JP6187784B2 - LED lighting fixtures - Google Patents

Description

  Embodiments described herein relate generally to an LED lighting apparatus using an LED (Light Emitting Diode) as a light source.

  LEDs have been widely used not only for industrial fields but also for general lighting because of their features such as long life, low power consumption, impact resistance, high-speed response, high-purity display color, and lightness and thinness. Moreover, the LED lighting fixture provided with the reflecting plate which controls light distribution other than an LED module is known (for example, patent document 1).

JP 2010-3679 A

  The present invention provides an LED lighting apparatus that can flexibly lay out a reflector in accordance with a change in the number of LED modules.

According to one aspect of the present invention, a main body having a through hole at the center of a light source mounting surface, a substrate, an LED (Light Emitting Diode) element mounted on the substrate, and the LED element on the substrate are mounted. A connector provided on the through hole side of the side surface, a plurality of LED modules mounted around the through hole of the light source mounting surface, and the substrate of the plurality of LED modules The connector formed to cover the surface on which the LED element is mounted and to expose the LED element, and to enter the region side opposite to the through hole side and where the hole is formed A cable for supplying power to the LED module, the reflector having a recess for storing the light source, and a plurality of heat radiation fins formed on the opposite side of the light source mounting surface of the main body. Mounting LED lighting apparatus, characterized in that said are wired through the through-hole is provided.

  According to the present invention, a highly versatile LED lighting apparatus is provided.

The external appearance perspective view of the LED lighting fixture of embodiment. The top view by the side of the light source attachment surface in the main body of the LED lighting fixture of embodiment. The top view of the heat radiating surface side in the main body. The perspective view by the side of the heat sink in the main body. (A) is the side view seen from the A-A 'direction in FIG. 3, (b) is B-B' sectional drawing in FIG. The side view seen from the C-C 'direction in FIG. The top view of the LED module in the LED lighting fixture of embodiment. The top view which illustrates the wiring pattern in the LED module. The top view of the reflecting plate in the LED lighting fixture of embodiment. D-D 'sectional drawing in Fig.9 (a). The top view which shows the 1st layout of a some LED module. The top view which shows the 2nd layout of a some LED module. (A) is a top view of the reflecting plate superimposed on the LED module of the 1st layout shown in FIG. 11, (b) is a top view of one LED module and the reflecting plate superimposed on it. The top view of the reflecting plate overlaid on the LED module of the 2nd layout shown in FIG. The top view which piled up the LED module arrange | positioned on the back side of a heat radiating surface with the broken line in the top view on the heat radiating surface side shown in FIG. The side view corresponding to FIG. 6 in the state in which the power supply unit was attached to the main body. FIG. 4 is a plan view in which a power supply unit is overlapped with a two-dot chain line on the plan view on the heat radiating surface side shown in FIG. 3. The top view inside a power supply unit.

  Hereinafter, embodiments will be described with reference to the drawings. In addition, the same code | symbol is attached | subjected to the same element in each drawing.

  Drawing 1 is an appearance perspective view of LED lighting fixture 1 of an embodiment.

  The LED lighting apparatus 1 of the embodiment includes a main body 2, an LED module 3 (shown in FIG. 7), a reflector 4 (shown in FIGS. 9A and 9B), a power supply unit 5, and an arm 6. It has.

  The LED lighting apparatus 1 according to the embodiment is a large-sized lighting apparatus whose power consumption is, for example, 100 W to 500 W. The LED lighting apparatus 1 is connected to an arm 6 that is a mounting member, for example, in a gymnasium or the like.

It is attached to the ceiling or a lifting device suspended from the ceiling.

  First, the main body 2 will be described.

  FIG. 2 is a plan view of the main body 2 on the light source mounting surface 11 side.

  FIG. 3 is a plan view of the heat radiating surface 12 side opposite to the light source mounting surface 11 in the main body 2.

  FIG. 4 is a perspective view of the main body 2 on the heat radiating surface 12 side.

  FIG. 5A is a side view seen from the A-A ′ direction in FIG. 3.

  FIG. 5B is a cross-sectional view along B-B ′ in FIG. 3.

  FIG. 6 is a side view seen from the direction C-C ′ in FIG. 3.

  The main body 2 has a circular plate 13. One surface side of the plate 13 is formed in a shallow dish shape, and a light source mounting surface 11 shown in FIG. 2 is formed on the bottom surface. At the outer peripheral edge of the light source mounting surface 11, an annular rim 14 is provided that protrudes from the light source mounting surface 11 toward the front side in FIG.

  The other surface of the plate 13 functions as the heat radiating surface 12, and the heat radiating surface 12 is provided with a plurality of heat radiating fins 15 and 16.

  The main body 2 is formed, for example, by molding aluminum or a metal containing aluminum as a main component by a die-cast method, and the plate 13 and the radiation fins 15 and 16 are integrally provided. Further, the entire surface of the main body 2 including the plate 13 and the heat radiation fins 15 and 16 is formed with an aluminum oxide film by, for example, alumite treatment in order to improve heat radiation.

  A through hole 13 a is formed at the center of the plate 13. Therefore, as shown in FIG. 2, the light source mounting surface 11 is formed in an annular shape around the through hole 13a.

  For example, four projecting bosses 21 are provided around the through hole 13 a in the light source mounting surface 11. The four bosses 21 are arranged at intervals of, for example, 90 ° in the circumferential direction. The boss 21 functions as a second positioning portion for positioning the later-described reflector 4 in the second layout shown in FIG.

  In the light source mounting surface 11, for example, twelve protruding bosses 22 are provided near the inner peripheral wall of the rim 14. The twelve bosses 22 are arranged, for example, at 30 ° intervals in the circumferential direction. The boss 22 functions as a first positioning portion for positioning the later-described reflector 4 in the first layout shown in FIG.

  Furthermore, for example, four projecting bosses 23 are provided on the light source mounting surface 11 on the inner circumferential side slightly from the bosses 22. In FIG. 2, the two left bosses 23 are arranged in the circumferential direction at intervals of 60 °, for example. In FIG. 2, the lower two bosses 23 are arranged in the circumferential direction at intervals of 120 °, for example. For example, the upper two bosses 23 in FIG. 2 are arranged at intervals of 120 ° in the circumferential direction. The boss 23 functions as a second positioning portion for positioning the later-described reflector 4 in the second layout shown in FIG.

  In addition, a plurality of screw holes 24 and 25 are formed in the light source mounting surface 11. As shown in FIGS. 11 and 13, the screw holes 24 are used to screw the six LED modules 3 and the reflection plate 4 to the light source mounting surface 11, respectively. As shown in FIGS. 12 and 14, the screw holes 25 are used for screwing the four LED modules 3 and the reflection plate 4 to the light source mounting surface 11, respectively.

  Next, the LED module 3 will be described.

  FIG. 7 is a plan view of the LED module 3.

  The LED module 3 includes a substrate 31 and LED elements 32 mounted on the substrate 31. A plurality (33 in the example shown in FIG. 7) of LED elements 32 are mounted on one substrate 31. For example, the plurality of LED elements 32 are mounted in groups of three. A connector 33 is mounted on the substrate 31.

  It is preferable that the element substrate (or package substrate) of the LED element 32 and the substrate 31 of the LED module 3 have the same or close thermal expansion coefficient. For example, when the element substrate of the LED element 32 is a ceramic substrate, a ceramic substrate can be used as the substrate 31.

  Alternatively, a metal plate that is cheaper than a ceramic substrate may be used as the substrate 31. In the present embodiment, an iron substrate 31 having a smaller difference in thermal expansion coefficient with respect to the ceramic substrate than that of aluminum or copper is used. The substrate 31 has a substantially fan-shaped planar shape, and a notch 39 is formed at the front end portion on the central angle side, and two notches 35 are formed on the arc-shaped outer peripheral portion.

  The mounting surface of the substrate 31 is covered with, for example, an insulating film such as resin, and a wiring pattern 36 shown in shaded or gray in FIG. 8 is formed on the insulating film. In FIG. 8, the LED element 32 and the connector 33 mounted on the wiring pattern 36 are represented by a one-dot chain line. Further, for example, a white resin film having reflectivity with respect to the light emitted from the LED element 32 is formed on the outermost surface of the substrate 31 so as to cover the wiring pattern 36. This resin film has insulating properties and does not short-circuit between the wiring patterns 36 having different polarities.

  The wiring pattern 36 is made of, for example, a copper material. In FIG. 8, the insulating part between the wiring patterns 36 is shown in a white line shape. The wiring pattern 36 is formed in a solid pattern shape instead of a line shape, and is formed in an area wider than the insulating portion (white line-shaped portion) between the wiring patterns 36 in the surface of the substrate 31. Thereby, the heat dissipation of the heat | fever of the LED element 32 through the wiring pattern 36 can be improved.

  Each LED element 32 has an anode side external terminal and a cathode side external terminal, and these external terminals are joined to the wiring pattern 36 by, for example, solder. In the present embodiment, a plurality of (for example, 33) LED elements 32 and one connector 33 are electrically connected in series via a wiring pattern 36.

  The LED element 32 is mounted with the light emission surface facing the opposite side of the mounting surface of the substrate 31. The LED element 32 has a semiconductor chip including a light emitting layer and a phosphor layer containing phosphor particles. For example, when the phosphor particles are yellow phosphor particles that emit yellow light, the mixed color of blue light from the light emitting layer that is a GaN-based material and yellow light that is wavelength converted light in the phosphor layer is white or Light bulb color light is emitted to the outside. The phosphor layer may include a plurality of types of phosphor particles (for example, red phosphor particles that emit red light and green phosphor particles that emit green light).

  The LED module 3 is mounted on the light source mounting surface 11 with the surface (back surface) opposite to the mounting surface of the substrate 31 on which the LED elements 32 are mounted contacting the light source mounting surface 11 of the main body 2.

  A pair of through holes 34 is formed in the substrate 31. The through holes 34 described above with reference to FIG. 2 are a pair of screw holes 24 arranged in the radiation direction of the light source mounting surface 11, or a pair arranged in the radiation direction of the light source attachment surface 11 at a position different from the screw hole 24. Are aligned with any one of the screw holes 25. Then, when the screw is screwed into the screw hole 24 or 25 through the through hole 34, the LED module 3 is fixed in close contact with the light source mounting surface 11. Thereby, the thermal conductivity from the LED module 3 to the main body 2 increases. The substrate 31 of the LED module 3 is a metal plate and has better heat conduction than a resin substrate or a ceramic substrate.

  In the present embodiment, the number of LED modules 3 can be arbitrarily selected and attached to the light source attachment surface 11.

  FIG. 11 shows a first layout in which, for example, six LED modules 3 are attached to the light source attachment surface 11.

  The outer shape of the light source mounting surface 11 is circular. The six LED modules 3 are arranged at equal intervals along the circumferential direction around the center of the light source mounting surface 11.

  In the first layout, the through hole 34 of each LED module 3 is aligned with the screw hole 24 shown in FIG. 2 formed in the light source mounting surface 11. Then, a screw (not shown) is screwed into the screw hole 24 through the through hole 34, and the LED module 3 is fixed to the light source mounting surface 11.

  As shown in FIG. 7, two notches 35 are formed in the arc-shaped outer peripheral portion of the substrate 31 of each LED module 3, and the bosses provided on the outer peripheral side of the light source mounting surface 11 in the respective notches 35. The root part of 22 fits in. Thereby, positioning of the through hole 34 of the LED module 3 with respect to the screw hole 24 of the light source mounting surface 11 is facilitated.

  Next, FIG. 12 shows a second layout in which, for example, four LED modules 3 having a smaller number of LED modules 3 than the first layout are mounted on the light source mounting surface 11.

  The four LED modules 3 are arranged at equal intervals along the circumferential direction around the center of the light source mounting surface 11.

  In the second layout, the through hole 34 of each LED module 3 is aligned with a screw hole 25 different from the screw hole 24 used in the first layout. Then, a screw (not shown) is screwed into the screw hole 25 through the through hole 34, and the LED module 3 is fixed to the light source mounting surface 11.

  The base portion of the boss 21 provided around the center of the light source mounting surface 11 is fitted into the notch 39 (FIG. 7) formed at the tip of each LED module 3. Further, the base portion of the boss 23 provided on the inner peripheral side of the boss 22 used in the first layout in one of the two notches 35 formed in the arc-shaped outer peripheral portion of each LED module 3. Get stuck. Thereby, positioning of the through hole 34 of the LED module 3 with respect to the screw hole 25 of the light source mounting surface 11 is facilitated.

  The plurality of LED modules 3 are arranged in a state of being divided in the surface direction of the light source attachment surface 11, and can be attached to and detached from the light source attachment surface 11 for each LED module 3 by attaching and detaching screws. Therefore, the number of LED modules 3 attached to the light source attachment surface 11 can be easily changed, and the luminous flux (brightness) can be adjusted according to the purpose of use of the LED lighting fixture 1.

  A boss 22 serving as a first positioning portion for positioning the LED module 3 in the first layout shown in FIG. 11 and a second positioning portion for positioning the LED module 3 in the second layout shown in FIG. Both bosses 21 and 23 are provided on the light source mounting surface 11 of the same main body 2.

  Therefore, there is no need to separately prepare a main body having a light source mounting surface designed for the first layout and a main body having a light source mounting surface designed for the second layout. The main body 2 having the same design can be used for both the first layout and the second layout. Only one type of mold for the main body 2 is required, which does not increase costs.

  As shown in FIG. 11, in the first layout, the boss 21 used in the second layout is located on the inner peripheral side of the LED module 3, and the boss 23 is located between the LED modules 3 adjacent in the circumferential direction. It does not disturb the arrangement of the six LED modules 3 in the first layout.

  Conversely, as shown in FIG. 12, in the second layout, the bosses 22 used in the first layout are located on the outer peripheral side with respect to the LED module 3, and the second layout of the four LED modules 3. Does not interfere with the placement.

  In the second layout in which the four LED modules 3 are arranged, not only the two LED modules 3 are simply removed from the first layout in which the six LED modules 3 are arranged. The direction position is shifted. That is, the circumferential positions of the LED modules 3 are shifted from the first layout in which the six LED modules 3 are arranged so that the four LED modules 3 are arranged at equal intervals in the circumferential direction.

  By arranging the plurality of LED modules 3 at equal intervals in the circumferential direction, the light emitting portions can be evenly distributed in the circumferential direction without unevenness. As a result, it is possible to realize an illumination that does not give a sense of incongruity in which a circular or annular portion that is often seen in existing lighting fixtures can be seen.

  Further, in the second layout in which the four LED modules 3 are arranged, each LED module 3 is brought closer to the center side of the light source mounting surface 11 than in the first layout in which the six LED modules 3 are arranged. Yes.

  That is, the LED element 32 mounted on the LED module 3 approaches the center side of the light source mounting surface 11. Thereby, compared with the case where the position of the radial direction of the four LED modules 3 is made the same as the 1st layout shown in FIG. 11, the distance of the circumferential direction between the LED elements 32 between the LED modules 3 adjacent is made. It becomes small and it becomes easy to visually recognize the part to shine circularly or annularly.

  As described above, in the present embodiment, the light source mounting surface of each LED module 3 in the first layout in which the six LED modules 3 are arranged and the second layout in which the four LED modules 3 are arranged. 11 in the circumferential direction and the radial direction (radial direction).

  Thereby, the surface direction distribution of the suitable light emission part according to the number (light beam) of the LED module 3 arrange | positioned at the light source attachment surface 11 is realizable.

  Further, the boss 22 used for positioning of the first layout is changed by changing the position in the circumferential direction and the position in the radial direction on the light source mounting surface 11 of each LED module 3 between the first layout and the second layout. And bosses 21 and 23 used for positioning in the second layout are provided on the same light source mounting surface 11, but the bosses 21 and 23 do not get in the way in the first layout, and the boss 22 in the second layout. It does not get in the way.

  Next, the reflecting plate 4 will be described.

  FIG. 9A is a plan view of the front surface of the reflecting plate 4, and FIG. 9B is a plan view of the back surface of the reflecting plate 4.

  FIG. 10 is an enlarged cross-sectional view taken along the line D-D ′ in FIG.

  The outer shape of the reflector 4 is formed to be substantially the same as the outer shape of the substrate 31 of the LED module 3. The outer shape of the reflecting plate 4 is formed in a substantially pentagonal shape surrounded by a pair of first side surface portions 41, a pair of second side surface portions 42, and an arcuate outer peripheral portion 43. Further, the planar size of the reflecting plate 4 is substantially the same as the planar size of the substrate 31 of the LED module 3.

  The pair of first side surface portions 41 forms a first angle θ1. A corner portion formed by the pair of first side surface portions 41 is defined as a tip portion of the reflecting plate 4. Its tip is rounded.

  1st angle (theta) 1 respond | corresponds to the angle of the central angle of the sector shape when a pair of 1st side part 41 is made into two sector-shaped radii. In the present embodiment, the first angle θ1 is approximately 90 °.

  A pair of second side surface portions 42 is provided between the pair of first side surface portions 41 and the arc-shaped outer peripheral portion 43. In a state where the reflector 4 is attached to the light source attachment surface 11 as shown in FIG. 13 or 14 described later, the second side surface portion 42 is away from the center of the light source attachment surface 11 from the first side surface portion 41. Extend to. The first side surface portion 41 and the second side surface portion 42 are connected via a bent or curved corner portion. The length of the second side surface portion 42 is longer than the length of the first side surface portion 41.

  The pair of second side surface portions 42 form a second angle θ2. The second angle θ <b> 2 corresponds to the angle of the central angle of the sector when the pair of second side surface portions 42 has two fan-shaped radii. In the present embodiment, the second angle θ2 is approximately 60 °.

  A plurality of light guide holes 45 are formed in the reflecting plate 4. The light guide hole 45 passes through the reflecting plate 4. Further, as shown in FIG. 9B, a recess 48 is formed near the tip on the back surface of the reflecting plate 4.

  As will be described later, the reflecting plate 4 is superimposed on the LED module 3 with the LED element 32 of the LED module 3 facing the light guide hole 45 and the connector 33 of the LED module 3 stored in the recess 48.

  Further, as shown in the cross-sectional view of FIG. 10, the inner wall surface of the light guide hole 45 is a tapered surface having a hole diameter that increases from the rear surface side to the front surface side of the reflection plate 4. As will be described later, the inner wall surface of the light guide hole 45 is tapered such that the diameter of the light guide hole 45 increases with increasing distance from the light source mounting surface 11 side in a state where the reflector 4 is superimposed on the LED module 3 mounted on the light source mounting surface 11. It is a surface.

  The inner wall surface of the light guide hole 45 is not limited to a tapered surface, but a curved surface such as a parabolic surface, a combination thereof, a combination of a surface perpendicular to the light source mounting surface 11 and a tapered surface, or a taper having a different inclination angle. A combination of surfaces may be used. A lens may be fitted into the light guide hole 45. By designing the inner wall surface of the light guide hole 45 and using a lens, the light distribution angle of light can be controlled as desired.

  The reflection plate 4 is a molded product of white resin having reflectivity with respect to light emitted from the LED element 32, and the first side surface portion 41, the second side surface portion 42, and the arc-shaped outer peripheral portion 43 are integrally provided. ing.

  In the reflection plate 4, a reflection film 48 (FIG. 10) is formed at least on the inner wall surface of the light guide hole 45. The reflective film 48 has reflectivity with respect to the light emitted from the LED element 32, and the inner wall surface of the light guide hole 45 functions as a reflective surface. As the reflective film 48, for example, an aluminum film formed by vapor deposition can be used. Alternatively, a metal film other than aluminum may be used as the reflective film 48.

  In addition, two through holes 46 are formed in the reflecting plate 4. The through hole 46 is aligned with the through hole 34 formed in the substrate 31 of the LED module 3 described above, and the substrate 31 and the reflection plate 4 are fastened to the light source mounting surface 11 with a common screw.

  In the present embodiment, as described above, the plurality of LED modules 3 are mounted in a state of being divided in the surface direction of the light source mounting surface 11, but the reflector 4 is also divided in the surface direction of the light source mounting surface 11 in accordance with this. In such a state, it can be laid out on the light source mounting surface 11.

  The plurality of LED modules 3 have the same structure including the outer shape and the outer size, and the plurality of reflectors 4 have the same structure including the outer shape and the outer size. The individual reflectors 4 are formed so as to approximate the individual LED modules 3 and the outer shape and size.

  FIG. 13A shows the layout of the reflector 4 in the first layout in which the six LED modules 3 shown in FIG. 11 are attached to the light source attachment surface 11.

  Each of the six reflectors 4 is overlaid on each of the six LED modules 3. The through hole 46 of each reflector 4 is aligned with the through hole 34 of each LED module 3. And the through-hole 34 of each LED module 3 is aligned with the screw hole 24 shown in FIG.

  Accordingly, a screw (not shown) is screwed into the screw hole 24 through the through hole 46 of the reflector 4 and the through hole 34 of the LED module 3, so that the reflector 4 and the LED module 3 are fixed to the light source mounting surface 11. That is, the LED module 3 and the reflection plate 4 are fastened and fixed to the light source mounting surface 11 with a common screw.

  FIG. 13B shows an enlarged plan view of one reflecting plate 4 in a state of being superimposed on one LED module 3.

  The light guide hole 45 formed in the reflecting plate 4 is aligned with the position where the LED element 32 in the LED module 3 is mounted. For example, three LED elements 32 are exposed from one light guide hole 45.

  As described above, the reflection film 48 is formed on the inner wall surface of the light guide hole 45. In addition, a reflection film is also formed on the surface of the reflection plate 4 opposite to the light source mounting surface 11. The material of the reflecting plate 4 itself is also a white resin having reflectivity with respect to the light emitted from the LED element 32. The light emitted from the LED element 32 is controlled by the reflecting plate 4.

  In the first layout shown in FIG. 13A, the six reflectors 4 are arranged at equal intervals along the circumferential direction around the center of the light source mounting surface 11 in accordance with the layout of the six LED modules 3. Are lined up.

  The boss 22 provided on the outer peripheral side of the light source mounting surface 11 is fitted into the two notches 44 (FIGS. 9A and 9B) formed in the arc-shaped outer peripheral portion 43 of each reflector 4. Thereby, positioning of the reflector 4 with respect to the light source attachment surface 11 becomes easy.

  Next, FIG. 14 shows the layout of the reflector 4 in the second layout in which the four LED modules 3 shown in FIG. 12 are attached to the light source attachment surface 11.

  Each of the four reflectors 4 is overlaid on each of the four LED modules 3. The through hole 46 of each reflector 4 is aligned with the through hole 34 of each LED module 3. In the second layout, the through hole 34 of each LED module 3 is aligned with the screw hole 25 instead of the screw hole 24 used in the first layout.

  Then, a screw (not shown) is screwed into the screw hole 25 through the through hole 46 of the reflector 4 and the through hole 34 of the LED module 3, so that the reflector 4 and the LED module 3 are fixed to the light source mounting surface 11. That is, the LED module 3 and the reflection plate 4 are fastened and fixed to the light source mounting surface 11 with a common screw.

  In the second layout shown in FIG. 14, the four reflectors 4 are arranged at equal intervals along the circumferential direction around the center of the light source mounting surface 11 according to the layout of the four LED modules 3. ing.

  In the second layout, one of the two notches 44 formed in the outer peripheral portion 43 of each reflector 4 is provided on the inner peripheral side with respect to the positioning boss 22 in the first layout. Boss 23 gets stuck. Thereby, positioning of the reflecting plate 4 with respect to the light source mounting surface 11 is facilitated also in the second layout.

  The plurality of reflectors 4 are arranged in a state of being divided in the surface direction of the light source attachment surface 11 according to the LED module 3, and are attached to and detached from the light source attachment surface 11 for each reflector 4 by attaching and detaching screws. It is free. Therefore, it is possible to flexibly cope with a change in the number of LED modules 3 attached to the light source attachment surface 11 and a layout change.

  As a result, the luminous flux (brightness) and light distribution can be adjusted by changing the number and layout of the LED modules 3 and the reflectors 4 according to the purpose of use of the LED lighting apparatus 1, and the versatility is high. The LED lighting apparatus 1 can be provided.

  Also in the reflector 4, according to the layout of the LED module 3, in the first layout shown in FIG. 13 and the second layout shown in FIG. 14, the circumferential position and the radial direction on the light source mounting surface 11 are used. The position of (radiation direction) is changed.

  In the second layout illustrated in FIG. 14, the reflector 4 is closer to the center of the light source mounting surface 11 than in the first layout illustrated in FIG. 13. In order to make this possible, as described above with reference to FIG. 9A, a pair of first side surface portions 41 and a pair of first side surface portions 41 each having a relatively large opening angle on the side surface of each reflecting plate 4 are provided. The second side surface portion 42 is provided. That is, the first angle θ1 formed between the pair of first side surface portions 41 is larger than the second angle θ2 formed between the pair of second side surface portions 42.

  Therefore, the distance between the first side surfaces 41 between the reflecting plates 4 adjacent in the circumferential direction is larger than the distance between the second side surfaces 42 in the first layout shown in FIG. In the second layout, the distance is smaller than the distance between the second side surfaces 42.

  For this reason, in the second layout in which the number of reflectors 4 is reduced and closer to the center side of the light source attachment surface 11 than in the first layout in which the reflectors 4 are densely arranged in the circumferential direction of the light source attachment surface 11. The plurality of reflectors 4 can be brought closer to the circumferential direction around the center. As a result, the distance in the circumferential direction between the light guide holes 45 where the LED elements 32 face between the adjacent reflectors 4 becomes small, and it becomes easy to visually recognize the shining portion in a circular or annular shape.

  Further, in the first layout shown in FIG. 13, the bosses 23 used in the second layout are positioned between the reflectors 4 adjacent in the circumferential direction, and the arrangement of the reflectors 4 in the first layout is made. I do not disturb.

  Conversely, in the second layout shown in FIG. 14, the boss 22 used in the first layout is positioned on the outer peripheral side of the reflector 4 and does not hinder the arrangement of the reflector 4 in the second layout. . Further, the boss 21 provided near the center of the light source mounting surface 11 is hidden under the tip of the reflecting plate 4 in the second layout.

  A transparent plate 26 represented by a two-dot chain line in FIG. 2 is attached to the light source attachment surface 11 side of the main body 2. The transparent plate 26 is transmissive to the light emitted from the LED element 32, and for example, an acrylic plate can be used.

  The transparent plate 26 is screwed into a screw hole 14 a formed in a part of the rim 14 of the main body 2. A gap is formed between the transparent plate 26 and the surface of the reflection plate 4 attached to the light source attachment surface 11. For this reason, an air layer (heat insulation layer) is interposed between the light source side and the transparent plate 26, and heat from the light source side can be suppressed from being conducted to the transparent plate 26. As a result, expansion and contraction due to heat of the transparent plate 26 can be suppressed. Further, even if the transparent plate 26 is thermally expanded or contracted, the reflecting plate 4 and the transparent plate 26 are not in contact with each other and are not rubbed. For this reason, it is possible to avoid scratching the transparent plate 26 which is light and mechanically weak. Therefore, the light transmission is not hindered by the scratch.

  Next, the structure on the opposite side of the light source mounting surface 11 in the plate 13 of the main body 2 will be described.

  In the plate 13, a heat radiating surface 12 shown in FIGS. 3 and 4 is provided on the opposite side of the light source mounting surface 11, and a plurality of heat radiating fins 15 and 16 are provided on the heat radiating surface 12.

  The plurality of heat radiating fins 15 and 16 protrude to the opposite side of the light source mounting surface 11 perpendicularly to the heat radiating surface 12 (this direction is represented as the Z direction in FIG. 4). In FIG. 4, the XY plane orthogonal to the Z direction represents a plane parallel to the heat dissipation surface 12. The X direction and the Y direction are orthogonal to each other. And all the radiation fins 15 and 16 are extended in the Y direction which is the same direction.

  The X direction, Y direction, and Z direction shown in FIGS. 1, 3, 15, and 17 correspond to the X direction, Y direction, and Z direction in FIG.

  The end portions on the outer peripheral side in the Y direction of the plurality of radiating fins 15 do not protrude from the plate 13 in the plan view shown in FIG. Moreover, the line which connects the edge part of the outer peripheral side of the several radiation fin 15 draws a circle | round | yen in the planar view.

  On the heat radiating surface 12, two ribs 17 extending in the diameter direction from a through hole 13 a formed at the center of the plate 13 are provided. The two ribs 17 extend in the opposite directions from the center of the plate 13 (the center of the through hole 13a), and extend in the X direction orthogonal to the Y direction in which the plurality of heat radiation fins 15 and 16 extend. The structure on the heat radiating surface 12 side including the plurality of heat radiating fins 15 and 16 has a line-symmetric relationship with respect to the rib 17.

  As shown in FIG. 4, the radiating fin 16 provided near the side surface of the rib 17 is higher than the radiating fin 15 provided in a positional relationship sandwiching the radiating fin 16 in the Y direction (from the radiating surface 12). The protruding height is low. Moreover, the radiation fins 15 and 16 are not provided around the through-hole 13a. Therefore, a space 58 that is recessed from the upper surface of the peripheral radiation fin 15 is formed on the heat radiation surface 12 side along the diameter direction in which the ribs 17 extend. On the space 58, the power supply unit 5 is provided as shown in FIG.

  A plurality of radiating fins 15 having a protruding height higher than the radiating fins 16 and the ribs 17 provided below the space 58 are provided with the space 58 sandwiched from both sides in the Y direction.

  In this embodiment, the space 58 is used for the arrangement of the power supply unit 5 by reducing the height of some of the radiating fins 16 to form the space 58. When the heat dissipating fins are lowered, the heat dissipating property is lowered. Therefore, the portion 15a on the space 58 side of the heat dissipating fins 15 provided on both sides in the Y direction of the space 58 is made higher than the other portions to improve the heat dissipation around the space 58.

  By making only the portion 15a on the space 58 side of the heat radiating fin 15 higher than the other portions, it is possible to promote heat dissipation in the region where the low heat radiating fin 16 is provided while suppressing an increase in cost and weight.

  Further, by supporting a power supply unit 5 described later on the portion 15 a having a high protruding height, the power supply unit 5 can be further away from the LED module 3 provided on the opposite side of the heat radiating surface 12. Thereby, the heat transmitted to the power supply unit 5 from the LED module 3 side can be suppressed.

  Moreover, as shown in FIG. 15, the space | interval of the several radiation fins 15 and 16 is not constant, According to arrangement | positioning by the side of the LED module 3, the area | region where the space | interval of the radiation fins 15 and 16 is relatively narrow, and relative Are mixed with a wide area.

  FIG. 15 is a plan view illustrating the LED module 3 disposed on the light source mounting surface 11 on the opposite side of the heat radiating surface 12 with a broken line superimposed on the heat radiating surface 12 side. The two LED modules 3 arrange | positioned on the back side of the radiation fin 16 with low protrusion height are shown in figure.

  In the main body 2 having a circular outer shape, the heat exchange efficiency with the outside air is lower on the inner peripheral side than on the outer peripheral side, and the temperature tends to be relatively high. In particular, on the inner peripheral side, the temperature tends to become high in a region 100 (represented by a two-dot chain line in FIG. 15) where the protruding height of the heat dissipating fins 16 is low.

  Therefore, in the present embodiment, the heat dissipating fins 16 provided in the region 100 and the heat dissipating fins 15b extending in the Y direction continuously to the heat dissipating fins 16 are arranged most densely. Therefore, the interval between the radiation fins 16 in the region 100 and the interval between the radiation fins 15b connected to the radiation fins 16 are the narrowest.

  If the heat dissipating fins are arranged closely and the space between the heat dissipating fins is narrowed, the cost and weight increase due to the increase in the number of heat dissipating fins. For this reason, in the present embodiment, the heat radiation surface 12 side becomes relatively high in temperature, and the dense arrangement of the heat radiation fins is limited only to places where higher heat dissipation is required. Thereby, efficient heat dissipation design can be performed while suppressing an increase in cost and weight.

  Since the LED element 32 is not disposed around the center of the plate 13 (the center of the through hole 13a), no heat radiating fin is provided around the center. That is, the cost and weight are reduced by omitting the heat dissipating fins that are not necessary in terms of thermal design.

  Next, the power supply unit 5 will be described.

  FIG. 16 is a side view corresponding to FIG. 6 in a state where the power supply unit 5 is attached to the main body 2.

  17 is a plan view in which the power supply unit 5 is overlapped with a two-dot chain line on the plan view of the heat radiating surface 12 shown in FIG.

  FIG. 18 is a plan view of the inside of the case 50 in the power supply unit 5.

  The power supply unit 5 includes, for example, three bar-shaped power supply circuits 51 and a metal case 50 that covers the power supply circuits 51.

  The case 50 includes a top plate portion 52, a pair of side plate portions 53, a pair of attachment portions 55, a pair of end plate portions 54, and a bottom plate portion 56.

  The case 50 is disposed above the space 58 described above formed on the heat radiating surface 12 side of the main body 2. In this state, the top plate portion 52, the bottom plate portion 56, and the attachment portion 55 are substantially parallel to the heat radiating surface 12, and the end plate portion 54 is substantially perpendicular to the heat radiating surface 12. The side plate portion 53 is inclined between the top plate portion 52 and the attachment portion 55 and is provided between the top plate portion 52 and the attachment portion 55. The end plate portion 54 is provided at the end of the case 50 in the longitudinal direction.

  One of the three power supply circuits 51 is attached to the back of the top plate portion 52 by, for example, screwing. Each of the other two power supply circuits 51 is attached to the back of each of the pair of side plate portions 53 by, for example, screwing.

  Here, as a reference example, consider a layout in which three power supply circuits are arranged in parallel in a plane parallel to the heat dissipation surface 12. In this case, the middle one can be arranged along the diameter direction passing through the center of the main body 2, but the two on the both sides extend in a direction not passing through the center of the main body 2, and the end portion protrudes from the main body 2. there is a possibility. This can hinder miniaturization and handling of the entire luminaire.

  On the other hand, as in the embodiment, one of the three power supply circuits 51 is attached to the top plate portion 52 installed in parallel to the heat radiating surface 12, and the other two are attached to the top plate portion 52. By attaching to the inclined side plate portion 53, the three power supply circuits 51 can be densely arranged on the rib 17 extending in the diameter direction. For this reason, the three bar-shaped power supply circuits 51 can be installed without protruding from the main body 2 in a plan view, and as a result, the entire power supply unit 5 can be accommodated inside the main body 2 in a plan view. Thereby, size reduction of LED lighting fixture 1 whole and improvement of handling nature can be aimed at.

  The case 50 is provided with a pair of side plate portions 53, and a pair of attachment portions 55 project from the lower ends of the pair of side plate portions 53 in the Y direction in which the radiation fins 15, 16 extend. Further, the attachment portion 55 extends in the longitudinal direction (X direction) of the case 50.

  The mounting portion 55 is supported on a portion 15 a having a protruding height higher than that of the other portions of the radiating fin 15. For example, six of the portions 15a are formed with screw holes 81 as shown in FIG. In the plan view shown in FIG. 3, three screw holes 81 exist in one region across the rib 17, and three screw holes 81 exist in the other region. These three screw holes 81 are positioned in a line-symmetric relationship with respect to the rib 17. Three screw holes 81 provided in one region sandwiching the rib 17 are arranged at equal intervals in the X direction. The screw hole 81 located in the middle of them is located on a straight line passing through the center of the main body 2. Three screw holes 81 provided in the other region sandwiching the rib 17 are also arranged at equal intervals in the X direction, and the screw hole 81 located in the middle thereof is located on a straight line passing through the center of the main body 2. .

  The mounting portion 55 of the case 50 supported on the portion 15a of the heat radiation fin 15 in which the screw hole 81 is formed is attached to the heat radiation fin 15 by a screw 57 (shown in FIG. 17) screwed into the screw hole 81. Fixed. In the example shown in FIG. 17, among the six screw holes 81, the screws 57 are fastened to the three screw holes 81 that have a relation of forming a triangle in plan view. That is, the case 50 is fixed to the heat radiating fins 15 at three points.

  In this state, the bottom plate portion 56 of the case 50 located on the inner side of the attachment portion 55 is positioned above the radiation fins 16 that are lower than the radiation fins 15. That is, the bottom plate portion 56 of the case 50 is separated from the heat radiation fin 16, and a space 58 exists between the bottom plate portion 56 and the heat radiation fin 16. That is, the three power supply circuits 51 accommodated in the case 50 are provided on the heat radiation fins 16 lower than the other heat radiation fins 15 with the space 58 therebetween.

  For this reason, it can suppress that the heat from the LED module 3 side is transmitted to the power supply circuit 11 through the radiation fin 16. In other words, in the present embodiment, the main body 2 to which the LED module 3 is attached and the power supply unit 5 are integrated to reduce the size of the entire LED lighting apparatus 1 and the heat dissipation of the power supply unit 5 is not impaired.

  In the radiating fin 15, the portion 15 a where the mounting portion 55 of the case 50 is supported is made higher than the other portions, thereby suppressing the increase in the cost and weight due to the increase in the height of the radiating fin 15 as a whole. It can be further away from the LED module 3, which is advantageous for heat dissipation of the power supply unit 5.

  The distance between the light source mounting surface 11 to which the LED module 3 is mounted and the bottom plate portion 56 of the case 50 of the power supply unit 5 is preferably 80 (mm) to 200 (mm). If the distance is smaller than 80 (mm), there is a concern that the temperature of the electronic component of the power supply circuit 51 exceeds the rated temperature. If the distance is greater than 200 (mm), the sense of unity between the main body 2 and the power supply unit 5 is impaired, and there is a concern that the assemblability including the wiring and the like may be deteriorated and miniaturization may be hindered.

  The power supply unit 5 extends in the X direction orthogonal to the Y direction in which the heat radiating fins 15 extend in the plan view of FIG. 17 when the main body 2 is viewed from the heat radiating surface 12 side. For this reason, the air convection formed by the radiation fins 15 is efficiently guided to the entire side surface of the power supply unit 5 extending in the longitudinal direction (X direction), and the power supply unit 5 can be effectively air-cooled.

  The power supply unit 5 extends in the diameter direction of the heat radiating surface 12 on a straight line (on the rib 17) passing through the center of the heat radiating surface 12. That is, by arranging the power supply unit 5 so as to extend along the diameter direction on the circular heat radiating surface 12 that can take the longest length, the main body can be seen in a plan view without protruding the power supply unit 5 from the main body 2. The power supply unit 5 can be accommodated inside 2. As a result, the entire LED lighting apparatus 1 can be reduced in size, and the handleability can be improved.

  A terminal block (not shown) is provided on, for example, the top plate 52 of the case 50 of the power supply unit 5. FIG. 1 shows a terminal block cover 71 that covers the terminal block. The terminal block has a terminal to which a power circuit 51 accommodated in the case 50 is electrically connected through a cable.

  The power supply circuit 51 is connected to the LED module 3 shown in FIG. 7 by the cable 95 shown in FIG. 18 through the notch or through hole formed in the bottom plate portion 56 of the case 50 and the through hole 13a formed in the center of the main body 2. The connector 33 is connected. Thereby, electric power is supplied from the power supply circuit 51 to the LED element 32 of the LED module 3, and the LED element 32 emits light. For example, one power supply circuit 51 supplies power to the two LED modules 3. The cable 95 is covered with, for example, frost.

  The terminals provided on the terminal block are electrically connected to an external power source such as a commercial power source through a cable (not shown).

  Next, the arm 6 which is an attachment member for attaching the LED lighting apparatus 1 to the ceiling or a lifting device suspended from the ceiling will be described.

  The arm 6 is attached to the main body 2. As shown in FIG. 4, a pair of arm attachment portions 75 are provided on the outer peripheral side of both ends of the rib 17 in the longitudinal direction on the heat radiating surface 12 side of the main body 2. The arm attachment portion 75 is provided in a plate shape and protrudes in the same Z direction as the heat radiation fins 15 and 16. A screw hole 76 is formed in the arm attachment portion 75.

  As shown in FIG. 1, the arm 6 is provided integrally with a horizontal plate portion 61 facing the top plate portion 52 of the case 50 of the power supply unit 5 and both ends in the longitudinal direction of the horizontal plate portion 61. And a pair of vertical plate portions 62 extending downward from both ends of 61.

  A through hole 64 is formed in the vertical plate portion 62. The arm 6 is attached to the main body 2 by being screwed into a screw hole 76 formed in the arm attachment portion 75 of the main body 2 through the through hole 64. The arm 6 is detachable from the main body 2.

  For example, a lighting fixture attached to a high ceiling such as a gymnasium is large and heavy. Therefore, in order to directly attach such a lighting fixture to the ceiling, it is necessary to increase the thickness of the mounting portion in order to ensure the strength of the mounting portion on the lighting fixture side. This increases the weight of the entire lighting fixture. If it becomes heavy and heavy, construction becomes difficult.

  On the other hand, in the present embodiment, the arm 6 is attached to the ceiling, the lifting device, and the like, and the main body 2 is suspended from the arm 6, thereby ensuring the strength of the attachment portion with respect to the ceiling and the like. Can be made lighter. For example, two mounting holes 63 are formed in the horizontal plate portion 61 of the arm 6, and the lifting device suspended from the ceiling, for example, is attached to the mounting holes 63.

  The vertical plate portion 62 of the arm 6 is superposed in surface contact with the outer surface of the arm mounting portion 75 provided in the main body 2. Thereby, the thermal conductivity from the main body 2 side to the arm 6 can be improved, and the heat dissipation through the arm 6 can be enhanced. That is, the arm 6 can function not only as an attachment member for attaching the LED lighting apparatus 1 to a ceiling or the like, but also as a heat dissipation member.

  The horizontal plate portion 61 and the vertical plate portion 62 of the arm 6 are made of a metal plate such as iron from the viewpoint of ensuring strength. By forming the coating 91 having a higher emissivity (heat dissipation) than the metal plate material on the surface of the metal plate, the heat dissipation of the arm 6 can be further increased.

  As such a film 91, for example, a resin film can be used. Further, the surface of the resin film is roughened to increase the surface area, and the heat dissipation of the arm 6 can be further improved. When an aluminum plate, for example, is used for the metal plate of the arm 6, the surface thereof may be black anodized to form an oxide film as a film that improves heat dissipation (radiation rate).

  As shown in FIG. 4, the arm attachment portion 75 of the main body 2 is provided in parallel to the heat radiation fins 15 and 16 and is parallel to the heat radiation fins 15 and 16. The vertical plate portion 62 of the arm 6 attached in surface contact with the arm attachment portion 75 is also parallel to the radiation fins 15 and 16. That is, the vertical plate portion 62 of the arm 6 does not block the opening on the outer peripheral side in the gap between the radiating fins 15.

  The horizontal plate 61 connecting the pair of vertical plates 62 extends in the X direction perpendicular to the Y direction in which the heat radiation fins 15 extend in the space above the power supply unit 5. The lateral plate portion 61 of the arm 6 does not block the space above the heat radiation fin 15 having a protruding height higher than that of the heat radiation fin 16 located below the power supply unit 5.

  Thus, since the arm 6 exists in a direction that does not interfere with the convection of the air formed by the radiation fins 15, the heat dissipation of the heat generated from the LED module 3 is not impaired by the arm 6. Rather, as described above, the heat dissipation of the entire LED lighting apparatus 1 is enhanced by actively using the arm 6 as a radiator.

  The power supply unit 5 may have a configuration without the case 50, or may have a structure in which the power supply circuit 51 is supported on the radiation fin and fixed to the radiation fin.

  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.

  DESCRIPTION OF SYMBOLS 1 ... LED lighting fixture, 2 ... Main body, 3 ... LED module, 4 ... Reflector plate, 5 ... Power supply unit, 6 ... Arm, 11 ... Light source mounting surface, 12 ... Heat radiation surface, 15, 16 ... Heat radiation fin, 21-23 ... Boss, 24, 25 ... Screw hole, 31 ... Substrate, 32 ... LED element, 36 ... Wiring pattern, 41 ... First side part, 42 ... Second side part, 45 ... Light guide hole, 48 ... Reflective film 50 ... Power supply case, 51 ... Power supply circuit, 55 ... Mounting portion of the power supply unit, 61 ... Horizontal plate portion of the arm, 62 ... Vertical plate portion of the arm, 91 ... Film, θ1 ... First angle, θ2 ... Second Angle of

Claims (2)

A body having a through hole in the center of the light source mounting surface;
A light source mounting comprising: a substrate; an LED (Light Emitting Diode) element mounted on the substrate; and a connector provided on the through hole side of the surface of the substrate on which the LED element is mounted. A plurality of LED modules attached around the through hole of the surface;
The hole of the plurality of LED modules covering the surface of the substrate on which the LED element is mounted and exposing the LED element is opposite to the through hole side and the hole is formed. A recess that houses the connector formed so as to enter the region side, and a reflector ,
A plurality of heat dissipating fins formed on the opposite side of the light source mounting surface of the main body,
With
A cable for supplying power to the LED module is wired through the through hole of the light source mounting surface.   The LED lighting apparatus according to claim 1, wherein the power supply unit for lighting the LED module is attached through a screw hole formed in the heat radiating fin.

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