JP2015097157A - Board illumination device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a board illumination device that reduces unevenness in the illuminance of a board and can be attached to the board properly according to the installation environment.SOLUTION: An illumination device 10 that illuminates a board 1 comprises an LED 62, and a reflector 70 that reflects and blocks light from the LED 62. The reflector 70 comprises a reflection part 75 that reflects light of the LED 62 to an illumination area of the board 1, and a light blocking face 77 that blocks light of the LED 62 directly going to an area on the LED 62 side in the illumination area of the board 1.

Description

  The present invention relates to a board illumination device that illuminates a board.

Conventionally, there has been a lighting device that can be installed on an advertisement billboard or the like (for example, Patent Document 1).
However, the conventional illuminating device has a large unevenness in the illuminance of the board.
In addition, the board installation environment (for example, the shape and size of the board, the arrangement of an AC outlet for supplying power to the lighting device, and the like) varies from site to site. The conventional lighting device cannot flexibly cope with such different installation environments.

JP2012-104345A

The subject of this invention is providing the illuminating device for boards which can reduce the nonuniformity of illumination intensity of a board.
Moreover, the subject of this invention is providing the illuminating device for boards which can be attached to a board corresponding to the installation environment of a board appropriately.

  The present invention solves the problems by the following means. In addition, in order to make an understanding easy, although the code | symbol corresponding to embodiment of this invention is attached | subjected and demonstrated, it is not limited to this. In addition, the configuration described with reference numerals may be improved as appropriate, or at least a part thereof may be replaced with another configuration.

-1st invention is a board illuminating device which illuminates a board, Comprising: The point light source (62) and the reflector (70) which reflects and shields the light from the said point light source, The said reflector is the said A reflection part (75) for reflecting the light of the point light source toward the illumination area of the board, and a light shielding part (77) for blocking the light of the point light source directly toward the area on the point light source side in the illumination area of the board And a board illumination device characterized by comprising:
-2nd invention is the board illumination device of 1st invention, The said reflection part (75) is provided in the emission range of the low-intensity light (75a) among the lights from the said point light source (62). The board illumination device is characterized by that.
-3rd invention is the board lighting apparatus of 1st or 2nd invention, The light of the said point light source (62) is a white system, The said light-shielding part (77) is on the board side of the said point light source. A back side light-shielding part (78) disposed on a certain back side (Y2) and shielding the light from the point light source toward the back side, and connected to the outside of the back side light-shielding part. And a left and right light-shielding part (79) that shields light that is displaced toward the front side, which is the opposite side of the point light source, and that travels directly from the left-right direction of the point light source toward the board.
-4th invention is provided with the front light-shielding part (90) which light-shields the light which goes to the near side and the lower side directly from the said point light source (62) in the board illuminating device of any one of the 1st-3rd invention. This is a board lighting device.

  ADVANTAGE OF THE INVENTION According to this invention, the illuminating device for boards which can reduce the nonuniformity of illumination intensity for a board can be provided. Further, it is possible to provide a board lighting device that can be attached to the board appropriately corresponding to the board installation environment.

It is the perspective view which looked at the state with which the illuminating device 10 of 1st Embodiment was mounted | worn to the board 1 from lower Z1. It is a figure explaining the single-piece | unit structure of the illuminating device 10 of 1st Embodiment. It is a figure which shows the state which removed the cover part 40 from the illuminating device 10 of 1st Embodiment. It is sectional drawing of the illuminating device 10 of 1st Embodiment. It is the figure which looked at the structure of the correction nail | claw 49 vicinity of the illuminating device 10 of 1st Embodiment from the lower side Z1. It is a top view which shows the structure of cap 50R vicinity of the illuminating device 10 of 1st Embodiment. FIG. 6 is a cross-sectional view illustrating a state where a cover part 40 is attached to the base part 20 It is a figure explaining the aspect which takes out the AC cable 58 from the other edge part of the illuminating device 10 of 1st Embodiment. It is a figure explaining the attachment method which connected the illuminating device 10 of 1st Embodiment. It is a perspective view of the illuminating devices 110 and 110A-110C of a comparative example. It is a figure explaining the attachment method which connected the illuminating device 10 of 1st Embodiment. It is a figure which shows the cap 50 of 1st Embodiment. It is a figure which shows the bushing 55 of 1st Embodiment. It is a perspective view in the state where cap 50R of lighting device 10 of a 1st embodiment was attached. It is the figure which looked at the illumination part 60 of 1st Embodiment from the electric board | substrate 67 side. It is sectional drawing explaining the effect | action of the reflective surface 75 of the reflector 70 of 1st Embodiment. It is sectional drawing explaining the effect | action of the light-shielding surface 77 of the reflector 70 of 1st Embodiment. It is the perspective view which looked at the reflector 70 of 1st Embodiment from diagonally lower side. It is a figure explaining the lens part 80 of 1st Embodiment. It is sectional drawing which shows the state in which light radiate | emits from the lens part 80 of 1st Embodiment. It is sectional drawing which compares the state which attached the illuminating device 10 of 1st Embodiment, and the illuminating device 110 of the comparative example to the board 5. FIG. It is a top view of the state with which the illuminating device 210 of 2nd Embodiment was mounted | worn with the board 201. FIG. It is a perspective view of one connection part (arrow B section of Drawing 22) of base 220 and arm part 230 of lighting installation 210 of a 2nd embodiment. It is a perspective view of the base 220 and the arm part 230 of 2nd Embodiment. It is sectional drawing of the arm part 230 vicinity of the illuminating device 210 of 2nd Embodiment. FIG. 10 is a perspective view illustrating a process of mounting the lighting device 210 on the board 201. FIG. 10 is a perspective view illustrating a process of mounting the lighting device 210 on the board 201.

(First embodiment)
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings and the like.
FIG. 1 is a perspective view of a state in which the lighting device 10 of the first embodiment is mounted on the board 1 as viewed from the lower side Z1.
1 is an enlarged view in the vicinity of the cap 50R.
In the drawings and embodiments, the left and right directions are illustrated and described as a longitudinal direction X, a depth direction is a short direction Y, and a vertical direction Z, and the left side X1, right side X2, The front side Y1, the back side Y2, the lower side Z1, and the upper side Z2 are illustrated and described. The longitudinal direction X, the lateral direction Y, and the vertical direction Z are orthogonal to each other.
In addition, when description is made by designating any one of the three lighting devices 10 (board lighting device), the base 20 and the like, the description will be made with A to C appended (the lighting device 10A and the like).

  The board 1 may be either a self-supporting board having columns or the like, or a board fixed to a wall or the like. The board 1 is a blackboard, a bulletin board, or the like. The blackboard includes a white board (so-called white board) on which letters and the like are written using a felt pen. The board 1 may not be dedicated to the lighting device 10. That is, the board 1 may be a general-purpose one, for example, a bulletin board or a blackboard that is distributed in the market or already installed. The board 1 in FIG. 1 is an example of a white board installed on a wall.

The illumination device 10 (10A to 10C) is a device that illuminates the board 1. The lighting device 10 is mounted on the board 1 in a single state or a plurality of the lighting devices 10 connected in the longitudinal direction X. Although embodiment demonstrates the form which connected 3 illuminating device 10A-10C, you may connect 2 or 4 or more.
The lighting device 10 has a box shape that is elongated in the left-right direction (longitudinal direction X), short in the depth direction (short direction Y), and small in the vertical direction Z.

[Single unit configuration of lighting device 10]
The form which attaches the illuminating device 10 to the board 1 alone, ie, without connecting, is demonstrated.
FIG. 2 is a diagram illustrating a single configuration of the illumination device 10 according to the first embodiment.
FIG. 2A is a top view.
FIG. 2B is a view seen from the longitudinal direction X. FIG.
FIG. 3 is a diagram illustrating a state where the cover unit 40 is removed from the lighting device 10 according to the first embodiment.
FIG. 3A is a top view.
FIG. 3B is a cross-sectional view seen from the longitudinal direction X.
FIG. 3C illustrates the electrical configuration of the wiring portion 35.
FIG. 4 is a cross-sectional view of the illumination device 10 according to the first embodiment.
FIG. 4A is a cross-sectional view through the L-shaped metal fitting 30 (or the connection metal fitting 31).
FIG. 4B is a cross-sectional view of the vicinity of the converter 32.
FIG. 4C is a cross-sectional view with the cover 40 removed.
FIG. 5 is a view of the configuration in the vicinity of the correction nail 49 of the illumination device 10 according to the first embodiment, as viewed from the lower side Z1.
FIG. 6 is a top view showing a configuration in the vicinity of the cap 50R of the illumination device 10 of the first embodiment. FIG. 6 shows a state in which the cap 50R and the bushing 55 are disassembled.
In addition, in each top view, in order to illustrate clearly, the line which shows the inside of the base 20 is abbreviate | omitted suitably.

As illustrated in FIG. 2, the lighting device 10 includes a base portion 20, a cover portion 40, a cap 50 (50L, 50R), and an AC cable 58.
As shown in FIG. 3, the base 20 is made of aluminum. The base portion 20 is integrally formed by extrusion molding and is elongated in the longitudinal direction X (connection direction). The base 20 is formed by cutting an extruded product. For this reason, the cross section when the base 20 is viewed from the longitudinal direction X has a constant shape except for a holed portion (L-shaped metal fitting fixing hole 25c and the like).
The cover part 40 is also formed in the same manner as the base part 20. The length of the base portion 20 in the longitudinal direction X is equal to the length of the cover portion 40 in the longitudinal direction X. For this reason, the edge part of the base 20 and the cover part 40 is located on the same surface.

(Configuration of base 20)
As shown in FIG. 3 and FIG. 4, the base 20 has a rear end portion of the plate-like bottom plate portion 21 and a tip portion of the plate-like rear plate portion 22 such that the standing wall 23 is connected in a Z shape. It is a configuration.
The base 20 includes a cap mounting hole 25a (cap mounting portion), a rib 25b, an L-shaped metal fitting fixing hole 25c, a connecting metal fitting fixing hole 25d, a rotating shaft 25e, and a stopper 25f. The L-shaped metal fitting fixing hole 25c and the connecting metal fitting fixing hole 25d are formed by drilling the extruded base portion 20.
The cap mounting hole 25 a is a hole for mounting the cap 50. A part of the periphery of the cap mounting hole 25a is cut off, but the entire periphery may be connected. Two cap mounting holes 25a are arranged on the front side Y1 and the back side Y2 of the base portion 20, respectively.
The rib 25b is a part for fixing the L-shaped metal fitting 30 and the connecting metal fitting 31 (described later). The rib 25b is provided so as to protrude from the bottom plate portion 21 to the upper side Z2. The rib 25b is provided with an L-shaped metal fitting fixing hole 25c and a connecting metal fitting fixing hole 25d. There is a gap between the rib 25b and the cover portion 40 (see FIG. 4B). Cables 32 a and 60 a connecting the converter 32 and the illumination unit 60 are passed through the gap.

The L-shaped metal fitting fixing hole 25 c is a hole for fixing the L-shaped metal fitting 30.
The connection fitting fixing hole 25 d is a hole for fixing the connection fitting 31. Two connecting fitting fixing holes 25d are provided in the vicinity of the ends in the longitudinal direction X (see FIG. 6), and a total of four are provided.
The rotation shaft 25e is a portion that functions as a rotation support shaft of the cover portion 40 or the like. The rotation shaft 25 e is provided at a connection portion between the standing wall 23 and the rear plate portion 22.
The stopper 25f is provided on the front side Y1 of the rotating shaft 25e. The stopper 25f positions the cover part 40 in the lateral direction Y by contacting an arc part 45c (described later) of the cover part 40.

As shown in FIGS. 3 and 4, the base 20 includes an L-shaped metal fitting 30, a connection metal fitting 31 (connection part), a converter 32 (AC-DC converter), and a wiring part 35.
The L-shaped metal fitting 30 and the connecting metal fitting 31 are L-shaped with the same cross-sectional shape and have different lengths in the longitudinal direction X.
The L-shaped metal fitting 30 is a member for fixing the cover portion 40 to the base portion 20. A plurality of L-shaped metal fittings 30 are provided, and are fixed to the base 20 by screws. The L-shaped metal fitting 30 includes two holes 30a and one hole 30b.
The two holes 30a are for the L-shaped metal fitting 30 to be screwed to the ribs 25b using the L-shaped metal fitting fixing holes 25c.
One hole 30b is for fixing the cover part 40. As shown in FIG.

The connection fitting 31 is a member used when fixing the cover 40 and connecting the lighting device 10. The length of the connecting metal 31 in the longitudinal direction X is longer than that of the L-shaped metal 30. The connecting fittings 31 are provided at both end portions of the base portion 20.
The connecting fitting 31 includes four holes 31a and two holes 31b (see FIG. 6).
The four holes 31a are for screwing the connection fitting 31 to the rib 25b using the connection fitting fixing hole 25d. The four holes 31a are arranged in the longitudinal direction X.
The two holes 31b are holes for fixing the cover part 40. The two holes are arranged side by side in the longitudinal direction X.

  The converter 32 is a device that converts AC power supplied from the AC cable 58 into DC power corresponding to the LEDs of the illumination unit 60. The converter 32 is electrically disposed between the connectors 36a and 37a (described later). DC power is output from the cable 32a.

The wiring part 35 is a part that distributes electric power in the base 20.
The wiring unit 35 includes cables 36, 37, and 38 and a distributor 39.
Each cable 36, 37 is composed of two wires, but may be composed of three wires by adding a GND (ground) wire.
The cable 36 is disposed on the right side X2 in the base 20. One end of the cable 36 is connected to the distributor 39. On the other end of the cable 36, a female connector 36a (first connector) is provided. The length of the cable 36, that is, the length from the distributor 39 to the connector 36a is a length that can be accommodated in the base portion 20 in a state where the cable 36 is extended.

The cable 37 is disposed on the left side X1 in the base 20. One end of the cable 37 is connected to the distributor 39. A male connector 37 a (second connector) is provided at the other end of the cable 37. The length of the cable 37 (that is, the length from the distributor 39 to the connector 37a) is such that the connector 37a side protrudes from the inside of the base 20 with the cable 37 extended. For this reason, when the lighting device 10 is used alone, the cable 37 is accommodated in the base 20 by being folded in two or the like.
The cable 38 connects between the distributor 39 and the converter 32.

The distributor 39 is an electrical device that distributes an AC current.
The circuit of the distributor 39 connects the ends of the cables 36 to 39 in a trifurcated manner. Therefore, when an AC current is input from the cable 36, the distributor 39 distributes and outputs the AC current to the cables 37 and 38, whereas when the AC current is input from the cable 37 (FIG. 8, see FIG. 11), which is distributed to the cables 36 and 38 and output.
The distributor 36 and the connector 36a may be integrated with each other by providing a current distribution function inside the connector 36a.

(Configuration of cover unit 40)
As shown in FIG. 4, the cover part 40 is attached so as to cover the upper part of the base part 20.
The cover part 40 is provided with an illumination part 60 and is fixed to the base part 20. The detailed configuration of the illumination unit 60 will be described later.

The cover portion 40 is configured such that the top plate portion 41, the front wall portion 42, and the bottom plate portion 43 are connected, and a rib-like partition wall 44 is formed from the lower surface of the top plate portion 41 toward the diagonally lower side Z1. Is provided.
The front portion of the top plate portion 41 is gently inclined toward the lower side Z1 toward the front side Y1 so as to correspond to the inclination of the illumination unit 60.

The cover part 40 includes an illumination part attachment part 45a, a cable insertion hole 45b, an arc part 45c, a cap attachment hole 45e (cap attachment part), a cover fixing hole 45f, and a correction nail attachment groove 45g. The cover fixing hole 45f and the cable insertion hole 45b are formed by punching the extruded cover portion 40.
The illumination part attachment part 45a is an area where the illumination part 60 is arranged. The illumination part attachment part 45a is an area surrounded by the partition wall 44, the front wall part 42, and the like. Details of the illumination unit attachment unit 45a will be described later.
The cable insertion hole 45 b is provided in the partition wall 44. The cable insertion hole 45 b is a hole through which the cable 60 a connected to the illumination unit 60 is inserted. The cable insertion hole 45b is provided with a protective member (not shown) such as a bushing for protecting the cable 60a.

  The arc portion 45 c is provided at the end of the top plate portion 41 of the cover portion 40. The inner surface of the arc portion 45 c is engaged with the rotation shaft 25 e of the base portion 20. Thereby, the circular arc part 45c and the rotating shaft 25e comprise the hinge 45d.

The cap mounting hole 45 e is a hole similar to the cap mounting hole 25 a of the base 20. The cap mounting hole 45e is disposed on the front side Y1 of the cover portion 40.
The cover fixing hole 45f is a hole for fixing the cover portion 40 to the L-shaped metal fitting 30 and the connecting metal fitting 31 (that is, the base portion 20). The cover fixing hole 45f is provided at a position corresponding to the holes 30b and 31b of the L-shaped metal fitting 30 and the connecting metal fitting 31.
The correction nail attachment groove 45g is a groove for mounting a correction nail 49 (described later). The correction nail attachment groove 45g is disposed on the back side Y2 of the bottom plate portion 43.

The cover unit 40 includes a correction nail 49 (tilt correction unit).
The correction nail 49 is a member that corrects the inclination of the adjacent illumination device 10 when the illumination device 10 is connected to the board 1. The correction nail 49 is attached to the correction nail attachment groove 45g.
The correction nail 49 is movable in a manner that slides in the longitudinal direction X along the correction portion mounting groove.
As shown in FIG. 5, for this reason, the correction nail 49 can be selected from the protruding state and the retracted state and can be arranged on the cover portion 40.
The protruding state is a state in which the correction nail 49 protrudes from the end portion of the cover portion 40 (FIG. 5B), while the retracted state is a state in which the correction nail 49 is retracted from the end portion of the cover portion 40 ( FIG. 5 (A)).
When the tip of the correction nail 49 is rotated to the upper side Z2, the engaging portion is pressed into the correction portion mounting groove. Thereby, the correction nail 49 is fixed to the cover part 40.

(Configuration of cap 50)
The cap 50 (50L, 50R) is a member that closes the opening in the longitudinal direction X of the lighting device 10. The cap 50 is a molded product of resin or the like. The caps 50L and 50R are symmetrical in the longitudinal direction X.
As shown in FIG. 6, the cap 50 includes a screwing hole 50a and an AC cable insertion hole 50b.
The screwing hole 50 a is a hole for attaching the cap 50 to the base portion 20, the cover portion 40, and the frame 2 (edge portion) of the board 1. Four screw holes 50a are provided (see FIG. 6). One is screwed into the cap mounting hole 45e of the cover portion 40, two is screwed into the cap mounting hole 25a of the base portion 20, and one is screwed to the frame 2 of the board 1. It is for stopping.
The AC cable insertion hole 50 b is a hole for inserting the AC cable 58. When the AC cable 58 is not inserted, the blind member 51 is attached (see FIG. 3).

The cap 50 includes a bushing 55 and a nut 56.
The bushing 55 is a member that protects the AC cable 58 wired outward from the AC cable insertion hole 50b. The bushing 55 includes a male screw portion 55b.
The nut 56 is a member for attaching the bushing 55 to the cap 50.
Details of the cap 50 will be described later with reference to FIG.

(Configuration of AC cable 58)
The AC cable 58 electrically connects the lighting device 10 and an insertion port that supplies AC power. At one end of the AC cable 58, an insertion plug 58a (see FIG. 2) is provided. The plug is inserted into the insertion slot. The insertion port is provided on the wall surface of the installation room of the board 1. A male connector 58 b is provided at the other end of the AC cable 58.

[Attaching method and holding structure of lighting device 10 as a single unit]
The basic holding structure and the like of the lighting device 10 will be described while explaining the basic mounting method of the single lighting device 10 of the lighting device 10.
FIG. 7 is a cross-sectional view illustrating a state where the cover 40 is attached to the base 20.
(Standard mounting method)
The operator can attach the lighting device 10 to the board 1 by the following steps.
The order of the steps in the embodiment is a standard one and may be changed as appropriate.
(# 1) As shown in FIG. 3B, the rear plate portion 22 of the base portion 20 is screwed to the frame 2 of the board 1.
As a result, the base 20 is fixed to the board 1.
The base 20 and the board 1 can be attached in various ways. For example, the standing wall 23 may be screwed to the frame 2 of the board 1 from the front side Y1.
(# 2) As shown in FIG. 3A, the connecting fitting 31 is screwed to the base 20 without protruding from the base 20.

(# 3) As shown in FIG. 6, the AC cable 58 is inserted into the AC cable insertion hole 50 b and the nut 56 of the cap 50.
(# 4) The connector 58b of the AC cable 58 and the connector 36a of the cable 36 are connected.
(# 5) The bushing 55 is inserted into the AC cable insertion hole 50 b of the cap 50 of the AC cable 58, and the portion of the AC cable 58 that is wired outward from the AC cable insertion hole 50 b is covered with the bushing 55.
(# 6) The bushing 55 is fixed to the cap 50 by meshing the threaded portion 55 b of the bushing 55 with the nut 56.
In FIG. 3A and the like, the bushing 55 shows an example in which the AC cable 58 is guided to the back side Y2, but the direction in which the AC cable 58 is guided can be selected according to the installation environment such as an AC insertion port. For example, the bushing 55 may guide the AC cable 58 to the lower side Z1.

(# 7) As shown in FIG. 7, the arc portion 45c is inserted into the rotary shaft 25e with the cover portion 40 standing. In this case, the cover part 40 is self-supporting so as to lean on the intersection 23 a of the rear plate part 22 and the standing wall 23 of the base part 20. For this reason, the operator can also perform inspection work (for example, inspection of cable wiring, etc.), etc., as necessary, with the cover unit 40 standing independently.
In addition, after the lighting device 10 is attached, even when wiring work or work such as connecting the lighting device 10 occurs as described later, if the worker opens the cover 40 and becomes independent, Can work easily.
(# 8) The cover portion 40 is rotated around the hinge 45d to bring the connector of the cable 32a and the connector of the cable 60a together while being tilted to the near side Y1, and then the cover portion 40 is connected to the L-shaped bracket 30 and It rotates until it abuts on the connection fitting 31.

Since the length of the base portion 20 in the longitudinal direction X is equal to the length of the cover portion 40 in the longitudinal direction X, the base portion 20 and the cover portion 40 are flush with each other at the end portion.
As shown in FIG. 4, the base portion 20 and the cover portion 40 are regulated by the hinge 45d so as not to move to the upper side Z2 and the rear side Y2. Further, the stopper 25f of the base portion 20 restricts the cover portion 40 from moving to the near side Y1 with respect to the base portion 20. For this reason, the cover part 40 is regulated so as not to move other than the rotational movement around the hinge 45d in the YZ plane.
Thereby, the cover part 40 does not fall off from the base part 20 in the closed state.

(# 9) The cover portion 40 is screwed to the L-shaped metal fitting 30 and the connecting metal fitting 31. Accordingly, the cover portion 40 is restricted from rotating and moving around the hinge 45 d and restricted from moving in the longitudinal direction X, and is fixed to the base portion 20.
Thus, since the cover part 40 can be fixed to the base part 20 by screwing several places on the near side Y1, the operator can work easily. In addition, when removing the cover 40 or performing the inspection work as described above, the operator may remove several screws.

  Through the above-described process, the cover 40 is held by the base 20 in the form of a cantilever projecting to the near side Y1 from the base 20. In addition, when the cover part 40 is going to bend by applying a big load to the lower side Z1, since it contacts the contact part 25g (refer FIG. 4 (A)) of the base 20, this bending can be suppressed. .

(# 10) The correction nail 49 is slid inward and placed in the retracted state (see FIG. 5A). In the retracted state, the base 20 is disposed on the inner side of the mounting position of the cap 50. That is, the correction nail 49 does not function when the lighting device 10 is attached alone.
(# 11) The cap 50 is screwed and attached to the base 20 and the cover 40. The ends of the base portion 20 and the cover portion 40 are the same surface, and the inner surface of the cap 50 is flat. For this reason, the cap 50 can be mounted in parallel to the base 20 and the cover 40. The cap 50 is also screwed to the frame 2 of the board 1.
(# 12) The cap 50 on the opposite side is similarly screwed. The cap 50 blinds the AC cable insertion hole 50b.
As described above, the lighting device 10 can be mounted on the board 1 in a single state.

(When the AC cable 58 is taken out from the other cap 50)
The illuminating device 10 can attach the AC cable 58 out of the other cap 50 as follows.
FIG. 8 is a diagram illustrating a manner in which the lighting device 10 according to the first embodiment extends the AC cable 58 from the other end.
In this case, the conversion cable 59 (conversion unit) is used. For example, the conversion cable 59 may be bundled when the lighting device 10 is shipped.
The conversion cable 59 includes connectors 59a at both ends. These connectors 59a are both female. Therefore, these connectors 59a can be connected to the male connector 37a of the cable 37 and the male connector 58b of the AC cable 58, respectively.
Thereby, the conversion cable 59 connects between the AC cable 58 and the cable 37.
As described above, the circuit of the distributor 39 is trifurcated, so that AC power can be input to the converter 32 even if AC power is supplied from the cable 37 side.

Even in this case, the operator can attach the illumination device 10 in the same manner as the attachment method described above except that the wiring of the AC cable 58 is taken out from the cap 50 side.
That is, the AC cable 58 is attached to the cap 50 </ b> R side, and the AC cable 58 and the cable 37 are connected via the conversion cable 59. The cable 37 is folded and accommodated in the base 20.
On the other hand, the cap 50 </ b> R may be screwed to the base 20 or the like by attaching the blindfold member 51.

Here, the illuminating device 10 has a short direction Y determined. That is, it cannot be mounted on the board 1 in a state rotated 180 ° on the XY plane.
Therefore, unlike the embodiment, in the form in which the outlet direction of the AC cable is determined, in an installation environment where the AC inlet is on the opposite side to the outlet, the AC cable needs to be stretched long outside the lighting device. is there.
On the other hand, the AC cable 58 of the lighting apparatus 10 of the embodiment can be connected by selecting one of the cables 37 and 38. For this reason, the AC cable 58 can be attached by selecting the outlet direction of the AC cable 58 according to the installation environment such as the AC insertion port. Thereby, the illuminating device 10 can shorten the length which turns the AC cable 58, and can install neatly.

[Linked mounting method, holding structure]
A mounting method and a holding structure in which the lighting devices 10A to 10C as shown in FIG. 1 are connected will be described.
(Standard mounting method)
FIG. 9 is a diagram for explaining an attachment method in which the illumination devices 10 of the first embodiment are connected.
FIG. 9 illustrates only the lighting devices 10A and 10B, and omits the illustration of the lighting device 10C.
The operator can connect the lighting device 10 and attach it to the board 1 by the following steps.
Hereinafter, the connection between the lighting devices 10A and 10B will be mainly described, but the connection between the lighting devices 10B and 10C is the same.

(# 21) Similarly to (# 1) above, the base 20 is screwed to the board 1 (see FIG. 3 and the like). In this case, the base portions 20A and 20B of the adjacent lighting devices 10A and 10B are brought into close contact with each other.
(# 22) As in the case of (# 2), the connection fitting 31 arranged at the right end of the lighting device 10A is screwed to the base 20A so as not to protrude from the base 20 (see FIG. 3). Similarly, the connection fitting 31 disposed at the left end of the lighting device 10C is also screwed to the base 20 (not shown).
On the other hand, about the connection part of illuminating device 10A, 10B, the connection metal fitting 31 is shifted outside and the connection metal fitting 31 is protruded from the base portion 20A and screwed to the base portion 20A. Then, the connection fitting 31 is screwed to the base 20B of the other lighting device 10B using the protruding portion of the hole 31a of the connection fitting 31. In addition, the arrangement | positioning and the pitch of the longitudinal direction X are set so that the connection metal fitting fixing hole 25d of the base 20 and the hole 31a of the connection metal fitting 31 may correspond even in the state which shifted the connection metal fitting 31 in this way.
Thereby, since the connection metal fitting 31 connects the adjacent base portions 20A and 20B, the inclination between the adjacent base portions 20A and 20B (that is, between the lighting devices 10A and 10B) (that is, the inclination of the lighting device 10 with respect to the board 1). It can be corrected.

(# 23) The cable 37A and the cable 36B of the illumination devices 10A and 10B are connected. The connector 37a of the cable 37A of the lighting device 10A is a male, while the connector 36a of the cable 36B of the lighting device 10B is a female. For this reason, the operator can perform the connection work without making a mistake.
In addition, since the cable 37A is sufficiently long, it can be extended into the adjacent base portion 20B and connected to the connector 36a of the cable 36B of the adjacent base portion 20B. For this reason, since the illuminating device 10 can be electrically connected without preparing another cable, the operator can perform a wire connection easily.
(# 24) The AC cable 58 is attached to the base 20A arranged at the end. The attachment method is the same as the single attachment method.
Since the distributor 39A is trifurcated, the AC cable 58 is connected from the distributor 39A to the DC converter 32, and also to the distributor 39B via the cable 37A and the cable 36B of the adjacent lighting device 10B. Connected. Since the lighting devices 10B and 10C are similarly connected, the AC cable 58 is connected to all the lighting devices 10A to 10C.
Thereby, AC power from one AC cable 58 can be supplied to the plurality of lighting devices 10A to 10C.

(# 25) Each cover 40 is attached to the three bases 20 in the same manner as (# 7 to # 9) above. Since the end portions of the base portion 20 and the cover portion 40 are on the same surface, the adjacent cover portions 40 can be brought into close contact with each other by bringing the adjacent base portions 20A and 20B into close contact with each other.
The cover part 40 is closed and screwed to the L-shaped metal fitting 30 and the connection metal fitting 31. In the connection portion of the lighting device 10, two cover portions 40 are screwed to one connection fitting 31.
Note that the cap 50 is not attached to the connecting portion. For this reason, since the cross-sectional shape of the base 20 and the cover part 40 is constant over the longitudinal direction X also in a connection part, cable 37A is not pinched in a connection part.
As described above, the connection fitting 31 can serve both as a connection portion for connecting the lighting device 10 and an attachment portion for attaching the cover portion 40 to the lighting device 10. For this reason, since it is not necessary for the lighting apparatus 10 to prepare separate components for connection, the number of components can be reduced.

(# 26) As shown in FIG. 5B, the correction nail 49 of the cover portion 40A is slid to the protruding state. In the protruding state, the correction nail 49 engages with the correction nail attachment groove 45g of another cover portion 40B disposed adjacent to the correction nail 49.
Further, the correction nail 49 is rotated to the upper side Z2, and is pressed into the correction nail attachment groove 45g and fixed.
Note that the correction nail 49 of the cover portion 40B may be removed or pulled inward.

Thus, the correction nail 49 corrects the inclination between the illumination devices 10A and 10B (the inclination of the illumination device 10 with respect to the board 1) by engaging both the correction nail attachment grooves 45g of the base portions 20A and 20B. . In the short-side direction Y, the correction nail 49 is disposed at a position far from the board 1, and thus this inclination can be corrected effectively.
In the embodiment, the correction nail 49 is an example of a resin molded product, but may be a metal rod, for example. In this case, the cross-sectional shape of the correction nail attachment groove 45g may be a circle corresponding to this bar.
(10A) Caps 50L and 50R are attached to the two illumination devices 10A and 10C at the extreme ends.
In this case, the bushing 55 is attached to the cap 50R through which the AC cable 58 is inserted, and the blindfold member 51 (see FIG. 3) is attached to the cap 50L through which the AC cable 58 is not inserted, as in the case of attachment alone. Install.

In this way, the lighting devices 10A to 10C can be individually installed even if they become longer in the longitudinal direction X as a whole. For this reason, it is possible to reduce the size of each lighting device 10 and reduce the weight, and the operator can easily perform the installation work. Moreover, since the connection at the time of a connection should just connect a connector, it can work easily.
Moreover, since the illuminating device 10 is provided with the connection metal fitting 31 and the correction nail | claw 49, the variation in the inclination between the illuminating devices 10 can be made small. Thereby, the illuminating device 10 can make the level | step difference of a connection part small.
Furthermore, the lighting device 10 can flexibly cope with the installation environment such as the size of the board 1 by changing the number of the boards 1 connected in the longitudinal direction X according to the size of the board 1 in the longitudinal direction X.

FIG. 10 is a perspective view of the illumination devices 110 and 110A to 110C of the comparative example.
As in the comparative example shown in FIG. 10A, unlike the embodiment, the integrated lighting device 110 is large and heavy. For this reason, the illumination device 110 has a problem that it is difficult for an operator to perform installation work. That is, the lighting device 10 according to the embodiment does not require the arm 111 or the like, and thus can be lighter than the lighting devices 110 and 110A to 110.
As in the comparative example as shown in FIG. 10 (B), unlike the embodiment, the illumination devices 110A to 110C that do not include the connection fitting 31 and the correction claws 49 have a large variation in inclination between the illumination devices 110A to 110C. . For this reason, illumination device 110A-110C has the problem that a level | step difference will be conspicuous.
10 shows an example in which the lighting devices 110, 110A to 110C are attached to the board 1 with the arm 111. The above problem is the same even when the lighting devices 110, 110A to 110C are directly attached to the board 1. FIG. is there.

(When connecting the AC cable 58 from the other cap 50L in the connected installation)
FIG. 11 is a diagram for explaining an attachment method in which the illumination device 10 according to the first embodiment is connected.
As shown in FIG. 11, the lighting device 10 (10A to 10C) connects the AC cable 58 and the cable 37C by using the conversion cable 59, so that the other cap 50L is connected to the AC by connecting the AC cable 58 and the cable 37C. The cable 58 can be taken out.
Since the distributor 39C has a trifurcated shape, the cable 37C is connected from the distributor 39C to the adjacent distributor 39 (FIG. 11 is omitted) via the cables 36C and 37B. The lighting devices 10B and 10C are similarly connected.

Thus, the cable 37 can be used as a cable 37B that electrically connects the lighting devices 10, and can also be used as a power supply cable 37C by connecting to the AC cable 58.
In addition, the lighting device 10 is connected, and the outlet of the AC cable 58 can be selected according to the setting environment, as in the case of a single unit.

[Configuration of cap 50]
The configuration of the cap 50 will be described in detail.
FIG. 12 is a diagram illustrating the cap 50 according to the first embodiment.
FIG. 12A is a view of the state in which the bushing 55 is attached as viewed from the right side X2.
FIG. 12B is a cross-sectional view.
FIG. 12C is a rear view (viewed from the left side X1).
FIG. 12D shows a state where the cap 50 is separated.
FIG. 12 is an example of the cap 50R. Since the cap 50L is symmetrical with the cap 50R in the longitudinal direction X, the description thereof is omitted.
As shown in FIG. 12, the cap 50 is a substantially flat member.
The cap 50 includes grooves 50c and 50d on the inner surface.
The thickness of the bottom of the grooves 50c and 50d is thinner than the surroundings.
The groove 50c is disposed at the same position as the standing wall 23 (see FIG. 4) of the base 20. The groove 50 d is provided at the rear end of the cap 50.
As shown in FIG. 12D, the operator can easily divide the cap 50 from the groove using a cutter knife.

FIG. 13 is a diagram illustrating the bushing 55 according to the first embodiment.
FIG. 13A is a diagram viewed from the right side X2.
FIG. 13B is a cross-sectional view.
FIG. 13C is a rear view (viewed from the left side X1).
FIG. 13D is a view as seen from the back side Y2.
FIG. 13E shows a state where the cable guide 55c is separated.
The bushing 55 includes a main body portion 55a and a cable guide 55c.
The main body portion 55a is provided with the aforementioned male screw portion 55b. The inside of the main body portion 55a has a hole shape.
The cable guide 55c is a portion that guides the AC cable 58 from the main body portion 55a in a desired direction.

In a state where the cable guide 55c is arranged in parallel with the short direction Y, the rear end of the cable guide 55c and the rear end of the cap 50 are substantially at the same position (see FIG. 12A).
The cable guide 55c has a U-shaped cross section, and the inside of the U-shape is continuous with the hole-shaped portion of the main body 55a. For this reason, the bushing 55 can accommodate the AC cable 58 continuously.
The cable guide 55c includes a groove 55d. The portion of the groove 55d is thinner than the surroundings.
As shown in FIG. 12E, the operator can easily cut the cable guide 55c from the groove 55d using a cutter knife.

FIG. 14 is a perspective view of the lighting device 10 according to the first embodiment with the cap 50R attached.
As shown in FIG. 14, for example, when the total length of the board 1 is longer than the lighting device 10 in the longitudinal direction X, the operator cuts the cap 50 from the groove 50 c (see FIG. 12C). Good. Thereby, the illuminating device 10 can attach the cap 50 without interfering with the board 1.
The AC cable 58, the blindfold member 51 and the like may be attached to the caps 50L and 50R as described above (see FIGS. 3 and 5).
In addition, the example which isolate | separates the cap 50 from the groove | channel 50d is demonstrated by embodiment mentioned later (refer FIG. 27).

Further, the cable guide 55c of the bushing 55 can be separated from the groove 55d in accordance with the situation where the AC cable 58 is bent.
As described above, if only two types of the left and right caps 50 are prepared, the cap 50 can be installed corresponding to various installation environments. For this reason, the illuminating device 10 can reduce a number of parts, can be made low-cost, and can reduce metal mold preparation costs etc. FIG.
Moreover, if only one type of bushing 55 is prepared, the AC cable 58 can be used in accordance with the installation environment.

[Configuration of Illumination Unit 60]
The configuration of the illumination unit 60 will be described.
FIG. 15 is a view of the illumination unit 60 of the first embodiment as viewed from the electric board 67 side.
FIG. 15A is a cross-sectional view taken along the line AA in FIG.
FIG. 15B is an enlarged view of a portion indicated by an arrow B in FIG.
FIG. 15C is a cross-sectional view taken along the line CC of FIG.
FIG. 16 is a cross-sectional view for explaining the operation of the reflecting surface 75 of the reflector 70 according to the first embodiment.
FIG. 16A is a cross-sectional view of the lighting device 10.
FIG. 16B is an enlarged view of the reflector 70.
FIG. 17 is a cross-sectional view for explaining the operation of the light shielding surface 77 of the reflector 70 according to the first embodiment.
FIG. 17A is a cross-sectional view of the lighting device 10.
FIG. 17B is an enlarged view of the reflector 70.
FIG. 18 is a perspective view of the reflector 70 according to the first embodiment as viewed obliquely from below.

The illumination unit 60 is a part for illuminating the board 1 with light of an LED 62 (light emitting diode) that is a point light source.
As shown in FIGS. 15 and 16, the illumination unit 60 includes an LED 62, a diffusion plate 65, a plate 66, a plate mounting groove 66 a, an electric board 67, a reflector 70, and a lens unit 80.
In the illumination unit 60, a plurality of unit illumination devices 61 each including the LED 62, the reflector 70, and the lens unit 80 as a unit are arranged in the longitudinal direction X (array direction). The reflector 70 and the lens unit 80 are optical components, and guide light from the LED 62 to an area on the LED 62 side in the illumination area of the board 1 and an area farther from the LED 62 than this area, as will be described later.
The LED 62 is a light source of the lighting device 10. The light from the LED 62 is white. The plurality of LEDs 62 are arranged in a line in the longitudinal direction X.
The diffusion plate 65 is a member that diffuses the light of the LED 62. The diffusion plate 65 is made of a transparent resin or the like. The diffusion plate 65 has an effect of softening the light of the LED 62 and making the internal configuration of the lighting device 10 difficult to see. The diffusion plate 65 is attached to the cover portion 40 by being inserted into the diffusion plate attachment groove 65 a of the cover portion 40.

(Attachment structure of illumination unit 60)
The plate 66 is a plate material such as aluminum for fixing the electric substrate 67. In the longitudinal direction X, the length of the plate 66 is the same as that of the cover portion 40.
The plate attachment groove 66a is a groove provided in the cover portion 40 in order to insert the plate 66. The operator can attach the plate 66 to the cover portion 40 by inserting the plate 66 into the plate attachment groove 66 a and sliding in the longitudinal direction X.

The electric board 67 is fixed to the plate 66 by screws. The LED 62 is mounted on the electric board 67, and the reflector 70 is fixed. The LED 62 and the reflector 70 are attached to the cover part 40 by attaching the plate 66 to the cover part 40.
In the longitudinal direction X, the length of the electric substrate 67 is shorter than the plate 66. Three LEDs 62 are arranged on the electric board 67. For this reason, the plurality of electric boards 67 are arranged on the plate 66 in a line in the longitudinal direction X. The electric boards 67 are connected by a cable 68. For this reason, the DC power from the converter 32 is supplied to all the electric boards 67.

In the embodiment, the interval L61 between the unit lighting devices 61 in the longitudinal direction X is 100 mm. For example, when the total length of the cover portion 40 and the plate 66 is 1200 mm, four electric boards 67 may be arranged on the plate 66 and a total of 12 unit lighting devices 61 may be accommodated in the cover portion 40.
For example, when the length of the cover part 40 and the plate 66 is 600 mm, the two electric substrates 67 may be disposed on the plate 66 to accommodate a total of six unit lighting devices 61 in the cover. .
Thus, since the lighting device 10 divides the electric board 67 and attaches it to the cover, the lighting apparatus 10 can flexibly cope with the installation environment having the length in the longitudinal direction X of the board 1. For example, unlike the embodiment, the form using a fluorescent lamp manufactured based on JIS or the like cannot flexibly cope with the installation environment of the length in the longitudinal direction X of the board 1.

  In the case of the above example, the distance L61a between the LED 62 arranged at the end portion and the end portion of the cover portion 40 is 50 mm. For this reason, when the illuminating devices 10A and 10B are connected, the LEDs 62 can be arranged at an interval L61 = 100 mm between the adjacent illuminating devices 10A and 10B.

The plate 66 and the electric substrate 67 are disposed so as to be inclined so that the lower surface slightly faces the back side Y2. For this reason, as described above, the top plate portion 41 of the cover portion 40 is gently inclined. Thereby, the illuminating device 10 has the visual effect which shows an external shape thinly.
That is, normally, the observer of the board 1 views the illumination device 10 from the front side Y1 and the lower side Z1 of the illumination device 10. For this reason, from the observer, the thickness of the illumination device 10 is observed as the length L40, and looks thinner than the actual thickness (length L40a).

(Reflector 70)
As shown in FIGS. 16 to 18, the reflector 70 is a portion that adjusts light by reflecting or blocking light from the LED 62.
The reflector 70 is a white resin injection-molded product or the like. The outer shape of the reflector 70 is substantially a rectangular parallelepiped (see FIG. 18). A lens unit 80 is disposed on the lower side Z1 of the reflector 70.
As shown in FIG. 18, the reflector 70 includes a through hole 71 and a rib 72.
The through hole 71 is provided at the center of the reflector 70. Inside the through hole 71, an LED 62 is arranged in the center.
The rib 72 is provided around the lower surface of the reflector 70. The rib 72 has the lens unit 80 disposed therein and positions the lens unit 80.

The inner surface of the through hole 71 of the reflector 70 includes a reflective surface 75 (reflective portion), a left and right reflective surface 76, and a light shielding surface 77 (light shielding portion).
The reflection surface 75 is a surface on the near side Y1 of the through hole 71. The reflection surface 75 is coplanar. That is, the inclination angle of the cross-sectional shape of the reflecting surface 75 viewed from the longitudinal direction X is constant at all cutting positions.
As shown in FIG. 16, the reflecting surface 75 is a steep slope. The angle at which the reflecting surface 75 and the electric substrate 67 intersect is, for example, 70 to 80 °.
Light 75 a directed from the LED 62 toward the reflection surface 75 is reflected by the reflection surface 75. The reflected light 77 b travels upward in the illumination area of the board 1.

The reflection surface 75 is provided in the light emission range (for example, 50 to 60 ° or more from the central axis 62a) of the low-luminance light 77a of the light of the LED 62. For this reason, the upper part of the board 1 is illuminated by the low-intensity light 77 b reflected by the reflecting surface 75.
Actually, the traveling direction of the reflected light of the reflecting surface 75 changes as it passes through the lens unit 80. However, since the distance from the lens unit 80 to the upper part of the board 1 is short, the traveling direction changes. Small change in illumination range. For this reason, for the sake of convenience, the above has been described without considering the influence of reflected light passing through the lens.

  As shown in FIG. 18, the left and right reflective surfaces 76 are arranged in a range outside the longitudinal direction X of the LEDs 62. The left and right reflecting surface 76 reflects light traveling in the longitudinal direction X (left and right direction) of the light from the LED 62 toward the lens unit 80. The incident angle of the light reflected by the left and right reflecting surfaces 76 to the lens unit 80 is small (not shown). For this reason, the lens unit 80 has a substantially desired lens effect on the light reflected by the left and right reflecting surfaces 76.

As illustrated in FIG. 18, the light shielding surface 77 is an inner surface disposed on the back side Y <b> 2 of the LED 62.
As shown in FIG. 17, the light shielding surface 77 directly blocks the light of the LED 62 that goes directly to the near side that is the area on the LED 62 side in the illumination area of the board 1 (that is, the light that goes directly to the top of the board). The light shielding surface 77 is disposed on the back side Y2 that is the board 1 side of the LED 62, and shields light traveling from the LED 62 toward the back side Y2.
As with the reflective surface 75, the light shielding surface 77 is a flat surface having a constant inclination angle. The light shielding surface 77 is a surface substantially perpendicular to the electric substrate 67.

As shown in FIG. 18, the light shielding surface 77 includes a back side light shielding surface 78 and left and right light shielding surfaces 79.
The back side light shielding surface 78 is a surface on the back side Y2 of the LED 62 when viewed from the direction of the central axis 62a of the LED 62, and is parallel to the longitudinal direction X.
The left and right light shielding surfaces 79 are continuously provided outside the longitudinal direction X (left and right direction) of the light shielding surface 77 when viewed from the direction of the central axis 62 a of the LED 62. The left and right light shielding surfaces 79 are displaced toward the front side Y1, which is the opposite side to the board 1 side, as reaching the outer side in the left and right direction, and shields the light directly directed to the board 1 from the left and right directions among the lights of the LEDs 62.

Here, when the white light of the LED 62 is incident from the periphery of the lens unit 80, the yellow component tends to be emphasized, which may result in unnatural illumination. The left and right light shielding surfaces 79 can maintain white natural illumination by blocking light incident on the lens unit 80 from the longitudinal direction X (left and right direction).
Thus, the effect of reducing the emphasis on the yellow component and maintaining the natural illumination was confirmed by actually producing a prototype.

  Note that light that is not shielded by the light shielding surface 77 and is not reflected by the reflective surface 75 and is directly incident on the lens unit 80 is narrowed to some extent by the lens effect and is emitted from the lens unit 80 (FIG. 19A). )reference).

Here, the upper part of the board 1 is close to the LED 62, and the influence of irregular reflection of light in the illumination unit 60 is large, so that the illuminance tends to increase.
In the illuminating device 10, the reflection surface 75 reflects low-brightness light toward the upper portion of the board 1, and the light shielding surface 77 directly blocks light directed toward the board 1, so that the illuminance at the upper portion of the board 1 is extremely high. It is restrained to become. For this reason, the illuminating device 10 can suppress effectively that the illumination intensity of board 1 upper part becomes high.
Thereby, the illuminating device 10 can reduce unevenness in the illuminance of the board 1.

(Lens part 80)
FIG. 19 is a diagram illustrating the lens unit 80 of the first embodiment.
FIG. 19A is an enlarged cross-sectional view of a state where the lens unit 80 is accommodated in the reflector 70.
FIG. 19B is a cross-sectional view of a convex lens corresponding to the Fresnel lenses 81 and 82.
FIG. 19C is a view of the lens unit 80 as viewed from the lower surface.
FIG. 20 is a cross-sectional view illustrating a state in which light is emitted from the lens unit 80 of the first embodiment.
The lens unit 80 is fixed to the lower surface of the reflector 70 with a claw structure, tape, or the like.
The lens unit 80 is a convex lens. The lens unit 80 refracts light emitted radially from the LED 62 into more parallel light and guides it to the board 1.
The lens unit 80 uses a plate-shaped Fresnel lens. Thereby, the lens part 80 can make lens thickness thin, and can also make thickness of illuminating device 10 itself thin.

The lens shape of the lens unit 80 is formed on the emission side which is the lower surface. The incident side of the lens unit 80 is planar, but may be satin-finished for a diffusion effect if necessary.
The lens unit 80 includes a convex portion 80a. The convex part 80a is accommodated in the fracture | rupture part 72a (refer FIG. 18) of the rib 72 of the reflector 70. FIG. For this reason, when an operator attaches the lens part 80 to the reflector 70, the direction and the front and back are not mistaken.

In the lens unit 80, a Fresnel lens 81 (far lens) and a Fresnel lens 82 (near lens) are arranged side by side in the lateral direction Y.
The Fresnel lens 81 and the Fresnel lens 82 are integrally formed and are, for example, resin injection-molded products.
The focal lengths of the Fresnel lenses 81 and 82 are the same, and are the same as the distance from the Fresnel lenses 81 and 82 to the LED 62. The focal length of the Fresnel lenses 81 and 82 is, for example, about 5 mm.

The Fresnel lens 81 is a lens disposed on the near side Y1.
As shown in FIG. 19B, the optical axis 81a of the Fresnel lens 81 and the center axis 62a of the LED 62 are misaligned. The optical axis 81a of the Fresnel lens 81 is disposed on the front side Y1 with respect to the central axis 62a of the LED 62. The amount of deviation L81a of the optical axis 81a of the Fresnel lens 81 is, for example, about 0.5 to 3 mm.
Similarly, the optical axis 82a of the Fresnel lens 82 and the central axis 62a of the LED 62 are misaligned, and the optical axis 82a of the Fresnel lens 82 is disposed on the front side Y1 with respect to the central axis 62a of the LED 62. .
The deviation amount L81a of the optical axis 81a of the Fresnel lens 81 is larger than the deviation amount L82a of the optical axis 82a of the Fresnel lens 82.

As described above, the optical axes 81a and 82a of the Fresnel lenses 81 and 82 are arranged on the front side Y1 with respect to the LED 62, so that the light emitted from the LED 62 has a larger emission angle from the boundary surface 80b.
As shown in FIG. 20, this allows the light emitted from the Fresnel lens 81 to refract and travel to the nearer side Y1. That is, the light emitted from the Fresnel lens 81 can reach farther on the lower side Z1 of the board 1, so that the area on the lower side Z1 of the board 1 can be illuminated.
Further, since the deviation amount L81a is larger than the deviation amount L82a, the Fresnel lens 81 guides light farther than the Fresnel lens 82 due to the refractive index and the incident angle (see the light center 81b).
That is, the Fresnel lens 82 guides the light from the LED 62 to the upper Z2 region (that is, the LED 62 side region) in the illumination region of the board 1. Further, the Fresnel lens 81 guides the light from the LED 62 to a region farther than the irradiation region of the Fresnel lens 82 (that is, the region on the lower side Z1) (see the light center 81b).

The light centers 81b and 81b shown in FIG. 20 are illustrated with exaggerated angles.
The form of the Fresnel lenses 81 and 82 is an example, and the amount of deviation between the optical axes 81a and 82a and the central axis 62a of the LED 62 can be set as appropriate. Further, for example, the lens unit 80 guides light in the vicinity by the Fresnel lens 81 disposed on the back side Y2 (board 1 side) and guides the light in the distance by the Fresnel lens 82 disposed on the near side Y1. , May be set.

(Front shading part 90)
As shown in FIG. 16, the front light-shielding portion 90 is a region on the back side Y <b> 2 of the bottom plate portion 43 of the cover portion 40. The front light-shielding unit 90 shields light directly traveling from the LED 62 toward the front side Y1 and the lower side Z1. The front light-shielding unit 90 blocks light from the LED 62 so that the observer cannot observe the light source (image) of the LED 62.
Thereby, since the illuminating device 10 can reduce the glare in the upper part of the board 1, it can improve the visibility of the board | substrate 1 of an observer.
Note that light traveling toward the upper side Z <b> 2 of the board 1 due to light leakage from the illumination unit 60 or the like is blocked by the light blocking unit 91 on the back side Y <b> 2 of the cover unit 40. Thereby, the illumination part 60 can suppress that the upper part vicinity of the board 1 becomes extremely bright.

In this way, the illumination unit 60 changes the light from the LED 62 into a plurality of directions by the action of the reflector 70 and the lens unit 80 and divides the light to reach the board 1. Thereby, the nonuniformity of the illumination intensity in the vertical direction of the board 1 can be reduced. Moreover, since the illumination unit 60 arranges the plurality of unit illumination devices 61 in the longitudinal direction X, it is possible to reduce unevenness in illuminance in the longitudinal direction X of the board 1. Thereby, the illumination unit 60 can reduce unevenness in illuminance on the entire surface of the board 1.
Furthermore, since the illumination part 60 changes the direction of the light from LED62 and makes light of moderate illumination intensity reach the upper part of the board 1, the exit width | variety from the board 1 to the near side Y1 can be made small. For this reason, the illuminating device 10 can make the magnitude | size of the transversal direction Y small, and can be made small.
In addition, the effect which can reduce the nonuniformity of illumination intensity by arranging multiple LED62, the reflector 70, and the lens part 80 in this way, and the effect which can make the protrusion width | variety from the board 1 small were confirmed by trial manufacture.

(Comparison with the illumination device 110 of the comparative example)
FIG. 21 is a cross-sectional view comparing the state in which the lighting device 10 of the first embodiment and the lighting device 110 of the comparative example are attached to the board 5.
The board 5 is a type having a board 5b (indicated by a two-dot chain line) movable in the longitudinal direction X on the front side Y1 of the board 5a. The board 5 is a so-called draw blackboard or the like. In order to emphasize the comparison between the lighting device of the first embodiment and the lighting device 110 of the comparative example, a draw blackboard or the like is taken as an example, but the following comparative explanation is the same for the board 1 described above. is there.
As shown in FIG. 21A, the illumination unit 60 of the illumination device 10 of the embodiment is disposed at a position that extends straight from the frame 6 of the board 5 to the near side Y1 as described above. For this reason, the illuminating device 10 can make small area | region A10 where the light from the illumination part 60 is interrupted | blocked by the frame 6. FIG.
Even if the lighting device 10 is installed near the upper part of the board, the lighting unit 60 changes the light from the LED 62 in a plurality of directions as described above and causes a part of the light to reach the upper part of the board. For this reason, the illumination unit 60 can reduce unevenness in illuminance.

  On the other hand, as shown in FIG. 21B, the illumination unit 160 of the illumination device 110 of the comparative example is arranged on the upper side Z <b> 2 and the near side Y <b> 1 of the frame 6 of the board 5 by the arm 111. Therefore, the light from the light source 162 of the illuminating unit 160 has a large area A110 that is blocked by the frame 6. In this case, the shadow of the frame 6 is reflected on the board 5a, and the illuminance unevenness is increased.

  Thus, the illumination device 10 can reduce unevenness in illuminance by changing the light from the LED 62 to a plurality of directions and reaching the board 5 in addition to the attachment position to the board 5.

Further, as described above, the lighting device 10 can reduce the protruding width from the board 5. For this reason, since the lighting device 10 does not apply strong light to a person near the lower side Z <b> 1 of the lighting device 10, the lighting device 10 does not feel dazzling, and a person's shadow is reflected on the board 5. Can also be suppressed. For this confirmation, when the lighting device 10 in which the LED 62 has an output width L10 of about 100 mm was prototyped, a person near the lower side Z1 of the lighting device 10 did not feel strong light. In this case, even if the length of the board 5 in the vertical direction Z is about 1500 mm, the illuminance unevenness of the embodiment is better than that of the comparative example. For this reason, the illuminating device 10 was able to make the dimension of the transversal direction Y to about one tenth with respect to the length of the board 5 in the vertical direction Z.
On the other hand, the illumination device 110 according to the comparative example needs an output width L110 of about 400 to 500 mm in order to make the blocked area A110 acceptable, and is larger than the embodiment. Further, a strong light hits a person in the vicinity of the lower side Z <b> 1 from the lighting device 110, and a person's shadow is reflected on the board 5.

(Second Embodiment)
Next, a second embodiment of the present invention will be described.
In the following description and drawings, parts having the same functions as those of the first embodiment described above are given the same reference numerals or the same reference numerals at the end (the last two digits), and overlapping explanations are appropriately given. Omitted.

[Single unit configuration of lighting device 210]
FIG. 22 is a top view of a state in which the lighting device 210 according to the second embodiment is mounted on the board 201.
FIG. 22A illustrates only two of a plurality of connected lighting devices 210.
FIG. 22B is an enlarged view of a portion indicated by an arrow B in FIG.
FIG. 23 is a perspective view of one of the connecting portions of the base portion 220 and the arm portion 230 (the arrow B portion in FIG. 22) of the lighting device 210 of the second embodiment.
FIG. 23 is a partially broken view of the base attachment assisting portion 226, the arm portion 230, and the like.
FIG. 24 is a perspective view of the base part 220 and the arm part 230 of the second embodiment.
FIG. 24A is an enlarged view of the vicinity of the connection portion between the base portion 220 and the arm portion 230.
FIG. 24B is an enlarged view of the connection fitting 235.
FIG. 25 is a cross-sectional view of the vicinity of the arm unit 230 of the illumination device 210 of the second embodiment.

As shown in FIG. 22, the board 201 is, for example, a curved blackboard. The board 201 includes a board main body 201a, an arm 201b, and a mounting plate 202.
The board body 201a has a curved shape such that the center is recessed. The board main body 201a is attached to the front side Y1 with respect to the attachment plate 202 by a plurality of arms 201b. The board body 201a is attached to the mounting plate 202 so that the positions in the short direction Y of both ends in the longitudinal direction X (left and right direction) are the same, and the center of the board is the farthest side Y2.
The mounting plate 202 is a member used as a base (base member) for mounting the board 201. The mounting plate 202 is fixed to the wall surface on which the board 201 is installed. Thereby, the board main body 201a is fixed to the wall surface. When the board 201 is movable, the mounting plate 202 is fixed to a pillar or the like.

  As shown in FIG. 22, when viewed from the upper side Z2, the mounting plate 202 is arranged in parallel in the direction W (direction along the edge of the board) in which the board body 201a extends. Yes. That is, the direction W is a direction of a straight line connecting both ends of the board body 201a in the longitudinal direction X (left and right direction), is parallel to the longitudinal direction X, and is also parallel to the wall surface.

[Configuration of Illumination Device 210]
As in the first embodiment, the lighting device 210 is attached to the board 201 so as to be connected alone or in a plurality.
As illustrated in FIG. 23, the lighting device 210 includes a base portion 220, an arm portion 230, a connection fitting 235 (connection portion), and a cable cover 240.
(Configuration of base 220)
The base part 220 includes a base body 20 and a base attachment auxiliary part 226.
The base body 20 is the same device as the base 20 of the first embodiment.
The base attachment auxiliary portion 226 is attached to the rear end of the base body 20 so as to extend in the longitudinal direction X. The base attachment auxiliary portion 226 is fixed to the plate-like rear plate portion 22 of the base main body 20 by being screwed. The screwing location can be appropriately selected according to the size of the lighting device 210 and the like. In the example of FIG. 22, one lighting device 210 is screwed at four places.

The base attachment auxiliary part 226 is an extruded product of aluminum. For this reason, the cross-sectional shape of the base attachment auxiliary portion 226 viewed from the longitudinal direction X is constant.
The outer shape of the base attachment auxiliary portion 226 is a prismatic member elongated in the longitudinal direction X. The cross-sectional shape of the base attachment auxiliary portion 226 is a symmetric shape in the YZ plane. That is, the cross-sectional shape of the base attachment auxiliary portion 226 is point symmetric with respect to the center. For this reason, the base attachment auxiliary part 226 can be attached to the base body 20 even if it is rotated 180 ° in the YZ plane or 180 ° in the XY plane.
In the longitudinal direction X, the base attachment auxiliary unit 226 may connect a plurality of prismatic members, and prepare a sufficiently long one prismatic member so that the plurality of lighting devices 210 share this one. May be.

As shown in FIGS. 24 and 25, the base attachment auxiliary portion 226 includes a groove 226a, a connection fitting engagement groove 226b (connection portion attachment portion), and a cable cover attachment groove 226c. In addition, since the base attachment auxiliary | assistant part 226 is symmetrical shape, a code | symbol etc. are illustrated only on one side.
The groove 226a is provided so that the side surface on the near side Y1 and the side surface on the back side Y2 of the base attachment auxiliary portion 226 are recessed.
The connection fitting engagement groove 226 b is a groove that engages with the connection fitting 235. The connection fitting engaging groove 226b is provided inside the groove 226a. The connection fitting engaging groove 226b is provided so that the upper and lower inner walls of the groove 226a are recessed in the vertical direction Z, respectively.
The cable cover attachment groove 226 c is a groove for attaching the cable cover 240. The cable cover attachment groove 226c is provided inside the groove 226a, similarly to the connection fitting engagement groove 226b. The cable cover attachment groove 226c is disposed closer to the surface side of the base attachment auxiliary portion 226 than the connection fitting engagement groove 226b.

(Configuration of arm unit 230)
As shown in FIGS. 23 and 24, the arm portion 230 is a member that attaches the base portion 220 to the upper portion of the mounting plate 202. The arm part 230 is attached so as to protrude from the base part 220 toward the board 201 when viewed from the upper side Z <b> 2, and the rear end part of the arm part 230 is fixed to the upper part of the attachment plate member 202.
The number of arm units 230 can be selected as appropriate according to the size of the illumination device 210 and the like. In this embodiment, two places are provided for one lighting device 210 (see FIG. 22).

The arm unit 230 includes an arm main body 231 and an arm mounting unit 232.
The shape of the arm main body 231 is a prismatic shape elongated in the short direction Y. The arm main body 231 is connected to the base attachment auxiliary portion 226 at a right angle from the back side Y2.
The arm body 231 is an extruded product of aluminum. The cross section of the arm main body 231 and the cross section of the base attachment auxiliary portion 226 have the same shape. For this reason, the arm main body 231 includes a groove 231a, a connection fitting engagement groove 231b, and a cable cover attachment groove 231c similar to the base attachment auxiliary portion 226. These functions are also the same as those of the base attachment auxiliary portion 226.
As described above, the base attachment auxiliary portion 226 and the arm main body 231 can be manufactured by processing an extruded product of aluminum. For this reason, the manufacturer can manufacture the base attachment auxiliary portion 226 and the arm main body 231 in the same process, so that the cost can be reduced and parts management (inventory, material management, etc.) is easy.
When the arm main body 231 is attached to the base attachment auxiliary portion 226, the arm main body 231 is in a substantially straight form with the base 220 (see FIG. 25). For this reason, the external appearance of the illuminating device 210 is smart.

The arm mounting portion 232 is a member for attaching the arm main body 231 to the upper part of the mounting plate 202. The arm mounting portion 232 has a shape in which a flange for mounting on the upper portion of the mounting plate 202 is provided on the lower side Z1 of the frame.
The arm mounting portion 232 is an extruded product of aluminum. When viewed from the short direction Y, the cross-sectional shape of the arm mounting portion 232 is constant.

The arm mounting portion 232 includes a through hole 232a (hole portion), an arm attachment hole 232b, and a board attachment hole 232c.
The through hole 232 a penetrates in the short direction Y and opens in the short direction Y. The size of the through hole 232a is substantially the same as the outer shape of the arm body 231. The arm body 231 is inserted through the through hole 232a.
The arm main body 231 is positioned in the ZX plane while being inserted through the through-hole 232a, and is prevented from rotating in each rotation direction (around each axis in the longitudinal direction X, the short direction Y, and the vertical direction Z). Is done.
Further, the arm main body 231 is restricted from moving in the lateral direction Y by being screwed to the arm mounting portion 232 using the arm attachment hole 232b. Thereby, the arm main body 231 is fixed to the arm mounting portion 232.
The board mounting hole 232 c is for screwing the arm mounting portion 232 to the upper portion of the mounting plate 202.

(Configuration of connection fitting 235)
As shown in FIG. 24, the connection fitting 235 is a member that connects the base portion 220 and the arm portion 230. The connection fitting 235 is formed by press-molding a metal plate such as iron.
The connection fitting 235 has a shape in which one piece 236 and the other piece 237 are connected at a right angle. The one piece 236 and the other piece 237 have the same shape. Further, as described above, since the cross-sectional shape of the base attachment auxiliary portion 226 and the cross-sectional shape of the arm main body 231 are the same, the base attachment auxiliary portion 226 and the arm main body 231 have the same shape that engages with the connection fitting 235. It is. For this reason, the connection fitting 235 may connect either the one piece 236 or the other piece 237 to the base attachment auxiliary portion 226 (or the arm body 231).
Each piece 236 includes a wide portion 236a and a narrow portion 236b having a smaller width than the wide portion 236a.

The wide portion 236a engages with the connection fitting engagement groove 226b of the base attachment auxiliary portion 226 (or the connection fitting engagement groove 231b of the arm main body 231). In the vertical direction Z, the length of the connection fitting engaging groove 226b is substantially the same (see length L226b in FIG. 25).
The wide part 236a includes a hole 236c for screwing to the base attachment auxiliary part 226 (or the arm main body 231).
The narrow portion 236b is located inside the groove 226a in a state where the connection fitting 235 is attached to the base attachment auxiliary portion 226. The width of the narrow portion 236b is substantially the same as the width of the groove 226a (or the groove 231a) (see the length L226a in FIG. 25).
The other piece 237 includes a wide portion 237a, a narrow portion 237b, and a hole portion 237c similar to the one piece 236.

(Configuration of cable cover 240)
The cable cover 240 is a member that covers the AC cable 58 so as not to be exposed to the outside. By covering the AC cable 58, the illumination device 210 can improve the appearance quality. The cable cover 240 is a resin extruded product or the like. The cable cover 240 is provided on the base attachment auxiliary part 226 and the arm main body 231, respectively.
The cable cover 240 includes a claw 240a.
The claw 240 a engages with the base attachment auxiliary portion 226 and the cable cover attachment groove 226 c of the arm main body 231. Thereby, the cable cover 240 is attached to the base attachment auxiliary part 226 and the arm main body 231.
The AC cable 58 is accommodated and disposed in the groove 226a of the base attachment auxiliary portion 226. The cable cover 240 is attached so as to cover the AC cable 58 and covers the AC cable 58.
The cable cover 240 is attached to the arm main body 231 similarly to the base attachment auxiliary portion 226.

[Attaching Method of Lighting Device 210]
26 and 27 are perspective views illustrating a process of mounting the lighting device 210 on the board 201. FIG.
An operator can attach the lighting device 210 to the board 201 by the following process.
(# 31) As shown in FIG. 26C, the arm mounting portion 232 is screwed to the top of the mounting plate 202. The same is done for other attachment points.
(# 32) As shown in FIG. 26A, the base attachment assisting portion 226 is disposed so as to be placed on the rear plate portion 22 of the base main body 20, and the base attachment assisting portion 226 is placed on the rear plate portion 22 of the base main body 20. Screw on. It carries out similarly about several places. In addition, if the tapping screw with a drill is used for a screw, since the base hole auxiliary | assistant part 226 need not be drilled, workability | operativity can be improved.
Thereby, the base main body 20 and the base attachment auxiliary | assistant part 226 are fixed.

(# 33) As shown in FIGS. 26A and 26B, the connection fitting 235 is inserted into the connection fitting engagement groove 226b of the base attachment auxiliary portion 226 and is slid along the longitudinal direction X. Similarly, the connection fitting 235 at the other attachment location is inserted into the connection fitting engagement groove 226b.
In this state, one piece 236 (or the other piece 237) of the connection fitting 235 protrudes from the base attachment auxiliary portion 226 to the back side Y2.
(# 34) As shown in FIG. 26C, the arm main body 231 is inserted into the through hole 232a of the arm mounting portion 232. Further, the other piece 237 of the connection fitting 235 shown in FIG. 25B is inserted into the connection fitting engagement groove 231b of the arm main body 231 (see arrow C in FIG. 26C).
In this state, the base body 20 is temporarily fixed to the board 201, so that the operator can release his hand from the base 20.
(# 35) As in the first embodiment, adjacent bases 220 are connected and connected.

(# 36) As shown in FIG. 27, the arm main body 231 is slid with respect to the through hole 232a (see arrow Y3), and the relative position between the base 220 and the board main body 201a is adjusted in the lateral direction Y. Thereby, the length to the board main body 201a of the illuminating device 210 is adjusted.
Further, the arm main body 231 is slid with respect to the base attachment auxiliary portion 226 (see arrow X3), and the relative position of the base 220 and the board main body 201a is adjusted in the longitudinal direction X.
These adjustments are performed so that the base 220 is substantially parallel to the direction W in which the board body 201a extends in the XY plane, and is arranged at the center of the board body 201a. .
Since the connection fitting 235 can move in the longitudinal direction X in the connection fitting engagement groove 226b of the base attachment auxiliary portion 226, the base attachment auxiliary portion 226 can slide in the longitudinal direction X with respect to the arm body 231. . Thereby, the connection fitting engagement groove 226b can change the attachment position of the connection fitting 235.

(# 37) As shown in FIG. 27, the connection fitting 235, the base attachment auxiliary portion 226, and the arm main body 231 are fixed with screws. Further, the arm body 231 and the arm mounting portion 232 are fixed with screws. For these screws, if a tapping screw with a drill is used, the workability can be improved because the drilling of the prepared hole is unnecessary.
Note that this screwing may be performed after the illumination state of the board body 201a is confirmed by actually illuminating the board body 201a with an illumination device.
(# 38) The portion of the arm main body 231 that protrudes further back Y2 than the arm mounting portion 232 is cut with a tool such as a gold saw.

(# 39) The cover part 40 is attached to each base part 220 as in the first embodiment.
(# 40) As shown in FIG. 23, the cap 50 is separated from the groove 50d (see FIG. 12) and attached to the base 220 with the notch 50e provided. Further, as in the first embodiment, a bushing is attached to the cap.
(# 41) As shown in FIG. 23, the AC cable 58 is accommodated in the base attachment auxiliary portion 226 and the grooves 226a and 231a of the arm main body 231 from the notch 50e at the rear end of the cap 50, and the arm main body 231 is inserted. Lead to the rear end. As a result, the AC cable 58 can be smartly wired without hanging down the front side Y1 of the board 201 or the like.
The cable cover 240 is cut with a cutter knife or the like and attached to the base attachment auxiliary portion 226 and the arm main body 231.

As described above, the lighting device 210 according to the present embodiment can be mounted in an installation environment where the board 201 is curved.
In addition, the lighting device 210 can be mounted by freely adjusting the mounting position of the lighting device 210 (that is, the distance from the board main body 201a) in the short direction Y.
Further, even if the entire upper surface of the mounting plate 202 is not flat, the lighting device 210 can be mounted on the board 201 as long as an area for screwing the arm mounting portion 232 can be secured above the mounting plate 202. Thereby, the illuminating device 210 can improve versatility.

Two connection fittings 235 may be provided on one arm portion 230 (see connection fitting 235B shown in FIG. 22). In this case, the mounting strength of the lighting device 210 can be improved. Further, common parts can be used for the connection fittings 235 and 235B.
Moreover, you may attach the illuminating device 210 to the flat board 201 similar to 1st Embodiment. Also in this case, the mounting position of the lighting device 210 can be adjusted so that the lighting state of the board 201 becomes good.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to embodiment mentioned above, For example, various deformation | transformation and a change are possible like the deformation | transformation form etc. which are mentioned later, These are also It is within the technical scope of the present invention. In addition, the effects described in the embodiments are merely a list of the most preferable effects resulting from the present invention, and the effects of the present invention are not limited to those described in the embodiments. It should be noted that the above-described embodiment and modifications described later can be used in appropriate combination, but detailed description thereof is omitted.

(Deformation)
In this embodiment, although the illuminating device showed the example attached to the upper frame of a board, it is not limited to this. The lighting device may be attached to the left or right frame of the board, for example.

1,5,201 board 2,6 frame 10,210 lighting device 20,220 base (base body)
31 Connecting Bracket 35 Wiring Portion 36-38 Cable 39 Distributor 40 Cover Portion 50 Cap 55 Bushing 59 Conversion Cable 60 Illumination Unit 61 Unit Illumination Device 62 LED
70 reflector 75 reflecting surface 77 light shielding surface 78 back light shielding surface 79 left and right light shielding surfaces 80 lens part 81 Fresnel lens 82 Fresnel lens 201a board body 202 mounting plate 202
230 Arm part 231 Arm body 232 Arm mounting part 232a Through-hole 235 Connection fitting

Claims (4)

A board lighting device for lighting a board,
A point light source,
A reflector that reflects and shields light from the point light source;
The reflector is
A reflection part for reflecting the light of the point light source toward the illumination area of the board;
A light shielding unit that blocks light from the point light source that directly goes to the area on the point light source side in the illumination area of the board;
Board lighting device characterized by. The board lighting device according to claim 1,
The reflective portion is
Of the light from the point light source, provided in the emission range of low-luminance light,
Board lighting device characterized by. The board lighting device according to claim 1 or 2,
The light from the point light source is white.
The shading part is
A back side light-shielding portion that is disposed on the back side, which is the board side of the point light source, and shields light from the point light source toward the back side;
A left and right light-shielding portion that is provided outside the back-side light-shielding portion and is displaced toward the outer side, which is opposite to the board side, and shields light directly from the left-right direction of the point light source toward the board. Providing
Board lighting device characterized by. In the board illuminating device in any one of Claims 1-3,
Comprising a front light-shielding portion that shields light directed directly from the point light source toward the near side and the bottom side;
Board lighting device characterized by.

Images