JP2019024022A - Lighting device - Google Patents

Abstract

To provide a light unit which makes the interior of a gap bright and prevents a gap portion from becoming dark in a stripe form even if the gap exists between a lighting device body and the light unit, and to provide the lighting device.SOLUTION: A lighting device includes: a device body 200; a translucent cover 10 which covers an LED substrate 9 and is partially housed in the device body 200; and bending parts 601, 602 which face a portion of the translucent cover 10 housed in the device body 200 across gaps 621, 622. Gaps 605, 606 are provided between the translucent cover 10 and the device body 200. Light reflected by the bending parts 601, 602 of light emitted from LEDs of the LED substrate 9 is radiated to the outside of the device body 200 from the gaps 605, 606.SELECTED DRAWING: Figure 33

Description

  The present invention relates to a lighting device.

  An illuminating device capable of detachably attaching a light unit to a luminaire is disclosed. (For example, see Patent Documents 1 and 2.)

WO2010 / 095710 JP 2012-003993 A Japanese Patent Application Laid-Open No. 2014-137992 JP 2012-186095 A JP 2014-137842 A

  However, when there is a gap between the luminaire main body and the light unit, there is a problem that the inside of the gap becomes relatively dark when the lighting device is turned on, and the gap portion becomes dark like a streak .

  It is an object of the present invention to provide a light unit and a lighting device that can brighten the inside of the gap even when there is a gap between the luminaire main body and the light unit, and the gap does not darken in a streak shape. To do.

The lighting device of the present invention is
An instrument body;
A light-transmitting cover that covers the light source and is at least partially housed in the instrument body;
A portion housed in the instrument body of the translucent cover and a facing portion facing each other across a first gap;
A second gap is provided between the translucent cover and the instrument body,
Of the light emitted from the light source, the light reflected by the facing portion is irradiated from the second gap to the outside of the instrument body.

  ADVANTAGE OF THE INVENTION According to this invention, even if it is a case where there exists a clearance gap between a lighting fixture and a light unit, the inside of a clearance gap can be brightened and the light unit and lighting apparatus which a clearance gap part does not become dark like a stripe form can be provided.

FIG. 3 is a perspective view of the lighting device 300 in the first embodiment. The perspective view which decomposed | disassembled the illuminating device 300 into the light unit 100 and the instrument main body 200 in the figure of Embodiment 1. FIG. The perspective view which decomposed | disassembled the light unit 100 in the figure of Embodiment 1. FIG. In the figure of Embodiment 1, the top view of the light unit 100, a front view, and a bottom view. FIG. 5 is a cross-sectional view taken along line AA in FIG. 1 (FIG. 8) and a cross-sectional view taken along line BB in the top view of FIG. FIG. 3 is a left side view of the light unit 100 in the first embodiment. FIG. 5 is a cross-sectional view taken along the line CC of the front view of FIG. 4, according to the first embodiment. FIG. 6 is a diagram of the first embodiment, and is a DD cross-sectional view of the front view of FIG. 5. In the figure of Embodiment 1, it is a perspective view of cover packing 20L, 20R. FIG. 3 is a perspective view of end covers 30R and 30L in the first embodiment. In the figure of Embodiment 1, it is a partially expanded view of the AA cross section. FIG. 5 is a diagram for explaining the attachment of the center of the light unit 100 in the first embodiment. FIG. 5 is another view for explaining the attachment at the center of the light unit 100 in the diagram of the first embodiment. FIG. 3 is a diagram for explaining the attachment of the left end portion of the light unit 100 in the diagram of the first embodiment. FIG. 3 is an exploded perspective view of the waterproof power supply device according to the first embodiment. FIG. 5 is a diagram for explaining the mounting of the packing to the waterproof power supply device in the first embodiment. FIG. 3 is a partial top view of the light unit 100 in the first embodiment. FIG. 5 is a diagram for explaining drainage properties (drainage properties) of the lighting device 300, according to the first embodiment. In the figure of Embodiment 2, it is the variation of the illuminating device 300. FIG. In the figure of Embodiment 2, it is the variation of the illuminating device 300. FIG. In the figure of Embodiment 2, it is the variation of the illuminating device 300. FIG. In the figure of Embodiment 2, it is the variation of the illuminating device 300. FIG. In the figure of Embodiment 2, the perspective view of the illuminating device 300-2 using the two light units 100. FIG. In the figure of Embodiment 3, it is a figure which shows the drain hole 38L-1. In the figure of Embodiment 3, it is a perspective view of end cover 30R-1. In the figure of Embodiment 3, it is a perspective view of end cover 30L-1. FIG. 6 is a diagram of the third embodiment, and is a cross-sectional view of the end cover 30L-1. In the figure of Embodiment 3, it is a perspective view which shows the mounting state to the edge part cover 30L-1 of the attachment metal fitting 50L-1. In the figure of Embodiment 3, it is sectional drawing which shows the cylindrical guide 390L of end part cover 30L-1, and the side part 511L of the attachment metal fitting 50L-1. FIG. 29 is a cross-sectional view taken along the line EE of FIG. 29 in the third embodiment. In the figure of Embodiment 3, it is a figure explaining the drainage property in the edge part cover 30L-1. In the figure of Embodiment 4, (a) The perspective view of the frame 60-1, and (b) X direction arrow directional view. FIG. 6 is a diagram of the fourth embodiment, and is a cross-sectional view corresponding to the CC cross section of FIG. 4. In the figure of Embodiment 5, it is a perspective view which shows the attachment to the instrument main body 200 of the attachment metal fitting 50L-2. In the figure of Embodiment 5, it is a perspective view of the mounting bracket 50L-1-1. FIG. 35 is a diagram of the fifth embodiment, and is a cross-sectional view taken along line FF of FIG. In the figure of Embodiment 6, the top view of the light unit 100, the front view, and the expansion perspective view of a hook part. FIG. 18 is a diagram of the sixth embodiment and shows a wire 240 with a hook. FIG. 19 is a diagram of the sixth embodiment, and shows a process for attaching the light unit 100 to the fixture body 200. In the figure of Embodiment 6, it is the schematic of the top view which shows arrangement | positioning of a hook part.

Embodiment 1 FIG.
The lighting apparatus 300 according to the first embodiment described below includes a light unit 100 and an instrument main body 200. The illumination device 300 mainly has the following characteristics.
(1) The light unit 100 includes thermal expansion in the longitudinal direction of the translucent cover 10 that accommodates an LED substrate (light source substrate) on which an LED (light source) is mounted, and the translucent cover that is generated in accordance with the use environment temperature. The difference with the thermal expansion in the longitudinal direction of the frame 60 to which 10 is attached is absorbed with a simple configuration. Thereby, the reliability and workability of the light unit 100 are improved. Moreover, the waterproofness (watertightness) of the translucent cover 10 is also ensured. Thereby, the light unit 100 improves waterproofness (watertightness) while improving workability, and reduces the risk of failure due to intrusion of liquid such as water.
(2) In the light unit 100, the LED substrate and the power supply device that supplies power to the LED substrate are housed in separate waterproof cases. Thereby, compared with the case where an LED board and a power supply device are accommodated in one case, the influence of a mutual temperature rise is suppressed and the reliability of the light unit 100 is improved. It also improves assembly and maintenance.
(3) The lighting device 300 provides a configuration with good drainage (drainage) even when a liquid such as water enters the inside of the instrument body 200. This reduces the risk of failure due to liquids such as entering water.
(4) Further, the waterproof power supply device 80 is provided on the outside of the translucent cover 10, for example, a suspension bolt 97 </ b> L (or FIG. 5A described later) so as not to interfere with the suspension bolt for fixing the lighting device 300. 98L) and a suspension bolt (not shown) located on the right side of the waterproof power supply device 80 in FIG. 5A. Thereby, the illuminating device 300 can be made thinner. That is, the illumination device 300 can be made thinner by disposing the waterproof power supply device 80 at a position where it does not interfere with the suspension bolt.

  A lighting apparatus 300 according to the first embodiment will be described with reference to FIGS. The lighting device 300 described below has a configuration in which the translucent cover 10 is attached to the frame 60 and the cover packings 20L and 20R and the end cover 30L at the left end 11L (FIG. 1) and the right end 11R in the longitudinal direction. , 30R is characterized by a closed configuration.

  FIG. 1 is a perspective view of the lighting device 300. FIG. 2 is an exploded perspective view of the lighting device 300 into the light unit 100 and the instrument main body 200. FIG. 3 is an exploded perspective view of the light unit 100. The directions shown in FIG. 3 are called the upper side and the lower side. 4A, 4B, and 4C are a top view, a front view, and a bottom view of the light unit 100, respectively. 5A is a cross-sectional view taken along line AA of the lighting device 300 (FIG. 1), and FIG. 5B is a cross-sectional view taken along line BB of the light unit 100 (FIG. 4A). FIG. 6 is a left side view of the light unit 100. FIG. 7 is a cross-sectional view of the light unit 100 taken along the line CC (FIG. 4B). The CC cross section is a cross section of the central portion of the light unit 100 in the longitudinal direction. FIG. 8 is a DD cross-sectional view (FIG. 5A) of the illumination device 300 (the light unit 100 attached to the instrument body 200). A specific position of the DD cross section is a cross section at a position where the thickness of the cover packing 20L is slightly cut as shown in FIG.

(Outline of configuration of lighting device 300)
As shown in FIGS. 1 and 2, the lighting device 300 includes a light unit 100 and an instrument main body 200. The light unit 100 is attached to the instrument body 200 with screws 96L and 96R that pass through the screw through holes 34L and 34R. The screw through holes 34L and 34R are covered with caps 90L and 90R.

  As shown in FIG. 3, the light unit 100 includes a translucent cover 10, a cover packing 20L (first packing), a cover packing 20R (second packing), an end cover 30L (first end cover), End cover 30R (second end cover), cover fixture 40L (first fixture), cover fixture 40R (second fixture), fixtures 50L and 50R (third fixture), A frame 60, a special screw 70L, a special screw 70R, a waterproof power supply device 80, caps 90L and 90R, and the like are provided.

  Assembly of the light unit 100 will be described with reference to FIGS. 2, 3, 10, 11, and 14. Inside the translucent cover 10, an LED board frame 8 to which an LED board 9 on which an LED (not shown) as a light source is mounted is housed. Hereinafter, the left end portion 11L will be described as an example. In a state where the LED board frame 8 is housed in the translucent cover 10, the harness housing rubber 91 is attached to the end of the LED board frame 8. Next, a cover packing 20L that closes the opening 12L of the translucent cover 10 is attached. Next, the end cover 30L is attached to the translucent cover 10 so as to cover the cover packing 20L (FIG. 11).

  Next, the insertion part 42L (FIG. 11) of the cover fixture 40L is connected to the end cover insertion part 35L (FIGS. 10 and 11) of the end cover 30L and the cover insertion part 13L of the translucent cover 10. (FIGS. 11 and 14). Next, a stopper screw 94L for preventing the cover fixture 40L from coming off in the direction opposite to the insertion direction is attached. Next, a mounting bracket 50L for mounting the translucent cover 10 to the instrument body 200 is placed on the upper surface side of the left end portion 11L. The above is the description of the left end portion 11L, but the same applies to the right end portion 11R. Next, the frame 60 is put on the upper side of the mounting brackets 50L and 50R, and the special screws 70L and 70R are tightened into the screw holes 41L and 41R of the cover fixtures 40L and 40R. 10 is mounted. Next, the light fitting 100 is attached to the fixture main body 200 by attaching the mounting brackets 50L and 50R to the fixture main body 200 with screws 96L and 96R (FIG. 2). The order of assembly described above is an example, and other orders may be used.

Next, each component of the light unit 100 will be described with reference to the drawings.
(Translucent cover 10)
As shown in FIG. 3, the translucent cover 10 is a long hollow body (tubular body) that is open at both ends. The translucent cover 10 is formed of a translucent material so as to transmit light emitted from an LED as a light source, and is manufactured, for example, by extrusion molding using acrylic. As shown in FIG. 3, the translucent cover 10 has protrusions 14-1 L, 14-2 L, 14-3 L, 14-4 L, and 14-1 R, 14-on the left and right sides of the cover fixing plate 93 in the longitudinal direction. A projecting portion 14-5C is formed at a central portion where 2R, 14-3R, 14-4R and the cover fixing plate 93 are provided. Among the projecting portions that continue in the longitudinal direction from the leftmost projecting portion 14-1L to the rightmost projecting portion 14-1R, a portion between the projecting portion 14-1L and the projecting portion 14-2L is cut off. It is the structure of such a shape.
FIG. 12A is a top view of the central portion of the light unit 100, and is a view in which a part of the frame 60 is cut away so that the protruding portion 14-5C can be seen. FIG. 12B is a perspective view showing the protruding portion 14-5C at the center. The protruding portion 14-5C is formed of a pair whose cross section is F-shaped. The protruding portions 14-1L, 14-2L, 14-3L, and 14-4L and the protruding portions 14-1R, 14-2R, 14-3R, and 14-4R have the same shape as the protruding portion 14-5C. It is. However, the length in the longitudinal direction is different in this embodiment. In the protruding portion 14-5C, the cover fixing plate 93C is inserted along the longitudinal direction into the gap formed by the F-shaped pair. As shown in FIG. 12B, the cover fixing plate 93C is formed with a screw hole 93C-1 into which the screw 96C is tightened.

(Cover insertion part 13L, 13R)
The translucent cover 10 includes a cover insertion portion 13L (first attachment portion) formed at the left end portion 11L and a cover insertion portion 13R (first attachment portion) formed at the right end portion 11R. Part). The cover insertion portion 13L and the cover insertion portion 13R are a protruding portion 14-1L and a protruding portion 14-1R (FIG. 3). The length in the longitudinal direction of the cover insertion portion 13L and the cover insertion portion 13R is shorter than the length in the longitudinal direction of the protruding portion 14-5C. The cover insertion portion 13L is disposed at the left end portion 11L, and, similar to the protruding portion 14-5C (FIG. 12), the insertion portion of the cover fixture 40L along the longitudinal direction in the gap formed by the F-shaped pair. 42L is inserted (FIG. 11). The cover insertion portion 13R is disposed at the right end portion 11R, and in the same manner as the protruding portion 14-5C (FIG. 12) and the cover insertion portion 13L (FIG. 11), the gap is formed in the longitudinal direction in the gap formed by the F-shaped pair. The insertion part 42R of the cover fixture 40R is inserted along

(Cover packing 20L, 20R)
9A and 9B are enlarged views of the cover packings 20L and 20R in FIG. In the present embodiment, the left cover packing 20L and the right cover packing 20R have the same structure. As shown in FIG. 9B, the cover packing 20 </ b> R is formed with a recess 21 </ b> R that is recessed over the entire circumference on the inner side of the translucent cover 10. The tip of the right end portion 11R of the translucent cover 10 is fitted into the recess portion 21R. If it demonstrates in the hollow part 21L, as shown in FIG. 8, FIG. 11, the hollow part 21L will be attached so that the outer wall and inner wall of the translucent cover 10 may be contact | connected. As shown in FIG. 11 (A-A cross section), in the cover packing 20L, the hollow portion 21L forms a “U-shaped” frame, and the transparent portion is formed between the “U-shaped” (the hollow portion 21L). In this structure, the end of the light cover 10 enters. With such a structure, the cover packing 20L closes the opening 12L of the translucent cover 10. The same applies to the cover packing 20R.

(End cover 30L, 30R)
10A and 10B are enlarged views of the end covers 30L and 30R in FIG. In the present embodiment, the left and right end covers have the same structure. The end cover 30L has a storage portion 31L (first storage portion) for storing the cover packing 20L, and the opening 12L of the translucent cover 10 is closed together with the cover packing 20L by the storage portion 31L. Further, the end cover 30R includes a storage portion 31R (second storage portion) that stores the cover packing 20R, and the opening 12R of the translucent cover 10 is closed together with the cover packing 20R by the storage portion 31R.
The left and right end covers 30L have drain holes 38L (drainage) for discharging water and other liquids to the outside when liquid such as water enters a slight gap generated between the cover packings 20L. Liquid hole) (FIGS. 6, 10A, and 11). Similarly, the end cover 30R has a drain hole 38L (a drain hole, not shown).

(Cover fixing tool 40L, 40R)
Next, the cover fixtures 40L and 40R will be described. In the present embodiment, the cover fixture 40R has the same structural shape as the cover fixture 40L. Therefore, the cover fixture 40L will be described, and the description of the cover fixture 40R will be omitted. As shown in FIG. 3, the cover fixture 40L has an L-shaped appearance. The cover fixture 40L has a screw hole 41L into which the special screw 70L is tightened.
FIG. 11 is a partially enlarged view of the AA cross section. As shown in FIG. 11, the cover fixture 40L includes an insertion part 42L (first insertion part), an extension part 43L (first extension part), and an opposing part 44L (first opposing part). The cover fixture 40R also has an insertion part 42R (second insertion part), an extension part 43R (second extension part), and an opposing part 44R (second opposing part). The insertion portion 42L has a “flat plate shape” and is inserted into the cover insertion portion 13L (first attachment portion). The extension portion 43L extends in a direction from the insertion portion 42L toward the left end portion 11L. The facing portion 44L is bent from the extension portion 43L and faces the end cover 30L.

(Mounting bracket 50L, 50R)
Next, the mounting brackets 50L and 50R will be described. In the present embodiment, the mounting bracket 50R has the same structure as that of the mounting bracket 50L. Therefore, the mounting bracket 50L will be described, and the description of the mounting bracket 50R will be omitted. As shown in FIG. 3, the mounting bracket 50L includes a flat plate portion 51L stacked on the lower surface side of the frame 60, a side surface portion 52L standing along the longitudinal direction from both sides of the flat plate portion 51L, and a left end portion 11L of the flat plate portion 51L. It has the arm part 53L formed in the L shape. The mounting bracket 50L has a long hole 54L that overlaps the long hole 60L formed in the frame 60.

(Frame 60)
As shown in FIG. 3, the frame 60 has a long shape and is a frame to which the translucent cover 10 is attached. The frame 60 includes a flat flat plate portion 62 and side portions 63 that stand downward from both sides of the flat plate portion 62 along the longitudinal direction. As shown in FIG. 7, the cross-sectional shape of the frame 60 is “U-shaped”. The front end of the side surface portion 63 is bent inward by about 90 degrees, and has a positioning function when the mounting brackets 50L and 50R are accommodated. The frame 60 has a recess 64 in which a through hole 65C is formed at the center. This is a structure for lowering the position of the head of the screw 96C so that the head of the screw 96C does not interfere with the bottom surface of the waterproof power supply device 80. FIG. 13 shows an enlarged view of the recess 64.

(Special screw 70L, 70R)
In the present embodiment, the special screw 70R has the same structure and shape as the special screw 70L, so the special screw 70L will be described, and the description of the special screw 70R will be omitted. The special screw 70L shown in FIG. 3 is a stepped screw. As shown in FIG. 11, the translucent cover 10 is attached to the frame 60 by the flange portion of the head pressing the frame 60 and the male screw being tightened into the screw hole 41 </ b> L of the cover fixture 40 </ b> L.

(Waterproof power supply 80)
As shown in FIG. 3, a waterproof power supply device 80 is attached to the upper side of the flat plate portion 62 of the frame 60. FIG. 15 is an exploded perspective view of the waterproof power supply device 80. The waterproof power supply 80 includes a power supply case body 81, a packing 82-1 (first power supply case packing), a packing 82-2 (second power supply case packing), and a packing fixture 83-1. (First fixture) and packing fixture 83-2 (second fixture). The power supply case main body 81 is a hollow body that opens at both ends, and houses a power supply device (not shown) that supplies power to the LEDs. The packing 82-1 closes one opening of the power supply case main body 81, and the packing 82-2 closes the other opening of the power supply case main body 81. The packing fixture 83-1 fixes the packing 82-1 and the packing fixture 83-2 fixes the packing 82-2. The packing fixture 83-1 is fixed to the power supply case main body 81 by being screwed into the screw holes 85 provided on both sides of the power supply case main body 81 with screws 84. FIG. 16 schematically shows a dimension A of the packing fixture 83-1, an outer dimension B of the packing 82-1, an inner dimension C of the packing 82-1, and an inner dimension D of the power supply case body 81. In FIG. 16, the relationship is A> B, C <D and (A−B) − (D−C)> 0. In addition, when the dimension of the depth direction (short side direction) corresponding to AD in FIG. 16 is set to a, b, c, d, that is, the packing fixture 83-1 is longitudinal A (mm), lateral a (mm). ), The outer side of the packing 82-1 is the vertical B (mm), the horizontal b (mm) is the rectangle, the inner side of the packing 82-1 (the power supply case body 81 side) is the vertical C (mm), the horizontal c ( mm), and when the opening of the power source case body 81 is assumed to be a rectangle of length D (mm) and width d (mm), a> b, c <d and (ab) − (D−c)> 0. The same applies to the packing fixture 83-2 side. In addition to the waterproof performance obtained by pressing the packings 82-1 and 82-2 against the end portion of the case body 81 for the power supply when the relationship between the dimensions A to D and the dimensions a to d is set. In addition, higher waterproofness (watertightness) can be obtained.

(Caps 90L, 90R)
As shown in FIG. 3, the screw through hole 34L of the end cover 30L through which the screw 96L passes is covered by attaching a cap 90L. Thereby, the designability is improved. The cap 90R has the same function and effect.

(Absorption of difference in expansion amount of thermal expansion)
The light unit 100 absorbs the difference between the thermal expansion in the longitudinal direction of the translucent cover 10 and the thermal expansion in the longitudinal direction of the frame 60 to which the translucent cover 10 is attached with a simple configuration. The simple configuration will be described below with reference to FIGS. 3, 11, 13, and 17. FIG. As described above, the translucent cover 10 is attached to the frame by tightening the special screws 70L, 96C, and 70R from the upper side of the frame 60 to the cover fixture 40L, the cover fixture plate 93C, and the cover fixture 40R, respectively. 60. At this time, the through hole 65C (FIG. 13) through which the shaft of the screw 96C passes is large enough to allow the shaft diameter of the screw 96C to pass therethrough. As shown in FIG. 3, the frame 60 is mounted on the cover fixture 40L and the cover fixture 40R from above with the mounting brackets 50L and 50R interposed therebetween. FIG. 17 is a top view of the light unit 100 and shows the relationship between the long hole 61L of the frame 60 and the long hole 54L of the mounting bracket 50L. The thicker axis of the stepped screw portion of the special screw 70L is indicated by a two-dot chain line. The screw hole 41L of the cover fixture 40L is visible from the long hole 61L and the long hole 54L. As shown in FIG. 17, the long hole 61L is shorter than the long hole 54L. The long hole 61L is included in the long hole 54L in the top view of FIG. The long hole 61L (first notch) of the frame 60 is cut into an elongated elliptical shape along the longitudinal direction, and the direction from the screw hole 41L (first screw hole) to the left end 11L in the longitudinal direction is The screw hole 41L is exposed so that there are regions 61L-1 and 61L-2 cut out in both directions from the screw hole 41L toward the right end portion 11R. The same applies to the long hole 61R (second notch) of the frame 60. The long hole 61L may have a notch shape in which the left end is cut off.

  When the use environment temperature rises in the assembled state shown in FIG. 11, the frame 60 and the translucent cover 10 expand in the longitudinal direction. Moreover, the translucent cover 10 expand | swells also by moisture absorption. For example, when the translucent cover 10 is made of acrylic, the frame 60 is made of aluminum, and the total length of the translucent cover 10 is about 1.2 m, the translucent cover 10 is made transparent as the assumed usage environment conditions (temperature, humidity) change. The light cover 10 expands or contracts by about 10 mm larger than the frame 60 in the longitudinal direction. Since the light unit 100 is fixed to the frame 60 at the center in the longitudinal direction with screws 96C that pass through the through holes 65C that are not long holes, the left and right expansion amounts (or contraction amounts) in the longitudinal direction with reference to the through holes 65C are respectively It is about 5 mm. The 5 mm expansion (or contraction) is absorbed by the notched regions 61L-1 and 61L-2 and the notched regions 61R-1 and 61R-2 (not shown) shown in FIG. When the light-transmitting cover 10 expands (or contracts), the light-transmitting cover 10, the cover fixing tool 40L, and the special screw 70L are displaced substantially integrally in FIG.

(Watertightness)
The cover fixing tool 40L used for the configuration that absorbs the difference in the expansion amount in the longitudinal direction is the opposed portion 44L at the tip, and prevents the end cover 30L from coming off. The longitudinal length 47L of the cover fixing tool 40L including the insertion portion 42L and the extension portion 43L is about 120 mm, and the amount of expansion of the translucent cover 10 at that portion is about 1 mm. This degree of expansion or contraction is an amount that can be absorbed by the elastic deformation of the cover packing 20L. The cover fixture 40R also has the same function and effect.

(Preventing movement of cover fixing tool 40L)
FIG. 14 is a top view of the left end portion 11L of the light unit 100, with the cover fixture 40L exposed. The cover fixing tool 40L is fastened with two stopper screws 94L. When the cover fixing tool 40L moves leftward with respect to the translucent cover 10, the stopper screw 94L hits the cover insertion portion 13L, and the leftward movement is stopped. When the cover fixing tool 40L moves in the right direction with respect to the translucent cover 10, the facing portion 44L hits the end cover 30L, and the movement in the right direction is stopped. The same applies to the cover fixing tool 40R.

(Function of end cover 30L, 30R)
As shown in FIG. 10, the end cover 30 </ b> R includes an outer peripheral facing portion 32 </ b> R (second outer peripheral facing portion) that faces at least a part of the outer periphery of the right end portion 11 </ b> R of the translucent cover 10, and the translucent cover 10. An inner periphery facing portion 33R (second inner periphery facing portion) facing at least a part of the inner periphery of the right end portion 11R is provided. Similarly, the end cover 30L also includes an outer peripheral facing portion 32L (first outer peripheral facing portion) and an inner peripheral facing portion 33L (first inner peripheral facing portion). As shown in FIG. 11, the end cover 30L holds down the end portion of the translucent cover 10 together with the cover packing 20L by the outer peripheral facing portion 32L and the inner peripheral facing portion 33R. As a result, the adhesiveness between the cover packing 20L and the end of the translucent cover 10 is maintained, and deformation of the translucent cover 10 is prevented. With such a configuration, the translucent cover 10 is waterproof (watertight). Further, as described in the explanation of FIG. 14, the end cover 30 </ b> L is moved leftward when the cover fixing tool 40 </ b> L moves leftward with respect to the translucent cover 10 and the stopper screw 94 </ b> L hits the cover insertion portion 13 </ b> L. When the movement is stopped and the cover fixing tool 40L moves to the right with respect to the translucent cover 10, the facing portion 44L hits the end cover 30L and the movement to the right is stopped. That is, when viewed from the end cover 30L side, the slide width in the longitudinal direction of the end cover 30L is regulated by the cover fixture 40L. Further, as shown in FIG. 11, the through hole forming portion 37L in which the through hole 36L through which the screw 96L passes is formed close to the tip of the facing portion 44L of the cover fixture 40L. For this reason, when the end cover 30L slides, the roll motion that warps in the vertical direction can be restricted by the front end of the facing portion 44L interfering with the through-hole forming portion 37L. The same applies to the end cover 30R.

(Drainage (drainage))
FIG. 18 is a view showing a CC cross section of the lighting apparatus 300. As shown in FIG. 2, the fixture body 200 is formed with an opening 201 serving as a storage port for storing the light unit 100 along the longitudinal direction, and one edge 202 of the opening 201 extends along the longitudinal direction of the translucent cover 10. Thus, a gap is formed between the translucent cover 10 and another edge 203 facing the one edge 202 forms a gap along the longitudinal direction of the translucent cover 10. In FIG. 18, the gap between the translucent cover 10 and the instrument main body 200 in the CC cross section is about 0.6 mm, and the gap between the instrument main body 200 and the end cover 30L in the DD cross section is about 1 mm. By such a gap, it is possible to improve drainage (drainage) for discharging liquid such as water that has entered the instrument body.
Moreover, the inclined surface 15 (FIG. 7, FIG. 18) which is shoulder-sloped toward the edge part of a width direction is formed so that the center part of the width direction (short direction) of the translucent cover 10 may become a vertex. By forming the inclined surface 15, oil smoke and water droplets (droplets) adhering to the upper surface of the translucent cover 10 drips along the inclined surface 15, so that drainage (drainage) can be improved. Further, since the projecting portions 14-1L, 14-1R, and 14-5C are divided into three blocks without being connected to the longitudinal direction, the projecting portions 14-1L, 14-1R, and 14-5C are separated. Smoke and water (liquid) droplets adhering to the water do not collect in the projecting portions 14-1L, 14-1R, and 14-5C, but easily drop along the inclined surface 15 in the width direction. (Drainage) can be improved.

Embodiment 2. FIG.
The second embodiment will be described with reference to FIGS. Embodiment 2 demonstrates the variation of the illuminating device 300 of Embodiment 1. FIG. 19, 20, 21, and 22 are illumination devices of a trough type, a shaded type, a V-type 1, and a V-type 2, respectively. The trough type of FIG. 19 is the illumination device 300 of the first embodiment. 19A, 19B, and 19C are respectively a left side view, a CC cross-sectional view, and a DD cross-sectional view. The reason why the CC sectional view is equivalent is that the CC sectional view is a sectional view of the light unit 100 and FIG. 19B is a sectional view of the lighting device. The same applies to FIGS. Although these lighting apparatuses differ in the shape of the fixture main body from the lighting apparatus 300, the light unit is the same as the light unit 100 of the first embodiment. In addition, in the illuminating device of FIGS. 19-21, the position of the harness extraction hole of a cover packing differs from the light unit 100. FIG.

(1) According to the illuminating device 300 described above, as shown in FIG. 17, there are notched regions 61L-1 and 61L-2 (the same applies to the right end portion 11R) on both sides of the special screw 70L. Therefore, in a long illuminating device with a simple configuration by the cover insertion portion 13L, the cover fixture 40L, the long hole 61L of the frame 60, the special screw 70L, etc., the members in the longitudinal direction (translucent cover 10, The difference in expansion amount accompanying the temperature change of the frame 60 and the like can be absorbed. Moreover, since the cover fixing tool 40L also has a function of preventing the end cover 30L that fixes the cover packing 20L from coming off, the above-described configuration also improves water tightness.
(2) According to the illuminating device 300 described above, the LED substrate 9 is accommodated in the translucent cover 10 and the power supply device is accommodated in the power supply case main body 81. Therefore, the LED substrate 9 and the power supply device are integrated. Temperature rise can be suppressed as compared with the case of being stored in two waterproof cases. As a result, it is possible to prevent a decrease in light output caused by a temperature rise. Moreover, since the required heat resistance (temperature resistance) of the parts is also lowered, the cost can be reduced. And the assemblability and maintainability can also be improved.
(3) According to the illuminating device 300 described above, since the gap is provided in the longitudinal direction between the translucent cover 10 and the instrument main body 200, the drainage property that discharges liquid such as water that has entered the instrument main body 200. (Drainage) can be improved.
(4) According to the illuminating device 300 described above, the outer peripheral facing portion 32L and the inner peripheral facing portion 33L of the end cover 30L support the outer wall and the inner wall of the end portion of the translucent cover 10 (the right end portion 11R is also the same). The same). Therefore, deformation of the end portion of the light-transmitting cover 10 can be prevented.
(5) According to the illuminating device 300 described above, the waterproof power supply device 80 has two suspending bolts outside the translucent cover 10 so as not to interfere with the suspending bolt for fixing the illuminating device 300. It is arranged between. Thereby, the illuminating device 300 can be made thinner. By making the lighting device 300 thinner, the overhanging dimension of the lighting device 300 from the ceiling or the like is suppressed, so that light can be emitted from the lighting device 300 to the entire lighting space more widely, and the lighting space can be used more widely. can do.

Embodiment 3 FIG.
The third embodiment will be described with reference to FIGS. The third embodiment relates to different configurations of the end covers 30L and 30R and the mounting brackets 50L and 50R described in the first and second embodiments. The end cover of the third embodiment will be described as end covers 30L-1 and 30R-1, and the mounting brackets will be described as mounting brackets 50L-1 and 50R-1.

  First, the end cover 30L-1 will be described, but the end cover 30R-1 has the same configuration as the end cover 30L-1. The end cover 30L-1 has a cylindrical guide 390L with respect to the end cover 30L of the first embodiment, the shape of the drain hole 38L-1, and the bottom surface has a drain hole 38L. It has a slope that goes down to -1.

  As shown in FIG. 27, when the end cover 30L-1 (first end cover) is attached to the instrument main body 200 in the same manner as the end cover 30L, a screw 96L for attachment to the instrument main body 200 is provided. A threaded through hole 34L that passes therethrough is formed.

  25 and 26 are perspective views of the end covers 30R-1 and 30L-1, and show the cylindrical guides 390R and 390L. As shown in FIG. 27 which is a cross-sectional view, the end cover 30L-1 has a bottom 310L that is the bottom when attached to the instrument body 200, and an end 315L of the bottom 310L in the direction indicated by the arrow 314L. A standing wall 320L in which a substantially circular drainage hole 38L-1 (including a circular shape) is formed is provided at a portion that stands up and begins to stand up. The bottom portion 310L is a through hole forming portion having a cylindrical guide 390L that rises in a cylindrical shape in a direction (arrow Z direction) in which the screw 96L passes from the peripheral edge 341L of the screw through hole 34L. In the end cover 30L-1, a cylindrical guide 390L that is a cylindrical screw guide surrounds the screw through hole 34L. As shown in FIG. 2, the light unit 100 is attached to the instrument body 200 using screws 96L and 96R. However, the end cover 30L-1 surrounds the screw through hole 34L with a cylindrical guide 390L. The screw 96L does not protrude from the inside of the cylindrical guide 390L. That is, when attaching the light unit 100 to the instrument main body 200, there is no possibility that the screw 96L falls into the end cover 30L-1. The same applies to the end cover 30R-1 (second end cover) and the screw 96R.

  As shown in FIGS. 25 and 31, slits 391L and 391R are formed in the cylindrical guides 390L and 390R in the vertical direction (arrow Z direction) of the cylindrical side surfaces. The slit 391L is formed on the side surface facing the drain hole 38L-1. FIG. 31 is a view of FIG. 26 as viewed in the X direction. As shown in FIG. 31, by providing the cylindrical guide 390L with a slit 391L, water (liquid) on the inner bottom portion 310L of the cylindrical guide 390L is provided. ) Can be discharged into the drain hole 38L-1 without being held inside the cylindrical guide 390L.

  As shown in FIGS. 25 and 26, the end covers 30R-1 and 30L-1 are provided with harness support portions 380R and 380L that support the harness with the harness interposed therebetween. The harness support portions 380R and 380L sandwich the harness provided to supply power from the power supply device to the LED (not shown) mounted on the LED board 9 by the recess formed by the two wall portions. It is the structure which supports. Note that the shapes of the harness support portions 380R and 380L are not limited to the illustrated shapes.

  As described above, the cylindrical guides 390L and 390R formed on the end covers 30R-1 and 30L-1 have screws 96L and 96R inside the end covers 30R-1 and 30L-1 when the lighting device 300 is assembled. Along with the effect of improving the workability by eliminating the possibility of dropping, the cylindrical guides 390L and 390R have high water tightness against the ingress of water (liquid) from the screw through holes 34L and 34R to which the caps 90L and 90R are attached. Has the effect of ensuring.

Next, the drain hole 38L-1 of the end cover 30L-1 will be described. The drain hole 38L-1 is shown in FIGS. The opening area of the drain hole 38L-1 is the area with improved drainage, it is preferable that the opening area is 20mm ² ~30mm ^2, the opening area in this embodiment is 20 mm ^2. The sectional shape of the opening is arbitrary, but the aspect ratio is preferably close to 1. As shown in FIG. 24, the shape of the opening in the drain hole 38L-1 may be a bowl shape. By setting it as such a shape, the water (liquid) inside end cover 30L-1 can be drained effectively. The same applies to the end cover 30R-1 (second end cover).

  Next, it will be described that the bottom surface 311L of the bottom portion 310L of the end cover 30L-1 has an inclination that descends toward the drain hole 38L-1. As shown in FIG. 27, the bottom surface 311L (surface) of the bottom portion 310L has a downward slope in the direction indicated by the arrow 314L toward the drain hole 38L-1 in a state where the light unit 100 is attached to the fixture body 200. It has a downward slope region 316L (FIG. 31). As shown in FIG. 27, the bottom surface 311L is provided with a drainage gradient (inclination) 312L toward the drainage hole 38L-1 (the direction of the solid arrow). When the drainage gradient 312L is in a posture to irradiate the light unit 100 horizontally and downward, the bottom surface 311L of FIG. 27 is directed to the drainage hole 38L-1 at an inclination angle of approximately 1 degree in the end cover 30L-1. A descending slope. The inclination angle is determined in consideration of drainage and formability. The drainage will be described with reference to FIG. In FIG. 31, the drainage gradient 312L at the center is indicated by a broken line arrow. However, in the downward gradient region 316L, the water becomes lower toward the arrow of the drainage gradient 312L, so that the water on the bottom surface 311L moves toward the drainage hole 38L-1. It is discharged from the hole 38L-1. The same applies to the end cover 30R-1 (second end cover).

  Next, the mounting bracket 50L-1 in FIG. 28 will be described. In the mounting bracket 50L shown in FIG. 11, the L-shaped horizontal portion of the L-shaped arm portion 53L is in contact with the instrument main body 200 when the light unit 100 is attached to the instrument main body 200 (the instrument main body 200). To be fixed).

  First, as shown in FIG. 27, the end cover 30L-1 includes a bottom portion 310L that is the bottom when attached to the instrument main body 200 of the first embodiment, and an outer shell that is formed continuously from the bottom portion 310L upward. 330L. The light unit 100 includes a mounting bracket 50L-1 (third mounting tool).

  The mounting bracket 50L-1 in FIG. 28 has side portions 511L and 512L formed by bending the side end portions on both sides of the L-shaped horizontal portion 502L of the arm portion 53L. In FIG. 28, the shape in the range surrounded by the broken line 501L is different from the mounting bracket 50L of the first embodiment, but the shape in the range surrounded by the broken line 501L may be the same shape as the mounting bracket 50L (FIG. 3).

  Similarly to the mounting bracket 50L, the mounting bracket 50L-1 is mounted on the light unit 100 by being sandwiched between the frame 60 and the translucent cover 10 (FIG. 11). The mounting bracket 50L-1 is attached such that the front ends 513L and 514L (end portions) of the side surface portions 511L and 512L press the inner wall 331L that is inside the outer shell 330L of the end cover 30L-1. As shown in FIG. 30 showing the EE cross section of FIG. 29 and a range 313L surrounded by a broken line ellipse in FIG. 29, the light units 100 are attached to the instrument body 200 at the tips 513 and 514 of the side portions 511L and 512L. In this state (a state in which the lighting device 300 is used), the end cover 30L-1 is abutted against the inner side (inner wall), so that the end cover 30L-1 is prevented from rattling. Moreover, since rattling is suppressed, watertightness (water-stopping) is also improved. The same applies to the mounting bracket 50R-1 and the end cover 30R-1.

Embodiment 4 FIG.
The fourth embodiment will be described with reference to FIGS. 32 and 33. FIG. The fourth embodiment relates to a frame 60-1 having a shape different from that of the frame 60 described in the first embodiment. The light unit 100 according to Embodiment 4 includes a translucent cover 10 having translucency and a frame 60-1 to which the translucent cover 10 is attached.

  As shown in FIGS. 32 and 33, the frame 60-1 has bent portions 601 and 602 (opposing portions) in which end portions of the respective side surface portions 63 are bent. The bent portions 601 and 602 are formed over the longitudinal direction of the frame 60-1, and one surface side faces the flat plate portion 62. As shown in FIG. 33, the other surface side of the bent portions 601 and 602 faces the translucent cover 10 with gaps 621 and 622 (first gaps) therebetween. Although the translucent cover 10 has a long shape, as shown in FIGS. 3 and 32, the frame 60-1 has a long shape along the longitudinal direction of the translucent cover 10 having a long shape. The bent portions 601 and 602 are formed along the longitudinal direction of the frame 60-1. As shown in FIG. 33, the gaps 621 and 622 are formed along the longitudinal direction of the frame 60. An opening 201 serving as a storage port for storing the light unit 100 is formed along the longitudinal direction of the translucent cover 10, and one edge 202 of the opening 201 is spaced from the translucent cover 10 along the longitudinal direction of the translucent cover 10. The other edge 203 which opposes 606 (second gap) and faces one edge 202 is separated from the translucent cover 10 and the gap 605 (second gap) along the longitudinal direction of the translucent cover 10. Facing each other.

(Frame surface treatment)
In the bent portions 601 and 602, lower lower surfaces 603 and 604 on which the LED substrate 9 is disposed are processed so as to have a reflectance higher than that of the material of the frame 60-1. The lower surfaces 603 and 604 are preferably white with high reflectivity. As a method of making the lower surfaces 603 and 604 have a higher reflectance than the material of the frame 60-1, for example, a method of applying and drying and curing a highly reflective paint, a method of attaching a highly reflective sheet material, a frame material In the case of aluminum, there is a method of applying white alumite treatment. By treating the lower surfaces 603 and 604 to have a high reflectance, the light reflected by the lower surfaces 603 and 604 of the bent portions 601 and 602 as shown by arrows 211 and 212 in FIG. The light is irradiated to the outside from a gap 606 formed by one edge 202 and the translucent cover 10 and a gap 605 formed by another edge 203 and the translucent cover 10.

  As shown in FIG. 33, the lower surfaces 603 and 604 of the frame 60-1 can be seen from the gaps 605 and 606 between the instrument main body 200 and the translucent cover 10. For this reason, in the state in which the light unit 100 attached to the instrument main body 200 is lit, the light that travels from the translucent cover 10 to the instrument main body 200 side out of the light emitted from the LED (not shown) as the light source is reduced. Since the light is returned to the irradiation side by the side surfaces 603 and 604, the light use efficiency in the entire lighting device can be improved. In addition, the gaps 605 and 606 have the effect of drainage (drainage), but even if the gaps 605 and 606 are viewed from all angles, the lower surfaces 603 and 604 where light is reflected are seen. 605 and 606 do not darken in a streak shape, and the design properties in a state where the light unit 100 is turned on are improved. Moreover, since the gaps 621 and 622 are formed, water can be discharged from the gaps 621 and 622.

Embodiment 5. FIG.
The fifth embodiment will be described with reference to FIGS. Embodiment 5 relates to a mounting structure between a mounting bracket and an instrument body. Hereinafter, the mounting brackets 50L-2 and 50L-1-1 will be mainly described, but the mounting brackets 50R-2 and 50R-1-1 have the same configuration as the mounting brackets 50L-2 and 50L-1-1.

  The mounting bracket 50L-2 will be described with reference to FIG. As shown in FIG. 34, the instrument main body 200 has an instrument-side flat plate portion 230 in which an instrument-side through hole 210 is formed. The mounting bracket 50L-2 is attached to the appliance-side flat plate portion 230. The mounting bracket 50L-2 is a recessed portion 532L having a concave shape that falls into the horizontal portion 531L (flat plate portion) of the L-shaped arm portion 53L toward the light unit 100 and is recessed with respect to the mounting bracket 50L shown in FIG. Is formed. A through hole 533L through which the screw 96L passes is formed in the recessed portion 532L in the recessed portion 532L. The screw 96L is used to attach the light unit 100 to the instrument body 200.

  FIG. 36 shows a state where FIG. 34 is assembled, and is a cross section taken along line FF of FIG. As shown in FIG. 36, the horizontal portion 531L is positioned below the appliance-side flat plate portion 230, a retaining washer 542L is disposed in the recess of the recess 532L, and the lower side of the retaining washer 542L ( A washer 541L is disposed on the opposite side. The screw 96L includes a screw shaft 962L having a screw groove and a screw head 961L. The screw shaft 962L of the screw 96L is screwed into the instrument side nut 220 (the counterpart part) via the washer 541L, the through hole 533L, the retaining washer 542L, and the instrument side through hole 210, so that the lower surface of the screw head 961L is attached to the washer 541L. The horizontal part 531L of the pressing and mounting bracket 50L-2 is pressed against the instrument side flat plate part 230 of the instrument body 200. The shape of the recess 532L is arbitrary as long as the retaining washer 542L is accommodated. Further, the depth H of the recess 532L is determined according to the thickness B of the retaining washer 542L. For example, if the thickness dimension B of the retaining washer 542L is 1 mm, the recess depth dimension H is preferably 1 mm or slightly larger than 1 mm. This is because the upper surface of the horizontal portion 531L and the lower surface of the appliance-side flat plate portion 230 are in close contact with each other with no gap and are in close contact with each other.

  The screw 96L, the washer 541L, and the retaining washer 542L are attached in the assembly process of the light unit 100. The screw 96L, the washer 541L, and the retaining washer 542L are circulated integrally with the light unit 100. In the case of distribution, in FIG. 34, a washer 541L is disposed below the recess 532L, the screw shaft 962L is passed through the washer 541L and the through hole 533L, and a retaining washer 542L is attached to the threaded shaft 962L. . In this way, in the light unit 100, the retaining washer 524L is disposed on the recessed portion 532L side of the mounting bracket 50L-2, and the washer 541L is disposed on the opposite side of the retaining washer 542L across the recessed portion 532L. The retaining washer 542L is attached to the screw shaft 962L with the screw shaft 962L of the screw 96L passing through the washer 541L and the through hole 533L of the recess 532L, so that the washer 541L and the retaining washer are attached to the mounting bracket 50L-2. 542L and the screw 96L are integrally attached.

  As shown in FIG. 35, it is apparent that the mounting bracket 50L-1-1 may be configured by providing the mounting bracket 50L-1 of the third embodiment with a recess 532L.

  According to the mounting bracket 50L-2, in the process of packaging the light unit 100, there is no need to separately wrap the screws 96L, so that the packaging operation time can be shortened and forgetting to package the screws 96 can be prevented. That is, the manufacturing process of the light unit 100 can be simplified and improved in quality. Further, since the screw 96L is integrated with the light unit 100 in the construction of the lighting device 300, there is no need to take out the screw 96L and there is no possibility of losing it. Further, it is not necessary to use a special tool such as a magnet driver when tightening the screw 96L. Since the recess 532L is provided, the adhesion between the mounting bracket 50L-2 and the instrument body 200 is increased, and the light unit 100 can be firmly fixed to the instrument body 200. Even when the retaining washer 542L is used, the end covers 30L, 30R (30L-1, 30R-1) do not float or tilt, so that the water stop and design of the light unit 100 can be ensured.

Embodiment 6 FIG.
The sixth embodiment will be described with reference to FIGS. The sixth embodiment relates to an attachment process when attaching the light unit 100 to the fixture body 200. The sixth embodiment relates to the frame 60-2. FIG. 38 shows an example of a hooked wire 240 having a hook 241 and a wire 242 (linear body). In the wire 240 with a hook, the hook 241 is attached to the tip of the wire 242. The wire with a hook is not limited to the illustrated form. As shown in FIG. 37, the frame 60-2 has hook portions 611 and 612 for hooking the hook 241 of the wire 240 with hook on the flat plate portion 62. Each hooked wire 240 is hooked on the hook portions 611 and 612.

  As shown in FIG. 37 (c), in the present embodiment, the hooking portions 611 and 612 have a roof shape constituted by two surfaces in which a part of the flat plate portion 62 is cut and raised, but the hook 241 is hooked. And sufficient strength to be able to maintain the state where the light unit 100 is suspended by hooking the hook 241. In addition, the hooks 611 and 612 may be mounted with a part for hooking the hook 241 by a method such as welding or screwing in addition to cutting and raising.

  The wire end portion 243 of FIG. 38 is attached to a wire end attachment portion 250 provided in the instrument main body 200 before the construction work. FIG. 29 shows an example of the wire end mounting portion 250. There is one wire end attachment portion 250 corresponding to each of the hook portions 611 and 612. The wire end attaching portion 250 provided in the instrument main body 200 may have a function of a storage portion that stores the wire 240 with the hook. In the attachment process of attaching the light unit 100 to the fixture main body 200, each wire end attachment portion 250 is substantially directly above the hook portions 611 and 612. As long as the wire end portion 243 can be attached to the wire end attachment portion 250, the shape of the wire end portion 243 and the structure and shape of the wire end attachment portion 250 are not limited.

  As shown in FIG. 37A, in the top view (plan view), the center of gravity 701 is shifted from the line 616 connecting the hooking portion 611 and the hooking portion 612. That is, in the light unit 100, the line 616 (area equivalent line) connecting the hook portions 611 and 612 is the light unit 100 in a plan view (FIG. 37A) when the light unit 100 is attached to the instrument body 200. The center of gravity 701 does not overlap. Therefore, in the state where the hook 241 of the wire 240 with one hook is hooked on the hook portion 611 and the hook 241 of the other wire 240 with hook is hooked on the hook portion 612 and the light unit 100 is suspended, the hook portion 611 and the hook portion Since a dynamic moment is generated around the line 616 connecting the line 612 as the center line, the light unit 100 settles in a tilted state as shown in FIG.

  As shown in FIG. 37 (c), the two hook portions 611 and 612 are cut and raised by two cuts made in the flat plate portion 62 of the frame 60-2 in a direction orthogonal to the direction of the line 616. Shape. It is not necessary to actually cut and raise. For example, a part having a shape that can be hooked with the hook 241 of the wire 240 with the hook is attached to the flat plate part 62 of the frame 60-2 by using a method such as welding or screwing. Also good.

  As shown in FIG. 37 (c), the hook 241 (shown by a two-dot chain line) is hooked so as to face the longitudinal direction. However, as shown in FIG. 39, the hook 241 is hooked in the direction perpendicular to the shaking direction. Therefore, even if the light unit 100 swings in the swing direction, the hook 241 does not come off from the hooking portions 611 and 612. In addition, since the selection range of the length of the wire 242 is wide, the length of the wire 242 can be easily selected so that the hook 241 can be attached to the hooking portions 611 and 612 at a height below the operator's line of sight. Further, the light unit 100 can be tilted by a mechanical moment and the wiring surface can be directed to the worker side, so that the worker can perform wiring work safely and efficiently using both hands. Thus, since the light unit 100 can be suspended from the fixture body 200 and wiring work can be performed while the light unit 100 is temporarily held, the workability is improved in the mounting step of attaching the light unit 100 to the fixture body 200.

  In FIG. 37, the case where the frame 60-2 has two hook portions (hook portions 611, 612) has been described. However, three or more hook portions may be provided. As shown in FIG. 40, when three or more hooks are provided (in the case of four in FIG. 40), an area surrounded by a line connecting a plurality of hooks so as to form a polygon (in FIG. 40, a square 620). Does not have the center of gravity 701 of the light unit 100 on the side of the polygon (the quadrangle 620) and in the polygonal region in a plan view in a state where the light unit 100 is attached to the fixture body.

  In addition, the illuminating device which concerns on embodiment mentioned above WHEREIN: The translucent cover 10 which accommodates the LED board (light source board) with which LED (light source) was mounted which generate | occur | produces with the change of use environment conditions (temperature, humidity). The difference between the thermal expansion in the longitudinal direction and the thermal expansion in the longitudinal direction of the frame 60 to which the translucent cover 10 is attached is absorbed at both ends (left and right) in the longitudinal direction of the light unit. Not limited to this, the light unit may be configured to absorb at one end in the longitudinal direction. By adopting such a configuration, a simpler configuration can be achieved.

  In addition, the lighting device according to the above-described embodiment uses a translucent cover that is a long hollow body (tubular body) that is open at both ends, and both ends are waterproofed using an end cover and cover packing. The structure has the property (watertightness). However, the present invention is not limited to this, and it is also possible to use a light-transmitting cover that is a long hollow body (cylinder) with one end closed, and the end cover and the cover packing close the other opened. Good. By setting it as such a structure, it can be set as the structure which has waterproofness (watertightness) still more easily.

  Furthermore, although the illumination device according to the above-described embodiment has been described as including one light unit, the present invention is not limited thereto, and the illumination device includes a plurality of light units in the longitudinal direction as illustrated in FIG. The illuminating device provided may be sufficient. FIG. 23 is a perspective view showing an illuminating device 300-2 in which two light units 100 are mounted on the fixture body 200-2. In FIG. 23, a gap for absorbing expansion in the longitudinal direction is provided between the right and left light units. The lighting device is not limited to the case of FIG. 23, and may have a configuration including three or more light units. Further, the lighting device may be a lighting device including a plurality of light units in the short direction (lateral direction). Furthermore, the illuminating device may include a plurality of light units in an oblique direction. Here, the diagonal direction is an arrangement in which one light unit is shifted in the longitudinal direction in a state where two light units are arranged in the short direction, for example. In this way, a simpler configuration can be achieved by a configuration in which one lighting device has a plurality of light units.

  As mentioned above, although Embodiment 1-6 of this invention was demonstrated, you may implement combining these embodiment. Alternatively, one of these embodiments may be partially implemented. Or you may implement combining these embodiment partially. In addition, this invention is not limited to these embodiment, A various change is possible as needed.

8 LED board frame, 9 LED board, 10 translucent cover, 11L left end, 11R right end, 12L, 12R opening, 13L, 13R cover insertion part, 14-1L, 14-2L, 14-3L , 14-4L, 14-1R, 14-2R, 14-3R, 14-4R, 14-5 Projection part, 15 Inclined surface, 20L, 20R Cover packing, 21L, 21R Recessed part, 30L, 30R, 30L- 1, 30R-1 end cover, 31L, 31R storage, 32L, 32R outer periphery facing portion, 33L, 33R inner periphery facing portion, 34L, 34R screw through hole, 35L, 35R end cover insertion portion, 36L through Hole, 37L Through-hole forming part, 38L, 38R Drain hole, 40L, 40R Cover fixing tool, 41L, 41R Screw hole, 42L, 42R Insertion part, 43L, 43R Extension part, 4 L, 44R Opposing part, 50L, 50R, 50L-1, 50L-2, 50L-1-1, 50R-1 Mounting bracket, 60, 60-1, 60-2 Frame, 61L, 61R Long hole, 62 Flat plate part , 63 Side face part, 64 recessed part, 65C through hole, 70L, 70R special screw, 80 waterproof power supply device, 81 power supply case body, 82-1, 82-2 packing, 83-1, 83-2
Packing fixture, 84 screws, 85 screw holes, 88 screws, 90L, 90R cap, 91L harness storage rubber, 92 fire spread prevention sheet, 93C cover fixing plate, 93C-1 screw holes, 94L, 94R stopper screw, 96L, 96R screws , 96C screw, 97L, 98L suspension bolt, 100 light unit, 200 instrument body, 210 instrument side through hole, 220 instrument side nut, 230 instrument side flat plate part, 240 hooked wire, 241 hook, 242 wire, 243 wire end , 250 wire end attachment, 300 lighting device, 310L bottom, 311L bottom surface, 312L drainage gradient, 313L range, 314L arrow, 315L end, 316L downward gradient region, 320L
Standing wall, 330L outline, 341L periphery, 380L, 380R harness support, 391L, 391R slit, 501L broken line, 502L horizontal, 511L, 512L side, 513L, 514L tip, 532L recess, 533L through hole, 541L washer, 542L retaining washer, 601, 602 bent portion, 603, 604 lower surface, 605, 606 gap, 621, 622 gap, 611, 612, 613, 614 hook, 701 center of gravity, 961L screw head, 962L screw shaft.

Claims (3)

An instrument body;
A light-transmitting cover that covers the light source and is at least partially housed in the instrument body;
A portion housed in the instrument body of the translucent cover and a facing portion facing each other across a first gap;
A second gap is provided between the translucent cover and the instrument body,
Of the light emitted from the light source, the light reflected by the facing portion is irradiated to the outside of the instrument body from the second gap. The facing portion is
The lighting device according to claim 1, wherein a surface facing the translucent cover is higher than a reflectance of a material of the facing portion. The facing portion is
The lighting device according to claim 1, wherein a surface facing the translucent cover is white.

Images