JP2020113551A - Luminaire - Google Patents

Abstract

To provide a structure that can improve assemblability of a luminaire.SOLUTION: A luminaire 100 comprises a light source unit 80 comprising a fitting plate fitted with a light source, a top plate 40 arranged so as to be opposed to the light source unit 80, and a strut framework 50 connecting the light source unit 80 and the top plate 40. The fitting plate and the top plate 40 are rectangular, and struts of the strut framework are provided at three places: a center part of one side of the light source unit 80 and the top plate 40, and both side parts separate from the center part. The light source unit 80 is fixed to only the struts. The struts comprise main struts provided at four corners of the fitting plate and the top plate 40, and intermediate struts provided at centers of opposite sides of the fitting plate and centers of opposite sides of the top plate 40. The heat sink comprises a heat dissipation plate and a plurality of heat dissipation fins. The fitting plate is the heat dissipation plate.SELECTED DRAWING: Figure 7

Description

The present invention relates to a lighting fixture.

There are luminaires that are attached to the ceiling or beams, or luminaires that are suspended from high ceilings.
Further, there is a lighting device that allows ventilation to the heat-generating components inside the main body of the lighting device to efficiently dissipate heat (see Patent Document 1 and FIG. 1).

JP, 2010-80244, A JP, 2014-026803, A JP, 2014-002916, A JP, 2013-182777, A

In the embodiment of the present invention, it is desired to provide a structure capable of improving the assembling property of the lighting fixture.

The lighting fixture of the present invention is
A light source unit having a mounting plate to which a light source is mounted,
A top plate arranged to face the light source unit,
It is characterized in that it comprises a pillar that fastens the light source unit and the top plate.

According to the present invention, since the light source unit and the top plate are fastened together by the columns, the assembling property of the lighting fixture can be improved.

FIG. 3 is a perspective view of the lighting fixture 100 according to the first embodiment. FIG. 3 is a front view of the lighting fixture 100 according to the first embodiment. FIG. 3 is a left side view of the lighting fixture 100 according to the first embodiment. FIG. 3 is a bottom view of the lighting fixture 100 according to the first embodiment. FIG. 3 is a plan view of the lighting fixture 100 according to the first embodiment. FIG. 3 is a central cross-sectional view of a front view of lighting fixture 100 of the first embodiment. FIG. 3 is an exploded perspective view of the lighting fixture 100 according to the first embodiment. FIG. 3 is a perspective view of the light source unit 80, the cover 90, and the support frame 50 of the first embodiment. 5 is a perspective view of the heat sink 82 according to the first embodiment. FIG. FIG. 6 is a perspective view of a regular square prism lighting device 100 according to a second embodiment. FIG. 4 is a four-sided view and a cross-sectional view of a regular square prism lighting fixture 100 according to a second embodiment. FIG. 6 is an exploded perspective view of a regular prismatic lighting device 100 according to a second embodiment. 7 is a perspective view of a lighting fixture 100 having two light source units according to Embodiment 2. FIG. 4A and 4B are a four-sided view and a cross-sectional view of a lighting fixture 100 having two light source units of Embodiment 2. 7 is a perspective view of a lighting fixture 100 having two light source units according to Embodiment 2. FIG. 4A and 4B are a four-sided view and a cross-sectional view of a lighting fixture 100 having two light source units of Embodiment 2. FIG. 10 is a schematic plan view of a support frame 50 of the third embodiment. It is a perspective view of the main support column 53 of Embodiment 3.

Embodiment 1.
In each of the drawings described below, Z indicates the vertical direction.
X indicates the lateral direction, that is, the lateral direction.
Y indicates the front-back direction, that is, the depth direction.
X, Y, and Z are orthogonal, X and Y are in the horizontal direction, and Z is in the vertical direction.
Further, in the following, when the term “screw fastening” is used, it is assumed that the screw holes into which the screws are screwed are respectively present in the plurality of components to be screwed.

***Composition explanation***
<<<Configuration of Lighting Fixture 100>>>

As shown in FIGS. 1 and 7, the lighting fixture 100 includes an arm 20, a power supply unit 30, a top plate 40, a support frame 50, a light source unit 80, and a cover 90.
The arm 20 attaches the lighting fixture 100 to a ceiling or a beam.
As shown in FIGS. 1 and 2, both ends of the arm 20 are attached to the centers of both side surfaces of the lighting fixture 100.
As shown in FIGS. 3 and 6, the arm 20 has a U-shape or a U-shape. An arcuate hole 24 and a shaft hole 28 are vertically provided at both ends of the arm 20.
The power supply unit 30 has a power supply circuit that supplies electric power to the light source unit 80.
The power supply unit 30 has a hexahedral box-shaped metal housing.
The power supply unit 30 is mounted on the center of the top surface of the top plate 40 to fix the power supply unit 30.
The top plate 40 is fixed to the upper surface of the support frame 50 and covers the light source unit 80.
The top plate 40 is made of metal.
The top plate 40 has a plate portion 42 and a skirt portion 44.
The plate portion 42 mounts the power supply unit 30 on the center of the upper surface and fixes the power supply unit 30.
The plate portion 42 is a rectangular thin flat plate.
The plate portion 42 has four screw holes near the center for fixing the power supply unit 30.
The plate portion 42 has a screw hole for fixing the intermediate support column 61 at the end edge portion in the front-rear direction at the center in the left-right direction.
The skirt portion 44 is a plate that hangs in a skirt shape from the end of the outer periphery of the plate portion 42.
The skirt portion 44 is provided to reinforce the top plate 40.
The skirt portion 44 is bent at a right angle along the corner of the top plate 40 and covers the lower side of the corner of the top plate 40.
There is one skirt portion 44 on each of the left and right sides, and the planar shape is a U-shape.
The skirt portion 44 covers the outer surfaces of the upper ends of all four main columns.
The skirt portion 44 has a screw hole for fastening the upper end of the support plate 56.
The support frame 50 houses the light source unit 80. The top surface of the support frame 50 is covered with the top plate 40. The lower surface of the column framework 50 is covered with a cover 90.
The support frame 50 is made of metal.
The light source unit 80 is fixed to the support frame 50, receives power from the power supply unit 30, and causes the light source to emit light.
The cover 90 is fixed to the support frame 50 and covers the front surface of the light source unit 80.
The cover 90 is made of plastic or resin.

As shown in FIGS. 4 and 5, the planar shape of the lighting fixture 100 is a rectangle or a rectangle.
The top plate 40, the support frame 50, the light source unit 80, and the cover 90 have a quadrangular shape with substantially the same size, and have the same quadrangular shape as the luminaire 100.

<<<Structure of the support frame 50>>>
As shown in FIG. 8, the column framework 50 forms a columnar arrangement space 92.
Here, the “arrangement space” refers to a space in which one light source unit 80 is arranged.
In FIG. 8, the arrangement space 92 is a square pole.
The upper part and the lower part of the arrangement space 92 of the support frame 50 are open, the upper opening 94 is formed in the upper part of the support frame 50, and the lower opening 95 is formed in the lower part of the support frame 50. There is.

As shown in FIG. 8, the support frame 50 includes the following parts.
1.4 main columns (2 main columns 51, 2 main columns 52)
2.4 guards (2 guards 71, 2 guards 72)
3.2 middle support columns 61

The main column is made by bending a single metal plate at a right angle.
The main columns are provided at four corners of the rectangular column arrangement space 92.
The main support column is arranged from the upper opening 94 to the lower opening 95.
The two main columns 51 are provided at diagonal corners of the arrangement space 92.
The two main columns 52 are provided at corners on different diagonal lines of the arrangement space 92.
The main support column 51 has a rectangular support plate 55 and a support plate 56.
The support plate 55 and the support plate 56 are long plates arranged from the upper opening 94 to the lower opening 95, and the surface of the support plate 55 and the surface of the support plate 56 are orthogonal to each other.
The height of the main columns is the height of the column framework 50, that is, the height of the arrangement space 92.
The pillar plate 55 of the main pillar 51 has a main mounting portion 57 that projects toward the inside of the arrangement space 92 at the lower end. There is a screw hole 59 in the center of the main mounting portion 57.
The pillar plate 56 of the main pillar 51 has a screw insertion portion 60 at the upper end. The screw insertion portion 60 is a screw hole.
The support plate 55 and the support plate 56 have three screw holes 58 arranged vertically.

The configuration of the main support column 52 is the same as the configuration of the main support column 51 except that the positions of the support column 55 and the support column 56 are reversed. That is, as viewed from the center of the column framework 50 in FIG. 8, the main column 51 has the column plate 56 on the left side of the column plate 55, and the main column 52 has the column plate 56 on the right side of the column plate 55.

The guard 71 and the guard 72 are metal plates having different lengths.
The length ratio of the guard 71 and the guard 72 is 2:3.
The guard 71 connects the main columns in the front-rear direction.
The guard 72 connects the main columns in the left-right direction.

The guard 71 and the guard 72 have screw holes at both ends.
Fix the screw hole of the guard and the screw hole of the support plate with screws.
In FIG. 8, the guard is screwed to the central screw hole 58 of the three screw holes 58 in the vertical direction of the support plate. Therefore, the guard 71 and the guard 72 are arranged across the center of the arrangement space 92 in the vertical direction.
The guard 71 and the guard 72 have a guard hole 75 in the center.

The intermediate support column 61 is mounted between the two main support columns and in parallel with the two main support columns.
The height of the intermediate support column 61 is the same as the height of the main support column.
The intermediate support column 61 is made of metal.
The intermediate strut 61 has a rectangular flat plate 62. The flat plate 62 of the intermediate strut 61 has an intermediate mounting portion 63 that projects toward the inside of the arrangement space 92 at the lower end. The intermediate mounting portion 63 has two left and right screw holes 68.
The flat plate 62 of the intermediate support column 61 has a ceiling mounting portion 65 that projects toward the inside of the arrangement space 92 at the upper end. The top mounting portion 65 has two left and right screw holes.
The intermediate support column 61 has two flat plate holes in the vertical direction. That is, a flat plate hole 67 is provided at the center of the flat plate 62, and a flat plate hole 66 is provided above the flat plate hole 67. The position of the flat plate hole 67 coincides with the position of the guard hole 75 of the guard 72.
The flat plate 62 of the intermediate support column 61 has a reinforcing portion 64 that protrudes toward the inside of the arrangement space 92 along the left and right long sides. The reinforcing portions 64 are formed at a total of four places except for the portion overlapping the guard 72.

The outer area of the upper opening 94 and the outer area of the lower opening 95 are the same.
In the case of the column frame 50 to which the intermediate column 61 is not attached, since the upper opening 94 has two ceiling mounting portions 65, the opening area of the upper opening 94 excludes the areas of the two ceiling mounting portions 65. Area.
Since the lower opening 95 has four main mounting portions 57 and two intermediate mounting portions 63, the opening area of the lower opening 95 is equal to that of the four main mounting portions 57 and two intermediate mounting portions 63. It is the area excluding the area.
As a result, the opening area of the upper opening 94 is larger than the opening area of the lower opening 95.
In the case of the column framework 50 to which the intermediate column 61 is not attached, the upper opening 94 does not have the two ceiling mounting portions 65 and the lower opening 95 has the four main mounting portions 57. Has an opening area larger than that of the lower opening 95.

<<<screw hole positions for main column and intermediate column of column framework 50>>>
FIG. 4 is a bottom view of the lighting fixture 100.
The main mounting portions 57 of the four main columns are screwed to the corners of the cover 90 via the screw holes 59.
The intermediate support column 61 is attached to the center of the lighting device 100 in the left-right direction.
The intermediate mounting portion 63 of the intermediate column 61 is screwed to the central portion of the cover 90 via the two screw holes 68.
In the left-right direction, the distance W10 between the end of the strut framework 50 and the screw hole 59 is equal to the distance W9 between the left and right bisectors of the strut framework 50 and the screw hole 68.

<<<Configuration of Light Source Unit 80>>>>
As shown in FIG. 8, the light source unit 80 has a heat sink 82 and an LED substrate 86.
The entire upper surface of the LED substrate 86 is in surface contact with the entire lower surface of the heat sink 82.
The LED board 86 has three LEDs 81 arranged in the left-right direction, two LEDs 81 arranged in the front-rear direction, and a total of six LEDs 81 are arranged.
Hereinafter, the light source unit 80 in which the M LEDs 81 are arranged in rows and the N LEDs 81 are arranged in columns will be referred to as an M×N light source unit 80.

As shown in FIG. 6, the cover 90 has M×N reflecting mirrors 87 corresponding to the LEDs 81. It should be noted that the opening (top side or bottom side) of the reflecting mirror 87 should be covered with a transparent or translucent resin component or an optical lens should be inserted to prevent dust from entering the cover 90. You can Also, the optical characteristics can be changed by the optical parts.
As shown in FIG. 6, a reflecting mirror 87 is attached to the LED 81. Although the reflecting mirror 87 is not shown in FIG. 7, the reflecting mirror 87 is attached to the cover 90 corresponding to each LED 81.

<<<Configuration of Heat Sink 82>>>
As shown in FIG. 9, the heat sink 82 has a rectangular heat dissipation plate 83 and a plurality of heat dissipation fins 84. The heat sink 82 is made of metal.
The radiation fins 84 are erected from the radiation plate 83.
The heat radiation fin 84 is a rectangular flat plate having a height H1 and a width H2.
The radiating fins 84 are arranged in parallel in the front-rear direction at equal intervals.
The radiating fins 84 that are adjacent to each other in the left-right direction are arranged with a fin gap 85 having a length W2 therebetween.
The ratio of the height H1 to the width H2 of the radiation fin 84 is 1:1.
The ratio of the length W2 of the fin gap 85 to the width H2 of the heat radiation fin 84 is 1:5.

The heat dissipation fin 84 is disposed at least directly above the LED 81.
The fin gap 85 is formed in a place where the LED 81 is not arranged.
The fin gap 85 is located between the three LEDs 81 arranged in the left-right direction of the light source unit 80, and is formed in a groove shape in the front-rear direction of the light source unit 80.
For the 2×3 light source unit 80 in which the LEDs of 2 rows and 3 columns are arranged, only two fin gaps 85 are formed between the LEDs of 3 columns.
That is, for the M×N light source unit 80 in which the LEDs of M rows and N columns are arranged, the fin gap 85 is formed by N−1 pieces between the LEDs of N columns when M<N. ..
As described above, the heat sink 82 has the radiation fins 84 arranged in accordance with the arrangement of the LEDs 81.

***Explanation of heat dissipation structure***
The heat dissipation structure will be described with reference to FIG.
The meanings of the symbols shown in FIG. 2 are as follows.
W1: Vertical length of heat dissipation space 96 W2: Horizontal length of fin gap 85 W3: Vertical length of upper ventilation window 98 W4: Vertical length of lower ventilation window 99 W5: Intermediate column Width W61: Vertical length of the guard 72 W7: Width of the main support column 51 and the main support column 52 between the support plate 55 and the support plate 56 in the horizontal direction W8: Left and right of the upper ventilation window 98 and the lower ventilation window 99 Direction length

The heat sink 82 is covered with the top plate 40 via the heat dissipation space 96.
The support frame 50 forms a heat dissipation space 96 having a length W1 between the heat sink 82 and the top plate 40 to fix the light source unit 80 and the top plate 40. That is, there is a heat dissipation space 96 having a length W1 between the upper end of the heat dissipation fin 84 and the lower surface of the top plate 40.
The length W1 is preferably 0.5 times or more the height H1 of the heat dissipation fin 84.
Alternatively, the length W1 is preferably 40 mm or more.

As shown in FIG. 2, the guard 72 connects the central portions of the main columns in the vertical direction, and the vertical length of the guard 72 is the length W6.
The lighting fixture 100 has an upper ventilation window 98 having a length W3 from the guard 72 to the upper end of the main pillar.
The luminaire 100 has a lower ventilation window 99 having a length W4 from the guard 72 to the lower end of the main column.
The length of the upper ventilation window 98 and the lower ventilation window 99 in the left-right direction is W8.
The upper ventilation window 98 is between the upper end of the guard 72 and the upper surface of the support frame 50, and the length W3 of the upper ventilation window 98 is the length W1 or more of the heat dissipation space 96.
The lower ventilation window 99 is located between the lower end of the guard 72 and the lower surface of the column framework 50, and the length W3 of the upper ventilation window 98 and the length W4 of the lower ventilation window 99 are the same or equivalent. is there.
The width W8 in the left-right direction between the upper ventilation window 98 and the lower ventilation window 99 is the distance between the main support column and the intermediate support column.
The width W8 of the upper ventilation window 98 and the lower ventilation window 99 in the left-right direction is calculated from the length of the long side of the supporting frame 50, the width W5 of the intermediate supporting column 61, the width W7 of the supporting plate 55 of the main supporting column 51, and the main width. It is half the length obtained by subtracting the width W7 of the strut plate 55 of the strut 52.
As shown in FIG. 3, the widths of the upper ventilation window 98 and the lower ventilation window 99 in the front-rear direction are calculated from the length of the short side of the support frame 50 to the width W7 of the support plate 56 of the main support 51 and the support of the main support 52. It is the length obtained by subtracting the width W7 of the plate 56.
With the above structure, the upper, lower, left and right sides of the heat dissipation space 96 communicate with the external space through the six upper ventilation windows 98. Further, the front, rear, left, and right of the heat sink 82 are communicated with the external space through six lower ventilation windows 99.

A fin gap 85 having a length W2 exists between the heat radiation fins 84.
The length W2 of the fin gap 85 is preferably 0.2 times or more the width H2 of the heat radiation fin 84. Alternatively, the length W2 is preferably 10 mm or more.
As shown in FIG. 2, the width W5 of the intermediate support column 61 is smaller than the width H2 of the heat dissipation fins 84.
The fin gap 85 is formed at a position that does not overlap the intermediate support column 61 in a side view of the support frame 50.
The fin gap 85 is formed at a position exposed to the lower ventilation window 99 in a side view of the support frame 50.

In FIG. 2, the width W5 of the intermediate column 61 is 0.17 times or 0.2 times or less the length of the column plate 55 in the left-right direction.
In FIG. 2, the width W6 of the guard 72 is 0.18 times or 0.2 times or less the vertical length of the support plate 55.
In FIG. 2, the width W7 of the main columns 51 and 52 is 0.09 times or less than 0.1 times the length of the column plate 55 in the left-right direction.
The ventilation area ratio of the front surface area of the column framework 50 to the total area of the upper ventilation window 98 and the lower ventilation window 99 shown in FIG. 2 is 50% or 50% or more.
The ventilation area ratio may be 40% or more and 80% or less, and it is desirable that the ventilation area ratio is 60% or more in order to enhance the heat dissipation effect.

In FIG. 3, the width W6 of the guard 72 is 0.18 times or 0.2 times or less the vertical length of the support plate 55.
In FIG. 3, the width W7 of the main columns 51 and 52 is 0.14 times or less than 0.15 times the length of the column plate 55 in the front-rear direction.
The ventilation area ratio of the side surface area of the column framework 50 to the total area of the upper ventilation window 98 and the lower ventilation window 99 shown in FIG. 3 is 50% or 50% or more.
The ventilation area ratio may be 40% or more and 80% or less, and it is desirable that the ventilation area ratio is 60% or more in order to enhance the heat dissipation effect.

***Explanation of heat dissipation operation***
The warm air generated by the heat sink 82 rises toward the top plate 40.
There is a heat dissipation space 96 above the entire surface of the heat sink 82, and warm air rises toward the heat dissipation space 96.
As shown in FIGS. 2 and 3, there is an upper ventilation window 98 around the heat dissipation space 96, and the upper ventilation window 98 flows out.
Since the upper ventilation window 98 is in the front, rear, left, and right directions, warm air can be released in any direction of 360 degrees. Also, wind from any direction can be passed.

Further, as shown in FIG. 9, since there is the fin gap 85, the warm air in the fin gap 85 flows out in the front-rear direction.
As shown in FIG. 2, the fin gap 85 is exposed to the lower ventilation window 99, and the warm air in the fin gap 85 is discharged to the outside from the lower ventilation window 99.

***Explanation of the manufacturing method of the support frame 50***
1. Manufacture of main pillars Four main pillars arranged at the corners of the arrangement space 92 are manufactured.
That is, the main support column 51 and the main support column 52 are manufactured.
2. Manufacture of multiple types of guards with different lengths.
Here, the guard 71 and the guard 72 having a length ratio of 2:3 are manufactured.
3. Manufacture of the intermediate support column 61 The intermediate support column 61 is manufactured.
4. Selection of Guard A guard having a length that matches the size of the arrangement space 92, that is, the size of the light source unit is selected from two types of guards, the guard 71 and the guard 72. The options here are either:
(1) 4 guards 71
(2) Two guards 71 and two guards 72
(1) 4 guards 72
The light source unit 80 shown in FIGS. 1 to 8 is a 2×3 light source unit 80. Therefore, here, two guards 71 and two guards 72 having a length matching the size of the light source unit 80 are selected.
That is, two guards 71 having the same length as the short side length of the light source unit 80 are selected, and two guards 72 having the same length as the long side length of the light source unit 80 are selected.
5. Assembly Next, the main column and the selected guard are fastened with the fastening parts to assemble the column framework 50 having an arrangement space of a size matching the size of the light source unit 80.
Specifically, the following work is performed.
The pillar plate 56 of the main pillar 51 on the left side, the pillar plate 56 of the main pillar 52, and the guard 71 are combined and screwed.
The pillar plate 56 of the main pillar 51 on the right side, the pillar plate 56 of the main pillar 52, and the guard 71 are combined and screwed.
The strut plate 55 of the main strut 51 on the front, the strut plate 55 of the main strut 52, and the guard 72 are combined and screwed.
The support plate 55 of the main support column 51 on the rear surface, the support plate 55 of the main support column 52, and the guard 72 are combined and screwed.
At this point, the column framework 50 excluding the intermediate column 61 is assembled.

Here, the “combination” or “assembly” means that a plurality of individual parts are combined to be assembled into one.
Further, "combination" or "assembly" means assembling two or more parts together by a fastening means.
Preferred examples of fastening means are fastening parts, welding, crimping, soldering or fitting.
Suitable examples of fasteners are screws, bolts and nuts, rivets, clips or adhesives.
Here, "combination" or "assembly" refers to making up a collective component called a column framework 50 in which two types of components, a main column and a guard, are combined.
Furthermore, if the intermediate columns are also combined, the term “combination” or “assembly” means that a column frame 50, which is a combination of the main column, the guard, and the intermediate column, is assembled.

When a screw or a bolt/nut is used as the fastening component, the guard, the main column and the intermediate column can be detachably attached.
Here, "detachable" refers to a case where a plurality of components can be attached and detached by the force of a human finger. Or, a case where a plurality of parts can be attached and detached with a hand tool or an electric tool.
Welding, caulking, soldering, or gluing is not said to be "detachable".

***Explanation of manufacturing method of lighting fixture 100***
The lighting fixture 100 is manufactured by the following procedure.
The LED board 86 is attached to the heat sink 82.
After the cover 90 is attached to the light source unit 80 and the light source unit 80 and the cover 90 are integrated, the light source unit 80 and the cover 90 are inserted into the column framework 50 in which the intermediate column 61 is not attached.
Alternatively, instead of integrating the light source unit 80 and the cover 90, the cover 90 may be first inserted into the column framework 50 in which the intermediate column 61 is not mounted, and then the light source unit 80 may be inserted into the column framework 50.

The upper opening 94 has the same size as the light source unit 80 and the cover 90 or a size slightly larger than the size of the light source unit 80 and the cover 90. Therefore, the light source unit 80 and the cover 90 can be inserted right below from the upper opening 94 toward the lower opening 95. That is, it is only necessary to drop the light source unit 80 and the cover 90 from top to bottom.
The corners of the light source unit 80 and the cover 90 slide down while hitting the inner surfaces of the four main columns, so that the light source unit 80 and the cover 90 are positioned in the front, rear, left, and right positions, and the column framework 50 is positioned. Be dropped into.

The main mounting portion 57 protrudes inward from the lower opening 95, and the lower opening 95 is a portion where the main mounting portion 57 is present and has a size smaller than the size of the light source unit 80 and the cover 90. That is, when the light source unit 80 and the cover 90 are dropped from the upper side to the lower side, the corners of the light source unit 80 and the cover 90 hit the main mounting portion 57, and the corners of the light source unit 80 and the cover 90 rest on the main mounting portion 57. Slide ends.

Next, a screw is screwed in from the screw hole 59 of the main mounting portion 57 to fix the light source unit 80 and the cover 90 to the main mounting portion 57.
The light source unit 80 and the cover 90 are fixed to the column framework 50 with the outer four screws 101 of the eight upward screws shown in FIG.
The screw inserted from the main mounting portion 57 passes through the screw hole of the LED board 86 and the cover 90 and is screwed into the screw hole of the heat dissipation plate 83 of the heat sink 82.
The LED board 86 and the cover 90 are sandwiched between the main mounting portion 57 and the heat dissipation plate 83.
As a result, the light source unit 80 and the cover 90 are fixed to the lower portion of the column framework 50.

Then, the lighting fixture 100 is manufactured in the following order.
The power supply unit 30 is attached to the top plate 40.
The top plate 40 is attached to the support frame 50. The top plate 40 is screwed to the screw insertion portions 60 of the four main columns.
The skirt portion 44 of the top plate 40 is fixed to the column framework 50 with four horizontally oriented screws 102 shown in FIG. 7. Since the arm 20 rotates on the front surface and the rear surface of the luminaire 100, the skirt portion 44 is screwed only on both side surfaces, and the front surface and the rear surface are not screwed.
By fixing the light source unit 80 and the cover 90 to the column framework 50, the positions of the lower ends of the four main columns are fixed, and when the top plate 40 is fixed to the column frame 50, the four main columns are fixed. The position of the bottom edge is fixed. In this way, the four main columns are fixed in parallel, and the shape of the column framework 50 is fixed.
In particular, the main mounting portion 57 of the column framework 50 is fixed to the heat dissipation plate 83 having the largest thickness among the components of the lighting fixture 100, so that the shape of the column framework 50 is reliably maintained.

Next, the intermediate support column 61 is attached so as to be fitted from the front-back direction toward the center direction of the support frame 50.
The upper surface of the ceiling mounting portion 65 is brought into contact with the lower surface of the plate portion 42, and the two downward facing screws 103 shown in FIG. 7 are screwed into the screw holes of the ceiling mounting portion 65. Will be stopped.
Further, by applying the upper surface of the intermediate mounting portion 63 to the lower surface of the cover 90 and screwing the four central screws 104 of the eight upward screws shown in FIG. 7 into the screw holes 68 of the intermediate mounting portion 63, The intermediate column 61 is screwed to the light source unit 80 and the cover 90. The screw 104 inserted from the intermediate mounting portion 63 passes through the screw hole of the cover 90 and the LED substrate 86 and is screwed into the screw hole of the heat dissipation plate 83 of the heat sink 82.
The LED board 86 and the cover 90 are sandwiched between the intermediate mounting portion 63 and the heat dissipation plate 83.
Since the intermediate support column 61 is attached to a portion of the top plate 40 where the skirt portion 44 does not exist, the lengths of the light source unit 80, the cover 90, and the top plate 40 in the front-rear direction are the same, and the two intermediate support columns 61 are accurate. Will be installed in parallel with.
Further, since the strut plate and the intermediate strut are attached to the outside of the guard 72 and the strut plates and the intermediate strut have the same plate thickness, the outer surfaces of the main strut and the intermediate strut are on the same plane.

Finally, the arm 20 is attached to the strut framework 50.
The arms 20 are attached to the front surface and the rear surface of the column framework 50.
Specifically, the protrusion shaft 22 of the arm 20 is fitted into the flat plate hole 66 of the intermediate column 61. A preferred example of the protrusion shaft 22 is a bolt nut.
Further, a bolt nut 26 or a through screw is passed through the flat plate hole 67 of the intermediate support column 61, the guard hole 75 of the guard 72, and the arcuate hole 24 of the arm 20 to attach the arm 20 to the intermediate support column 61 and the guard 72.
The arm 20 can rotate about the protrusion shaft 22 within the range of the arcuate hole 24.
As described above, screwing is used for assembling the support frame 50 and the lighting fixture 100. When the two components to be screwed have different plate thicknesses, the screws are first attached to the thin plate component. Then, it is preferable to screw it into a thicker part.
Specific examples in the case where the plate thicknesses of the parts are different are as follows.
A. Heat sink plate thickness> Main support plate thickness B. Heat sink plate thickness> Intermediate support plate thickness C. Main support plate thickness> Top plate thickness D. Thickness of the middle support> Thickness of the top E. Guard thickness> Main strut thickness F. Guard thickness> Intermediate support thickness

***Explanation of the effect of the embodiment***
According to the present embodiment, the main strut, the intermediate strut, and the guard are separately manufactured and combined to manufacture a strut framework of a plurality of sizes. Therefore, the yield of the material of each component can be suppressed, the components can be shared even if the housing dimensions are different, and furthermore, the lighting fixture can be easily assembled and the processing cost can be reduced.

According to the present embodiment, since the radiation fins 84 are arranged according to the arrangement of the LEDs 81, the heat radiation effect is enhanced.
Further, since the heat radiation space 96 exists from the upper portion of the heat radiation fins 84 to the lower surface of the top plate 40, it is possible to eliminate heat accumulation and temperature rise due to the top plate 40.
Further, by setting the heat dissipation space 96 to be 40 mm or more, it is possible to provide a state substantially equivalent to the state without the top plate 40.
Further, since the upper ventilation window 98 exists around the heat dissipation space 96, hot air in the heat dissipation space 96 can be discharged to the outside.

Further, since there is the fin gap 85, it is possible to discharge the hot air between the radiating fins 84 that are adjacent in the left-right direction to the outside. When there is no fin gap 85, the heat radiation fin 84 becomes one heat radiation fin connected in the left-right direction, and the air flow path is blocked, so that the heat radiation efficiency deteriorates.
Since there is the fin gap 85, hot air can be discharged in a direction orthogonal to the surface of the heat dissipation fin 84, and air passages can be secured from the four front, rear, left, and right surfaces, so that the temperature rise can be reduced.
Further, since there is the fin gap 85 on the side surface on the long side where the arm 20 is attached, the number of fin gaps 85 can be increased compared to the case where the fin gap 85 is provided on the side surface on the short side.
As a result, the heat radiation of the LED can be performed by natural air cooling.

According to the present embodiment, since the main mounting portion 57 is provided, the light source unit 80 and the cover 90 can be dropped into the column framework 50, which facilitates manufacturing.
Further, since the four main columns are in the corners and the four main columns surround the light source unit 80 and the cover 90, the light source unit 80 and the cover 90 can be positioned simply by dropping the light source unit 80 and the cover 90. ..
Further, since the main mounting portion 57 is provided, it is possible to prevent the parts from falling.
Further, since the cover 90 is screwed through the main mounting portion 57, the screw tightening stress from the screw to the cover 90 can be received by the surface of the main mounting portion 57. As a result, the screw tightening stress can be dispersed over the entire surface of the main mounting portion 57, and the plastic cover 90 can be prevented from cracking.
When the cover 90 is screwed without using the main mounting portion 57, the screw tightening stress concentrates on a small area of the cover 90 where the screw head hits, so that the cover 90 is likely to crack.
Similarly, since the cover 90 is screwed through the intermediate mounting portion 63, cracking of the plastic cover 90 can be prevented.
Further, since the intermediate support column 61 is fixed to the center of the long side of the cover 90, the deformation and distortion of the plastic cover 90 can be prevented.
According to the present embodiment, the upper part of the support frame 50 is fixed with the top plate 40 made of metal, and the lower part of the support frame 50 is fixed with the heat dissipation plate 83 made of metal. Even if only the strut framework 50 is used, the solid lighting fixture 100 can be provided.

***Other configurations***

When assembling the strut framework 50, the intermediate strut 61 may be attached to the strut framework 50 first. Specifically, the intermediate column 61 may be screwed to the guard 72 by a mechanism (not shown) so as not to interfere with the arm 20.
When the intermediate support column 61 is screwed to the guard 72 when assembling the support frame 50, the ceiling mounting portions 65 are projected inward from the upper opening 94 at two front and rear positions.
When the top mounting portion 65 interferes with the insertion of the light source unit 80 and the cover 90, the light source unit 80 and the cover are so arranged that the outer peripheral portions of the light source unit 80 and the cover 90 do not hit the top mounting portion 65 of the upper opening 94. 90 may be slanted and inserted into the upper opening 94. After the light source unit 80 and the cover 90 have passed through the ceiling mounting portion 65 of the upper opening 94, the light source unit 80 and the cover 90 can be horizontal and the light source unit 80 and the cover 90 can be dropped from the top to the bottom.

The intermediate support column 61 may not have the ceiling mounting portion 65. If the ceiling mounting portion 65 is not provided, even if the intermediate support column 61 is attached to the support column framework 50 first, the light source unit 80 and the cover 90 can be dropped into the support column framework 50 while being horizontal.

The intermediate support column 61 may not have the intermediate attachment portion 63. If the intermediate mounting portion 63 is not provided, the light source unit 80 and the cover 90 are fixed only to the main column.

The guard is not limited to one in the vertical direction, but a plurality of guards may be provided. Specifically, since the support plate 55 and the support plate 56 have three screw holes 58 in the vertical direction, it is possible to provide a maximum of three guards in the vertical direction, and a maximum of two additional guards. be able to. The additional guard does not have to be plate-shaped, and a rod-shaped guard, a mesh guard, or a mesh guard is a suitable example for keeping air permeability.

The guard may not be provided at the center in the vertical direction. Since the support plate 55 and the support plate 56 have three screw holes 58 in the vertical direction, the guard may be attached at any one of the upper, middle, and lower positions.

The guard 71 shown in FIG. 3 may be omitted. Without the guard 71, the breathability is improved.

The number of intermediate columns is not limited to one, and a plurality of intermediate columns may be provided. Providing a plurality of intermediate columns increases the strength of the column framework 50 and also functions as a guard.

When the arm 20 is not used in mounting the lighting fixture 100 on the ceiling, the arm 20 and the intermediate support column 61 may be omitted. Without the intermediate struts 61, the stanchion framework 50 can be manufactured with only the main struts and guards.
Instead of screws, bolts and nuts may be used as the fastening parts. Alternatively, rivets may be used.

In order to ventilate the top plate 40, the top plate 40 may be a net top plate or a mesh top plate.
Alternatively, in order to enhance the heat dissipation effect, the top plate 40 may not be used and a guard may be used instead of the top plate 40.
Specifically, instead of the top plate 40 that covers the entire surface of the upper opening 94 of FIG. 5, two guards similar to the guard 71 of FIG. The power supply unit 30 may be fixed to the two guards 71.
Alternatively, two guards similar to the guard 72 of FIG. 2 may be attached to the upper opening 94 in parallel in the left-right direction, and the power supply unit 30 may be fixed to these two guards 72.
Alternatively, two guards similar to the guard 71 and the guard 72 shown in FIG. 2 may be attached to the upper opening 94 in a cross pattern, and the power supply unit 30 may be fixed to the intersection of these guards.

Ventilation slits may be provided in the strut plate of the main strut so that heat is dissipated from the ventilation slits in the strut plate.
The guard may be provided with a ventilation slit so that heat is radiated from the ventilation slit of the guard.
Further, although the case where the reflecting mirror 87 is integrally formed with the cover 90 has been described in the present embodiment, the reflecting mirror 87 may be a separate body from the cover 90, or the reflecting mirror 87 may be a lens or the like. It may be replaced with an optical component.

Embodiment 2.
In this embodiment, points different from the above-described embodiments will be described.
***Composition explanation***
In this embodiment, a case will be described in which the arrangement space 92 is a quadrangular prism, n types of lengths of guards are manufactured, and a strut framework having an arrangement space of any of the following sizes is manufactured.
1. Size that chooses two kinds of guards from n kinds of guards.
2. A size with one type of guard selected from n types of guards.
As a suitable example, a case will be described in which a plurality of sizes of strut frameworks are manufactured by guards of three types of lengths having a length ratio of 2:3:4.

10, FIG. 11, and FIG. 12 show a lighting fixture 100 in which the support frame 50 has a square prism shape in plan view.
In the light source unit 80, the LEDs 81 have four LEDs 81 arranged in a 2×2 array.
The lighting fixture 100 uses the guard 71 having the same length. Since the guard 71 has the guard hole 75, the intermediate column 61 and the arm 20 can be attached to the guard 71.

13 and 14 show the lighting fixture 100 in which the column framework 50 has two columnar arrangement spaces 92 adjacent to each other to form a joint space 93.
Here, the “congruent space” refers to a space in which a plurality of arrangement spaces are combined. The arrangement space is a space in which one light source unit 80 is arranged, but the congruent space is a space in which a plurality of light source units 80 are arranged.
The congruent space is the entire internal space of the column framework 50, and one side surface of one arrangement space 92 and one side surface of the other arrangement space 92 are arranged on the same plane. This same plane is called an adjacent boundary. Further, one side surface of one arrangement space 92 and one side surface of the other arrangement space 92 are referred to as adjacent side surfaces.
The luminaire 100 has two light source units 80, and each light source unit 80 is a 2×3 light source unit 80. Four main columns are arranged at the corners of the two arrangement spaces 92. There are main columns at all corners of the two arrangement spaces 92, and eight main columns at the congruent space 93.

The lighting fixture 100 uses two top plates 40 having the same size as the upper opening 94.
The power supply unit 30 is composed of one housing.

The lighting fixture 100 uses a guard 72 and a guard 73 having different lengths.
The length ratio of the guard 72 and the guard 73 is 3:4.
The guard 72 has a guard hole 75 in the center, but the guard 73 does not have the guard hole 75.
There is no guard 72 on the adjacent side surface where the two arrangement spaces 92 are adjacent to each other.
Therefore, in the column framework 50 shown in FIGS. 13 and 14, two column frameworks 50 shown in Embodiment 1 are connected by using the guard 73 instead of the guard 71, and the guard 72 on the adjacent side surface is omitted. It is a thing.
As shown in the plan view and the cross-sectional view of FIG. 14, two intermediate columns 61 are attached to the adjacent side surfaces where the two arrangement spaces 92 are adjacent to each other.
The intermediate mounting portions 63 of the two intermediate columns 61 at the adjacent boundaries are fixed to the light source unit 80 and the cover 90 with screws.
The top mounting portions 65 of the two intermediate columns 61 at the adjacent boundaries are fixed to the plate portion 42 of the top plate 40 with screws.
Since the intermediate support columns 61 have no outward protrusion, they can be adjacent to each other back to back at the adjacent boundary. Further, since there is no guard 72 on the adjacent side surface, there is no screw for stopping the guard 72, and there is no screw for the skirt portion 44, so that they can be adjacent to each other without a gap.
Further, by fixing the shaft holes 28 of the two intermediate columns 61 on the adjacent side surfaces with the bolts and nuts 26, the connection between the two arrangement spaces is strengthened.
In order to fasten the two strut frameworks 50, the strut plate 55 of the main strut 51 and the strut plate 55 of the main strut 52 are fastened with fastening parts through the screw holes 58.
There are guards only around the joint space 93, and there are two guards 72 and two guards 73 around the joint space 93.
Both the guard 72 and the guard 73 connect a plurality of main columns arranged on the same side surface of the congruent space.
The guard 73 has screw holes at both ends, has no guard hole 75 in the center, and has two screw holes. Since the guard 73 connects the four main columns, it is arranged outside the column plate of the main columns.
The guard 72 connects two main columns arranged on the side surface on the short side of the congruent space.
The intermediate column 61 and the arm 20 are attached to the guard 72.
The guard 73 connects the four main columns arranged on the side surface on the long side of the congruent space.
Both ends of the guard 72 are fixed to the inside of the column plate of the main column with fasteners.
Both ends of the guard 73 are fixed to the outside of the pillar plate of the main pillar by fastening parts.
The center of the guard 73 is fixed to the outside of the column plates of the two main columns adjacent to and in contact with each other by a fastening component by means of a screw hole in the center of the guard 73.

FIG. 15 and FIG. 16 show a lighting fixture 100 in which the column framework 50 has two columnar arrangement spaces 92 adjacent to each other to form a congruent space 93.
The luminaire 100 has two light source units 80, and each light source unit 80 is a 2×2 light source unit 80. Not all the corners of the two arrangement spaces 92 have the main pillars, but the corners on the adjacent side surfaces of the two arrangement spaces 92 do not have the main pillars. The main columns are arranged only at four corners of the joint space 93, and there are four main columns in the joint space 93.

The lighting fixture 100 may use two top plates 40 of the same size as the upper opening 94, or may use one top plate 40 of the same size as the congruent space 93.
The power supply unit 30 is composed of one housing.

The lighting fixture 100 uses a guard 71 and a guard 74 having different lengths.
The ratio of the lengths of the guard 71 and the guard 74 is 2:4.
The guard 71 and the guard 74 have a guard hole 75 in the center.
Since there is no main pillar on the adjacent side surface where the two arrangement spaces 92 are adjacent to each other, there is no guard 71 on the adjacent side surface.
Around the joint space 93, there are two guards 71 and two guards 74.
Both the guard 71 and the guard 74 connect a plurality of main columns arranged on the same side surface of the congruent space.
The guard 74 has screw holes at both ends and a guard hole 75 at the center.
The guard 71 connects two main columns arranged on the side surface on the short side of the congruent space.
The guard 74 connects two main columns arranged on the side surface on the long side of the congruent space.
Both ends of the guard 71 are fixed to the inside of the pillar plate of the main pillar by fastening parts.
Both ends of the guard 74 are fixed to the inside of the pillar plate of the main pillar by fastening parts.
At the center of the guard 74, the intermediate column 61 and the arm 20 are attached by a guard hole 75 at the center of the guard 73.
Since the intermediate column 61 is fixed to the center of the long side of the cover 90, it is possible to prevent the plastic cover 90 from being deformed and distorted.

As shown in FIG. 4, since W9=W10, in FIGS. 15 and 16, the position of the screw hole 68 of the intermediate mounting portion 63 of the intermediate mounting portion 63 of the intermediate supporting column 61 is the position of the main mounting portion 57 of the main supporting column omitted. It is in the same position as the screw hole 59.
Therefore, in FIG. 15 and FIG. 16, the screw holes 68 of the intermediate mounting portion 63 of the intermediate support column 61 coincide with the positions of the screw holes of the light source unit 80 and the cover 90, and the light source unit 80 and the cover 90 include the intermediate support column. It is fixed to 61 with a screw.
As described above, the support frame 50 shown in FIGS. 15 and 16 does not include the two main support columns and one guard 71 from the support frame 50 shown in FIGS. Instead of 71, a guard 74 is used to connect two.

When the arrangement space is a square pole and there are three types of guards with a length ratio of the guards of 2:3:4, a column framework in which the aspect ratio of the horizontal cross section of the arrangement space 92 is one of the following aspect ratios: Can be manufactured.
(1) 2:2 (Fig. 10)
(2) 2:3 (Fig. 1)
(3) 2:4 (Fig. 15)
(4) 3:3
(5) 3:4 (Fig. 13)
(6) 4:4

Further, when there are four types of guards having a length ratio of the guards of 2:3:4:6, it is possible to further manufacture a support frame having the following aspect ratios.
(7) 2:6
(8) 3:6
(9) 4:6
(10) 6:6

Theoretically, the total number of combinations (combination) that selects two kinds of guards from n kinds of guards and the total number of combinations (combination) that selects one kind of guards from n kinds of guards are added, Different sizes of strut frameworks 50 can be assembled.

Further, for the column framework 50 of these sizes, the light source units 80 of four sizes in which LEDs are arranged in 2×2, 2×3, 3×3, 4×4 are arranged as follows. be able to.
(1) For 2:2, one 2×2 (FIG. 10)
(2) For 2:3, one 2x3 (Fig. 1)
(3) For 2:4, two 2×2 (FIG. 15)
(4) For 3:3, one 3×3
(5) Two 3:2 (3:4) (Fig. 13)
(6) For 4:4, four 2x2 or one 4x4
(7) For 2:6, three 2×2 or two 2×3
(8) For 3:6, three 2×3,
(9) For 4:6, 6 2x2 or 4 2x3
(10) For 6:6, 9 2x2, 4 3x3, 5 2x2 and 1 4x4, or 3 2x2 and 1 4x4 and one 2x3

***Effects of the embodiment***
When the light source units 80 are connected and used as shown in FIGS. 13 and 14, the cost can be suppressed and the weight of the device can be reduced by removing the unnecessary guard from the mating surfaces.
As shown in FIGS. 13 and 14, even when the light source units 80 are connected and used, since there are four main columns around the arrangement space 92, front, rear, left, and right positioning can be reliably performed, and further, main mounting is possible. Positioning in the vertical direction is facilitated by the portion 57, and assembly workability is improved.

When the light source units 80 are connected and used as shown in FIGS. 15 and 16, the cost can be suppressed and the weight of the device can be reduced by removing unnecessary main columns from the mating surfaces.
As shown in FIGS. 15 and 16, when the light source units 80 are connected and used, since there is no main column in the center and there is a margin in the left-right direction, it is easy to drop the light source unit 80 into the column frame 50, and assembling workability. Is improved.
Further, even if there is no main pillar in the center, the intermediate pillar 61 can fix the long sides of the top plate 40, the light source unit 80 and the cover 90, so that the strength can be maintained.

***Other configurations***
In FIG. 13, the guard 72 may be provided on the adjacent side surface where the two arrangement spaces 92 are adjacent to each other.
Specifically, the guard 72 is sandwiched between the strut plate 55 of the main strut 51 and the strut plate 55 of the main strut 52 on the adjacent side surfaces, and the strut plate 55 of the main strut 51, the guard 72, and the strut plate of the main strut 52 are sandwiched. 55 is fastened with a bolt nut through the screw hole 58.
Alternatively, as shown in FIG. 8, one guard 72 is arranged inside the main column of the one arrangement space 92, and the guard 72, the column plate 55 of the main column 51, and the column plate 55 of the main column 52 are arranged. Fastening parts are fastened through the screw holes 58.
Alternatively, the two guards 72 are arranged inside the main support columns of both the arrangement spaces 92, and the guard 72, the support plate 55 of the main support column 51, the support plate 55 of the main support column 52, and the guard 72 are provided with screw holes 58. Fasten with fastening parts through.

Although the guard 73 and the guard 74 have different structures, the guard 73 and the guard 74 may be formed in the same part by forming a guard hole 75 and two screw holes in the center of the guard 73 and the guard 74.
It is also possible to use the structure of the strut framework 50 with the guard 71 shown in the first embodiment as it is and further add a guard 73 to the outside of the guard 71 to connect the two strut frameworks 50.
Similarly, the structure of the column framework 50 with the guard 71 shown in FIGS. 10, 11, and 12 is used as it is, and a guard 73 is added to the outside of the guard 71 to connect the two column frameworks 50. You may.

The two arrangement spaces forming the congruent space may have different shapes.
More specifically, a combination of a regular quadrangular prism arrangement space and a long quadrangular prism arrangement space, and a triangular prism arrangement space and a quadrangular prism arrangement space can be considered.
The number of arrangement spaces forming the congruent space may be three or more instead of two.
The planar shape of the congruent space is not limited to a square. If the guard is bent at a right angle to form an L-shaped guard, a cross-shaped, T-shaped, L-shaped, or E-shaped congruent space can be formed.

Embodiment 3.
In this embodiment, points different from the above-described embodiments will be described.
***Composition explanation***
FIG. 17 is a simplified plan view of a column framework 50 in which a main column and a guard are combined.
As in (a), the support frame 50 may have a hexagonal planar shape.
As in (b), the support frame 50 may have an octagonal planar shape.
As shown in (c), the support frame 50 may have an elongated hexagonal planar shape.
As shown in (d), the support frame 50 may have a trapezoidal planar shape.
As in (e), the support frame 50 may have a circular planar shape.
As in (f), the support frame 50 may have a parallelogram planar shape.
As described above, the outer shape of the support frame 50 may be a polygonal column shape or a column shape.
As shown in FIG. 17, a columnar arrangement space other than a square pole can be provided by setting the intersecting angle of the two column plates of the main column to be other than 90 degrees.
By using only the main columns in which the intersecting angles of the two column plates exceed 90 degrees, it is possible to provide the column framework 50 of pentagonal columns or more.
Further, as shown in (d) or (f), if a main strut having an intersection angle of less than 90 degrees and a main strut having an intersection angle of more than 90 degrees are used, a complicated shape can be obtained. A strut framework 50 can be provided.
Although not shown, the outer shape of the support frame 50 may be a truncated pyramid shape or a truncated cone shape.

FIG. 18 is a perspective view showing another example of the main column.
In the main column 53 of FIG. 18, the column plate 55 and the column plate 56 have the same structure.
That is, the support plate 55 and the support plate 56 have the following.
A. Main mounting part 57 with screw hole 59
B. 3 screw holes 38
C. Screw insertion part 60
Therefore, the main pillars 53 having the same shape can be arranged at a plurality of positions of the square pole.
The main support column 53 can be used for all corners of a square pole, and parts can be shared.

20 arm, 22 protrusion shaft, 24 arc hole, 26 bolt nut, 28 shaft hole, 30
Power supply unit, 40 top plate, 42 plate part, 44 skirt part, 50 column frame, 51 main column, 52 main column, 53 main column, 55 column plate, 56 column plate, 57 main attachment part, 58 screw hole, 59 screw Hole, 60 screw insertion part, 61 intermediate support, 62 flat plate, 63 intermediate mounting part, 64 reinforcing part, 65 top mounting part, 66 flat plate hole, 67 flat plate hole, 68 screw hole, 71 guard, 72 guard, 73 guard, 74 Guard, 75 Guard hole, 80
Light source unit, 81 LED, 82 heat sink, 83 heat dissipation plate, 84 heat dissipation fin, 85 fin gap, 86 LED substrate, 87 reflector, 90 cover, 92 arrangement space, 93 congruent space, 94 upper opening, 95 lower opening, 96 heat dissipation space, 98 upper ventilation window, 99 lower ventilation window, 100 lighting fixture, 101 screw, 102 screw, 103 screw, 104 screw.

Claims (6)

A light source unit having a mounting plate to which a light source is mounted,
A top plate arranged to face the light source unit,
A lighting fixture comprising: a pillar that fastens the light source unit and the top plate. The mounting plate and the top plate are rectangular,
The lighting fixture according to claim 1, wherein the support columns are provided at three locations, that is, a central portion of one side of the light source unit and the top plate and both side portions apart from the central portion. The lighting device according to claim 2, wherein the light source unit is fixed only to the column. The lighting fixture according to claim 2 or 3, wherein the pillar has main pillars provided at four corners of the mounting plate and the top plate. The lighting fixture according to claim 2 or 3, wherein the support column includes an intermediate support column provided at a center of opposing sides of the mounting plate and a center of opposing sides of the top plate. The light source unit includes a heat sink,
The heat sink has a heat dissipation plate and a plurality of heat dissipation fins,
The lighting device according to claim 1, wherein the mounting plate is the heat dissipation plate.

Images