JP7294400B2 - lighting equipment - Google Patents

Description

Article 30, Paragraph 2 of the Patent Act applies Exhibition name: Nationwide Special Agency Presidents' Meeting Date: November 14, 2017

Embodiments of the present invention relate to lighting fixtures using light emitting modules.

2. Description of the Related Art Conventionally, there are lighting fixtures for high ceilings, which are used to illuminate spaces with high ceilings, such as facilities.
This lighting fixture uses a light-emitting module having a light-emitting element, and the light-emitting module is attached to the lower surface side of the radiator. A plurality of radiating fins for radiating heat generated by the light emitting element are protruded from the upper surface side of the radiator. The radiator is supported by a main body chassis arranged above the radiator, and a power supply section is arranged on the main body chassis. An arm for installation on the ceiling or the like is connected to the main body chassis.

Such a lighting fixture is desired to have a simple structure, light weight, and good assembling efficiency.

Japanese Patent Application Laid-Open No. 2013-201080

The problem to be solved by the present invention is to provide a lighting fixture that can be simplified and reduced in weight and that is easy to assemble.

A lighting fixture according to an embodiment of the present invention includes a light-emitting module, a radiator having the light-emitting module arranged on one side, and an engaging portion that elastically engages with the radiator. A translucent cover main body attached to the lower surface side, and a cover body fall prevention portion formed by bending from both sides of the radiator toward the one surface side are provided, and the cover body fall prevention portion is provided on the lower surface side of the cover body. and a pair of arm portions attached to the radiator so as to overlap and not overlap with the engaging portion .

ADVANTAGE OF THE INVENTION According to this invention, the lighting fixture which can be simplified and reduced in weight and can be assembled easily can be provided.

It is a perspective view of the lighting fixture which shows one Embodiment. It is a perspective view at the time of assembling the power supply part of the lighting fixture same as the above. Fig. 3 is an exploded perspective view of the same lighting fixture; It is sectional drawing of a lighting fixture same as the above. It is the perspective view which removed the power supply part of the lighting fixture same as the above. It is a perspective view of the radiator of the lighting fixture same as the above. Fig. 2 is a perspective view of one fin of the radiator of the same lighting fixture; It is a perspective view of a reflector and a translucent cover of the lighting fixture same as the above.

An embodiment will be described below with reference to the drawings.

As shown in FIG. 1, the luminaire 10 is a high-ceiling luminaire used for illuminating a space with a high ceiling such as a facility.

As shown in FIGS. 3 and 4, the lighting fixture 10 includes a light-emitting module 11, a radiator 12 on which the light-emitting module 11 is arranged, a reflector 13 arranged opposite the light-emitting module 11 to control light distribution, a light-emitting module A translucent cover (lower surface cover) 14 that covers 11 and reflector 13, an arm 15 that supports radiator 12, a power supply unit 16 that supplies power to light emitting module 11, and the like are provided.

The light-emitting module 11 includes a substrate 20 and a plurality of light-emitting elements 21 mounted on one surface of the substrate 20. As shown in FIG.

As shown in FIG. 3, the substrate 20 is formed in a substantially quadrangular shape (for example, a substantially square shape) in which the four corners or the vicinity of the center of each side or the vicinity of the entire center are cut off. A pattern for mounting the light emitting element 21 is provided on one surface of the substrate 20 . The substrate 20 is attached so that the other surface of the substrate 20 is in close contact with the lower surface of the radiator 12 via a heat radiation sheet 22 having insulating properties. For attaching the substrate 20, a plurality of insulating substrate pressers 23 for pressing the substrate 20 and a plurality of screws (not shown) for tightening and fixing the substrate 20 to the radiator 12 via the substrate pressers 23 are used.
A wiring hole 20a is formed in the center of the substrate 20. As shown in FIG. Fitting portions 20b and 20c are formed around the four corners of the board 20 and the wiring hole 22a, into which the board retainer 23 is fitted. The fitting portions 20b at the four corners of the substrate 20 are groove-shaped, and the fitting portions 20c around the wiring holes 22a are hole-shaped. A semi-circular groove 20d is formed in the center of each side of the substrate 20 to allow the reflector 13 to be attached to the radiator 12. As shown in FIG. A wiring hole 22a is also formed in the center of the heat dissipation sheet 22. As shown in FIG. A light source side connector (not shown) is mounted on the pattern on one surface of the substrate 20 .

A substrate retainer 23 made of an insulating member such as resin is provided separately from the reflector 13 . As a result, dimensional changes and the like due to heat from the light emitting element 21 are suppressed even during long-term use.

The fitting portions 20b and 20c and the groove portion 20d may have any shape. By increasing the area of the fitting portions 20b and 20c formed by cutting the substrate 20 and the groove portion 20d, the weight of the substrate 20 can be reduced. Alternatively, the shape of the substrate 20 may be simplified by reducing the areas of the fitting portions 20b and 20c and the groove portion 20d, thereby facilitating manufacture and assembly.

A surface-mounted LED, for example, is used as the light-emitting element 21 . The light emitting elements 21 are mounted on a pattern on one surface of the substrate 20 in a predetermined arrangement. The light-emitting element 21 is divided and mounted on a plurality of mounting regions of the substrate 20, and a plurality of light-emitting portions 24 are configured. In this embodiment, four light-emitting portions 24 are configured by being mounted in four mounting areas corresponding to the four corners of the substrate 20 .
The light emitting part 24 is a region in which, for example, a plurality of light emitting elements 21 are arranged in a substantially circular shape. Note that the light emitting element 21 is not limited to an LED, and may be another light emitting element such as an organic EL.

Also, as shown in FIGS. 1 to 6, the radiator 12 is made of a metal material such as aluminum. The radiator 12 has a base 26 and a plurality of fins 27 protruding from the upper surface of the base 26 . In this embodiment, the base 26 and the radiation fins 27 are formed separately, but the base 26 and the fins 27 may be integrally formed by, for example, extrusion molding or a 3D printer.

The base 26 includes a rectangular (for example, square) and flat base plate portion 28, one side plate portion 29 bent upward from one opposite side edge of the base plate portion 28, and the base plate portion 28. The other side plate portion 30 is bent upward from the other opposite side edges. The radius of curvature of the curved surface portions of the one side plate portion 29 and the other side plate portion 30 bent upward from the base plate portion 28 may be different. For example, the curvature radius of the curved surface portion where one side plate portion 29 is bent upward from the base plate portion 28 is larger than the curvature radius of the curved surface portion where the other side plate portion 30 is bent upward from the base plate portion 28. It may be made large. Further, the substrate 20 of the light emitting module 11 is attached to the lower surface of the base plate portion 28 with the heat dissipation sheet 22 interposed therebetween.

A wiring hole 26a is formed in the center of the base plate portion 28. As shown in FIG. One of the side plate portions 29 is formed with a connecting hole 29a for connecting a wire for preventing vibration during installation, a wire for preventing falling, and the like.

A plurality of crimping projections 31 are provided on the upper surface of the base 26 so as to correspond to the fixed positions of the fins 27 . The fixed position of each fin 27 is on both sides of the wiring hole 26a in the center of the base 26 between one of the side plate portions 29 on both sides.

The fins 27 are arranged in parallel on the upper surface of the base 26 between one of the side plate portions 29 on both sides. The fins 27, as shown in FIGS. 6 and 7, have a fixed portion 32 fixed to the upper surface of the base 26 and a pair of fin portions 33 bent from the fixed portion 32 so as to face each other. It is formed in a U shape.

The fixed portion 32 is provided with a plurality of through holes 32a through which the plurality of projections 31 projecting from the upper surface of the base 26 pass. The fins 27 are fixed to the base 26 by crimping the protrusions 31 passing through the through holes 32a from above against the upper surface of the fixing portion 32. As shown in FIG.

An opening 34 is formed from the fixing portion 32 to the lower edges of the fins 33 contacting the base 26 to avoid interference with a projection (not shown) projecting from the upper surface of the base 26 . The openings 34 are formed in shapes such as rectangles, semicircles, and polygons, for example. Examples of protrusions include screws for fixing the light emitting module 11, the reflector 13, and the translucent cover 14 to the lower surface side of the base 26, respectively. Moreover, the projecting object may be a structural member (not shown) that serves as a mounting position for mounting another component to the radiator 12, or another heat dissipating member (not shown) different from the fin portion 33, or the like. Furthermore, a plurality of openings 35 are formed below each fin portion 33 . The opening 35 is formed in a shape such as a rectangle or ellipse that is elongated in the direction along the lower edge of the fin portion 33, for example. The openings 34 and 35 are displaced in the direction along the lower edge of the fin portion 33 . That is, the openings 34 and 35 are arranged scattered over the entire area of the fin 27 in the width direction. These openings 34 and 35 function as ventilation openings through which air flows.

For example, since the opening 34 is provided at a portion in contact with the base 26 on which the heat-generating light-emitting element 21 is arranged, the heat from the base 26 can be directly dissipated into the outside air, and a high heat dissipation effect can be expected. In addition, since the opening 35 is formed so as to be surrounded by the fins 33, the surface area of the fins 33, which have conducted heat from the base 26, can be increased to contact the outside air, and efficient heat dissipation can be expected. Further, as another embodiment, the openings 34 and 35 may be arranged side by side so as to partially or more overlap in the width direction, which is the direction along the lower edge of the fin portion 33 . Also, the openings 34 may be formed in a rectangular or oval shape that is long in the rising direction of the fins 33, for example. The openings 35 may be located not only on the lower side of the fin section 33 but also on the center side or the upper side thereof, or may be arranged in two or more rows in the direction in which the fin section 33 rises.

A concave portion 38 is formed in the center of the upper edge of the fin portion 33 . The recess 38 is provided so that the holding member 37 can hold an intermediate portion of the wiring 36 that electrically connects the light emitting module 11 and the power supply unit 16, for example. For example, the recess 38 has a protrusion 39 projecting upward from the vicinity of the center and cutouts 40 provided on both sides of the protrusion 39 . At this time, a wide retaining portion is provided on the tip end side of the convex portion 39 . A binding band is used as the holding member 37 . The holding member 37 is hooked on the protrusions 39 through the cutouts 40 on both sides, and holds the wires 36 by tightening them against the protrusions 39 . The holding member 37 holds the wiring 36 without falling off from the tip side of the protrusion 39 by the retaining portion on the tip side of the protrusion 39 .

In addition, the concave portion 38 is not a cutout from the upper edge of the fin portion 33, for example, but a mouth-shaped hole is provided on the upper side of the fin portion 33 as a cutout portion 40 in two places side by side in the direction of the upper edge of the fin portion 33. A portion formed between the two cutouts 40 may be configured as a protrusion 39 so that the wiring 36 can be held by the holding member 37 .

In addition, since the concave portion 38 is provided above the fin portion 33, it serves to expand the surface area of the upper portion of the fin portion 33, so that the heat from the base 26 conducted upward along the fin portion 33 can be efficiently dissipated. expected to be effective. In addition, the concave portion 38 can also be expected to have the effect of efficiently ventilating outside air to the vicinity of the upper center of the fin portion 33 .

Common parts are used for the plurality of fins 27 . That is, all the fins 27 have a fixing portion 32 and a pair of fin portions 33, and also have openings 34 and 35 and recesses 38. As shown in FIG.

Therefore, the plurality of fins 27 have a plurality of openings 34, a plurality of openings 35, and a plurality of recesses 38 which are formed to penetrate to the innermost fin portion 33 when viewed from the plane side of the fin portion 33. As shown in FIG. By having the plurality of openings 34, the plurality of openings 35, and the plurality of recesses 38, the plurality of fins 27 can take in the flow of outside air so as to pass through the fins 27, so that a high heat dissipation effect can be expected.

The fins 27 are arranged on both sides of the base 26 between the side plate portions 29 on both sides except for the central region where the wiring hole 26a of the base 26 is provided. That is, the center region of the base 26 is not provided with the fins 27, and the wiring hole 26a of the base 26 is opened.

The fins 27 are not limited to having a substantially U-shaped cross section, but may have a substantially L-shaped cross section having the fixing portion 32 and one fin portion 33, or may have a flat plate shape having only the fin portion 33. FIG. In the case of a flat plate, a plurality of slits may be provided in the upper surface of the base 26, and each fin 27 may be inserted into each slit and fixed.

Further, as shown in FIGS. 3, 4 and 8, the reflector 13 includes a plurality of reflecting cylindrical portions 43 arranged opposite to the respective light emitting portions 24 of the light emitting module 11, and a plurality of mounting portions attached to the base 26. Equipped with 44. In this embodiment, the plurality of reflecting cylinder portions 43 and the plurality of mounting portions 44 are integrally formed, but the plurality of reflecting cylinder portions 43 are formed separately, and the mounting portion 44 is provided for each reflecting cylinder portion 43. good too.

The reflecting tube portion 43 is formed in a cylindrical shape that opens vertically and widens downward. A reflecting surface 43a having a high reflectance such as a mirror surface is formed on the inner surface of the reflecting tube portion 43. As shown in FIG. Each reflecting tube portion 43 is arranged at a position corresponding to each light emitting portion 24 of the light emitting module 11, and the lower side of the adjacent reflecting tube portion 43 is integrally provided. An edge portion 43b protrudes upward from a lower end peripheral portion located outside the reflecting cylinder portion 43, and the edge portion 43b is integrally provided around the outer circumference of the reflector 13. As shown in FIG. Furthermore, a plurality of ribs 43c are provided between the outer surface of each reflecting tube portion 43 and the inner side of the edge portion 43b. Such a structure ensures the strength of the reflector 13 . The reflecting cylinder part 43 receives the light from the light emitting part 24 of the light emitting module 11 through the upper opening and controls the light distribution of the light emitted from the lower opening.

In addition, for example, the reflecting cylinder portion 43 may not be provided, and in that case, the structure becomes simpler, so that there is an effect that reduction in weight, reduction in manufacturing cost, and simplification of assembly can be expected.

Further, a lens member (not shown) provided so as to cover the light emitting element 21 may be provided instead of the reflecting tube portion 43 . In that case, effects such as weight reduction, miniaturization, and improvement in light distribution can be expected.

The mounting portion 44 is provided at the upper end of the boss portion 45 raised from between the adjacent reflecting cylinder portions 43, and is arranged on the lower surface side of the heat sink 12 (heat radiation sheet 22) through the groove portion 20d of the substrate 20. It is fixed to the underside of the base 26 by screws.

The mounting portion 44 is provided at the upper end of a boss portion 45 raised from between the adjacent reflecting cylinder portions 43 . The mounting portion 44 protrudes upward by the thickness of the substrate 20 from the reflecting cylinder portion 43, and is arranged on the lower surface side of the base 26 of the radiator 12 through the groove portion 20d of the substrate 20 with the heat dissipation sheet 22 interposed therebetween. It is fixed to the bottom side of the base 26 by screws.

In addition, the light-transmitting cover 14 includes a light-transmitting cover body 48 that covers the light-emitting module 11 and the reflector 13 and is attached to the lower surface side of the heat sink 12, and a light-transmitting cover body 48 that engages with the side portion of the heat sink 12. are provided with engaging portions 49a and 49b for positioning. This translucent cover 14 is integrally formed.

The translucent cover main body 48 includes a lower surface portion 50 covering the lower surface side of the light emitting module 11 and the reflector 13, a side surface portion 51 covering the side surface side of the light emitting module 11 and the reflector 13, and a base provided on the upper edge of the side surface portion 51. It has a frame-shaped mounting edge 52 that is mounted on the lower surface side of 26 . The lower surface portion 50 is formed in a planar shape, and the side surface portion 51 is formed in a shape along the shape of the side surface of the reflector 13 . The shape of the side surface portion 51 includes a plurality of curved surface portions 51a along the side surface of each reflecting cylinder portion 43 of the reflector 13, and flat portions (recessed portions) along the side surface (boss portion 45) between the adjacent reflecting cylinder portions 43. ) 51b. The curved surface portions 51a are arranged at the four corner positions of the side surface portion 51, and the flat surface portions 51b are arranged at recessed positions between the adjacent curved surface portions 51a. Moreover, the mounting edge portion 52 is formed in a rectangular frame shape corresponding to the shape of the lower surface of the base 26 of the radiator 12 . The mounting edge portion 52 has four corner portions protruding laterally from the curved surface portions 51 a of the side surface portion 51 , and the central portion of each side of the mounting edge portion 52 is aligned with the plane of the side surface portion 51 . It protrudes laterally from the portion 51b. A protruding portion of the mounting edge portion 52 is fixed to the lower surface of the base 26 of the radiator 12 with a screw (not shown).

The engaging portions 49a and 49b project upward from four sides of the attachment edge portion 52 of the light-transmitting cover main body 48. As shown in FIG.
The engaging portion 49a is arranged corresponding to the position of one side plate portion 29 of the radiator 12, and the engaging portion 49b corresponds to the position of the other side plate portion 30 of the radiator 12. It is arranged as The engaging portions 49a and 49b are elastically engaged with the outside of the pair of one side plate portions 29 and the pair of other side plate portions 30 of the radiator 12 to position the translucent cover main body 48 with respect to the radiator 12. Hold. The engaging portions 49a and 49b are spaced apart from each other on each side of the mounting edge portion 52 of the translucent cover main body 48 at two positions corresponding to the positions of the curved surface portions 51a.

The curved portions of the engaging portions 49a and 49b protruding upward from the mounting edge portion 52 are formed by a pair of side plate portions 29 and a pair of side plate portions 30 protruding upward from the base 26 of the radiator 12. may be engaged with the curved surface portion of the In this case, the curved surface portion of one of the pair of side plate portions 29 and the curved surface portion of the other side plate portion 30 of the pair are engaged with the curved surface portion of the pair of side plate portions 29 corresponding to the difference in curvature radius between the curved surface portion of the pair of side plate portions 29 and the curved surface portion of the other side plate portion 30 of the pair. The curvature radius of the engaging portion 49a and the curved surface portion of the engaging portion 49b that engages with the curved surface portion of the other side plate portion 30 may be formed so as to be different. For example, the radius of curvature of the engaging portion 49a that engages with one side plate portion 29 of the pair may be larger than the radius of curvature of the engaging portion 49b that engages with the other side plate portion 30 of the pair. good. According to this configuration, it can be expected that the engagement strength of the light-transmitting cover main body 48 becomes stronger than when the radiator 12 is engaged with only the engaging portions 49a and 49b having the same radius of curvature. When the light-transmitting cover main body 48 is attached to the radiator 12, if the light-transmitting cover main body 48 is rotated by 90°, the radius of curvature of the one side plate portion 29 and the other side plate portion 30 of the heat radiator 12 becomes Since the different engaging portions 49a and 49b are at the engaging positions, the correct mounting direction of the light-transmitting cover main body 48 can be easily recognized.

The engaging portions 49a and 49b are, for example, two side portions (one side plate portion 29) on the mounting side of the radiator 12 to which the arm 15 is attached and both side portions (the other side plate portion 29) on the non-mounting side perpendicular to these mounting side portions. Of the side plate portions 30), it may be provided only on both sides of the mounting side (one side plate portion 29), or may be provided only on both sides of the non-mounting side (the other side plate portion 30). .

In addition, if the engaging portions 49a and 49b are configured to prevent the light-transmitting cover 14 from falling in the direction of gravity, both sides of the mounting side (one side plate portion 29) and/or both sides of the non-mounting side It does not have to be engaged with (the side plate portion 30), and it does not have to be elastically engaged with the curved surface.

For example, the pair of engaging portions 49a (or 49b) may have claws (not shown) that protrude upward from the mounting edge 52 of the translucent cover body 48 and then extend toward the inside of the lighting device 10. The light-transmitting cover 14 may be engaged with the heat sink 12 by sliding the claw portion on the edge of the base 26 . Alternatively, the pair of engaging portions 49a (or 49b) protrude upward from the mounting edge portion 52 of the light-transmitting cover body 48, and are formed to have downward barbs at the protruding ends. By penetrating through a hole or the like (not shown) formed in the back, it may be configured to be able to prevent falling by turning.

The translucent cover 14 may be a clear cover with good light transmissivity or a diffusion cover that diffuses light. Although the entire translucent cover 14 has translucency in this embodiment, it is sufficient that at least the lower surface portion 50 has translucency. 49 etc. may be non-permeable. Also, the translucent cover 14 may be formed integrally with a lens or the like capable of optically controlling the light emitted from the light emitting element 21 .

A leg portion 53 protrudes from the outer peripheral edge of the lower surface portion 50 of the translucent cover 14 . Due to the protruding leg portions 53, when the lighting device 10 is placed on a floor surface or the like, the leg portions 53 come into contact with the floor surface or the like, and the surface of the lower surface portion 50 comes into contact with the floor surface or the like and is damaged. to prevent

The translucent cover 14 closes the lower surface side of the radiator 12 to which the light emitting module 11 and the reflector 13 are attached, and prevents insects, dust, and the like from entering.

Since the wiring hole 26a through which the wiring 36 is passed is opened in the base 26, the wiring hole 26a also needs to be closed in order to prevent insects, dust, etc. from entering the translucent cover 14. . In order to close the wiring hole 26a, a packing 56 through which the wiring 36 passes and a packing retainer 57 for attaching the packing 56 to the base 26 are used. The packing 56 and the packing retainer 57 are attached from the bottom side of the base 26 . The packing retainer 57 is fixed to the base 26 via the packing 56 with a screw (not shown).

1 to 5, the arm 15 includes a pair of arm portions 60 attached to both sides of the radiator 12, and an arm mounting portion connected between the upper ends of these arm portions 60 so as to be able to adjust the angle. It has 61. It should be noted that the arm 15 may be attached directly to the base 26 instead of the both sides rising upward.

The arm portion 60 is made of, for example, a metal plate such as aluminum. A plurality of insertion holes 62 are provided on the lower end side of the arm portion 60 . The lower end side of the arm portion 60 is arranged on both sides of the heat sink 12, that is, on the outer side portion of one side plate portion 29, and is attached to the heat sink by fastening means including a plurality of screws, bolts, etc. (not shown) inserted through the insertion holes 62. It is fixed to both sides of 12, that is, one side plate portion 29 .

A fulcrum hole 63 and an adjustment hole 64 for connecting with the arm mounting portion 61 are provided on the upper end side of the arm portion 60 so as to be separated vertically. At the lower end side of the arm portion 60, a fall prevention portion 65 arranged on the lower surface side of the translucent cover 14 (mounting edge portion 52) is formed by bending. The fall prevention part 65 is arranged on the lower surface side of the mounting edge 52 that enters the recessed portion between the adjacent curved surface parts 51a of the translucent cover 14, faces the flat part 51b, and protrudes outward from the upper end of the flat part 51b. It is

A pair of positioning portions 66 for positioning the power source portion 16 at a predetermined mounting position A between the pair of arm portions 60 are provided facing each other at a vertical intermediate position of the pair of arm portions 60, and a predetermined mounting position is provided. A plurality of insertion holes 67 are provided at the position A for mounting the power source section 16 while supporting it from the horizontal direction with a plurality of fastening members S (see FIG. 1) such as screw bolts.

The positioning portion 66 has cut and raised pieces 68 cut and raised from both side edges of the arm portion 60 . By placing the power supply section 16 on the four cut-and-bent pieces 68 of the pair of arm sections 60, the power supply section 16 can be positioned at the predetermined height of the mounting position A and supported.

By providing the positioning part 66, the power supply part 16 is fixed in the horizontal direction by using the fastening member S in the insertion hole 67, and the power supply part 16 is placed on the cut-and-bent piece 68 to be fixed in the direction of gravity. be. By fixing the power supply unit 16 from a plurality of directions in this manner, a main body chassis unlike the conventional one is not required, and the lighting fixture 10 can be greatly reduced in weight and simplified.

The positioning portion 66 is not limited to the cut-and-bent piece 68, and may be a plurality of mountain-shaped protrusions projecting from the inner surface of the arm portion 60, a stepped portion formed by bending the arm portion 60, or the like. Also, the positioning portion 66 may be provided in the arm portion 60 as a notch instead of a projecting portion. In that case, the power supply section 16 may have a projection that engages with the notch of the positioning section 66 . Alternatively, of the pair of arm portions 60, the positioning portion 66 provided on one arm portion 60 and the positioning portion 60 provided on the other arm portion 60 may have different shapes. Further, a plurality of positioning portions 66 may be arranged side by side in the longitudinal direction of the arm portion 60 . In this case, since the position of the power supply unit 16 can be determined from a plurality of directions, the power supply unit 16 can be easily arranged, and the power supply unit 16 can be fixed more stably and firmly.

For example, of the pair of arm portions 60, the positioning portion 66 provided on one arm portion 60 is provided separately in the upper and lower stages in the longitudinal direction of the arm portion 60, and the upper positioning portion 66 is provided on the power supply portion 16. The lower positioning part 66 is formed as a cut-and-raised piece 68 whose upper surface is in contact with the bottom surface of the power supply unit 16. As shown in FIG. The upper positioning portion 66 provided on the other arm portion 60 and corresponding to the positioning portion 66 of the one arm portion 60 is formed as a cut-and-raised piece 68 whose lower surface contacts the upper surface of the power supply portion 16. The lower positioning portion 66 provided on the arm portion 60 and corresponding to the positioning portion 66 of one arm portion 60 may be formed as a notch that engages with a projection provided on the power supply portion 16 .

Also, the positioning portion 66 may be formed to determine the position of a member other than the power source portion 16 .
For example, a configuration in which a sensor that performs wireless communication or the like, a top plate on which other members are loaded, or the like is similarly positioned by the positioning portion 66 may be used.

The arm installation portion 61 is made of a metal plate. The arm installation portion 61 has an installation portion 69 and support portions 70 bent downward from both ends of the installation portion 69 . The installation portion 69 is provided with a wiring hole 71a through which a power supply line for supplying power to the power supply portion 16 is inserted, and a plurality of installation holes 71b for installation in an installed portion such as a ceiling. The support portion 70 is provided with a fulcrum hole 72 and an adjustment groove 73 for connecting with the arm portion 60 . The adjustment groove 73 is provided in an arc shape centering on the fulcrum hole 72 .

The support portions 70 on both sides of the arm installation portion 61 are arranged outside the arm portion 60, and support shaft means (for example, a bolt and a nut), and are fastened and fixed by fastening means (for example, bolts and nuts) inserted through the adjustment groove 73 of the arm mounting portion 61 and the adjustment hole 64 of the arm portion 60 (not shown). With the fastening means loosened, the angle of the arm part 60 can be adjusted with respect to the arm installation part 61 installed on the installation part such as the ceiling. For example, the angle can be adjusted so as to be in an arbitrary direction such as directly below. That is, the arm 15 has an angle adjuster 70a for adjusting the irradiation angle.

The support portion 70 is formed shorter than the arm portion 60 in the longitudinal direction, for example. That is, the fulcrum hole 72 and the adjustment groove 73, which are the angle adjusting portion 70a for adjusting the irradiation angle of the arm portion 60, the lighting device 10, and the light emitting module 11, are provided above the power supply portion 16. FIG. In this case, since the positioning portion 66 is provided, there is an effect that the power supply portion 16 can be quickly arranged at a position where it does not interfere with the arm installation portion 61 and the support portion 70 even if the angle is adjusted.

Further, for example, as another embodiment, the support portion 70 may be formed longer than the arm portion 60 in the longitudinal direction, and the fulcrum hole 72 and the adjustment groove 73 for adjusting the angle may be provided below the power supply portion 16 .
In this case, the insertion hole 67 and the positioning portion 66 are provided between the arm installation portion 61 and the fulcrum hole 72 in the support portion 70 . At that time, if the angle of the arm installation portion 61 and the support portion 70 is adjusted with respect to the lighting fixture 10, the power supply portion 16 is fixed to the support portion 70 and moves together. Even in such a case, provision of the positioning portion 66 at an appropriate position has the effect of preventing the power supply portion 16 from interfering with the fins 27 .

Also, the power source section 16 is mounted at a predetermined mounting position A between the pair of arm sections 60 of the arm 15 . The power supply unit 16 is arranged between the radiator 12 and the arm installation portion 61 (installation portion 69) of the arm 15 with a space between the radiator 12 and the arm installation portion 61 (installation portion 69). ing.
The power supply unit 16 is disposed in a positional relationship such that the distance between the radiator 12 and the power supply unit 16 is narrower than the distance between the arm installation portion 61 (installation portion 69) of the arm 15 and the power supply unit 16. ing.

The power supply unit 16 includes a power supply box 76 , a plurality of terminal blocks 77 arranged in the power supply box 76 , and a power supply circuit 78 housed in the power supply box 76 .

The power supply box 76 is formed in a flat box shape with a thin height (thickness) in the vertical direction. The power supply box 76 includes a power supply case 79 with an open upper surface and a power supply cover 80 covering the upper surface side of the power supply case 79 .

One opposing side surface of the power supply box 76 is configured as a mounting surface 81 that is mounted on the inner surface side of the pair of arm portions 60 . The mounting surface 81 is provided with a plurality of mounting holes 82 into which the fastening members S (see FIG. 1) inserted through the insertion holes 62 of the arm portion 60 are screwed. A part of one side surface perpendicular to the mounting surface 81 of the power supply box 76 is opened, and a terminal block 77 is arranged inside the power supply box 76 facing this opening. A wiring hole 76a is provided in the center of the lower surface of the power supply box 76. As shown in FIG.

The power circuit 78 includes a power board 83 and a plurality of electronic components 84 mounted on the power board 83 . The power supply circuit 78 receives AC power through one of the terminal blocks 77, converts the AC power into predetermined DC power, and supplies the DC power to the light emitting module 11 to light the light emitting element 21. FIG.
Also, the power supply circuit 78 inputs a dimming signal from an external control unit or a dimmer through the other terminal block 77, and controls the light emitting element 21 according to this dimming signal.

The power supply unit 16 and the light emitting module 11 are electrically connected by wiring 36 . One end of the wiring 36 is electrically connected to the light source side connector mounted on the light emitting module 11, and the other end is connected to the power source side connector 85 of the power source circuit 78. FIG. Between one end and the other end of the wiring 36 are the wiring hole 20a of the substrate 20, the wiring hole 22a of the heat dissipation sheet 22, the packing 56, the wiring hole 26a of the radiator 12, the space between the adjacent fins 27 on the central side, and the power supply box 76. is inserted through the wiring hole 76a. The wiring 36 is held in a concave portion 38 of one fin 27 by a holding member 37 such as a binding band between the radiator 12 and the power supply section 16 .

In addition, the power supply box 76 may be provided with a positioned portion positioned by the positioning portion 66 of the arm portion 60 at the predetermined mounting position A. In this case, the insertion hole 62 of the arm portion 60 and the power supply box 76 A mounting hole 82 can be positioned. The portion to be positioned includes a groove, a recess, a pair of projections, or the like that fits into the cut-and-bent piece 68 of the arm portion 60 .

In order to assemble the lighting device 10, the packing retainer 57 is screwed to the lower surface of the radiator 12 via the packing 56, and the heat dissipation sheet 22 and the light emitting module 11 are screwed via a plurality of board retainers 23. do.

A reflector 13 is placed on the lower surface side of the radiator 12 and screwed, and a translucent cover 14 is placed so as to cover the reflector 13 and screwed. The translucent cover 14 is positioned on the radiator 12 by engaging the four engaging portions 49a and 49b projecting from the mounting edge 52 with the peripheral side surfaces of the radiator 12, and the mounting edge 52 is positioned on the radiator 12. can be easily screwed to the bottom side of the

A pair of arm portions 60 of the arm 15 are arranged on both sides of the radiator 12 and fixed by fastening means. The pair of arm portions 60 of the arm 15 and the arm mounting portion 61 may be assembled in advance, or the separated pair of arm portions 60 may be arranged on both sides of the radiator 12 and fixed by fastening means. An arm installation portion 61 may be attached to the pair of arm portions 60 .

The power source section 16 is inserted between the pair of arm sections 60 and placed on a plurality of cut-and-raised pieces 68 projecting to the inner surface side of the arm sections 60 . As a result, the power source section 16 can be positioned and supported at a predetermined mounting position A (at least at the height of the mounting position A) between the pair of arm sections 60 . At this time, even if the position of the mounting hole 82 of the power supply section 16 is deviated from the insertion hole 67 of the arm section 60 , the power supply section 16 can be easily aligned by sliding the cut and raised pieces 68 . The fastening member S (see FIG. 1) is screwed into the mounting hole 82 of the power supply section 16 through the insertion hole 67 of the arm section 60 to mount the power supply section 16 between the pair of arm sections 60 .

In addition, the wiring 36 is passed through the packing 56 during assembly, and one end side is connected to the light emitting module 11 and the other end side is connected to the power supply circuit 78 . The wiring 36 drawn upward from the wiring hole 26a of the radiator 12 and the wiring 36 drawn downward from the wiring hole 76a of the power supply section 16 may be connected by a connector. An intermediate portion of the wiring 36 between the radiator 12 and the power supply section 16 is held in a recess 38 provided in one fin 27 by a holding member 37 .

In order to install the lighting device 10, the arm installation portion 61 of the arm 15 is attached to the installed portion such as the ceiling. For example, when the installation part is inclined, the arm installation part 61 of the arm 15 is also inclined. For example, the direction of light irradiation can be set directly downward.

If necessary, a wire for preventing vibration from the installed portion, a wire for preventing falling, or the like is connected to the connecting hole 29a of one of the side plate portions 29. As shown in FIG.

Further, when the lighting equipment 10 is lit, the power supply unit 16 converts AC power into predetermined DC power and supplies it to the light emitting module 11, so that the light emitting element 21 of the light emitting module 11 is lit. Light from the lit light-emitting element 21 passes through the reflector 13 and the light-transmitting cover 14 and is irradiated into the illumination space. In the light-transmitting cover 14, the lower surface portion 50 shines brightly, but part of the light incident on the light-transmitting cover 14 is guided to the side surface portion 51, and light leaks from the gap between the reflector 13 and the inner surface of the lower surface portion 50. When incident on the side surface portion 51, the side surface portion 51 also shines.

The heat generated by the light-emitting element 21 during lighting is mainly transmitted from the substrate 20 to the heat sink 12 and radiated from the plurality of fins 27 of the heat sink 12 into the air. Since the fins 27 are provided with the openings 34 and 35, even when the plurality of fins 27 are arranged in parallel, the relatively low-temperature outside air flows from the outside fins 27 to the inside fins 27. , and heat is efficiently dissipated by the plurality of fins 27.

Further, the translucent cover 14 closes the lower surface side of the heat sink 12 to which the light emitting module 11 and the reflector 13 are attached, and the wiring hole 26a of the heat sink 12 through which the wiring 36 is inserted is closed with the packing 56. To prevent insects, dust, etc. from entering the inside of a light cover 14.例文帳に追加

In addition, in the lighting fixture 10 of the present embodiment, the pair of arm portions 60 of the arm 15 are attached to the radiator 12, and the power source portion 16 is attached between the pair of arm portions 60. Therefore, the main body chassis and the like are unnecessary. , can be simplified and lightened.

The lighting fixture 10 that is simplified and lightened in this way can be easily installed, can reduce the time required for installation, and can reduce the load applied to the installed part such as the ceiling side where the lighting fixture 10 is installed. can be reduced.

Moreover, since the power supply unit 16 is attached to the arm 15, the thermal influence from the radiator 12 can be reduced.

Moreover, since the arm 15 has the positioning portion 66 for positioning the power supply section 16 at the predetermined mounting position A between the arm sections 60, the power supply section 16 can be easily mounted at the predetermined mounting position A between the arm sections 60. It can be attached and the assembling efficiency can be improved.

By using a cut-and-raised piece 68 cut and raised from the arm portion 60 as the positioning portion 66, the configuration can be simplified. Furthermore, by providing the cut-and-raised pieces 68 on both side edges in the width direction of each arm portion 60, the state of the power supply portion 16 placed on these cut-and-raised pieces 68 is stabilized, and the work can be facilitated.

In addition, since the pair of arm portions 60 has the drop prevention portion 65 arranged on the lower surface side of the light-transmitting cover 14, even if the light-transmitting cover 14 is affected by the heat from the light emitting module 11 or the like, the effect of vibration, etc. Therefore, even if the light-transmitting cover 14 is detached from the radiator 12, the lower surface side of the light-transmitting cover 14 is supported by the drop prevention portion 65, so that the light-transmitting cover 14 can be prevented from falling. Moreover, by integrally providing the fall prevention portion 65 with the arm portion 60, the fall can be prevented with a simple configuration.

Furthermore, since the light-transmitting cover 14 is provided with engaging portions 49a and 49b that engage with the side portions of the radiator 12, the light-transmitting cover 14 is removed from the radiator 12 and supported by the drop prevention portion 65. In this state, it is possible to prevent the light-transmitting cover 14 from slipping off from the fall prevention portion 65. As shown in FIG.

In addition, since the arm mounting portion 61 is connected to the pair of arm portions 60 attached to the radiator 12 and to which the power supply portion 16 is attached so that the angle can be adjusted, the ceiling or other installation portion may be tilted. Also, the direction of light irradiation from the lighting device 10 can be appropriately adjusted.

Furthermore, since the power supply unit 16 is attached to the arm unit 60 fixed to the radiator 12, the positional relationship between the radiator 12 and the power supply unit 16 can be kept constant while the angle can be adjusted. Even if the angle is adjusted, the heat sink 12 and the power supply unit 16 do not come into contact with each other.

In addition, since one side plate portion 29 and side portion 30 are bent from the peripheral portion of the base 26 of the radiator 12, a plurality of fins 27 are crimped to the base plate portion 28 of the base 26. Also, the strength of the base 26 can be improved and deformation of the base portion 26 can be prevented.

While several embodiments of the invention have been described, these embodiments have been 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 modifications can be made without departing from the scope of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are included in the scope of the invention described in the claims and equivalents thereof.

10 lighting fixtures
11 light emitting module
12 Heatsink
14 Translucent cover
15 arms
16 Power supply
48 Translucent cover body
49a, 49b engaging part
60 Arm
61 Arm installation part
66 Positioning part
70a Angle adjuster

Claims (2)

a light emitting module;
a radiator with the light emitting module disposed on one side;
a translucent cover main body having an engaging portion that elastically engages with the radiator and attached to the lower surface side of the radiator;
A cover fall prevention portion is provided which is formed by bending from both sides of the radiator toward the one surface side. a pair of arm portions attached to the radiator;
A lighting fixture comprising: 2. The lighting equipment according to claim 1, further comprising a power supply section for supplying a power source to said light emitting module, said power supply section being attached to said arm sections facing between said arm sections.

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