JP2021153071A - Light fitting - Google Patents

Abstract

To provide a light fitting capable of suppressing deterioration of resin parts due to environmental factors.SOLUTION: A light fitting of the present invention includes: a light source; a heat sink which has a heat radiation plate formed with a first surface where the light source is provided and a second surface corresponding to the rear surface of the first surface; and a body frame which is fixed at the heat sink, the heat sink has an opening part provided so as to penetrate through the first surface and the second surface of the heat radiation plate, a resin part is fitted at the opening part, and the body frame has a top surface opposite to the resin part.SELECTED DRAWING: Figure 1

Description

The present invention relates to a luminaire, and more particularly to a luminaire provided with a heat sink.

Conventional lighting fixtures include a light source, a rectangular heat sink arranged on the light source, a plurality of columns provided on the periphery of the heat sink, and a top plate fixed to the end of each column. , A device including an arm rotatably attached to a support column has been proposed (see, for example, Patent Document 1). The arm of the luminaire of Patent Document 1 is fixed to a structure of a building, for example, a ceiling and a beam.

In the lighting fixture of Patent Document 1, the structure in which the top plate, the support column, and the heat radiating plate are combined has a rectangular parallelepiped shape. Further, the columns of the lighting fixture of Patent Document 1 are not provided on the entire peripheral edge of the heat radiating plate, and the columns are provided at intervals. That is, the above-mentioned structure is closed at the upper surface corresponding to the top plate and the lower surface corresponding to the heat radiating plate, but is open at four surfaces other than the upper surface and the lower surface.

Japanese Unexamined Patent Publication No. 2017-41328

Some lighting fixtures have a resin member provided on the heat sink. An example of a resin member is a cable gland for a feeder that supplies power to a light source. In addition, the lighting equipment may be used not only indoors but also outdoors such as under the eaves. In general, the environmental conditions are harsher outdoors than indoors, so the resin parts of lighting fixtures installed outdoors are liable to deteriorate due to environmental factors. Specifically, since outdoor luminaires are more easily exposed to sunlight than indoor luminaires, resin parts of outdoor luminaires are more likely to be deteriorated by ultraviolet rays contained in sunlight. Other environmental factors include thermal cycle factors such as sunlight, water factors such as rain, salts contained in flying water, and ozone factors in the air.

When the resin component is provided on the heat sink of the lighting fixture of Patent Document 1, the resin component on the heat sink is liable to deteriorate due to environmental factors because the four surfaces of the structure of Patent Document 1 are open. However, in order to satisfy the environmental resistance, a structure such as covering the resin parts on the heat sink is required, which causes an increase in weight and a problem that the mountability of the lighting equipment is lowered. Further, if the weight of the structural member is reduced in order to avoid a decrease in the mountability of the luminaire, there is a problem that the strength and rigidity of the component member are reduced.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a lighting fixture capable of suppressing deterioration of resin parts due to environmental factors.

The luminaire according to the present invention includes a light source, a heat sink having a heat sink on which a first surface on which the light source is provided and a second surface corresponding to the back surface of the first surface are formed. A main body frame fixed to the heat sink, and the heat sink has an opening provided so as to penetrate the first surface and the second surface of the heat sink, and the opening is provided. A resin component is attached to the portion, and the main body frame has a top surface portion facing the resin component.

According to the present invention, since the resin component is provided in the opening penetrating the heat sink and is arranged between the top surface portion and the heat radiating plate, it is possible to prevent the resin component from deteriorating due to environmental factors. can do.

It is a perspective view of the lighting equipment which concerns on embodiment. It is a perspective view of the state which disassembled the luminaire which concerns on embodiment. It is a top view of the lighting equipment which concerns on embodiment. It is a figure which looked at the lighting fixture from the direction of arrow A shown in FIG. It is a top view of the heat sink. It is a figure which looked at the lighting fixture from the direction of arrow B shown in FIG. It is a figure which showed typically the part where stress is likely to occur in the 2nd side surface part. It is a figure which showed how the resin member of a lighting fixture is protected from sunlight and the like. It is a figure which showed the state that the air passes through the gap of the heat radiation fin of the heat sink of a lighting fixture. It is a modification (lighting fixture) of the lighting fixture according to the embodiment. It is a perspective view of the heat sink provided in a lighting fixture. It is a top view of the heat sink provided in the lighting equipment.

Embodiment.
Hereinafter, embodiments will be described with reference to the drawings as appropriate. In the following drawings including FIG. 1, the relationship between the sizes of the constituent members may differ from the actual one.

<Structure of Embodiment>
FIG. 1 is a perspective view of the lighting fixture 100 according to the embodiment. FIG. 2 is a perspective view of the lighting fixture 100 according to the embodiment in a disassembled state. FIG. 3 is a top view of the lighting fixture 100 according to the embodiment. FIG. 4 is a view of the luminaire 100 viewed from the direction of arrow A shown in FIG.

As shown in FIGS. 1 and 2, the luminaire 100 is provided on the light source 40 having a COB (chip on board) type LED 40A (light emitting diode) and the light irradiation side of the light source 40, and the light of the light source 40 is provided. It is provided with a reflector 51 that reflects the light source 40 and a cover 50 that houses the light source 40 and the reflector 51. Further, the lighting fixture 100 is provided on the edge portion 50A of the cover 50, and has an annular packing 52 for ensuring the airtightness of the space inside the cover 50, and a plurality of lighting fixtures 100 provided on the rectangular heat sink 34 and the heat sink 34. It is provided with a heat sink 30 having the heat radiating fins 35 of the above, and a heat radiating sheet 41 in contact with the light source 40 and the heat radiating plate 34. In the embodiment, the heat sink 34 has a square shape. Further, the lighting fixture 100 includes a main body frame 10 fixed to the heat sink 30, an arm 20A fixed to one side of the main body frame 10, and an arm 20B fixed to the other side of the main body frame 10. ing.

The lighting fixture 100 is a power supply line 33 that supplies power to the light source 40 from a separately placed power source (not shown), a cable ground 31 into which the power supply line 33 is inserted, and an outside air pressure in the space outside the cover 50. It is provided with an internal pressure adjusting valve 32 that adjusts the difference between the atmospheric pressure and the internal pressure which is the pressure in the space inside the cover 50. The cable gland 31 and the internal pressure adjusting valve 32 are resin parts provided on the heat sink 30. Further, the luminaire 100 is inserted into the edge portion 50A of the cover 50 and inserted into the four fixing members 60A for fixing the cover 50 to the heat radiating plate 34 of the heat sink 30 and the edge portion 50A of the cover 50, and is inserted from the fixing member 60A. Also equipped with four long fixing members 60B. Further, the luminaire 100 includes four fixing members 61 for fixing the arm 20A and the arm 20B to the main body frame 10. Further, the luminaire 100 includes a wire 70 for preventing the luminaire 100 from falling when the arm 20A and the arm 20B fall off from an attached portion such as a building, and a metal ring attached to one end side of the wire 70. A member 70A and a metal metal fitting 71 attached to the other end side of the wire 70 are provided. The metal fitting 71 is attached to a building or the like.

As shown in FIG. 2, the light source 40 includes four LEDs 40A, and a cable ground 31 is arranged at the center of the four LEDs 40A. The light source 40 is electrically connected to the feeder line 33. The reflector 51 is provided between the light source 40 and the cover 50. The cover 50 has a function of protecting the light source 40. The edge portion 50A of the cover 50 is formed with a hole into which the fixing member 60A is inserted and a hole into which the fixing member 60B is inserted. Further, the edge portion 50A of the cover 50 is supported by the arm 20A and the arm 20B. A heat radiating sheet 41, a light source 40, and a reflector 51 are provided in a space formed by the cover 50 and the heat radiating plate 34. An annular groove (not shown) is formed in the edge 50A of the cover 50, and the packing 52 is provided in the groove of the edge 50A. The lighting fixture 100 includes four heat radiating sheets 41, which is the same number as the LED 40A. The heat radiating sheet 41 has a circular shape in a plan view.

As shown in FIGS. 2 and 4, the heat radiating plate 34 of the heat sink 30 is formed with a first surface S1 in which the light source 40 is provided and a second surface S2 corresponding to the back surface of the first surface S1. A plurality of heat radiating fins 35 arranged in parallel are provided on the second surface S2 of the heat radiating plate 34. A plurality of heat radiating fins 35 are erected in parallel in the central portion of the heat radiating plate 34, and a portion in which the radiating fins 35 are not erected is formed at the end portion of the heat radiating plate 34. The portion of the heat radiating plate 34 on which the radiating fins 35 are not erected has a long first edge portion S21 in contact with the main body frame 10 and a length parallel to the first edge portion S21 in contact with the main body frame 10. It is a scale-shaped second edge S22. That is, the portion where the plurality of heat radiation fins 35 are erected is located sandwiched between the first edge portion S21 and the second edge portion S22. The directions Dr2 shown in FIGS. 1 and 3 indicate the longitudinal direction of the first edge portion S21 and the longitudinal direction of the second edge portion S22. The main body frame 10 is fixed to the first edge portion S21 and the second edge portion S22. In the rectangular heat sink 34, the second edge portion S22 corresponds to the opposite side of the first edge portion S21. The first edge portion S21 is formed with a hole through which the fixing member 60A passes and a hole through which the fixing member 60B is fastened. The second edge portion S22 is also formed with a hole to which the fixing member 60A is fastened and a hole to which the fixing member 60B is fastened. A cable gland 31 is provided at the center of the heat sink 34, and an internal pressure adjusting valve 32 is provided on the first edge S21 side of the heat sink 34 with respect to the center of the heat sink 34. The heat radiating fins 35 are provided in parallel with the first side surface portion 12 described later. As shown in FIG. 3, a gap 35A is provided between the adjacent heat radiation fins 35.

As shown in FIGS. 1 to 4, the main body frame 10 has a plate-shaped top surface portion 11 provided at intervals on the second surface S2 of the heat radiating plate 34, and one end portions 11A to the first portion of the top surface portion 11. A plate-shaped first side surface portion 12 extending to the edge portion S21 of 1 and a plate-shaped second side surface portion 13 extending from the other end portion 11B of the top surface portion 11 to the second edge portion S22 are provided. The top surface portion 11, the first side surface portion 12, and the second side surface portion 13 are made of the same plate material. That is, as a result of bending or the like of the plate material, the top surface portion 11, the first side surface portion 12, and the second side surface portion 13 are formed. As shown in FIGS. 1 to 4, the top surface portion 11 is a rectangular plate-shaped member provided in parallel with the heat radiating plate 34. The cable gland 31 and the internal pressure adjusting valve 32 are arranged between the top surface portion 11 and the heat radiating plate 34. That is, as shown in FIG. 3, when the luminaire 100 is viewed from the top surface portion 11, the cable gland 31 and the internal pressure adjusting valve 32 are hidden by the top surface portion 11. In other words, when the luminaire 100 is viewed from the top surface portion 11, the cable gland 31 and the internal pressure adjusting valve 32 are arranged at positions inside the peripheral edge of the top surface portion 11. As shown in FIG. 4, the top surface portion 11 is provided with a saddle 11C for fixing the feeding line 33 to the top surface portion 11. The feeder line 33 is a wiring for connecting a power supply (not shown) and a light source 40. The feeder line 33 is provided along the top surface portion 11 and passes through the cable ground 31. The power supply line 33 is fixed to the cable ground 31. The cable ground 31 suppresses the application of tension to the feeder line 33 and the application of vibration to the feeder line 33.

As shown in FIG. 2, the first side surface portion 12 has a plate-shaped main body 12a rising from the heat sink 34 and a plate-shaped first fixed end portion 12A abutting on the first edge portion S21. And have. The main body 12a has a first hem-shaped portion 12B whose width increases from the one end portion 11A side of the top surface portion 11 toward the first edge portion S21 side. The direction Dr1 shown in FIGS. 1, 2 and 4 indicates a direction from one end 11A side (upper side) of the top surface portion 11 to the first edge portion S21 side (lower side). The upper end portion of the main body 12a is connected to one end portion 11A of the top surface portion 11, and the lower end portion of the main body 12a is connected to the first fixed end portion 12A. The main body 12a is provided parallel to the heat radiation fins 35. The main body 12a is formed with a hole into which the fixing member 61 is inserted. The fixing member 61 fixes the main body 12a and the arm 20A so that the main body 12a and the arm 20A are in contact with each other. The first fixed end portion 12A is a plate-shaped member extending parallel to the first edge portion S21. The first fixed end 12A faces the first edge S21. Further, the first fixed end portion 12A extends from one end side in the longitudinal direction of the first edge portion S21 to the other end side in the longitudinal direction of the first edge portion S21. The first fixed end portion 12A is formed with a hole into which the fixing member 60B is inserted from the lower surface side.

The second side surface portion 13 has substantially the same configuration as the first side surface portion 12. As shown in FIG. 2, the second side surface portion 13 has a plate-shaped main body 13a rising from the heat sink 34 and a plate-shaped second fixed end portion 13A abutting on the second edge portion S22. And have. The cable gland 31 and the internal pressure adjusting valve 32 are arranged between the first side surface portion 12 and the second side surface portion 13. Specifically, the cable gland 31 and the internal pressure adjusting valve 32 are arranged between the main body 12a and the main body 13a. The main body 13a has a second hem-shaped portion 13B whose width increases from the other end 11B side of the top surface portion 11 toward the second edge portion S22 side. The direction Dr1 shown in FIGS. 1, 2 and 4 indicates a direction from the other end 11B side of the top surface portion 11 toward the second edge portion S22 side. The upper end portion of the main body 13a is connected to the other end portion 11B of the top surface portion 11, and the lower end portion of the main body 13a is connected to the second fixed end portion 13A. The main body 13a is provided parallel to the heat radiation fins 35 and the main body 12a. A hole into which the fixing member 61 is inserted is formed in the main body 13a. The fixing member 61 fixes the main body 13a and the arm 20B so that the main body 13a and the arm 20B are in contact with each other. Further, the main body 13a is formed with a hole for attaching the ring member 70A. The second fixed end 13A is a plate-like member extending parallel to the second edge S22. The second fixed end 13A faces the second edge S22. Further, the second fixed end portion 13A extends from one end side in the longitudinal direction of the second edge portion S22 to the other end side in the longitudinal direction of the second edge portion S22. A hole into which the fixing member 60B is inserted is formed in the second fixed end portion 13A from the lower surface side.

As shown in FIG. 3, the end portion of the first side surface portion 12 in the longitudinal direction (Dr2) of the heat radiation fin 35 is bent toward the heat radiation fin 35 to form the bent portion 15. Further, in the first side surface portion 12, the end portion and the bent portion 15 in the longitudinal direction of the heat radiation fin 35 project downward from the first fixed end portion 12A to form the projecting portion 16. The bent portion 15 is bent perpendicular to the main body 12a. The end portion of the heat radiating fin 35 of the first side surface portion 12 in the longitudinal direction (Dr2) and the protruding portion 16 of the bent portion 15 are formed along the corner portion of the heat radiating plate 34, that is, with the corner of the heat radiating plate 34 sandwiched between the two. It is arranged across the sides. Similar to the first side surface portion 12, the second side surface portion 13 is also formed with a bent portion 15 and a protruding portion 16 projecting downward from the second fixed end portion 13A. That is, the main body frame 10 surrounds the four corners of the heat radiating plate 34 by the protrusions 16 formed at the four positions. That is, the heat radiating plate 34 has a main body frame in two directions, a direction parallel to the longitudinal direction (Dr2) of the radiating fin 35 and a direction parallel to the radiating plate 34 and orthogonal to the longitudinal direction of the radiating fin 35. Relative movement with 10 is restricted. In other words, the heat sink 34 is restricted from moving relative to the main body frame 10 in the parallel direction of the first surface S1 and the second surface S2.

As shown in FIGS. 2 and 4, the arm 20A is attached to a hook portion 20A1 hooked on the edge portion 50A of the cover 50, a fixed surface portion 20A2 having a hole into which the fixing member 61 is inserted, and a building or the like. It is provided with a mounting surface portion 20A3 to be attached. A hooking portion 20A1 is formed at the lower end of the fixed surface portion 20A2, and a mounting surface portion 20A3 is formed at the upper end of the fixed surface portion 20A2. The arm 20B has the same configuration as the arm 20A. The arm 20B includes a hooking portion 20B1 hooked on the edge portion 50A of the cover 50, a fixed surface portion 20B2 having a hole into which the fixing member 61 is inserted, and a mounting surface portion 20B3 to be mounted on a mounted portion such as a building. I have. A hooking portion 20B1 is formed at the lower end of the fixed surface portion 20B2, and a mounting surface portion 20B3 is formed at the upper end of the fixed surface portion 20B2. Since the hooking portion 20A1 and the hooking portion 20B1 support the cover 50, the hooking portion 20A1 and the hooking portion 20B1 further strengthen the fixing between the cover 50 and the heat sink 34.

The fixing members 60A are provided at the four corners of the edge portion 50A of the cover 50. The fixing member 60A penetrates the holes provided in the cover 50 and the heat sink 34, and is fastened to the first fixed end portion 12A of the main body frame 10. The fixing member 60A fixes the cover 50 and the heat sink 34 to the main body frame 10. The fixing member 60B penetrates the holes provided in the cover 50 and the heat sink 34, and is fastened to the second fixed end 13A of the main body frame 10. The fixing member 60B fixes the cover 50 and the heat sink 34 to the main body frame 10. The fixing member 60B on the first side surface portion 12 side fixes the first fixed end portion 12A to the first edge portion S21 side of the heat sink 34, and the fixing member 60B on the second side surface portion 13 side is the first. The fixed end portion 13A of 2 is fixed to the second edge portion S22 side of the heat sink 34. Screws can be adopted for the fixing member 60A and the fixing member 60B. The fixing member 61 on the first side surface portion 12 side fixes the fixing surface portion 20A2 of the arm 20A and the main body 12a of the first side surface portion 12, and the fixing member 61 on the second side surface portion 13 side is the fixing surface portion of the arm 20B. The 20B2 and the main body 13a of the second side surface portion 13 are fixed. As shown in FIG. 2, bolts 61A and nuts 61B can be adopted as the fixing member 61.

FIG. 5 is a top view of the heat sink 30. An opening Op1 in which a cable gland 31, which is a resin component, is provided is formed in the central portion of the heat radiating plate 34 of the heat sink 30. Here, the central portion of the heat radiating plate 34 is a portion where the diagonal lines of the rectangular region where the heat radiating plate 34 is installed intersect. Further, an opening Op2 in which the internal pressure adjusting valve 32 is provided is formed on the first edge portion S21 side of the heat radiating plate 34 with respect to the formed portion of the opening Op1. The opening Op1 and the opening Op2 penetrate the heat sink 34. The opening Op1 and the opening Op2 are provided on the virtual line CL connecting the midpoint P1 of the first edge S21 and the midpoint P2 of the second edge S22. Therefore, the cable gland 31 and the internal pressure adjusting valve 32 are provided on the virtual line CL connecting the midpoint P1 of the first edge portion S21 and the midpoint P2 of the second edge portion S22. The virtual line CL is provided at a position where the virtual surface L1 and the heat radiating plate 34, which will be described later, are orthogonal to each other. Some of the heat radiation fins 35 are installed so as to avoid the opening Op1 and the opening Op2. The heat radiation fins 35 arranged with the opening Op1 or the opening Op2 sandwiched between the end faces in the direction parallel to the second surface S2, in other words, the end faces in the longitudinal direction (Dr2) of the heat radiation fins 35 are the opening Op1. Alternatively, they are arranged so as to face each other with the opening Op2 interposed therebetween.

The cable gland 31 includes packing (not shown). Further, the internal pressure adjusting valve 32 includes a ventilation filter (not shown) for adjusting the difference between the external air pressure, which is the pressure in the space outside the cover 50, and the internal pressure, which is the pressure in the space inside the cover 50, and the inside of the cover 50. It is equipped with a pipe that communicates the space and the ventilation filter, and a packing. Since the cable gland 31 is provided in the opening Op1, the opening Op1 is closed by the cable gland 31. Further, since the internal pressure adjusting valve 32 is provided in the opening Op2, the opening Op2 is closed by the internal pressure adjusting valve 32. That is, the cable gland 31 and the internal pressure adjusting valve 32 prevent dust, water, and the like from entering the space inside the cover 50 via packing and the like.

FIG. 6 is a view of the luminaire 100 viewed from the direction of arrow B shown in FIG. The cable gland 31 and the internal pressure adjusting valve 32 are provided at positions intersecting the virtual surface L1. The configuration of the top surface portion 11 and the like will be described with reference to FIGS. 6 and 3 and 5 described above. The width WL of the top surface portion 11 is the width in the direction parallel to the top surface portion 11. Further, as shown in FIGS. 3 and 6, the virtual surface L1 passes through the midpoint T1 of one end 11A of the top surface 11 and the midpoint T1 of the other end 11B of the top 11 and is orthogonal to the heat sink 34. It is the side to do. The virtual line CL is located on the virtual surface L1. Therefore, the cable gland 31 and the internal pressure adjusting valve 32 intersect the virtual surface L1. Further, the virtual surface L1 is also orthogonal to the top surface portion 11. The virtual line CL is located at the upper end of the fixing member 61 on the heat sink 34 side as shown in FIG. 6 when the lighting fixture 100 is viewed from the direction of arrow B shown in FIG.

The virtual surface L2 shown in FIG. 6 is a surface passing through the virtual line CL which forms 45 degrees with respect to the virtual surface L1. The virtual surface L3 shown in FIG. 6 has a symmetrical relationship with the virtual surface L2 with respect to the virtual surface L1. The virtual surface L3 is also a surface passing through the virtual line CL, which forms 45 degrees with respect to the virtual surface L1.

Here, the intersection of the virtual surface L1 and the top surface portion 11 is defined as a line segment P3, the intersection of the virtual surface L2 and the top surface portion 11 is designated as a line segment P4, and the virtual surface L3 and the top surface portion 11 intersect. Let the place be a line segment P5. At this time, the distance from the line segment P3 to the line segment P4 is equal to the distance H from the virtual line CL to the line segment P3, and the distance from the line segment P3 to the line segment P5 is the distance from the virtual line CL to the line segment P3. Is equal to the distance H to. Therefore, the distance from the line segment P4 to the line segment P5 is twice the distance H. Here, as shown in FIG. 6, it can be seen that the width WL of the top surface portion 11 is the distance from the line segment P4 to the line segment P5, that is, more than twice the distance H. By setting the width WL of the top surface portion 11 in this way, the top surface portion 11 is provided with sunlight in an angle range between the virtual surface L2 and the virtual surface L3 on the virtual line CL of the heat sink 34. It prevents direct contact with the resin parts.

<Operations and actions of the embodiment>
FIG. 7 is a diagram schematically showing a portion of the second side surface portion 13 where stress is likely to occur. The operation and operation of the luminaire 100 will be described with reference to FIG. 7 and FIGS. 1 and 2 described above. In the description of FIG. 7, since the first side surface portion 12 and the second side surface portion 13 are symmetrically provided on the luminaire 100, the stress of the second side surface portion 13 will be described and the first. The description of the stress of the side surface portion 12 of the above is omitted. The stress of the first side surface portion 12 is the same as the stress of the second side surface portion 13 described with reference to FIG. 7. Further, in FIG. 7, for convenience of explanation, the arm 20A, the arm 20B, the fixing member 61, the ring 70A, the wire 70 and the metal fitting 71, the saddle 11C, and the feeder line 33 are not shown.

Electric power is supplied to the light source 40 from a power source (not shown) via a feeder line 33. When power is supplied to the light source 40, the LED 40A of the light source 40 emits light. The light of the LED 40A passes through the cover 50 and is radiated to the outside of the cover 50. A part of the light of the LED 40A is reflected by the reflector 51 and reaches the cover 50. The heat generated in the light source 40 when the LED 40A emits light is transferred to the heat sink 30 via the heat radiating sheet 41. The heat transferred to the heat sink 30 is transferred to the air from the heat radiating plate 34 and the heat radiating fins 35.

When the building or the like vibrates, the vibration of the building or the like propagates from the attached portion of the building or the like to the arm 20B of the luminaire 100. The vibration propagated to the arm 20B propagates to the main body frame 10. The vibration propagated to the main body frame 10 propagates to the heat sink 30, the cover 50, and the like.

The second fixed end portion 13A of the second side surface portion 13 of the main body frame 10 receives the load of the heat sink 30, the cover 50, the light source 40, and the like. The second fixed end portion 13A is formed with a hole into which the fixing member 62 is inserted and a hole into which the fixing member 60B is inserted. Since the second fixed end portion 13A is a portion that supports the heat sink 30 and the like in this way, the second fixed end portion 13A is a portion where stress is likely to be concentrated. However, the second fixed end portion 13A extends from one end side in the longitudinal direction of the second edge portion S22 to the other end side in the longitudinal direction of the second edge portion S22. That is, even if the stress generated in the second fixed end portion 13A increases, the portion where the second fixed end portion 13A contacts the second edge portion S22 is long in the direction Dr2, so that the second fixing is performed. The stress of each part constituting the end portion 13A is dispersed.

Further, the second side surface portion 13 is bent and formed at a portion where the second fixed end portion 13A and the main body 13a are connected. That is, the second side surface portion 13 includes a bent portion Rg2 formed at a portion where the second fixed end portion 13A and the main body 13a are connected. The bent portion Rg2 is a portion where the outer shape of the plate material changes, and is generally a portion where stress is likely to be concentrated. However, since the second fixed end portion 13A extends from one end side in the longitudinal direction of the second edge portion S22 to the other end side in the longitudinal direction of the second edge portion S22, the bent portion Rg2 also has the second edge. It extends from one end side in the longitudinal direction of the portion S22 to the other end side in the longitudinal direction of the second edge portion S22. That is, the width of the bent portion Rg2 parallel to the direction Dr2 is longer than the width parallel to the direction Dr2 of the other end portion 11B of the top surface portion 11, and the stress of each portion constituting the bent portion Rg2 is dispersed.

The arm 20B receives the load of the main body frame 10, the heat sink 30, the cover 50, the light source 40, and the like. As shown in FIG. 7, a hole 13a1 into which the fixing member 61 is inserted is formed in a portion of the second side surface portion 13 to which the arm 20B is fixed. Since the peripheral edge portion Rg1 of the hole 13a1 is a portion supported by the arm 20B in this way, the peripheral edge portion Rg1 of the hole 13a1 is a location where stress is likely to be concentrated. However, the peripheral edge portion Rg1 of the hole 13a1 is provided at a position avoiding a portion of the second side surface portion 13 that is relatively vulnerable. Specifically, the peripheral edge portion Rg1 of the hole 13a1 is a portion where the top surface portion 11 and the second side surface portion 13 are connected, and a portion where the main body 13a of the second side surface portion 13 and the second fixed end portion 13A are connected. And, it is provided away from the portion where the second hem-shaped portion 13B is formed. Therefore, even if vibration is applied to the luminaire 100 and the stress of the peripheral portion Rg1 increases, it is possible to prevent the main body frame 10 from being damaged or the like. Further, since the two holes 13a1 are formed at the top and bottom, the stress generated in the main body 13a is dispersed. Therefore, even if the lighting fixture 100 is vibrated and the stress of the main body 13a is increased, it is possible to prevent the main body frame 10 from being damaged or the like.

FIG. 8 is a diagram showing how the resin member of the lighting fixture 100 is protected from sunlight and the like. The top surface portion 11 prevents the cable gland 31 and the internal pressure adjusting valve 32 from being directly exposed to sunlight or the like. Specifically, since the top surface portion 11 can reflect the sunlight sn1 coming toward the top surface portion 11, the top surface portion 11 can prevent the sunlight sn1 from hitting the cable ground 31 and the internal pressure adjusting valve 32. Further, although not shown, the top surface portion 11 can prevent the rain or the like from directly hitting the cable ground 31 and the internal pressure adjusting valve 32 even when it is raining or the like. Although salt may be contained in rain or the like, even in this case, since the top surface portion 11 blocks the salt contained in rain or the like, the cable gland 31 and the internal pressure adjusting valve 32 are prevented from being exposed to salt. be able to. Further, ozone may be contained in the air, but even in this case, since the top surface portion 11 blocks ozone, it is possible to prevent the cable gland 31 and the internal pressure adjusting valve 32 from being exposed to ozone. ..

The first side surface portion 12 and the second side surface portion 13 also prevent the cable gland 31 and the internal pressure adjusting valve 32 from being exposed to sunlight or the like. Specifically, since the first side surface portion 12 can reflect the sunlight sn2 coming toward the first side surface portion 12, the sunlight sn2 of the first side surface portion 12 is the cable ground 31 and the internal pressure adjusting valve 32. It can be prevented from hitting. Further, since the second side surface portion 13 can reflect the sunlight sn3 coming toward the second side surface portion 13, the second side surface portion 13 indicates that the sunlight sn3 hits the cable gland 31 and the internal pressure adjusting valve 32. Can be prevented. Further, similarly to the contents described in the top surface portion 11, the first side surface portion 12 and the second side surface portion 13 also block rain, salt and ozone, and the cable gland 31 and the internal pressure regulating valve 32 block rain, salt and ozone. It is possible to avoid being exposed to.

FIG. 9 is a diagram showing how the air Air passes through the gap between the heat radiation fins 35 of the heat sink 30 of the lighting fixture 100. A gap 35A is formed between the adjacent heat radiation fins 35. The gap 35A extends parallel to the direction Dr2. Here, in the main body frame 10, one end side 35a of the heat radiation fin 35 in the longitudinal direction and the other end side 35b of the heat radiation fin 35 in the longitudinal direction are open. As a result, as shown in FIG. 9, the air Air easily passes through the gap 35A of the heat radiation fins 35. Therefore, heat dissipation in the heat sink 30 is efficiently promoted.

<Effect of embodiment>
In the explanation of the effect, the cable gland 31 and the internal pressure adjusting valve 32 are collectively referred to as resin parts. The resin component is arranged between the first side surface portion 12 and the second side surface portion 13. Therefore, as shown in FIG. 8, the resin component is protected from sunlight sn2 and the like by the first side surface portion 12, and is protected from sunlight sn3 by the second side surface portion 13. Since the resin part is less exposed to rain and salt by the first side surface portion 12 and the second side surface portion 13, the resin part is also protected from rain and salt by the first side surface portion 12 and the second side surface portion 13. Will be done. Further, the resin parts are arranged between the top surface portion 11 and the heat radiating plate 34. Therefore, as shown in FIG. 8, the resin component is protected from sunlight sn1 and the like by the top surface portion 11. Since the resin part is less exposed to rain and salt by the top surface portion 11, the resin part is also protected from rain and salt by the top surface portion 11. In this way, since the resin parts of the luminaire 100 are protected from environmental factors such as sunlight, even if the luminaire 100 is installed in a place with severe environmental conditions, for example, outdoors, the resin parts of the luminaire 100 deteriorate. It is suppressed that it is stored.

The first fixed end portion 12A is provided on the side of the first edge portion S21 and extends parallel to the first edge portion S21. Further, the second fixed end portion 13A is provided on the second edge portion S22 side and extends parallel to the second edge portion S22. Since the first fixed end portion 12A is provided on the first edge portion S21 side and the second fixed end portion 13A is provided on the second edge portion S22 side, the first side surface is correspondingly increased. The distance between the portion 12 and the second side surface portion 13 is widened. Therefore, the space for arranging the resin parts of the heat radiation fin 35 and the lighting fixture 100 can be expanded. Further, the first fixed end portion 12A extends parallel to the first edge portion S21, and the second fixed end portion 13A extends parallel to the second edge portion S22. That is, since the first fixed end portion 12A and the second fixed end portion 13A extend in the direction Dr2, the main body frame 10 can obtain the stress dispersion effect described with reference to FIG. 7. Therefore, even if vibration is applied to the luminaire 100 and the stress of the first fixed end portion 12A and the stress of the second fixed end portion 13A increase, it is possible to prevent the main body frame 10 from being damaged or the like. can. That is, the main body frame 10 has excellent vibration resistance.

The first fixed end portion 12A extends from one end side in the longitudinal direction of the first edge portion S21 to the other end side in the longitudinal direction of the first edge portion S21. Further, the second fixed end portion 13A extends from one end side in the longitudinal direction of the second edge portion S22 to the other end side in the longitudinal direction of the second edge portion S22. Therefore, the main body frame 10 is further improved in the above-mentioned effect related to vibration resistance.

A first hem-shaped portion 12B is formed on the first side surface portion 12, and a second hem-shaped portion 13B is formed on the second side surface portion 13. That is, as shown in FIG. 7, the main body 13a of the second side surface portion 13 is not rectangular, and the main body 13a has a shape in which the region Ar shown by the dotted line in FIG. 7 is removed. Although not shown in FIG. 7, the same applies to the first side surface portion 12. Therefore, the main body 12a and the main body 13a are lighter than the case where the main body 12a and the main body 13a are rectangular. Here, as the weight of the luminaire 100 increases, the stress generated in the main body frame 10 increases. The main body 13a has a shape in which the region Ar far from the peripheral portion Rg1 of the hole 13a1 where the stress is concentrated is removed, so that the main body 13a is lightened. Therefore, as the weight of the main body 13a is reduced, the moment of force generated in the lighting fixture 100 when vibration is applied to the lighting fixture 100 is reduced, and as a result, the stress generated in the main body frame 10 is reduced. Since the main body 12a also has the same shape as the main body 13a, the main body 12a is made lighter. Therefore, as the weight of the main body 12a is reduced, the moment of force generated in the lighting fixture 100 when vibration is applied to the lighting fixture 100 is reduced, and as a result, the stress generated in the main body frame 10 is reduced.

As shown in FIGS. 1 to 4, in the heat sink 34, the first edge portion S21 is fixed to the first fixed end portion 12A, and the second edge portion S22 is fixed to the second fixed end portion 13A. There is. That is, the heat radiating plate 34 is fixed so as not to move relative to the main body frame 10 in the vertical direction (Dr1) of the first surface S1 and the second surface S2 of the heat radiating plate 34. Further, since the heat radiating plate 34 is surrounded by four corners by the protruding portions 16 of the main body frame 10, it moves relative to the main body frame 10 in the horizontal direction of the first surface S1 and the second surface S2. Is restricted. Therefore, even if vibration is applied so that the heat sink 34 and the main body frame 10 move relative to the first surface S1 and the second surface S2 in the parallel direction, the fixing member that fixes the heat sink 34 and the main body frame 10 is fixed. It reduces the possibility that the 60 will break.

In the main body frame 10, the first side surface portion 12 is bent toward the heat radiation fin 35 at the end portion in the longitudinal direction (Dr2) of the heat radiation fin 35, and the bent portion 15 is formed. Further, in the main body frame 10, the second side surface portion 13 is bent toward the heat radiation fin 35 at the end portion in the longitudinal direction (Dr2) of the heat radiation fin 35, and the bent portion 15 is formed. Therefore, since the first side surface portion 12 and the second side surface portion 13 are bent at the end portion in the longitudinal direction (Dr2) of the heat radiation fin 35, the first side surface portion 12 and the second side surface portion 13 are bent. The rigidity and strength of the main body frame 10 are further improved. Therefore, the lighting fixture 100 has a structure having excellent rigidity and strength while realizing weight reduction.

Further, as shown in FIG. 7, the width parallel to the direction Dr2 of the lower portion 13a2 of the main body 13a is equal to the width parallel to the direction Dr2 of the second edge portion S22 of the heat radiating plate 34. The second hem-shaped portion 13B is formed above the lower portion 13a2. That is, the lower end of the second hem-shaped portion 13B is not located at the portion where the second fixed end portion 13A and the main body 13a are connected, that is, the bent portion Rg2, and the lower end of the second hem-shaped portion 13B is. It is located above the bent portion Rg2. The bent portion Rg2 is generally a place where stress is likely to be concentrated, but since the second hem-shaped portion 13B is provided away from the bent portion Rg2, the shape of the main body frame 10 from which the region Ar is removed causes the main body frame 10. The reduction in rigidity is suppressed. The first side surface portion 12 has the same configuration as the second side surface portion 13, and the first side surface portion 12 also has the effect of suppressing the reduction in the rigidity of the main body frame 10.

Since the top surface portion 11, the first side surface portion 12, and the second side surface portion 13 are made of the same plate material, the number of parts constituting the main body frame 10 is suppressed by that amount. If the top surface portion 11, the first side surface portion 12, and the second side surface portion 13 are made of different plate materials, the top surface portion 11 and the first side surface portion 12 are joined or joined. , It is necessary to fix the top surface portion 11 and the first side surface portion 12 with a fixing member. However, since the main body frame 10 can be configured by bending the same plate material, the processing cost of the main body frame 10 can be suppressed.

In the main body frame 10, one end side 35a of the heat radiation fin 35 in the longitudinal direction and the other end side 35b of the heat radiation fin 35 in the longitudinal direction are open. Sunlight or the like hits the open portion of the main body frame 10. Here, the resin component of the lighting fixture 100 is provided at a position intersecting the virtual surface L1. The virtual surface L1 is a surface that passes through the midpoint T1 of one end 11A of the top 11 and the midpoint T2 of the other end 11B of the top 11. Therefore, the resin component of the lighting fixture 100 is located directly below the center of the width parallel to the one end portion 11A of the top surface portion 11. That is, the resin component of the lighting fixture 100 is provided at a position far from both the one end side 35a of the heat radiation fin 35 in the longitudinal direction and the other end side 35b of the heat radiation fin 35 in the longitudinal direction. Therefore, sunlight and the like do not easily reach the resin parts of the lighting fixture 100. Therefore, deterioration of the resin component of the lighting fixture 100 is further suppressed.

The width parallel to one end 11A of the top surface portion 11 is more than twice the distance between the top surface portion 11 and the second surface S2. Therefore, as shown in FIG. 6, the main body frame 10 can prevent sunlight in the angle range between the virtual surface L2 and the virtual surface L3 from hitting the resin component on the heat sink 34. That is, sunlight and the like are more difficult to reach the resin parts of the lighting fixture 100. Therefore, deterioration of the resin component of the lighting fixture 100 is further suppressed.

The luminaire 100 includes a cable gland 31. Therefore, it is possible to prevent dust, water, and the like from entering the space inside the cover 50. Further, it is suppressed that tension is applied to the feeder line 33 and that vibration is applied to the feeder line 33. The luminaire 100 includes an internal pressure adjusting valve 32. Therefore, it is possible to prevent dust, water, and the like from entering the space inside the cover 50. Further, it is possible to prevent an increase in the difference between the external air pressure, which is the pressure in the space outside the cover 50, and the internal air pressure, which is the pressure in the space inside the cover 50.

If the heat radiating fins 35 are provided, for example, orthogonally to the direction Dr2, the gap 35A of the heat radiating fins 35 is blocked by the first side surface portion 12 and the second side surface portion 13. Therefore, if the heat radiating fins 35 are provided, for example, orthogonally to the direction Dr2, the heat radiating efficiency of the heat sink 30 will decrease. The heat radiation fins 35 of the lighting fixture 100 are provided parallel to the first side surface portion 12. As a result, as shown in FIG. 9, the air Air easily passes through the gap 35A of the heat radiation fins 35. Therefore, heat dissipation in the heat sink 30 is efficiently promoted.

<Modification example>
FIG. 10 is a modification (lighting fixture 101) of the lighting fixture 100 according to the embodiment. FIG. 11 is a perspective view of the heat sink 130 included in the luminaire 101. FIG. 12 is a top view of the heat sink 130 included in the luminaire 101. In the modified example, the parts different from the lighting fixture 100 according to the embodiment will be mainly described, and the common parts will be omitted.

The luminaire 100 includes four COB (chip on board) type LEDs 40A, whereas the luminaire 101 includes six LEDs 40A. That is, the lighting fixture 101 is provided with two rows of three LEDs 40A arranged side by side, so that the brightness of the lighting fixture 101, that is, the rated luminous flux is larger than the rated luminous flux of the lighting fixture 100. The row direction of the LEDs 40A, that is, the direction in which the three LEDs 40A are lined up is parallel to the direction Dr2. Therefore, the heat sink 34 of the heat sink 30 of the lighting fixture 100 according to the embodiment has a square shape, but the heat sink 134 of the heat sink 130 of the lighting fixture 101 has a rectangular shape. Further, the width parallel to the direction Dr2 of the cover 150 is longer than the width parallel to the direction Dr2 of the cover 50 of the lighting fixture 100 according to the embodiment. Further, the width parallel to the direction Dr2 of the heat radiation fin 135 is longer than the width parallel to the direction Dr2 of the heat radiation fin 35 of the lighting fixture 100 according to the embodiment.

Here, as shown in FIG. 12, the opening Op1 of the heat sink 134 and the opening Op2 of the heat sink 134 have a midpoint P1 of the first edge portion S21 and a midpoint P2 of the second edge portion S22. It is not provided on the connecting virtual line CL. The opening Op1 of the heat sink 134 and the opening Op2 of the heat sink 134 are parallel to the virtual line CL and are provided on the virtual line CL2 located on one end side 35a of the heat dissipation fin 135 with respect to the virtual line CL. ing. This is because the LED 40A is arranged directly under the virtual line CL of the heat radiating plate 134, and therefore, if a resin component such as a cable gland 31 is arranged, the resin component and the LED 40A interfere with each other. That is, in the modified example, the opening Op1 of the heat sink 134 and the opening Op2 of the heat sink 134 are formed at positions deviated from the virtual line CL to prevent the resin component and the LED 40A from interfering with each other.

In a state where the main body frame 110 is fixed to the heat sink 134, the center of the width parallel to the direction Dr2 of the main body frame 110 coincides with the position of the virtual line CL. Also in the modified example, the cable gland 31 and the internal pressure adjusting valve 32 are arranged between the top surface portion 11 and the heat radiating plate 34, and are arranged between the first side surface portion 12 and the second side surface portion 13. ing. Therefore, the luminaire 101 according to the modified example has the same effect as the luminaire 100 according to the embodiment. Further, the lighting fixture 101 according to the modified example includes a main body frame 110 whose dimensions are changed according to the heat radiating plate 134 with respect to the main body frame 10 of the embodiment 100. That is, since the main body frame 110 includes the bent portion 15 and the protruding portion 16, the strength and rigidity are improved as in the main body frame 10 applied to the square heat sink 34, and the vibration resistance is also improved. It is improving.

10 body frame, 11 top surface, 11A one end, 11B other end, 11C saddle, 12 first side surface, 12A first fixed end, 12B first hem, 12a body, 13 second Side surface, 13A second fixed end, 13B second hem, 13a body, 13a1 hole, 13a2 lower, 15 bent, 16 protruding, 20A arm, 20A1 hook, 20A2 fixed surface, 20A3 mounting surface , 20B arm, 20B1 hook part, 20B2 fixed surface part, 20B3 mounting surface part, 30 heat sink, 31 cable gland, 32 internal pressure adjustment valve, 33 power supply line, 34 heat dissipation plate, 35 heat dissipation fin, 35A gap, 35a end side, 35b end Part side, 40 light source, 40A LED, 41 heat sink, 50 cover, 50A edge, 51 reflector, 52 packing, 60 fixing member, 60A fixing member, 60B fixing member, 61 fixing member, 62 fixing member, 70 wire, 70A Ring member, 71 metal fittings, 100 lighting equipment, 101 lighting equipment, 110 body frame, 130 heat sink, 134 heat sink, 135 heat sink, 150 cover, A arrow, Air air, Ar area, B arrow, CL virtual line, CL2 virtual Line, Dr1 direction, Dr2 direction, H distance, L1 virtual surface, L2 virtual surface, L3 virtual surface, Op1 opening, Op2 opening, P1 midpoint, P2 midpoint, P3 line segment, P4 line segment, P5 line segment , Rg1 peripheral edge, Rg2 bend, S1 first surface, S2 second surface, S21 first edge, S22 second edge, T1 midpoint, T2 midpoint, sn1 sunlight, sn2 sunlight, sn3 sunlight.

Claims (6)

Light source and
A heat sink having a heat sink having a first surface on which the light source is provided and a second surface corresponding to the back surface of the first surface are formed.
The main body frame fixed to the heat sink and
With
The heat sink is
It has an opening provided so as to penetrate the first surface and the second surface of the heat sink.
A resin part is attached to the opening,
The main body frame
A lighting fixture having a top surface portion facing the resin component. The heat sink
The first edge to which the main body frame is fixed and
The main body frame is fixed and has a second edge portion corresponding to the opposite side of the first edge portion.
The main body frame
A plate-shaped top surface portion provided at intervals on the second surface of the heat radiating plate, and
A plate-shaped first side surface portion extending from one end of the top surface portion to the first edge portion, and
It has a plate-shaped second side surface portion extending from the other end portion of the top surface portion to the second edge portion.
The resin parts are
The first aspect of the present invention, wherein the first side surface portion and the second side surface portion are arranged, and the top surface portion and the heat radiating plate are arranged between the first side surface portion and the second side surface portion. lighting equipment. The top surface portion has a rectangular shape and has a rectangular shape.
The one end portion of the top surface portion extends parallel to the first edge portion, and the other end portion of the top surface portion extends parallel to the second edge portion.
The resin parts are
The claim is characterized in that it is provided at a position that passes through the midpoint of the one end portion of the top surface portion and the midpoint of the other end portion of the top surface portion and intersects the virtual surface orthogonal to the heat radiating plate. The lighting equipment according to 2. The resin parts are
The luminaire according to any one of claims 1 to 3, further comprising a cable gland into which a feeder line electrically connected to the light source is inserted. Further provided with a cover fixed to the first surface and accommodating the light source.
The claim is characterized in that the resin component has an internal pressure adjusting valve that adjusts the difference between the external air pressure, which is the pressure in the space outside the cover, and the internal pressure, which is the pressure in the space inside the cover. Item 2. The lighting equipment according to item 2 or 3. The heat sink
A plurality of heat radiating fins are provided on the second surface.
Some of the heat radiation fins among the plurality of heat radiation fins
The luminaire according to any one of claims 1 to 5, wherein the end faces in the direction parallel to the second plane are arranged so as to face each other with the opening thereof interposed therebetween.

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