between these arm parts 24a, 24a are U-shaped.

  The arm portions 24a, 24a are pivotally supported by shaft support portions 32b, 32b projecting outside the side portions 32a, 32a located on both sides of the side wall portion 32 of the heat dissipating member 21 so as to be vertically rotatable (tilt rotation). ing. A rotating plate 47 is positioned between one arm portion 24a and one shaft support portion 32b, and this rotating plate 47 is fixed to one shaft support portion 32b. Then, one arm portion 24a is provided with a rotation stopper plate 48 that is a rotation stopper, and the one rotation arm 48 sandwiches the rotating plate 47 with the one arm portion 24a. By being fixed to the part 24a, the projector 11 is configured to be fixed in a state of being set at a predetermined rotation angle with respect to the mounting position.

  In addition, a turntable 49 is provided at the center of the connecting portion 24b. The turntable 49 has a circular opening 49a for fixing to a predetermined mounting position via a bolt (not shown) at the center, and the turntable 49 allows the projector 11 (common main body portion) to be opened. 15) can be rotated left and right (pan rotation). Furthermore, a long hole-shaped rotation angle regulating hole 49b is curved and opened in a concentric arc shape outside the opening 49a. A rotation restricting body (not shown) protruding from the mounting position is inserted into the rotation angle restricting hole 49b so as to restrict the maximum angle of left-right rotation of the projector 11 (common main body portion 15). .

  In addition, the power supply unit 25 is configured in a unit shape in which a plurality of power sources (not shown) are arranged in a matrix shape on a rectangular case body 51, for example, so as to supply predetermined DC power to the light emitting unit 22. It has become.

  Further, the cover part 26 includes a cover 53 as a cover part main body formed in, for example, a hexagonal plate shape by a member such as glass having translucency, and a hexagonal frame-like frame that holds an outer edge part of the cover 53 And a body 54. The cover 53 is formed so that the outer edge portion is slightly larger than the emission opening 37 and is fitted to the attachment receiving portion 38. Further, the frame body 54 protrudes in a flange shape from the center portion of each side portion 54b of the frame body 54a to the side, and is fitted to the front end portion of the side wall portion 32 of the radiator 21. Mounting piece portion 54c. In these attachment pieces 54c, a through hole 54d that is aligned with the screw hole 39a of the attachment seat 39 and into which a screw or the like is inserted is opened at a substantially central portion.

  On the other hand, as shown in FIG. 2 and FIG. 4, the adapter portion 16 is connected to the extended reflector 56 attached to the front end portion of the reflector 23, and the radiator 21 of the common main body portion 15 surrounding the extended reflector 56. And a cylindrical frame portion 57 to be attached. That is, the adapter part 16 is attached to the common main body part 15 so as to extend in the optical axis direction. The adapter portion 16 is attached to the common main body portion 15 instead of the cover portion 26, and the extension cover portion 58 is attached to the frame portion 57, so that the adapter portion 16 together with the common main body portion 15 is more than the first light distribution angle. It functions as a second light projector (narrow-angle light projector) capable of narrow-angle light distribution, which is a narrow second light distribution angle.

  The extended reflector 56, which can also be called a narrow-angle mirror, has a cylindrical shape with open front and rear ends, and is formed in a parabolic shape that gradually increases in diameter from the rear side to the front side. The rear end opening having a mirror-like surface is formed with a stepped portion 56a outwardly orthogonal to the optical axis direction and an extending portion 56b extending from the stepped portion 56a in the rear end opening direction. . The inner surface of the extending portion 56b is formed with a polarity that is substantially the same as the outer surface of the reflector 23, and is formed into a reflecting surface in which the inner surfaces are continuous by joining each other. Note that the front end opening of the reflector 23 and the circumferential direction of the stepped portion 56a of the extended reflector 56 are joined. In short, the inner surfaces of these extended reflectors 56 are formed in a paraboloid shape that is continuous with the inner surface of the reflector 23 without a step when attached to the front end portion of the reflector 23. That is, the inner surface of each of the extended reflector 56 and the reflector 23 is a planar dividing surface PL along a direction intersecting (orthogonal) a continuous paraboloid for narrow-angle light distribution with respect to its axial direction. The shape is divided in the length direction. Therefore, the arrangement of the light emitting section 22 and the reflector 23 of the common main body section 15 is set based on the arrangement for narrow-angle light distribution.

  The frame portion 57 is formed in a hexagonal cylindrical shape having an axial direction along the optical axis direction by a lightweight member such as aluminum, aluminum die casting, or synthetic resin, and is separated from the extended reflector 56, for example. ing. The frame portion 57 is formed in a longer shape in the optical axis direction than the extended reflector 56. Therefore, the front end portion of the frame portion 57 is positioned in front of the front end portion of the extended reflector 56. Further, the frame portion 57 is gradually expanded from the rear side to the front side. The frame portion 57 has a fitting portion 61 that fits in the mounting receiving portion 38 at the rear end portion, and is recessed in a step shape. At the rear end portion of each side portion 57a, the adapter portion is attached. A mounting protrusion 62 as a portion protrudes from each other. These mounting protrusions 62 are opened with through holes 62a that are aligned with the screw holes 39a of the mounting seat portion 39 of the radiator 21 and into which screws or the like are inserted. Therefore, the frame portion 57 (adapter portion 16) is detachably attached to the heat radiating body 21 by the attachment portion 40 for fixing the cover portion 26. In other words, the attachment part 40 is a common attachment part when attaching the cover part 26 and the adapter part 16 to the radiator 21. The front end portion of the frame portion 57 serves as a (second) emission opening 64 when the projector 11 is used as a second projector. An extension cover portion 58 is fitted to the front end portion of the frame portion 57 that surrounds the entire circumference of the emission opening 64, and a (second) attachment receiving portion 65 is formed to expand outward in a flange shape. Has been. Further, a (second) mounting seat portion 66 for mounting and fixing the extension cover portion 58 is provided on the outer edge portion of the mounting receiving portion 65, that is, the front end portion of each side portion 57a of the frame portion 57, respectively. ing. These mounting seats 66 are each opened with a screw hole 66a for fixing and fixing a screw or the like (not shown) for fixing the extension cover 58.

Further, the extension cover part 58 includes an extension cover 71 as an extension cover part body formed of, for example, a hexagonal plate by a member such as glass having translucency, and a hexagonal shape that holds the outer edge part of the extension cover 71. A frame-like extension frame 72. The extension cover 71 has an outer edge portion slightly larger than the emission opening 64 and is formed so as to fit into the attachment receiving portion 65. The extension frame 72 protrudes in a flange shape from the center of the extension frame body 72a fitted to the front end of the frame 57 and the side portions 72b of the extension frame body 72a to the side. And an attachment piece 72c. The mounting piece 72c has a through hole 72d that is aligned with the screw hole 66a of the mounting seat 66 and into which a screw or the like is inserted, and is opened at a substantially central portion.
Next, the operation of the one embodiment will be described.

  First, when the projector 11 is used for medium-angle light distribution or wide-angle light distribution, the adapter part 16 is removed and the cover part 26 is attached to the common main body part 15 (FIGS. 1 and 5).

  That is, the reflectors 23 are first attached to the radiators 21 to which the light emitting units 22 are attached and connected to the power supply unit 25, respectively. At this time, each of the reflectors 23 is fixed to the radiator 21 by screwing the flange portion 23a of the radiator 21 to the radiator. In this state, each reflector 23 is aligned with the light emitting unit 22 at the center axis position, and the light emitting unit 22 is inserted on the rear end side.

  Next, the cover part 26 is attached to the radiator 21 to which the reflectors 23 are attached. At this time, the cover portion 26 fits the outer edge portion of the cover 53 to the attachment receiving portion 38 of the radiator 21, and the through holes 54d of the attachment pieces 54c of the frame body 54 are connected to the side portions 32 of the radiator 21. The front end portion of the radiator 21 is covered and fixed by being aligned and screwed to the screw holes 39a of the mounting seat portion 39, respectively.

  The completed projector 11 (common main body portion 15) attaches the rotating base 49 of the mounting arm 24 to the mounting position with a bolt or the like, and corresponds to the positional relationship between the irradiation object and the mounting position, The rotation angle in the vertical direction and the horizontal direction is adjusted and fixed by the 24a and the turntable 49.

  Then, each light-emitting unit 22 to which power is supplied from the power supply unit 25 emits light, and the light distribution from these light-emitting units 22 is reflected by the inner surface of each reflector 23 to be a medium-angle light distribution or a wide-angle light distribution. Lights through 53 and illuminates the object to be irradiated.

  On the other hand, when the projector 11 is used for narrow-angle light distribution, the adapter portion 16 is attached to the common main body portion 15 and the extension cover portion 58 is attached to the adapter portion 16 (FIGS. 2 and 6).

  That is, the extended reflector 56 is first attached to the common main body 15 (with the cover 26 removed from the state shown in FIG. 5) with the reflectors 23 attached to the radiator 21. At this time, the front end opening of each reflector 23 and the stepped portion 56a of the rear end opening of the extended reflector 56 are joined in the circumferential direction so that the front end opening outer surface of each reflector 23 is joined. The extension reflectors 56 are fixed to the radiator 21 integrally with the corresponding reflectors 23 by fitting the inner surfaces of the extension portions 56b of the rear end openings of the extension reflectors 56. In this state, the central axes of the reflectors 23 and the corresponding extended reflectors 56 coincide with each other, and the inner surfaces of the reflectors 23 and the inner surfaces of the extended reflectors 56 are continuously used for narrow-angle light distribution. Form a paraboloid.

  Next, the frame portion 57 is attached to the radiator 21 of the common main body portion 15 to which the extended reflector 56 is attached. At this time, the frame portion 57 causes the fitting portion 61 to be fitted to the attachment receiving portion 38, and the through hole 62a of each attachment protrusion 62 is screwed to the screw hole 39a of each attachment seat portion 39 of the side wall portion 32 of the radiator 21. Are fixed to the front end portion of the radiator 21 so as to surround the extended reflectors 56 and to enclose the extended reflectors 56.

  Further, the extension cover portion 58 is attached to the frame portion 57. At this time, the extension cover part 58 fits the outer edge part of the extension cover 71 to the attachment receiving part 65 of the frame part 57, and the through holes 72d of the attachment piece parts 72c of the extension frame body 72 are attached to the frame part 57. The front end portion of the frame portion 57 is covered and fixed by positioning and screwing with the screw holes 66a of the seat portion 66.

  The completed projector 11 (common main body portion 15) attaches the rotating base 49 of the mounting arm 24 to the mounting position with a bolt or the like, and corresponds to the positional relationship between the irradiation object and the mounting position, The rotation angle in the vertical direction and the horizontal direction is adjusted and fixed by the 24a and the turntable 49.

  Then, each light-emitting unit 22 to which power is supplied from the power supply unit 25 emits light, and the light distribution from these light-emitting units 22 is reflected by the inner surface of each reflector 23 and each extended reflector 56 to be distributed at a narrow angle, The light is emitted through the extension cover 71 to illuminate the irradiation object.

  Note that in the radiator 21, the outside air passes through the passage portion 44 and the space 45 regardless of the mounting angle of the projector 11 (common main body portion 15). Dissipate heat.

  According to the embodiment described above, the heat dissipating member 21 can be attached to and detached from the heat dissipating member 21. By using the adapter part 16 having the extended reflector 56 that is controlled to a narrower angle, the adapter part 16 is not used and the radiator 21 and the reflector 23 are used when using the adapter part 16 for the medium angle or wide angle. In the case of narrow-angle use, the adapter portion 16 is attached to the radiator 21 and the reflector 23 is extended by the extension reflector 56. As a result, the heat radiator 21 and the reflector 23 can be used for each of a plurality of different light distribution angles (beam angles), that is, each of these different light distribution angles can be used while using a common structure. Therefore, it is possible to cope with a plurality of different light distribution angles with a smaller number of parts, improving convenience and reducing costs.

  In addition, because the projector 11 must be designed with the heat dissipation structure for outdoor use, it is not easy to adopt a forced air cooling structure, and the lighting direction can be freely turned on and off and horizontally depending on the structure of the irradiation object. It is desirable to be able to design. Therefore, by providing the radiator 21 with a plurality of radiation fins 34 that are separated so that air passes between each other, a sufficient heat radiation effect can be obtained regardless of the mounting direction of the projector 11, etc. Even in the light emitting unit 22 using the LED element 22a, the light emission efficiency is not lowered by heat, and sufficient brightness can be obtained.

  Further, the adapter unit 16 is attached to and detached from the common main body 15 (heat radiator 21) by using the mounting portion 40 (mounting receiving portion 38 and mounting seat 39) for attaching the cover portion 26 to the common main body portion 15 (heat radiator 21). Mounting is possible, that is, the attachment work of the cover part 26 and the adapter part 16 can be made more efficient by sharing the attachment / detachment structure of the adapter part 16 and the cover part 26 to the common main body part 15 (heat radiator 21). .

  Further, since the respective openings of the reflector 23 and the extended reflector 56 can be used to join each other, the attaching work of the reflector 23 and the extended reflector 56 can be made more efficient.

  In this way, by providing a large number of structures that can be shared between the medium-angle or wide-angle case and the narrow-angle case, the light projector 11 can reduce a plurality of different light distributions while reducing costs with a smaller number of parts. Can handle corners.

  In addition, since the reflector 23 and the extended reflector 56 are fixed by overlapping their openings, the reflector 23 and the extended reflector 56 can be stably fixed, and the light from the reflector 23 and the extended reflector 56 can be fixed. Axial misalignment and rattling can be reduced.

  Further, by making the extended reflector 56 and the frame portion 57 separate, each extended reflector 56 can be attached to each reflector 23 without the frame portion 57 being in the periphery, thus extending the work space for this attachment. It can be sufficiently secured around the reflector 56, and workability can be further improved.

  In the above embodiment, the frame portion 57 may be configured to hold the extended reflector 56 integrally. In this case, the plurality of extended reflectors 56 can be easily aligned with the reflector 23 at a time.

Furthermore, the junction between the reflector 23 and the extended reflector 56 may be formed with a stepped portion and an extending portion on the front opening side of the reflector. It may be given.
Further, the radiator 21 may be provided radially from the center of the bottom surface 31 of the radiator 21, for example.
Furthermore, the solid light emitting element is not limited to the LED element 22a, and for example, an organic EL element or the like may be used.

  Further, the cover portion 26 and the extension cover portion 58 are different from each other, but the frame portion 57 is formed so as to hardly expand from the rear side to the front side, so that the attachment receiving portion 65 of the frame portion 57 is formed. Further, the cover portion 26 and the extension cover portion 58 may be made common so that the cover portion 26 can be attached to the attachment seat portion 66.

  Although one embodiment of the present invention has been described, this embodiment is presented as an example and is not intended to limit the scope of the invention. The novel embodiment can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. This embodiment and its modifications are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

11 Floodlight as a lighting fixture
16 Adapter section
21 radiator
22 Light emitter
22a LED elements as solid state light emitting devices
23 Reflector
26 Cover
34 Radiation fin
40 Mounting part
53 Cover
56 Extended reflector

Claims (2)

An instrument body;
At least one light emitting part comprising a solid state light emitting element;
A reflector formed in a parabolic shape surrounding said onset optical unit;
An extended reflector having a reflecting surface that is continuous with the reflector while a rear opening side formed in a parabolic shape with a cylindrical shape with both front and rear ends open is joined to the front end of the reflector;
It is possible to change the light distribution angle by being attached by joining one of the reflector inner surface and the reflector outer surface at the reflector joint portion of either the reflector and the extended reflector , The instrument main body has a bottom surface portion to which the light emitting portion is attached and a side wall portion surrounding the side surface portion, and the height of the side wall portion is longer in the optical axis direction than the reflector. A lighting apparatus characterized by that. The lighting fixture according to claim 1, wherein a plurality of heat radiation fins are formed on a surface opposite to a bottom surface portion to which the light emitting portion of the fixture body is attached .

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