JP7499567B2 - Fixtures for Fixtures - Google Patents

Description

The present invention relates to a fixture that secures lighting fixtures and other items to a mounting surface.

Conventionally, technology has been proposed that includes a ceiling mounting arm and a wall mounting arm that can be fixed to the ceiling mounting arm in order to mount a lighting fixture on a ceiling or wall.

JP 2016-162514 A

However, in the lighting fixture described in Patent Document 1, when fixing to a wall, it is necessary to fix it to the side of the ceiling arm using the mounting holes on the side of the wall arm. Both sides of each arm need to be fixed to the mounting holes, making it difficult to work with a heavy fixture. In addition, the lighting direction of the fixture is determined only by the wall arm, making it difficult to adjust the lighting direction.

The present invention provides an appliance fixing bracket that allows an appliance to be easily attached to a mounting portion such as a wall surface.

The fixture fastener of the present invention is
An instrument mounting portion is provided which is inclined with respect to a gravity direction,
The instrument mounting portion is provided with an instrument fixing hole whose width decreases in the direction of gravity.

According to the present invention, the inclined tool mounting section is provided with a tool fixing hole whose width decreases in the direction of gravity, so that the tool can be installed while temporarily hanging the tool in the tool fixing hole.

1 is a perspective view of a lighting fixture according to a first embodiment. FIG. 2 is an exploded perspective view of the lighting fixture according to the first embodiment. FIG. 2 is an exploded perspective view of the lighting fixture according to the first embodiment. FIG. 2 is a perspective view of a heat sink 110 of the lighting fixture according to the first embodiment. FIG. 4 is a perspective view of a connecting portion 130 of the lighting fixture according to the first embodiment. FIG. 4 is a perspective view of a reinforcing portion 140 of the lighting fixture according to the first embodiment. 11 is a reference diagram showing how a reinforcing portion 140 is attached to a heat sink 110 of a lighting fixture according to the first embodiment. FIG. 13 is a reference diagram showing how to attach a connecting portion 130 to a heat sink 110 of the lighting fixture according to the first embodiment. FIG. FIG. 4 is an exploded perspective view of a case portion 123 of the lighting fixture according to the first embodiment. 3 is a cross-sectional view of the lighting device according to the first embodiment taken along line BB in FIG. 2 . FIG. 2 is a perspective view of the appliance mounting bracket 200 according to the first embodiment. 2 is a diagram showing a state in which the lighting fixture according to the first embodiment is attached to the fixture mounting bracket 200. FIG. 13A and 13B are diagrams showing modified examples of a case body 1231 of a power supply unit 120 for a lighting fixture according to the first embodiment. FIG. 4 is a perspective view of a wiring through portion 119 of the lighting fixture according to the first embodiment. FIG. 2 is a schematic side view of a sheet 170 of the lighting device according to the first embodiment. 4 is a cross-sectional view of a cover portion 160 of the lighting fixture according to the first embodiment. FIG. 1 is a diagram of a bent portion 1111 of a base portion 111 and a bent portion 1131 of a top plate portion 113 of the lighting fixture according to the first embodiment. 13 is a diagram of a bent portion 1131 of a top plate portion 113 of the lighting fixture according to the first embodiment. FIG. 13 is a diagram of a bent portion 1111 of a base portion 111 of a lighting fixture according to embodiment 1. FIG. 1 is a perspective view of a connecting portion 130 having enhanced vibration resistance of the lighting fixture according to the first embodiment. FIG. FIG. 4 is a partial perspective view of a cover 161 and a cover gasket 162 of the lighting fixture according to the first embodiment. FIG. 11 is a perspective view of a lighting fixture according to a second embodiment. FIG. 11 is a side view of a lighting fixture according to a second embodiment. FIG. 11 is an exploded perspective view of a lighting fixture according to a second embodiment. 11A and 11B are a perspective view and a side view of a heat sink 110 of a lighting fixture according to a second embodiment. FIG. 11 is an installation diagram of a base portion 111 of a lighting fixture according to a second embodiment. 13A and 13B are three-sided views and a perspective view of an insulating sheet 172 of a lighting fixture according to a second embodiment. 13A and 13B are diagrams showing modified examples of the bent portion 1111 of the base portion 111 according to the second embodiment. FIG. 11 is a diagram showing a wiring through portion 119 of a lighting fixture according to a second embodiment.

The following describes an embodiment of the present invention with reference to the drawings. In each drawing, the same or corresponding parts are given the same reference numerals. In the description of the embodiment, the description of the same or corresponding parts will be omitted or simplified as appropriate. In addition, the material, shape, size, etc. of the configuration of the device, equipment, parts, etc. may be changed as appropriate within the scope of the present invention.

Embodiment 1.
The configuration of the lighting fixture according to the first embodiment will be described with reference to the drawings.
***Configuration Description***
Figure 1
(Lighting fixture 1)
FIG. 1 is a perspective view of a lighting fixture 1 to be attached to the ceiling of a facility with a high ceiling, such as a gymnasium.
The lighting fixture 1 includes an arm 10 that is attached to a mounting portion, and a light source unit 100 that is rotatably held on the arm 10.

●Figures 2 to 4
FIG. 2 is an exploded perspective view of the lighting device 1 of FIG.
FIG. 3 is an exploded perspective view of the lighting fixture 1 as viewed in the direction of the arrow A in FIG.

The lighting fixture 1 includes an arm 10 and a light source unit 100 .
The light source unit 100 includes a heat sink 110 , a power supply unit 120 , a connecting portion 130 , a reinforcing portion 140 , a light source portion 150 , a cover portion 160 , and a sheet 170 .

(Arm 10)
The arm 10 is formed in a substantially U-shape, and has a mounting hole 11 formed therein for fastening to a mounting portion with a fastener (such as a bolt).

(Heat sink 110)
FIG. 4 is a perspective view of the heat sink 110.
The heat sink 110 has a plate-shaped base portion 111 to which the light source portion 150 is attached, a plurality of fin portions 112 arranged radially on the base portion 111, and a top plate portion 113 attached to cover the fin portions 112.
The base portion 111 and the top plate portion 113 are mounting members in the form of square or rectangular plates.

In FIG. 4, the base portion 111 and the top plate portion 113 are squares with a side length of L, and have arcs at the corners with an interior angle of 90 degrees and a radius of R. The length of the straight line portion of each of the four sides of the base portion 111 and the top plate portion 113 is M, and L = M + 2R.

The base portion 111 has four screw holes 1119 at the corners and one screw hole 1118 in the center of each side. The screw holes 1118 are closer to each side than the screw holes 1119 to avoid the fin portions 112.

The top plate 113 has four screw holes 1139 at the corners and two screw holes 1119 in the center of each side.
The base portion 111 and the top plate portion 113 have a plurality of holes on the inside for fixing the fin portion 112 .
The base portion 111 and the top plate portion 113 are disposed apart from each other with the fin portion 112 therebetween.

The lower portion of the fin portion 112 is fixed to the base portion 111 , and the upper portion of the fin portion 112 is fixed to the top plate portion 113 .
The upper and lower ends of the outer periphery of the fin portion 112 have notches 1121 to prevent interference with other parts and screws.
The heat sink 110 may be composed of only the base portion 111 .

In this embodiment, the fin portion 112 is a metal plate bent into a U-shape, but it may be a metal plate bent into an L-shape or an I-shape.
Furthermore, the fin portion 112 is not limited to being made of sheet metal, but may be manufactured by aluminum extrusion molding or aluminum die casting, and the base portion 111 and the fin portion 112 may be integrated.

(Power supply unit 120)
The power supply unit 120 receives power from an external source and supplies the power to the light source unit 150 for lighting.
The power supply unit 120 includes a lighting circuit section 121 that converts external power into power for lighting the light source section 150, a harness 122 that connects to the lighting circuit section 121 and the light source section 150 and supplies power to the light source section 150, and a case section 123 that is attached to the top plate section 113 so as to cover the lighting circuit section 121. Two wires 1221 are provided at the end of the harness 122.
The lighting circuit section 121 has a power supply board 1222 on which the lighting circuit is mounted.

(Connecting portion 130)
The connecting portions 130 are disposed on both opposing sides of the heat sink 110 and are used to attach the arms 10 .

(Reinforcing portion 140)
The reinforcing portion 140 has a U-shaped cross section and is attached so as to cover the side of the base portion of the heat sink 110 .
The reinforcing portion 140 supplements the strength of the heat sink 110 .

(Light source unit 150)
The light source section 150 includes a light source board 151 on which a plurality of light emitting elements are mounted as light sources, and a lens section 152 which is attached to cover the light source board 151 and controls the light from the light emitting elements to a predetermined light distribution.
The light source unit 150 is thermally connected to the base unit 111 which serves as a mounting member.
The lens portion 152 is provided with a plurality of lenses corresponding to the light emitting elements.

(Cover portion 160)
The cover portion 160 transmits light from the light source portion 150 .
The cover unit 160 includes a cover 161 that is attached to the base unit 111 so as to cover the light source unit 150 , and a cover packing 162 that is sandwiched between the cover 161 and the base unit 111 .
The cover 161 has a box-shaped main cover 1611 with one side open, and a cover flange 1612 provided so as to protrude from the edge of the opening of the main cover 1611 .
The cover gasket 162 has an opening in the center and is disposed so as to be pressed between the cover flange portion 1612 and the base portion 111 .

●Figures 5 to 8
The connecting portion 130 and the reinforcing portion 140 will be described with reference to FIGS.
FIG. 5 is a perspective view of the connecting portion 130.
FIG. 6 is a perspective view of the reinforcing portion 140. As shown in FIG.
FIG. 7 is a reference diagram showing how to attach the reinforcing portion 140 to the heat sink 110. As shown in FIG.
FIG. 8 is a reference diagram showing how to attach the connecting portion 130 to the heat sink 110. As shown in FIG.

(Connecting portion 130)
The connecting portion 130 has a rectangular shape, a width L, and a height that is the same as or approximately the same as the height of the heat sink 110 .
The connecting portion 130 has a rectangular connecting main portion 131 having a connecting opening 1311, a top plate side protruding portion 132 protruding from the upper edge of the connecting main portion 131, a base side protruding portion 133 protruding from the lower edge of the connecting main portion 131, and a pair of lateral protruding portions 134 protruding from both side edges of the connecting main portion 131.

The main connection portion 131 has a window frame shape.
The main connecting portion 131 is a flat plate and has a connecting opening 1311 , a pillar portion 1312 , a central pressing portion 1313 which serves as a holding portion, frame side portions 1314 , a frame lower portion 1315 , and a frame upper portion 1316 .
The connecting opening 1311 is provided so as not to impede heat dissipation from the fin portion 112 (so as not to impede the flow of air in and out).

The pillar portion 1312 has a connection hole 13121 for connecting the arm 10 with a fastener such as a screw.

The central pressing portion 1313 , together with the base side protruding portion 133 , is a holding portion that sandwiches and holds the cover flange portion 1612 , the cover gasket 162 , and the base portion 111 .
The central pressing portion 1313 has a holding hole portion 13131 into which a cover fastener 169 such as a screw is screwed and fixed.

The top plate side protrusion 132 has a rectangular shape with a width of L and a depth of R, and abuts against the side (underside) of the top plate 113 where the fin portion 112 is located to hold the heat sink 110.

The base side protrusion 133 has a rectangular shape with a width of L, a depth of R at both ends, and a depth at the center that is greater than or equal to R. It abuts against the cover flange 1612 of the cover part 160 to hold the cover part 160 in place.

The lateral protrusion 134 has a rectangular shape, with a depth at the top that is R and gradually increases in depth toward the bottom, with the depth at the bottom being 2R or more.
The lateral protrusion 134 has a lateral pressing portion 1341 that abuts against the reinforcing portion 140 in order to improve the strength of the connecting portion 130 .
The side pressing portion 1341 has a pressing cutout portion 13411 that comes into contact with a cylindrical hole portion 141 described later. The pressing cutout portion 13411 is a semicircular or C-shaped cutout having an opening inwardly in a direction perpendicular to the main connection portion 131.
The lower frame portion 1315 and the upper frame portion 1316 are at the same height.
The distance between the central pressing portion 1313 and the base side protruding portion 133 is the same as the height of the frame lower portion 1315 , and is the same as the combined thickness of the cover flange portion 1612 and the base portion 111 .

(Reinforcing portion 140)
The reinforcing portion 140 has a U-shaped cross section and a width M.
The reinforcing portion 140 has an upper plate 147 , a back plate 148 , and a lower plate 149 .
The reinforcing portion 140 is attached to the base portion 111 so as to sandwich the cover flange portion 1612 , the cover gasket 162 , and the base portion 111 .

The distance between the upper plate 147 and the lower plate 149 is the sum of the thicknesses of the cover flange portion 1612 and the base portion 111.

The reinforcing portion 140 is provided with a cylindrical hole portion 141 and a reinforcing hole portion 142 so as to be fixed to the base portion 111 together with the cover portion 160 and the like by a cover fixing device 169 such as a screw.
The reinforcing portion 140 has a sloped portion 143 at its tip, making it easier to insert.
By attaching the reinforcing portion 140 to the base portion 111, the rigidity of the base portion 111 is improved, and the rigidity of the heat sink 110 is also improved.
The reinforcing portion 140 has a function and effect similar to that of a beam, and is provided between the two connecting portions 130 to suppress bending of the heat sink 110 .

Figures 9 and 10
The case 123 of the power supply unit 120 will be described with reference to FIGS.
FIG. 9 is an exploded perspective view of the case portion 123. As shown in FIG.
10 is a cross-sectional view of the case portion 123 taken along the line BB shown in FIG.

The case portion 123 has a case main body 1231 , a case gasket 1232 , and a bush 1233 .
The case body 1231 is formed by pressing a plate-shaped metal member from one direction (direction C in FIG. 9 ), and includes a box-shaped main case portion 12311 with one side open, and a case packing 12321.
232 and a case flange 12313 which abuts against the top plate 113 and is fixed by a case fastener 129 such as a screw.

The case packing 1232 is made of a resin material having elastic properties such as rubber, and is pressed and housed between the step portion 12312 and the top plate portion 113. By pressing and housing the case packing 1232, the sealing performance of the inside of the case body 1231 is improved, and the intrusion of water, etc. can be prevented.

The case body 1231 can be made thinner and lighter than a cast case, reducing the weight of the lighting fixture 1. In addition, the reduced rigidity can be compensated for by providing multiple steps (steps formed by the main case portion 12311, step portion 12312, and case flange portion 12313).

In addition, when the case body 1231 is formed by bending a cross-shaped metal plate, the ends of the bent plate are not connected to each other. This creates gaps that may allow water or other liquids to seep in. When a load is applied, there is also a risk that the unconnected ends may deform, but by forming the case body as a single unit, these concerns can be alleviated.

In addition, the case flange 12313 is provided around the entire circumference of the step 12312, and can be pressed against the case gasket 1232 all around, ensuring better sealing.

Figures 11 and 12
11 and 12, a fixture mounting bracket 200 for fixing the lighting fixture 1 to a mounting portion will be described.

FIG. 11A is a perspective view of the instrument mounting bracket 200. FIG.
FIG. 12 is a diagram showing the lighting fixture 1 attached to the fixture mounting bracket 200 of FIG. 11(a).
The fixture mounting bracket 200 is used to mount the lighting fixture 1 to a mounting base 900 having a vertical surface such as a wall.

The fixture mounting bracket 200 in FIG. 11(a) includes a fixture mounting portion 210 to which the lighting fixture 1 is attached, a bracket leg portion 220 that fixes the fixture mounting bracket 200 to the mounting portion, a bracket abdomen portion 230, and a bracket waist portion 240.

The bracket legs 220 are located on both sides of the appliance mounting bracket 200 and have a wall mounting portion 221 and a side portion 222 .
The wall mounting portion 221 is a flat plate portion that is fixed to the vertical surface of the mounting portion 900 by metal fasteners 901 such as screws.
The side surface portion 222 is a plate portion in the shape of a right triangle perpendicular to the wall mounting portion 221, and has a curved portion 223 on the hypotenuse.

The metal fitting waist portion 240 is a rectangular flat plate portion having a pair of side portions 222 on both ends.
The metal fitting waist portion 240 has a wire hole 241 in the center for passing an electric wire therethrough.
The metal body portion 230 is a rectangular flat plate portion that is perpendicular to the metal waist portion 240 .
The instrument mounting portion 210 is a rectangular flat plate portion that intersects with the metal fitting body 230 at an obtuse angle.

In FIG. 12, the tool attachment portion 210 intersects with the bracket body 230 at an angle of 150 degrees, and the tool attachment portion 210 attaches the arm 10 at an angle of 30 degrees relative to the horizontal plane. The arm 10 can be attached at an angle of 60 degrees relative to the vertical plane.

The fixture mounting portion 210 has a fixture fixing hole 211 into which a fastener such as a bolt for fixing the lighting fixture 1 can be attached.

The tool fixing hole 211 is provided so that two openings of different sizes are connected to each other, with the larger hole on the upper side and the smaller hole on the lower side. Because the tool fixing hole 211 has this shape, the bolt 291 and nut 292, which are the fixing devices, can be temporarily fixed to the mounting hole 11 of the arm 10 first, and then the head of the bolt can be inserted into the larger diameter tool fixing hole 211 and then slid into the smaller diameter hole (lower).

In other words, the head of the bolt temporarily attached to the arm 10 can be hooked into the tool fixing hole 211, and then the bolt and nut 292 can be tightened, making installation easier.

In addition, a gap 250 is formed between the tool mounting portion 210 and the metal fitting leg portion 220 when viewed from the side. This gap 250 allows a tool to be inserted horizontally from the side into the inside of the tool mounting fitting 200 when fastening the fastener, making the work easier (the worker does not have to reach behind).

In addition, an arc-shaped curved portion 223 is formed on the side of the metal fitting leg portion 220 in FIG. 11(a), forming a gap 250 so that a tool can be inserted from the side.

Furthermore, by having the metal fitting body 230, even if the fastening between the bolt 291 and the nut 292 becomes loose and the lighting fixture 1 attempts to move, the head of the bolt interferes with the metal fitting body 230, thereby preventing the movement.
FIG. 11B shows a modified example of the appliance mounting bracket 200 .
The appliance mounting bracket 200 in FIG. 11( b ) comprises an appliance mounting portion 210 and a bracket leg portion 220 .
The appliance mounting bracket 200 in FIG. 11(b) has a bracket leg 220 in the shape of a right triangle.
The side surface portion 222 and the tool attachment portion 210 are connected by being bent at a 90 degree intersection angle at a straight portion 224. A rectangular window 225 is formed in the side surface portion 222, and the window 225 forms a gap 250 so that a tool can be inserted from the side.

Figure 13
FIG. 13 shows a modified example of the case body 1231 of the power supply unit 120, and the case body 1231 may be cylindrical rather than box-shaped.

Figure 14
(Convex portion 114 of base portion 111 of heat sink 110 and packing structure)
As shown in FIG. 14, a base portion 111 of a heat sink 110 is plate-shaped.
The base portion 111 is made of, for example, an aluminum plate, but may be made of metal other than aluminum, such as stainless steel or iron.

As shown in FIG. 14A , the base portion 111 has a wiring through portion 119 .
The wiring through portion 119 has a convex portion 114 and a wire-passing packing 116 .
The convex portion 114 is a wire-passing portion.
The convex portion 114 is formed in a convex shape facing the opposite direction to the direction in which the light source substrate 151 is installed.
The convex portion 114 has a through hole 115 for passing a wiring 1221 for supplying power from the lighting circuit section 121 to the light source.
A packing 116 for passing wires is fitted into the through hole 115 of this convex portion 114 .

The wire-passing packing 116 prevents water and moisture from entering through the through-hole 115 through which the wire 1221 passes.
The wire-passing packing 116 is made of silicone rubber, fluororubber, etc. By disposing the wire-passing packing 116 on the convex portion 114 in this manner, it is possible to make it waterproof.
The wire-passing packing 116 has one or more wiring holes 117 for passing the wires 1221 therethrough.
The wire-passing packing 116 passes a wire 1221 having an outer diameter equal to or larger than the hole diameter of the wiring hole 117 through the wiring hole 117 .

The wire-passing packing 116 has wiring holes 117 in the same number as the number of wires 1221, and each wiring hole 117 passes only one wire.
The inside of wiring hole 117 is provided with projections and recesses to prevent water and moisture from entering. The outer shape of wire-passing packing 116 is made substantially the same as the inner shape of convex portion 114 of base portion 111, so that it is possible to reduce gaps when wire-passing packing 116 is attached to through hole 115 of base portion 111.

As shown in FIG. 14B , the wire-passing packing 116 of the wire-through portion 119 has a protrusion 118 .
The protruding portion 118 is a part of the wire-passing packing 116, and is a portion that protrudes from the base portion 111 of the heat sink 110 towards the side where the light source board 151 is located.
The protrusion 118 is inserted into the board hole 153 of the light source board 151 .
The protruding portion 118 has a protruding shape that corresponds to the board hole 153 of the light source board 151. In this embodiment, the protruding shape of the wire-passing packing 116 is an oval convex shape.
As shown in FIG. 14C, the substrate hole 153 of the light source substrate 151 may be an oval or elliptical hole, or may be a circle, a rectangle, a polygon, or another shape.
As shown in (d) and (e) of FIG. 14, instead of the board hole 153, the protrusion 118 may be inserted into a board cutout portion 154 formed by cutting out an end portion of the light source board 151.
The board cutout portion 154 in FIG. 14D is formed by cutting out a semicircular shape at the center of one side of the light source board 151 .
The board cutout portion 154 in FIG. 14E is formed by cutting out a protruding corner of the light source board 151 in a straight line.

By configuring the shape of the wire-passing gasket 116 to be thicker than the thickness of the light source board 151, it is possible to connect the wiring 1221 to the connection portion (connector) of the light source board 151 without the wiring 1221 touching the edge of the board hole 153 of the light source board 151.
The light source substrate 151 has an elliptical substrate hole 153 near the outer diameter of the substrate, allowing the wiring 1221 to pass through.

This makes it possible to route the wiring 1221 to the outside without increasing the outer diameter of the light source board 151, making it possible to implement wiring design without increasing the size of the lighting fixture.

According to the configuration shown in FIG. 14, even if the light source unit 150 and the heat sink 110 are in close contact with each other, a convex portion 114 having a through hole 115 is provided on the side of the base portion 111 opposite the surface on which the light source unit 150 is placed, so that a waterproofing material or other member can be provided in the through hole 115 of the convex portion 114.

The convex portion 114 of the wiring penetration portion 119 can be formed at any position on the base portion 111, and the shape of the convex portion 114 is also free.

In this way, the layout of the wiring penetration part 119 can be easily changed, and restrictions on component placement can be eliminated while keeping the light source part 150 and the heat sink 110 in close contact, making it possible to miniaturize the device. In other words, it is possible to route wiring without increasing the size of the device, and it is possible to provide a waterproof structure.

The through hole 115 of the convex portion 114 functions as a space between the light source portion 150 and the base portion 111, and by providing a through hole 115 (space) between the light source portion 150 and the base portion 111 and disposing a wire-passing gasket 116, which serves as a waterproof member, in the space between the light source portion 150 and the base portion 111, it is possible to easily ensure waterproof performance.

In other words, the configuration shown in Figure 14 makes it possible to route wiring without increasing the size of the device, and to provide a waterproof structure.

Figure 15
(Heat sink 110 and sheet 170 of light source substrate 151)
The light source unit 150 is disposed on the opposite side of the base unit 111 of the heat sink 110 to the fin unit 112 .

The light source unit 150 is composed of a light source board 151, a light source disposed on the light source board 151, and a connection unit (connector).
The light source substrate 151 is made of aluminum, composite substrate epoxy resin (CEM3), glass cloth substrate epoxy resin (FR-4), paper phenol, or the like.
If heat dissipation performance is required, the light source substrate 151 is preferably made of aluminum.

On the other hand, when the light source substrate 151 is made of aluminum, it is preferable to provide an insulator between the base portion 111 of the heat sink 110 and the light source substrate 151 to ensure insulation performance.

In this case, it is preferable to install a heat dissipation sheet with insulating properties.

In cases where heat dissipation capability is not required, an insulating sheet such as a polyethylene terephthalate (PET) sheet or a polycarbonate (PC) sheet may be provided.
Generally, heat dissipation sheets are made by blending various materials, and therefore are more expensive than insulating sheets.

As shown in FIG. 15, the sheet 170 of this embodiment uses two types of sheets, a heat dissipation sheet 171 serving as a thermally conductive sheet, and an insulating sheet 172 .
FIG. 15 is a schematic diagram showing the thicknesses of the heat dissipation sheet 171 and the insulating sheet 172 in an enlarged scale.

As shown in FIG. 15A, one sheet of two types of sheets may entirely overlap the other sheet.
In order to ensure an insulating distance from the outer periphery of the light source board 151 to the heat sink 110, the sheet 170 is provided with a heat dissipation sheet 171 having approximately the same shape as the light source board 151, and an insulating sheet 172 that overlaps the heat dissipation sheet 171 when viewed from the light emitting surface of the light source unit.

As shown in FIG. 15B, the insulating sheet 172 may be formed in an annular, annular, or ring-like shape, so that the entirety of one of the two types of sheets overlaps with a portion of the other sheet.
Since the insulating sheet 172 has a lower thermal conductivity than the heat dissipation sheet 171, it is preferable that the portion that overlaps with the heat dissipation sheet 171 be as small as possible. Therefore, it is preferable that the insulating sheet 172 has a substantially ring-like shape with an opening in the center.

As shown in FIG. 15C, the insulating sheet 172 may be formed in an annular, loop, or ring shape, with a portion of one of the two types of sheets overlapping a portion of the other sheet.
At least a portion of the insulating sheet 172 , i.e., the inner edge of the insulating sheet 172 , overlaps with at least a portion of the heat dissipation sheet 171 , i.e., the outer edge of the heat dissipation sheet 171 .
At least a portion of the insulating sheet 172 , i.e., the outer edge of the insulating sheet 172 , does not overlap the heat dissipation sheet 171 and is disposed outside the heat dissipation sheet 171 .

As shown in FIG. 15(d), the insulating heat dissipation sheet 171 may be made circular and smaller than the light source substrate 151, and the insulating sheet 172 may be made annular, annular, or ring-shaped, and disposed outside the heat dissipation sheet 171 without overlapping the heat dissipation sheet 171. This ensures an insulating distance from the outer periphery of the light source substrate 151 to the heat sink 110.

If there is a gap at the boundary between the heat dissipation sheet 171 and the insulating sheet 172, there is a possibility that an electrical path may be formed through the gap. Therefore, it is possible to ensure the insulating performance by increasing the thickness of the sheet or by stacking the sheets to ensure a specified distance (the required insulating distance).

The sheet 170 in FIG. 15 uses two types of sheets, thereby achieving both heat dissipation performance and insulation performance without increasing costs.
15, it is possible to ensure the insulation distance from the board end while ensuring heat dissipation performance. Also, by providing insulating sheet 172 while reducing the size of heat dissipation sheet 171 having insulating performance, it is possible to ensure the insulation distance, which is also effective as a surge countermeasure, and it is possible to ensure a predetermined insulation performance with an inexpensive configuration.

FIG. 16
(Configuration of Cover Part 160: Film Insert)
A cover portion 160 for protecting the light source is disposed on the light source side of the base portion 111 of the heat sink 110 .
The cover portion 160 is made of resin such as PC or polymethylmethacrylate resin (PMMA), or made of a metal member such as aluminum die-cast, and glass.
The material of the cover portion 160 can be changed as appropriate depending on the usage environment.

For example, in a high-temperature environment or an environment containing oil, if the cover portion 160 is made of PC or PMMA resin, the heat resistance temperature or the aggressiveness of the oil may cause the resin to melt, deteriorate, or crack, so it is preferable to make the cover portion 160 out of metal members and inorganic materials such as glass.

On the other hand, if metal and glass are used for the cover 160, the product will be heavy because of its higher specific gravity compared to resin. In addition, it is difficult to form the shape as a single piece like resin, and there are issues such as poor assembly due to the increased number of parts and increased costs.

Therefore, in this embodiment, as shown in FIG. 16A, a cover 161 of a cover unit 160 is configured with a main body unit 1601 and a film 1602 .
When the body 1601 of the cover 161 of the cover unit 160 is made of a resin such as PC or PMMA, a resin film 1602 made of a material other than PC or PMMA is integrally formed on the entire outer surface of the body 1601 .
By molding resin film 1602 integrally with the entire outer surface of main body 1601, it is possible to complement weak portions of the main resin that constitutes cover 160.

For example, by using film 1602 made of a material such as PET or polyethylene naphthalate (PEN), even in an environment where various chemical substances such as oil or chemicals are present and it is difficult to use PC or PMMA, the barrier properties of film 1602 integrally molded into the outer shell make it possible to use resin cover portion 160 without affecting the main resin.
Specifically, since polycarbonate is vulnerable to oil, an oil-resistant film is provided on the outside.

The cover 161 may be provided with different types of films 1602 depending on the parts of the outer shell, such as a heat-resistant film, an oil-resistant film, a reinforced film, a polarizing film, a diffusion film, a color film, a reflective film, and the like.
As shown in FIGS. 16A, 16B, and 16C, the cover 161 has different types of films 1602, 1603, and 1604 provided on the underside of the main body 1601, the sides of the main body 1601, and the underside of the cover flange 1612.
As shown in FIG. 16D, films 1602 and 1603 may be provided on the lower and upper surfaces of a main body 1601 of a cover 161 .
As shown in FIG. 16E, two or more different types of films 1602 and 1603 may be disposed on the lower surface of the main body 1601 of the cover 161 in a fully layered or partially layered manner.

Specifically, the following configurations and combinations thereof are possible:
A reinforced film is provided on the inner surface, the outer surface, or both surfaces of the cover flange 1612.
- Reinforced film is installed on the corners of the main cover.
- Reinforced film is applied to the underside of the main cover.
- Reinforced film is applied to the sides of the main cover.
-Reflective film is placed on the side of the main cover.
- A heat-resistant or oil-resistant film is provided on the outer surface of the main cover.
- A polarizing film, a diffusion film or a color film is arranged on the inner surface of the main cover.
According to the configuration of FIG. 16, different types of films are provided depending on the portion of the cover 161, so that protection suited to the portion of the cover 161 can be achieved.

By imparting optical properties to film 1602, it is possible to give it the function of changing the direction of light, and at the same time, it is possible to give it a light distribution control function. Methods for imparting optical properties to film 1602 include blending a diffusing material, pigment, or dye into film 1602, arranging a geometric pattern, controlling light distribution by changing the cross-sectional shape, etc.

This makes it possible to easily ensure the performance required for the lighting fixture's intended use by changing the film 1602 without changing the main resin of the cover portion 160.

In addition, in this embodiment, the lens of the lens unit 152 is arranged on the light source of the light source substrate 151, but the lens may be integrally formed on the inner surface of the main body 1601 of the cover unit 160.

According to the configuration of Figure 16, it is possible to complement the weak physical properties of the base resin by placing a film on the outer periphery of the molded product without performing coating or two-color (multi-color) molding.

Figure 2
(Waterproofing by packing between heat sink 110 and cover part 160)
As shown in FIG. 2, the cover 161 has a main cover 1611 that covers the light source unit 150, and a cover flange 1612 that is fixed to the base unit.

The cover gasket 162 is a waterproof member that is fixed in close contact with the cover flange portion 1612 and the base portion 111 .
The cover gasket 162 is a water-tight gasket having an annular shape that fits the cover flange 1612 .

The base portion 111 and the cover portion 160 of the heat sink 110 are fixed together by a cover fastener 169 , which is a fastening member such as a screw, and the reinforcing portion 140 .
In the absence of the cover gasket 162 , the cover fastener 169 fastens the cover 161 to the base portion 111 .
The base portion 111 and the cover portion 160 are fixed together by a cover fixing device 169 , and the reinforcing portion 140 is not necessary for fixing the base portion 111 and the cover portion 160 together.

If a cover gasket 162 is present, the cover fixing device 169 adheres the cover gasket 162 tightly between the base portion 111 and the cover 161, fixing the cover 161 to the base portion 111.

Normally, when lighting fixtures are used indoors, there are no particular problems with a structure that fastens them with fastening members such as screws. However, when lighting fixtures are used under the eaves or on the roof side, water or moisture may get in due to rainfall, and if there are gaps between parts, there is a concern that water may get in and cause poor insulation or rust in the parts.

Therefore, in this embodiment, a cover packing 162 shaped to match the shape of the portion of the cover part 160 that contacts the base part 111 of the heat sink 110 is disposed between the base part 111 (plate-shaped mounting member) of the heat sink 110 and the cover part 160 to prevent the intrusion of water and moisture. The cover packing 162 is made of silicone rubber or fluororubber.

A waterproofing member is clamped between either the contact surface between the head of the screw and the base portion 111 or the contact surface between the head of the screw and the cover 161 .
The base portion 111 of the heat sink 110, the cover packing 162, and the cover portion 160 are fixed with a cover fastener 169 such as a screw. If the screw is used as is, water or moisture may get in through the gap at the tip of the screw or the screw head.

For this reason, it is desirable to place a waterproof washer (a metal or plastic washer with a waterproof material such as rubber integrated on one side) on the screw head side.

In addition, a waterproofing member is provided at the tip of the screw (screw tip).
In addition to the waterproof washer on the screw head side, it is desirable to provide a waterproof washer and a cap nut on the screw tip side as well. Alternatively, a crimp nut or the like may be pressed into the base portion 111 of the heat sink 110 in advance, thereby making it unnecessary to process the screw tip side.

According to the configuration in FIG. 2, the cover fixing device 169 and the reinforcing part 140 fix the base part 111 and the cover 161 regardless of whether the cover packing 162 is present or not, so it is possible to configure a fixture that requires waterproof performance without changing the structure of the lighting fixture.

In addition, according to the configuration of FIG. 2, even if the number of light source units is increased or decreased, it is possible to configure a lighting fixture that does not require waterproof performance and a lighting fixture that does require waterproof performance by simply using or not using one cover gasket 162 (one waterproof member) without changing the structure of the lighting fixture.

In addition, with the configuration shown in FIG. 2, it is possible to share parts with non-waterproof general equipment and provide waterproof performance by adding only one cover gasket 162.

Figures 6 and 7
(Reinforcing portion 140 suppressing deformation of base portion 111 of heat sink 110)
When a cover gasket 162 is sandwiched between the base portion 111 (plate-shaped mounting member) and cover portion 160 of the heat sink 110 to achieve a waterproof structure, if the base portion 111 of the heat sink 110 is made of a plate material such as sheet metal and is fixed in place with a fixing member such as a screw, there is a possibility that the base portion 111 of the heat sink 110 will be deformed by sandwiching the cover gasket 162 (while crushing it).

Therefore, as shown in FIG. 6, in this embodiment, in addition to the base portion 111, cover packing 162, and cover portion 160 of the heat sink 110, a reinforcing member is provided as the reinforcing portion 140 to prevent deformation of the base portion 111 of the heat sink 110.

The reinforcing member is provided to increase the rigidity of the end portion (outer peripheral surface) of the base portion 111 of the heat sink 110 .
Methods for increasing the rigidity of the base portion 111 include the following configurations.
(1) The thickness of the base portion 111 is increased.
(2) A U-shaped part is fixed to the end cross section of the base portion 111 to increase the section modulus.
(3) An L-shaped part is fixed to the end cross section of the base portion 111 to increase the section modulus.

In the case of increasing the plate thickness of (1), the following configurations can be mentioned.
(1-1) Increase the thickness of the entire base portion 111.
(1-2) A ring plate having the same outer circumferential shape as the outer circumferential shape of the base portion 111 is fixed to the outer edge of the base portion 111.

When the cross section of (2) is U-shaped, a reinforcing part 140 with a U-shaped cross section is attached. The U-shaped reinforcing part 140 is arranged so that the reinforcing member sandwiches the cover part 160, the cover packing 162, and the base part 111.

The reinforcing portion 140 will be described below with reference to FIG.
The reinforcing portion 140 is fixed to the edge of the base portion 111 .
The reinforcing portion 140 is an individual component having a generally U-shaped cross section, and sandwiches the base portion 111 and the cover 161. Alternatively, the reinforcing portion 140 sandwiches the base portion 111, a cover packing 162, and the cover 161.

The reinforcing portion 140 has an upper plate 147 , a back plate 148 , and a lower plate 149 .
The upper plate 147 has three cylindrical holes 141 at both ends and in the center.
The cylindrical hole portion 141 protrudes in a cylindrical shape from the upper surface of the upper plate 147, and a thread is formed on the inner wall into which a cover fastener 169 such as a screw is fitted.
The lower plate 149 has three reinforcing holes 142 at both ends and in the center.
The reinforcing hole 142 is a through hole through which a cover fastener 169 such as a screw passes.
The upper plate 147 has an upper recess 1471 in the center which is recessed toward the back plate 148 .
The upper recess 1471 is recessed in an arc shape so as not to interfere with the circular outer periphery of the fin portion 112 .
On both sides of the reinforcing hole 142 in the center of the upper recess 1471 , there are cutouts 1472 so as not to interfere with the outer ends of the fin portions 112 arranged on both sides of the reinforcing hole 142 .
The lower plate 149 has a lower recess 1481 in the center that recesses toward the back plate 148 .
The lower recess 1481 is recessed in a trapezoidal shape so as not to interfere with the outer periphery of the base of the main cover 1611 of the cover portion 160 .
Since the circular outer periphery of the fin portion 112 bulges outward more than the outer periphery of the base of the main cover 1611 , the amount of depression of the upper depression 1471 is greater than the amount of depression of the lower depression 1481 .

The central cylindrical hole portion 141 and the central reinforcing hole portion 142 are formed at positions closer to the back plate 148 than the two cylindrical hole portions 141 and the two reinforcing hole portions 142 on either side.
The upper plate 147 has five inclined portions 143 formed parallel to the back plate 148 .
The lower plate 149 has four inclined portions 143 formed parallel to the back plate 148 .
Except for both ends of the upper plate 147 , the upper plate 147 and the lower plate 149 have inclined portions 143 on all sides parallel to the back plate 148 .
Since the side holding portions 1341 rest on both ends of the upper plate 147, there are no inclined portions 143 on both ends of the upper plate 147.
Since both ends of the lower plate 149 do not interfere with the base-side protruding portion 133, the lower plate 149 has inclined portions 143 at both ends.

(Method of attaching the reinforcing portion 140)
As shown in FIG. 7 , the reinforcing portion 140 is inserted from the side so as to sandwich the cover flange portion 1612 , the cover packing 162 and the base portion 111 , and is fixed to the straight portion of the base portion 111 with a cover fixing device 169 .

At this time, the reinforcing portion 140 is inserted so as to press the cover packing 162 .
The reinforcing portion 140 has an inclined portion 143, so that it can be easily inserted.
The reinforcing portion 140 has a width M, the base portion 111 has a length L, and the ends of the reinforcing portion 140 are each spaced a distance R from the sides perpendicular to the side to which the reinforcing portion 140 is attached.

(Method of attaching connecting portion 130)
8 , the connecting portion 130 is attached by being inserted from the side of the heat sink 110. The distance between the central pressing portion 1313 and the base side protruding portion 133 is smaller than the distance between the side pressing portion 1341 and the base side protruding portion 133 by the thickness of the upper plate 147 of the reinforcing portion 140.

The relationship of each part when installed is as follows:
The top plate side protrusion 132 abuts against the side (lower surface side) of the top plate portion 113 on which the fin portion 112 is located.
The base side protrusion 133 abuts against the cover flange 1612 .
Since the base side protrusion 133 has a depth R, the base side protrusion 133 does not collide with the lower plate 149 of the reinforcing part 140 .
The center pressing portion 1313, together with the base side protruding portion 133, sandwiches and holds the cover flange portion 1612 and the cover packing 162. At this time, the cover packing 162 is pressed toward the base portion 111.
The side pressing portion 1341, together with the base-side protruding portion 133, sandwiches and holds the cover flange portion 1612, the cover packing 162, the base portion 111, and the upper plate 147 of the reinforcing portion 140. At this time, the cover packing 162 is pressed toward the base portion 111.
The side pressing portion 1341 abuts against the upper surface of the end portion of the upper plate 147 of the reinforcing portion 140 (not shown in FIG. 8).

The end of the upper plate 147 of the reinforcing part 140 is separated by R from the main connecting part 131 of the connecting part 130, but since the depth of the side pressing part 1341 is 2R or more, the side pressing part 1341 can be placed on the upper surface of the end of the upper plate 147.

The side retaining portion 1341 comes into contact with the reinforcing portion 140, which increases the resistance to loads such as shaking or twisting, thereby improving the strength of the lighting fixture 1. In addition, by placing the side retaining portion 1341 on the end of the upper plate 147 of the reinforcing portion 140 at the corner of the base portion 111, deformation of the base portion 111 in the diagonal direction is suppressed.

In addition, the pressing notch portion 13411 abuts against the tubular hole portion 141, which can prevent catching and twisting when a load such as twisting is applied. In addition, the pressing notch portion 13411 abuts against the outer peripheral wall of the tubular hole portion 141, preventing the reinforcing portion 140 from coming loose.

When the reinforcing portion 140 is an individual component having an L-shaped cross section, the reinforcing portion 140 having an L-shaped cross section is attached. The reinforcing portion 140 having an L-shaped cross section covers the edges and end faces of the base portion 111.

An L-shaped metal fitting is placed on the base portion 111 of the heat sink 110 as a reinforcing member, and the cover portion 160, cover gasket 162, and base portion 111 of the heat sink 110 are fastened together, thereby making it possible to fix the base portion 111 of the heat sink 110 while suppressing deformation of the base portion 111.

By attaching a reinforcing member such as reinforcing portion 140 shown in FIG. 6 around the periphery of base portion 111, deformation of base portion 111 can be prevented.
The reinforcing portion 140 shown in FIG. 6 suppresses deformation of the plate-like base portion 111, and by sandwiching the cover packing 162, it is possible to reduce the weight of the device while ensuring waterproof performance.
Furthermore, when the reinforcing portion 140 is made of a metal such as aluminum or iron, and the cover 161 is made of a metal such as aluminum die-cast (aluminum die-cast material), a heat dissipation effect can be expected. That is, the heat of the heat sink 110 can be transferred to the aluminum die-cast cover 161 via the reinforcing portion 140.

Figure 17
(Suppression of deformation of base portion 111 of heat sink 110)
The peripheral edge of the base portion 111 is bent by 90 degrees to form an outer periphery of the base portion 111 having an L-shaped cross section.
As a method for increasing the rigidity of the base portion 111 of the heat sink 110 without using a reinforcing member, it is possible to bend the end portion of the base portion 111 of the heat sink 110 as shown in FIG.

The base portion 111 has a circular light source fixing portion 1112 to which the light source portion 150 is fixed on the lower surface, and a bent portion 1111 bent downward from the outer end portion of the light source fixing portion 1112 .
The bent portion 1111 is formed by bending one entire side of the base portion 111 along a straight bending line parallel to the side of the base portion 111 .
Top plate portion 113 has a circular fin fixing portion 1132 that fixes fin portion 112 to its underside, and a bent portion 1131 that is bent downward from the outer end portion of fin fixing portion 1132 .
The bent portion 1131 is formed by bending one entire side of the top plate portion 113 along a straight bending line parallel to the side of the top plate portion 113 .

In FIG. 17A, the bent portion 1111 is bent 90 degrees downward from the end of the light source fixing portion 1112. Similarly, the bent portion 1131 is bent 90 degrees downward from the end of the fin fixing portion 1132.

In FIG. 17B, the bent portion 1111 is bent downward at an angle greater than 90 degrees and less than or equal to 180 degrees from the end of the light source fixing portion 1112. Similarly, the bent portion 1131 is bent downward at an angle greater than 90 degrees and less than or equal to 180 degrees from the end of the fin fixing portion 1132.

A bent portion may be formed in only one of the base portion 111 and the top plate portion 113. That is, a bent portion may be formed in at least one of the base portion 111 and the top plate portion 113.
Bent portions 1111 and 1131 are formed on a pair of opposing sides to which connecting portion 130 is not fixed. In this embodiment, base portion 111 and top plate portion 113 are rectangular, connecting portion 130 is fixed to two opposing sides of the rectangle, and bent portions are formed on the remaining two opposing sides of the rectangle.

Adding a reinforcing member requires an increase in the number of parts, but bending the base portion 111 of the heat sink 110 makes it possible to increase rigidity without changing the number of parts.

In the case of a waterproof device, it is expected that water will come into direct contact with the device. If water remains inside the device, it can cause rust or water infiltration. Therefore, as shown in Figures 25 and 28, it is preferable that the bending direction of the bent portion 1111 at the end of the base portion 111 of the heat sink 110 is opposite to the fin portion 112 of the heat sink 110.

If the base portion 111 of the heat sink 110 is bent in the same direction as the fin portion 112 of the heat sink 110, the base portion 111 of the heat sink 110 will become tray-shaped and water will accumulate therein.
By bending the heat sink 110 in the opposite direction to the fin portion 112, even if water is splashed on the heat sink 110, the water flows away without stagnating.
Even in a device that does not have a packing, bending the end of the base portion 111 of the heat sink 110 is an effective method for increasing the rigidity of the base portion 111 of the heat sink 110. Increasing the rigidity of the base portion 111 of the heat sink 110 makes it possible to directly fix the ceiling mounting arm 10 to the base portion 111 of the heat sink 110.

The case of the top plate portion 113 is similar to that of the base portion 111 .
According to the configuration of Figure 17, by providing a bent portion on each side of the base portion 111 or the top plate portion 113 of the heat sink 110, deformation can be suppressed, and when a gasket or the like is tightened to the base portion 111 or the top plate portion 113, deformation of the base portion 111 or the top plate portion 113 and the gasket, etc. can be suppressed.

FIG. 18 is a diagram showing a modified example of the bent portion 1131 of the top plate portion 113. In FIG.
(a) shows that the bent portion 1131 of the top plate portion 113 is bent downward 90 degrees to form an L-shaped cross-sectional shape perpendicular to the side of the base portion 111, the top plate side protrusion portion 132 of the connecting portion 130 is placed on top of the top plate portion 113, the bent portion 1131 is placed inside the main connecting portion 131 of the connecting portion 130, and the bent portion 1131 and the main connecting portion 131 are fixed with a top plate fixing device 137 such as a screw.

(b) shows that the bent portion 1131 of the top plate portion 113 is bent downward by 90 degrees to form an L-shaped cross-sectional shape perpendicular to the side of the base portion 111, the top plate side protrusion portion 132 of the connecting portion 130 is located below the top plate portion 113, the bent portion 1131 is on the outside of the main connecting portion 131 of the connecting portion 130, and the top plate side protrusion portion 132 and the top plate portion 113 are fixed with a top plate fixing device 137 such as a screw.

(c) shows a structure in which the top plate-side protrusion 132 is removed from the connecting part 130, the bent part 1131 of the top plate part 113 is bent downward by 90 degrees to form an L-shaped cross section perpendicular to the side of the base part 111, the bent part 1131 is placed inside the main connecting part 131 of the connecting part 130, and the bent part 1131 and the main connecting part 131 are fixed with a top plate fixing device 137 such as a screw.

(d) shows a structure in which the top plate-side protrusion 132 has been removed from the connecting part 130, the bent part 1131 of the top plate part 113 has been bent downward by 90 degrees to form an L-shape, the bent part 1131 is on the outside of the main connecting part 131 of the connecting part 130, and the bent part 1131 and the main connecting part 131 are fixed together with a top plate fixing device 137 such as a screw.

(e) shows that the bent portion 1131 of the top plate portion 113 is bent 180 degrees to form a U-shaped cross section perpendicular to the side of the base portion 111, and the bent portion 1131 is placed on the top plate side protrusion 132 of the connecting portion 130, and the top plate portion 113, bent portion 1131, and top plate side protrusion 132 are fixed together with a top plate fixing device 137 such as a screw.

(f) shows that the bent portion 1131 of the top plate portion 113 is bent 180 degrees to form a U-shaped cross section perpendicular to the sides of the base portion 111, and the bent portion 1131 is placed below the top plate side protrusion 132 of the connecting portion 130, and the top plate portion 113, bent portion 1131, and top plate side protrusion 132 are fixed together with a top plate fixing device 137 such as a screw.

In the configurations (c) and (d), there are no parts protruding from the upper surface of the top plate portion 113.
In the configurations (b) and (e), the only parts protruding from the upper surface of the top plate portion 113 are the screw heads of the top plate fixing devices 137.

FIG. 19 is a diagram showing a modified example of the bent portion 1111 of the base portion 111. In FIG.
1A, the bent portion 1111 of the base portion 111 is bent downward by 90 degrees to form an L-shaped cross-sectional shape perpendicular to the side of the base portion 111, the bent portion 1111 is on the outside of the cover flange portion 1612, the base side protrusion portion 133 of the connecting portion 130 is below the lower tip of the bent portion 1111, the bent portion 1111 is on the inside of the main connecting portion 131 of the connecting portion 130, and the central pressing portion 1313 and the base side protrusion portion 133 are fixed by a cover fixing device 169 such as a screw between the cover flange portion 1612 and the base portion 111.

(b) shows that the bent portion 1111 of the base portion 111 is bent twice by 90 degrees to form a U-shaped cross section perpendicular to the sides of the base portion 111, the cover flange portion 1612 is placed in close contact with the recess of the U-shape of the bent portion 1111, the bent portion 1111 is placed inside the main connection portion 131 of the connection portion 130, and the cover flange portion 1612 and the base portion 111 are sandwiched between the center pressing portion 1313 and the base side protruding portion 133 and fixed with a cover fixing device 169 such as a screw.

(c) shows that the bent portion 1111 of the base portion 111 is bent 180 degrees to form a U-shaped cross-sectional shape perpendicular to the side of the base portion 111, with the bent portion 1111 on the outside of the cover flange portion 1612 and the bent portion 1111 on the inside of the main connection portion 131 of the connection portion 130, and the cover flange portion 1612 and the base portion 111 are sandwiched between the central pressing portion 1313 and the base side protrusion portion 133 and fixed with a cover fixing device 169 such as a screw.
Although not shown, in the area where the central pressing portion 1313 is not present, the base portion 111 and the base side protruding portion 133 may be fixed with a cover fastener 169 such as a screw, sandwiching the cover flange portion 1612 therebetween.

Figures 9 and 10
(Power supply case draw structure)
The lighting device 1 has a lighting circuit section 121 and a case section 123 that covers the lighting circuit section 121 .
In this embodiment, the lighting circuit section 121 and the case section 123 are placed on a top plate section 113 disposed on the upper part of the heat sink 110 .

The lighting circuit unit 121 and the case unit 123 may be installed directly on the base unit 111 of the heat sink 110 instead of on the top plate unit 113, or may be attached to the arm 10 for ceiling mounting. Also, a space may be provided above the fin unit 112 of the heat sink 110, and the case unit 123 may be attached across the left and right sides of the arm 10.
The case 123 has a function of protecting the lighting circuit 121. Specifically, the case 123 has a function of preventing direct contact with the power supply board 1222, a function of preventing dust from accumulating, a function of ensuring insulation performance, and the like.

In general, when making the box-shaped case portion 123 from sheet metal, the box shape is formed by bending the unfolded shape of a roughly cross shape. In this case, gaps will be created at the ridges (butt joints) of each bent and raised surface. If there are gaps, there is a risk of dust accumulating as mentioned above, or of the board coming into contact with the surface. It is possible to solve the above problem by welding the ridges (butt joints), but welding takes time to process and requires confirmation that the welding has been done without any gaps.

In this embodiment, in order to solve the above problem, a single plate material (sheet metal) is drawn (deep drawn) to form a box-shaped (cylindrical) case portion 123 with no gaps. The drawing can be performed by pressing or the like. The box shape is formed by pressing from one direction, and one side is open.

The case portion 123 is a seamless recess formed from a single metal plate and houses the lighting circuit portion 121 in the recess.
The case portion 123 has a recessed main case portion 12311 having an opening, a step portion 12312 formed around the opening, and a case flange portion 12313 formed around the step portion 12312.
The step portion 12312 is a packing storage portion that stores the case packing 1232.
The step portion 12312 is in the form of a staircase.
The step portion 12312 has a horizontal ring portion 12314 and a vertical band portion 12315 .
The horizontal ring portion 12314 is located between the main case portion 12311 and the vertical band portion 12315 and is a rectangular ring portion parallel to the case flange portion 12313.
The vertical band portion 12315 is located between the horizontal ring portion 12314 and the case flange portion 12313 and is a circular band portion parallel to the side of the main case portion 12311.
The case portion 123 is formed by drawing a single metal plate from one direction, and each corner has no sharp edges and all corners have curved surfaces.

When waterproofing the case portion 123, this can be easily achieved by arranging a ring-shaped case packing 1232 on the opening side of the case portion 123.
The case gasket 1232 is disposed on the step portion 12312 and is sandwiched between the step portion 12312 and the top plate portion 113 .
The case packing 1232 has a rectangular annular frame, and the cross section of the frame is rectangular.
The outer shape of the case gasket 1232 is the same as the inner shape of the vertical band portion 12315.
The height of the case gasket 1232 is higher than the height of the vertical band portion 12315, but is compressed by the horizontal ring portion 12314 and the case flange portion 12313 to make it the same height as the vertical band portion 12315.
The case packing 1232 has two annular protrusions 111 on its lower surface, which is in intimate contact with the upper surface of the top plate 113.
2321.
The annular convex portion 12321 is deformed by pressure applied by the horizontal ring portion 12314 and the top plate portion 113, thereby improving the water-stopping effect.
The case gasket 1232 has two annular ridges 12322 on its outer surface which is in intimate contact with the inner surface of the vertical band portion 12315 .

When the case packing 1232 is pressurized and expands outward, the annular ridge portion 12322 is pressed against the inner wall of the vertical band portion 12315 and deforms, improving the water-stopping effect.
Case packing 1232 is preferably made of silicone rubber or fluororubber.

When fixing the case portion 123 to the top plate portion 113, the rigidity of the top plate portion 113 can be increased by bending the ends of the top plate portion 113, similar to the base portion 111 of the heat sink 110 described above, and deformation of the top plate portion 113 can be suppressed.

In addition, by bending the case 123 in the opposite direction (downward), it is possible to prevent water from accumulating.

The case 123 shown in Figures 9 and 10 is formed by pressing from one direction and has a box-shaped (cylindrical) power supply storage section with one open side. Since there are no butt joints on the side of the case 123, airtightness can be easily ensured.

As a result, there are absolutely no gaps at the corners of the case 123, and airtightness can be easily ensured without post-processing such as welding the ridges (butt joints), making it possible to prevent the intrusion of dust and water.

In addition, the case fixing device 129 fixes the top plate portion 113 and the case portion 123 regardless of whether the case packing 1232 is present or not, so it is possible to configure a device that requires waterproof performance without changing the structure of the lighting fixture.

In addition, it is possible to configure devices that do not require waterproofing and devices that do require waterproofing, simply by the presence or absence of one case gasket 1232 (one waterproofing member).

In addition, it is possible to share parts with non-waterproof general equipment and provide waterproof performance by adding only one case gasket 1232.

Figures 5 and 8
(Fixed portion 139 of connecting portion 130)
The cover portion 160 is fixed to the base portion 111 of the heat sink 110 by a cover fastener 169 which is a fastening member such as a screw.
Furthermore, a top plate portion 113 is provided on the heat sink 110, and a lighting circuit portion 121 and a case portion 123 are fixed on top of the top plate portion 113.
The base portion 111 and the top plate portion 113 of the heat sink 110 are fixed together by a connecting portion 130 .

The ceiling mounting arm 10 is also fixed to this connecting portion 130 .
The connecting portion 130 is a fixing metal fitting that fixes the base portion 111, the top plate portion 113, and the cover portion 160 together.
The lateral protrusion 134 is a connection portion that extends in the vertical direction.
The lateral protrusion 134 has a vertically long elongated shape, and the skirt portion at the bottom of the lateral protrusion 134 gradually becomes wider as it approaches the base portion 111 .

The top plate side protrusion 132 is an upper fixing part for attaching the top plate part 113 .
The base side protrusion 133 is a lower fixed part that covers and supports the cover part 160 .
The side retaining portion 1341 is located between the upper fixing portion and the lower fixing portion, and is an intermediate fixing portion that fixes the screw that penetrates the base portion 111 of the heat sink 110 and receives the base portion 111 of the heat sink 110.

The connecting portion 130 connects the base portion 111 and the top plate portion 113 , and fixes the cover portion 160 and the base portion 111 .
The connecting portion 130 has a flat connecting main portion 131 located between the top plate portion 113 and the base portion 111 .
The connecting portion 130 has a fixing portion 139 at the lower portion of the connecting portion 130 that sandwiches and fixes the cover portion 160 and the base portion 111 .

The fixing portion 139 is composed of a base side protruding portion 133 , side pressing portions 1341 and a central pressing portion 1313 .
The base side protrusion 133 is perpendicular to the main connection portion 131 at the lower end of the main connection portion 131 .
The base side protrusion 133 covers the lower surface of the edge of the cover portion 160 , i.e., the lower surface of the cover flange portion 1612 .

The base side protrusion 133 is formed by bending the lower end of the main connection portion 131 by 90 degrees.
The side pressing portions 1341 and the central pressing portion 1313 are disposed midway along the main connecting portion 131 and parallel to the base side protruding portion 133 .

The side pressing portion 1341 covers the upper surface of the end portion of the reinforcing portion 140 .
The central pressing portion 1313 covers the upper surface of the center of the edge of the base portion 111 .
The connecting portion 130 has a lateral protruding portion 134 that is perpendicular to the connecting main portion 131 at a side end of the connecting main portion 131 .
The lateral protrusion 134 can be formed by bending the lateral end of the main connecting portion 131 by 90 degrees.
The side pressing portion 1341 is perpendicular to the side protruding portion 134 below the side protruding portion 134 .
The side pressing portions 1341 can be formed by bending the lower ends of the side protruding portions 134 inward by 90 degrees.

The side pressing portion 1341 is a plate that presses the end portion of the base portion 111 .
The connecting portion 130 has a pillar portion 1312 at the center of the connecting main portion 131,
The central pressing portion 1313 is perpendicular to the column portion 1312 below the column portion 1312 .
The central pressing portion 1313 can be formed by cutting out a portion of the lower part of the pillar portion 1312 into a tongue shape and bending it inward by 90 degrees.

The central pressing portion 1313 is formed in the center of the connecting portion 130 in the left-right direction, and protrudes from the main connecting portion 131 by a length equal to the width of the base side protruding portion 133 .
The side pressing portions 1341 are formed on both left and right ends of the connecting portion 130 , and protrude from the main connecting portion 131 longer than the base side protruding portion 133 and the central pressing portion 1313 .
The base side protrusion 133 and the central pressing portion 1313 sandwich the base portion 111 and the cover flange portion 1612 .
The distance between the base side protrusion 133 and the central pressing portion 1313 is the sum of the thickness of the base portion 111 and the thickness of the cover flange portion 1612 .

The base side protrusion 133 and the side pressing portion 1341 sandwich the base portion 111 , the cover flange portion 1612 , and the upper plate of the reinforcing portion 140 .
The distance between the base side protrusion 133 and the side pressing portion 1341 is the sum of the thickness of the base portion 111 , the thickness of the cover flange portion 1612 , and the thickness of the metal plate of the upper plate 147 of the reinforcing portion 140 .

The side pressing parts 1341 are formed to protrude inwardly at both the left and right ends of the connecting part 130. The side pressing parts 1341 overlap with the ends of the upper plate 147 of the reinforcing part 140, and also sandwich the ends of the upper plate 147 of the reinforcing part 140, and have pressing cutout parts 13411 that avoid the hole tube part 141 protruding from the upper plate 147 of the reinforcing part 140.

In this embodiment, a cover packing 162 is disposed between the base portion 111 of the heat sink 110 and the cover portion 160 to provide waterproof performance.
In this embodiment, in order to fix the base portion 111 of the heat sink 110, the cover gasket 162, and the cover portion 160 at once, the connecting portion 130 has multiple functions, making it possible to fix various parts without increasing the number of parts.
Specifically, the cover part 160, the base part 111 of the heat sink 110, and the cover packing 162 are fixed with fastening members such as screws by being sandwiched between the base side protrusion 133 which is the lower fixing part of the connecting part 130 and the side pressing part 1341 which is the intermediate fixing part, and the top plate part 113 is fixed to the top plate side protrusion 132 which is the upper fixing part with fastening members such as screws. At this time, a hole through which a screw passes is formed in the base side protrusion 133 which is the lower fixing part, and a screw hole through which a screw can be fastened is provided in the side pressing part 1341 which is the intermediate fixing part.
Further, the arm 10 for mounting the lighting fixture on the ceiling can be fixed to the pillar portion 1312 which is the connection portion of the coupling portion 130.

According to the configurations of Figures 5 and 8, the fixing portion 139 has the function of fixing multiple members. Therefore, there is no need to provide an attachment structure for fixing the cover portion 160 to the light source portion 150, and it is possible to reliably fix the cover 161 without increasing the number of parts and assembly steps.

According to the configurations shown in Figures 5 and 8, by providing a fixing portion 139 to the connecting portion 130 that connects the base portion 111 and the top plate portion 113 of the heat sink 110, it is possible to fix the cover 161 while controlling the dimensions without providing a separate member, and the use of common parts makes assembly easier.

Figures 5 and 20
(Connecting portion 130 with enhanced vibration resistance)
As described above, the main function of the connecting portion 130 is to fix the base portion 111 and the top plate portion 113 of the heat sink 110 and to fix the arm 10 .

On the other hand, if the equipment is to be installed in an environment where it is subject to vibrations, such as from a crane, it is necessary to strengthen the vibration resistance. Generally, vibrations must be considered in the horizontal direction (x direction, y direction) and the vertical direction (z direction). When strengthening vibration resistance, it is necessary to consider improving rigidity in each of the above x, y, and z directions.

In order to improve the rigidity, it is necessary to improve the rigidity of the connecting part 130 in the x, y, and z directions, and to increase the number of fixing points between the base part 111 and the top plate part 113 of the heat sink 110 and the connecting part 130.

The connecting portion 130 of the present embodiment has a shape that increases the strength in the x, y, and z directions. Specifically, as shown in FIG.
xy plane: base side protrusion 133, top plate side protrusion 132, side pressing portion 1341
yz plane: connecting main part 131
xz plane: a pair of lateral protrusions 134

The base portion 111 and the top plate portion 113 of the heat sink 110 have substantially the same rectangular shape.
The main connection portion 131 of the connection portion 130 is a rectangular plate having sides the same length as the sides of the base portion 111 and the top plate portion 113 .

The connecting portion 130 has a base-side protruding portion 133 , a top-plate-side protruding portion 132 , and a pair of lateral protruding portions 134 on the four sides of the connecting main portion 131 .
The base-side protrusion 133 and the top-plate-side protrusion 132 are formed by bending the top and bottom of the main connection portion 131 at 90 degrees.
The lateral protrusions 134 are formed by forming first bent portions on the left and right sides of the main connecting portion 131 and bending them in a 90 degree direction.
The side pressing portion 1341 is formed by forming a second bent portion below the side protruding portion 134 and bending it in the 90 degree direction.
The side pressing portion 1341 is parallel to the base portion 111 of the heat sink 110 .

The base side protrusion 133, the top plate side protrusion 132, the side pressing portion 1341, the main connecting portion 131, and the side protrusion 134 are perpendicular surfaces, increasing rigidity in all directions.

Although not shown, the side of the frame side portion 1314 may be bent 90 degrees to form an xz plane parallel to the lateral protrusion portion 134.

The lower edge of the lower frame portion 1315 and the upper edge of the upper frame portion 1316 may also be bent 90 degrees to form an xy plane parallel to the base side protrusion portion 133 and the top plate side protrusion portion 132.

In the xy plane formed by bending the lower side of the frame lower part 1315 and the upper side of the frame upper part 1316, a recess is formed similarly to the upper plate of the reinforcing part 140.
In the xy plane formed by bending the lower side of the frame lower portion 1315, an inclined portion is formed similarly to the upper plate of the reinforcing portion 140.

As shown in FIG. 20, in this embodiment, the main connecting portion 131, which is expanded in the width direction of the connecting portion 130, has multiple holes 138 in the pillar portion 1312 and the frame side portion 1314 to reduce weight. The diameter of the holes 138 is made smaller as it approaches the base portion 111, thereby ensuring the strength of the base portion 111 side. In addition, by drilling holes, it is possible to create a shape that does not obstruct the flow of air to the fin portion 112 of the heat sink 110 contained therein, and it is possible to increase rigidity without affecting heat dissipation performance.

The configuration shown in Figure 5 makes it possible to construct a lighting fixture that can withstand vibrations (forces) in different directions without having to provide reinforcing members for each direction.

According to the configuration in Figure 5, the connecting portion 130 has three-dimensional orthogonal surfaces, so it is possible to provide a frame structure for a vibration-resistant device.

The configuration shown in Figure 5 makes it possible to increase rigidity against horizontal and vertical vibrations without providing additional components, thereby improving vibration resistance.

Figures 11 and 12
(Fixture mounting bracket)
The lighting fixture of this embodiment is fixed to a ceiling surface by an arm 10 fixed to a connecting portion 130 .
The arm 10 is formed in a U-shape so as to straddle the lighting fixture 1, and is fixed to two connecting parts 130 with two bolts each.
The arm 10 is provided with holes corresponding to the two bolts, with the upper hole 12 being a substantially circular hole and the lower hole 13 being an arc-shaped hole.
By changing the position of the arc-shaped hole of the lower hole 13 with the bolt of the upper hole 12 as an axis, the irradiation direction of the instrument can be changed.

The range of change in the irradiation direction is determined by the arc-shaped hole shape of the lower hole 13 of the arm 10, but if an angle is added, there is a risk of interference with the case part 123 or the top plate part 113 mounted on the device relative to the arm 10, so it is common to limit the angle to a certain extent (approximately about 30 degrees). If the angle can be adjusted to about 90 degrees, this can be achieved by lengthening the arm 10, but this will move the device's center of gravity farther away from the ceiling mounting surface, which is disadvantageous in terms of strength, so it will become necessary to increase the strength of the arm 10 relatively.

On the other hand, the lighting fixture 1 is generally installed on the ceiling, but in cases where the ceiling is high, the fixture may be installed on a wall and the angle of the lighting fixture may be adjusted to illuminate the light.

In this case, by using an instrument mounting bracket 200 shown in FIG. 11, even a typical arm 10 (with angle adjustment of about ±30 degrees) can be easily attached to a wall surface.
The appliance mounting bracket 200 in this embodiment has a bracket foot 220 which serves as a wall fixing part to be fixed to a wall surface, and an appliance mounting part 210 which is formed at a predetermined angle to the wall surface, and the appliance mounting part 210 has an appliance fixing hole 211 formed along the direction of gravity.
The instrument fixing hole 211 has a lateral diameter that decreases toward the direction of gravity.

The worker loosely fastens the bolt 291 and nut 292 in the mounting hole 11 of the arm 10, inserts the bolt 291 from bottom to top into the wide upper part of the tool fixing hole 211, and then slides the bolt 291 into the narrow lower part of the tool fixing hole 211. In this state, the bolt 291 is temporarily hung in the tool fixing hole 211 by the tool's own weight, so the worker can install the tool with both hands, eliminating the need to hold down the bolt 291 with one hand while installing the tool, improving workability.

In addition, since the arm 10 of the lighting fixture 1 is used as is without being replaced with a separate part, the lighting direction can be easily adjusted by using a fixture having a lighting direction adjustment function.
11(a) has a wall surface mounting portion and a side surface portion 222 perpendicular to the wall surface mounting portion, and the side surface portion 222 is arranged so as not to overlap the instrument fixing hole 211 of the instrument mounting portion 210 in a side view. This makes it possible to install the bolt 291 in the instrument mounting bracket 200 from the side when mounting an instrument.

11(a) , the edge of the side portion 222 of the instrument mounting bracket 200 on the instrument mounting portion 210 side is a curved portion 223, which provides a working gap 250 with respect to the instrument mounting portion 210 in side view. The curved portion 223 is spaced 10 mm or more from the instrument mounting portion 210 in side view.
The side portion 222 of the instrument mounting bracket 200 in Fig. 11(b) is connected to the instrument mounting portion 210 by a straight portion 224. The length of both the left and right sides of the instrument mounting portion 210 is the same as the length of the straight portion 224 of the side portion 222. The side portion 222 has a horizontally long rectangular window 225 along the straight portion 224. The window 225 provides a working gap 250 for the instrument mounting portion 210 in side view. The window 225 provides a gap 250 of 10 mm or more for the instrument mounting portion 210 in side view.

The presence of the gap 250 allows a tool to be inserted from the side portion 222 of the appliance mounting bracket 200 to the rear side of the appliance mounting portion 210 (the side opposite the appliance mounting surface) when fixing the appliance to the appliance mounting portion 210 with the bolt 291 and nut 292, facilitating installation.

As shown in FIG. 11, the tool mounting portion 210 is formed with only the tool fixing hole 211 through which the mounting bolt 291 passes, but a hole for reducing weight may be provided.
As shown in FIG. 11, the tool attachment portion 210 has no welds or fastening points and can be manufactured as a one-piece component by folding a single piece of sheet metal.
If the curved portion 223 of the instrument mounting bracket 200 in FIG. 11( a ) is set back significantly, the bracket body portion 230 may be omitted, and the instrument mounting portion 210 may be directly connected to the bracket waist portion 240 .
The instrument mounting bracket 200 in Figure 11(b) does not have a bracket abdomen portion 230 and a bracket waist portion 240, and therefore is lighter than the instrument mounting bracket 200 in Figure 11(a), and furthermore, requires fewer bendings and is easier to manufacture.
Moreover, the fixture mounting bracket 200 in Figure 11 (b) has the left and right sides of the fixture mounting portion 210 connected to the straight portion 224 of the side portion 222 over their entire length excluding the window 225, so that it has a robust structure and there is little possibility that the inclination angle of the fixture mounting portion 210 will change due to the weight of the lighting fixture.

In addition, in the present embodiment shown in FIG. 12, the arm 10 is fixed to the lower side of the tool mounting part 210, but the arm 10 may be fixed to the upper side of the tool mounting part 210. In this case, the arm 10 without the bolt 291 and nut 292 attached is placed on the upper side of the tool mounting part 210 of the tool mounting bracket 200 via the gap 250, and the bolt 291 and nut 292 are passed through the mounting hole 11 and the tool fixing hole 211 of the arm 10, and the nut 292 is tightened to fix it from the lower side. When the arm 10 is fixed to the upper side of the tool mounting part 210, it is possible to hook the tool to the tool mounting bracket 200 before inserting the bolt 291 into the mounting hole 11 of the arm 10, which makes the installation even easier.

As shown in FIG. 12(b), the fixture mounting bracket 200 can be attached to a mounting portion 900 such as a horizontal ceiling surface, rather than a vertical wall. The fixture mounting bracket 200 shown in FIG. 12(b) has a smaller horizontal diameter near the fixture abdomen 230, which is the opposite of the fixture fixing hole 211 in FIG. 11, and the fixture fixing hole 211 has a smaller horizontal diameter toward the direction of gravity.

As shown in FIG. 12(c), the fixture mounting bracket 200 can be attached to a mounting portion 900 such as a sloping wall surface, rather than a vertical wall.

Figure 21
(Cover gasket 162)
The cover gasket 162 is disposed on the cover flange 1612 and is sandwiched between the cover flange 1612 and the base portion 111 .
As shown in FIG. 21 , the cover flange 1612 has a horizontal flange portion 16121 and a flange band portion 16122 .

The horizontal flange portion 16121 is a rectangular ring portion that is perpendicular to the side surface of the main cover 1611 and parallel to the lower surface of the main cover 1611.
The flange portion 16122 is a ring-shaped belt portion that is perpendicular to the flange horizontal portion 16121, is located around the flange horizontal portion 16121, and is parallel to the side of the main cover 1611.
The cover flange portion 1612 has an inner convex portion 1613 , a plurality of convex portions 1614 , and a plurality of concave portions 1615 on the inside of the flange horizontal portion 16121 and the flange band portion 16122 .

The inner protrusion 1613 protrudes inward beyond the inner surface of the side surface of the main cover 1611 .
There are eight inner protrusions 1613 in total, two on each side.
The inner convex portion 1613 is L-shaped and is an L-shaped protrusion that protrudes from the inner surface of the cover flange portion 1612 along the inner surface of the side surface of the main cover 1611.
The inner convex portion 1613 has a step portion 1616 at the upper corner of the L shape.
The light source units 150 having a circular outer shape are attached to the total of eight step portions 1616 by being positioned by the orthogonal walls of the step portions 1616 .

The outer shape of the cover gasket 162 is the same as the outer shape of the flange portion 16122 .
The outer periphery of the cover gasket 162 is pressed by the upper end surface of the flange portion 16122 and the base portion 111, and is deformed thin, so that the thickness of the cover gasket 162 becomes a predetermined thickness (a predetermined amount of compression).
The cover gasket 162 has a plurality of recesses 1622, a plurality of protrusions 1623, and one annular protrusion 1624 on its lower surface.

The annular protrusion 1624 is a rail-shaped protrusion that goes around the lower surface of the cover packing 162 .
The annular protrusion 1624 is deformed by pressure applied by the flange horizontal portion 16121 and the base portion 111, thereby improving the water-stopping effect.

The recess 1622 of the cover packing 162 fits over the protrusion 1614 of the cover flange 1612 for close contact.
The protrusion 1623 of the cover packing 162 is fitted into the recess 1615 of the cover flange 1612 and comes into close contact with it.
The cover packing 162 has a lid portion 1621 that protrudes inward in a glans shape.
The lid portion 1621 of the cover packing 162 fits closely to cover the inner protrusion 1613 of the cover flange portion 1612 .

The cover portion 1621 has a step portion 1629 having an orthogonal wall corresponding to the step portion 1616 of the inner convex portion 1613 .
The step portion 1629 of the lid portion 1621 has a horizontal wall 1627 and an arcuate wall 1628 .
The horizontal wall 1627 is a flat surface that abuts against the lower surface of the outer edge of the light source unit 150 .
The arc wall 1628 is an arc-shaped surface that abuts against the outer circumferential surface of the light source unit 150 .
The eight arc walls 1628 are surfaces having the same radius as the outer periphery radius of the light source unit 150 .
The lid portion 1621 is disposed between the light source portion 150 and the cover portion 160, and thus can provide a cushioning function and protect the light source portion 150 from impact.

The cover packing 162 has two annular protrusions 1625 on the upper surface.
The annular protrusion 1625 is a rail-shaped protrusion that goes around the top surface of the cover packing 162 .
Both of the annular protrusions 1625 are formed inside the screw hole 1626 .
The annular convex portion 1625 is deformed by pressure applied by the horizontal flange portion 16121 and the base portion 111, thereby improving the water-stopping effect. There may be one or more annular convex portions.

The outer shape of the cover packing 162 may be made the same as the inner shape of the flange portion 16122, and the cover packing 162 may be hidden inside the flange portion 16122. The cover packing 162 is not pressurized by the flange portion 16122, but is pressurized and deformed by the flange horizontal portion 16121 and the base portion 111.

Embodiment 2.
The configuration of lighting device 1 according to embodiment 2 will be described with reference to Figs. 22 to 27.
The following describes the differences from the first embodiment.

FIG. 22, FIG. 23 and FIG. 24
(Configuration of lighting fixture 1)
As shown in FIGS. 22, 23 and 24, a main connection portion 131 of a connection portion 130 is composed of only the pillar portion 1312 of the first embodiment.
A top plate side protrusion 132 and a base side protrusion 133 are formed above and below the column portion 1312 .
A central pressing portion 1313 is formed at the bottom of the pillar portion 1312 .
The configurations of the top plate side protrusion 132, the base side protrusion 133, and the central pressing portion 1313 are the same as those in the first embodiment.

The base portion 111 has two pins 1115 for positioning the heat dissipation sheet 171 .
The top plate portion 113 has a concave portion 1138 facing the top plate side protrusion portion 132 .
The concave portion 1138 is recessed below the upper surface of the top plate portion 113 and is a flat portion having the same shape as the top plate side protrusion portion 132 .
The concave surface portion 1138 is recessed below the upper surface of the top plate portion 113, thereby improving the resistance of the top plate portion 113 to deformation.

As shown in FIG. 24, an insulating sheet 172, a heat dissipation sheet 171, a light source substrate 151, and a lens portion 152 are arranged on a base portion 111 in this order.
The lighting fixture 1 does not have a reinforcing portion 140, and the base portion 111 is reinforced by a bent portion 1111 that is bent into an L shape from the base portion 111.

Figures 25 and 26
(Bent portion 1111 of base portion 111)
As shown in Figures 25 and 26, the base portion 111 has bent portions 1111 on each side.
One bent portion 1111 is disposed on each straight portion of a pair of opposing sides of the base portion 111 .
Two bent portions 1111 are disposed on the straight portions of each of another pair of opposing sides of the base portion 111. Between the two bent portions 1111, there is an attachment space 1114 for attaching the connecting portion 130.

The width of the connecting portion 130 and the width of the mounting space 1114 are the same, and the base side protrusion 133 of the connecting portion 130 passes through the mounting space 1114 and is fixed to the lower surface of the base portion 111 .
The height of the bent portion 1111 is the same as or less than the thickness of the cover flange portion 1612 .

Although not shown, the bent portion 1131 of the top plate portion 113 may also be configured similarly to the bent portion 1111 of the base portion 111 in Figures 25 and 26.

Figures 26 and 27
(Heat dissipation sheet 171 and insulating sheet 172)
As shown in FIGS. 26 and 27, the light source substrate 151 has an octagonal or approximately octagonal shape.
The heat dissipation sheet 171 has an octagonal or approximately octagonal shape that is larger than the light source substrate 151 .
The heat dissipation sheet 171 has a tongue portion 1711 having through holes on two sides.
The heat dissipation sheet 171 is positioned by passing the pins 1115 of the base portion 111 through the through holes of the tongue portion 1711 .
The heat dissipation sheet 171 has wire-passing holes 176 (not shown) on the outer periphery.
The wire-passing hole 176 has the same shape as the board hole 153, and is a hole through which the wire-passing packing 116 is inserted and through which the wire 1221 passes.

The insulating sheet 172 is ring-shaped.
The insulating sheet 172 has a ring-shaped portion 173 and a return portion 174 .

The annular portion 173 is a ring-shaped flat sheet, and the inner shape of the annular portion 173 shown by the dashed line is an octagon or approximately octagonal shape smaller than the heat dissipation sheet 171, and the outer shape of the annular portion 173 is an octagon or approximately octagonal shape larger than the heat dissipation sheet 171.
The annular portion 173 has two pin holes 177 through which the pins 1115 of the base portion 111 pass.

The return portions 174 are disposed on every other one of the eight sides.
The return portion 174 is folded back 180 degrees from the end of the annular portion 173 of the insulating sheet 172 in a U-shape.
The folded portion 174 folds over the outer edge of the light source substrate 151 while sandwiching the heat dissipation sheet 171 , and covers the side end faces of the heat dissipation sheet 171 and the outer peripheral edge of the light source substrate 151 .

The return portions 174 are located at four positions in the cross direction, but because the insulating sheet 172 is flexible, the return portions 174 can be attached so that they overlap the outer edge of the light source substrate 151 while bending the annular portion 173.

The insulating sheet 172 has a wire-running portion 175 on its inner periphery.
The wire portion 175 is a trapezoidal piece formed from the center of the inner side of the annular portion 173 toward the center.
The wire-passing portion 175 has a wire-passing hole 176 in the center, which has the same shape as the board hole 153 .
The wire-passing hole 176 is a hole into which the wire-passing packing 116 is fitted and through which the wire 1221 passes.
As shown in FIG. 27(e), the relationship of the diameters is as follows:
Inner diameter of insulating sheet 172<outer diameter of light source substrate 151<outer diameter of heat dissipation sheet 171<outer diameter of insulating sheet 172<outer diameter of base portion 111

In this embodiment, the insulation is improved without increasing the amount of insulating sheet 172 used.
Furthermore, by covering with the return portion 174, the insulation distance increases, and the insulation properties improve.
The return portion 174 may be provided on one or more sides, or may be provided on all eight sides.

Figure 28
(Modifications of the bent portion 1111 of the base portion 111)
As shown in FIG. 28, a bent portion 1113 may be formed in a mounting space 1114 between two bent portions 1111 .
The bent portion 1113 is formed by bending an end of the base portion 111 into a 180 degree U-shape.
The bent portion 1113 has a screw hole 1118 in the center, similar to that of the base portion 111, for fixing the base side protrusion 133 thereto.
Although not shown, some or all of the bent portions 1111 may be bent into a 180 degree U-shape in the same manner as the bent portion 1113 .
Although not shown, the top plate portion 113 may also be provided with a bent portion similar to the bent portion 1113 of the base portion 111 in FIG.
Figure 29
(Wiring Through Portion 119)
FIG. 29 shows the wiring through portion 119 .
The wiring through portion 119 has a convex portion 114 and a wire-passing packing 116 .
The convex portion 114 has a box shape that rises from the base portion 111 in the opposite direction to the direction in which the light source substrate 151 is installed.
The convex portion 114 provides a space 1141 between the rear surface of the base portion 111 and the light source substrate 151 .
The convex portion 114 has a circular through hole 115 in the center of the rectangular upper surface.
The through hole 115 is a hole into which a wire-passing packing 116 is fitted.
The wire-passing packing 116 has annular grooves 1161 on the outer periphery at the center of the top and bottom.
The annular groove 1161 is an annular recess that fits into the through hole 115 .
The upper portion of the wire-passing packing 116 above the annular groove 1161 is exposed on the convex portion 114 .
The lower part of the wire-passing packing 116 below the annular groove 1161 is housed in the space 1141 .

The wire-passing packing 116 has wiring holes 117 in the same number as the number of wires 1221, and each wiring hole 117 passes only one wire.
Moreover, the inside of the wiring hole 117 is provided with projections and recesses to prevent the infiltration of water and moisture.

The wire-passing packing 116 has a protrusion 118 .
The protruding portion 118 is a portion that protrudes beyond the base portion 111 toward the side where the light source board 151 is located.
The horizontal cross-sectional shape of the protrusion 118 is the same as or smaller than the substrate hole 153 .
The protrusion 118 is inserted into the wire-passing hole 176 of the sheet 170 (the heat dissipation sheet 171 and the insulating sheet 172 ) and the board hole 153 of the light source board 151 .

By configuring the protrusion 118 to be thicker than the thickness of the light source substrate 151, the wiring 1221 does not come into contact with the edge of the substrate hole 153 of the light source substrate 151.

In this way, by providing the convex portion 114 on the base portion 111 and forming a space 1141 on the back side of the convex portion 114, a gasket 116 for passing wires can be placed on the base portion 111, and the wiring 1221 can be passed through without increasing the outer diameter of the light source board 151.

Although the embodiments of the present invention have been described above, two or more of these embodiments may be combined and implemented. Alternatively, one of these embodiments may be partially implemented. Alternatively, two or more of these embodiments may be partially combined and implemented. Note that the present invention is not limited to these embodiments, and various modifications are possible as necessary.

Reference Signs List 1 Lighting fixture, 10 Arm, 11 Mounting hole, 12 Upper hole, 13 Lower hole, 100 Light source unit, 110 Heat sink, 111 Base portion, 1111 Bent portion, 1112
light source fixing portion, 1113 bent portion, 1114 mounting space, 1115 pin, 1118, 1119 screw hole, 112 fin portion, 1121 notch, 113 top plate portion, 1131 bent portion, 1132 fin fixing portion, 1138 concave portion, 1139 screw hole, 114 convex portion, 1141 space, 115 through hole, 116 wire passing packing, 1161 annular groove, 117 wiring hole, 118 protrusion, 119 wiring penetration portion, 120 power supply unit, 121 lighting circuit portion, 122 harness, 1221 wiring, 1222 power supply board, 123 case portion, 1231 case body, 12311 main case portion, 12312 step portion, 12313 case flange portion, 12314 Horizontal ring portion, 12315 Vertical band portion, 1232 Case packing, 12321 Annular convex portion, 12322 Annular mountain portion, 1233 Bush, 129 Case fixing device, 130 Connection portion, 131 Connection main portion, 1311 Connection opening, 1312 Pillar portion, 13121 Connection hole, 1313 Center pressing portion, 1314 Frame side portion, 1315 Frame lower portion, 1
316 Upper frame portion, 13131 Holding hole portion, 132 Top plate side protrusion portion, 133 Base side protrusion portion, 134 Side protrusion portion, 1341 Side pressing portion, 13411 Pressing notch portion, 137 Top plate fixing device, 138 Hole portion, 139 Fixing portion, 140 Reinforcing portion, 141 Hole cylinder portion, 142
Reinforcing hole portion, 143 inclined portion, 147 upper plate, 1471 upper recess portion, 1472 notch portion, 148 back plate, 149 lower plate, 1481 lower recess portion, 150 light source portion, 151 light source board, 152 lens portion, 153 board hole, 154 board notch portion, 160 cover portion, 1601 main body portion, 1602, 1603 film, 161 cover, 1611 main cover, 1612 cover flange portion, 1613 inner convex portion, 1614 convex portion, 1615 concave portion, 1616 step portion, 16121 flange horizontal portion, 16122 flange portion, 162 cover packing, 1621 lid portion, 1622 concave portion, 1623 convex portion, 1624 Annular protrusion, 1625
annular convex portion, 1626 screw hole, 1627 horizontal wall, 1628 arc wall, 1629 step portion, 169 cover fixing device, 170 sheet, 171 heat dissipation sheet, 1711 tongue portion, 172 insulating sheet, 173 annular portion, 174 return portion, 175 wire passing portion, 176 wire passing hole, 177 pin hole, 200 fixture mounting bracket, 210 fixture mounting portion, 211 fixture fixing hole, 220 fixture leg portion, 221 wall mounting portion, 222 side portion, 223 curved portion, 224 straight portion, 225 window, 230 fixture abdomen portion, 240 fixture waist portion, 241 electric wire hole, 250 gap, 291 bolt, 292 nut, 900 mounted portion, 901 fixture fixing device.

Claims (4)

An instrument mounting portion that is a rectangular flat plate and is disposed at an angle with respect to the direction of gravity;
a pair of metal fitting legs that are fixed perpendicular to the mounting portion, that are disposed on both the left and right sides of the instrument mounting portion and perpendicular to the instrument mounting portion, and that have a narrower width in the direction of gravity in a side view;
The instrument mounting portion is provided with an instrument fixing hole whose width decreases in a direction of gravity,
Each of the pair of metal fitting legs has a wall surface mounting portion fixed to a mounting portion, and a side surface portion that is perpendicular to the wall surface mounting portion and has a narrower width in a direction of gravity in a side view,
The fixture mounting portion, the wall mounting portion, and the side surface portion are formed by bending a single metal plate ,
The side surface is triangular in shape,
The side portion and the appliance mounting portion are bent at a cross angle of 90 degrees to be connected to each other in the appliance fixing bracket. An instrument mounting portion that is a rectangular flat plate and is disposed at an angle with respect to the direction of gravity;
A metal fitting waist portion disposed perpendicular to the attached portion;
a metal fitting body portion that is perpendicular to the metal fitting waist portion and has the tool attachment portion inclined with respect to the metal fitting waist portion;
a pair of metal fitting legs that are fixed perpendicular to the mounting portion, that are disposed on both the left and right sides of the metal fitting waist portion and perpendicular to the metal fitting waist portion, and that have a narrower width in the direction of gravity in a side view;
The instrument mounting portion is provided with an instrument fixing hole whose width decreases in a direction of gravity,
Each of the pair of metal fitting legs has a wall surface mounting portion fixed to a mounting portion, and a side surface portion that is perpendicular to the wall surface mounting portion and has a narrower width in a direction of gravity in a side view,
The appliance mounting portion, the metal fitting waist portion, the metal fitting abdomen portion, the wall mounting portion, and the side portion are formed by bending a single metal sheet ,
The side surface is triangular in shape,
An instrument fixing bracket , wherein the edge of the side portion facing the instrument mounting portion has an arc-shaped curved portion that points away from the instrument mounting portion in a side view . An instrument mounting portion that is a rectangular flat plate and is disposed at an angle with respect to the direction of gravity;
a pair of metal fitting legs that are fixed perpendicular to the mounting portion, that are disposed on both the left and right sides of the instrument mounting portion and perpendicular to the instrument mounting portion, and that have a narrower width in the direction of gravity in a side view;
The instrument mounting portion is provided with an instrument fixing hole whose width decreases in a direction of gravity,
Each of the pair of metal fitting legs has a wall surface mounting portion fixed to a mounting portion, and a side surface portion that is perpendicular to the wall surface mounting portion and has a narrower width in a direction of gravity in a side view,
The fixture mounting portion, the wall mounting portion, and the side surface portion are formed by bending a single metal plate ,
The side surface is a right-angled triangle,
The instrument mounting portion is inclined along the hypotenuse of the side portion . The fixture fixing bracket according to any one of claims 1 to 3, wherein there is a gap between the fixture leg and the fixture mounting part in a side view, and the fixture leg does not overlap the fixture mounting part in a side view.

Images