JP6839636B2 - lighting equipment - Google Patents

Description

The present invention relates to a luminaire.

Lighting fixtures equipped with a plurality of LEDs, a reflector provided for each LED, and a fixture body for accommodating these are known, and this type of luminaire is widely used for floodlighting (for example,). , Patent Document 1).

Japanese Patent No. 6004104

The reflector is installed in the instrument body so that the LED is arranged at the position of the light source in the optical design.

In a configuration including a plurality of reflectors, there is a problem that the luminaire becomes large due to the space between the reflectors.

Therefore, an object of the present invention is to provide a luminaire in which the space between the reflectors is suppressed.

The present invention relates to a lighting fixture in which a mounting substrate on which a plurality of light emitting elements are mounted and a plurality of reflectors having a reflector for controlling the light of the light emitting elements are housed in a main body of the fixture. Each of the reflector fixtures is provided, and the reflector fixture surrounds a plurality of the reflectors, and the outer frame member fixed to the instrument body and the inside of the outer frame member. Provided with a plate-shaped middle plate extending between the plurality of reflectors and engaging with the reflector, and the plate surface of the middle plate is provided parallel to the outer surface of the reflector. It is characterized by being.

The present invention is characterized in that, in the luminaire, the outer frame member has a plate shape in which the plate surface is provided parallel to the outer surface of the reflector.

The present invention is characterized in that, in the luminaire, a convex portion is formed on the outer surface of the reflector so as to be pressed against the luminaire body by the middle plate.

According to the present invention, in the lighting equipment, the reflector is configured to be separable into a plurality of parts in the optical axis direction of the reflector, and the light distribution angle of the reflector depends on the combination of the plurality of parts. Is changeable, and each of the plurality of parts is provided with the convex portion at the same height position from the mounting substrate.

According to the present invention, the space between the reflectors is suppressed.

It is a perspective view which shows the structure of the LED lighting fixture which concerns on embodiment of this invention. It is a figure which shows the structure of the LED lighting fixture, (A) is a front view, (B) is a rear view. It is sectional drawing of the LED lighting equipment. It is an exploded view of the LED lighting equipment. It is a top view which shows the state which only one light source unit is arranged in the case main body of the instrument main body. It is a figure which shows the structure of the light source unit fixture. It is a figure which shows the use state of the light source unit fixture. It is a figure which shows the structure of the reflector, (A) is a front view, (B) is a side view, (C) is a rear view, (D) is a bottom view. It is a partially enlarged sectional view which shows the arrangement mode of the LED mounting substrate 34 on the apparatus main body. It is a partially enlarged sectional view of the LED lighting fixture 1 which shows the engaging state of the LED mounting board and a reflector. It is an exploded view which looked at the reflector from the front side. It is an exploded view which looked at the reflector from the back side. It is sectional drawing which shows the structure of a reflector.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 and 2 are views showing the configuration of the LED lighting fixture 1, FIG. 1 is a perspective view, FIG. 2 (A) is a front view, and FIG. 2 (B) is a rear view.
The LED lighting fixture 1 is installed in a lighting tower of a stadium such as a stadium, and is a fixture for floodlighting the inside of the stadium, and includes an appliance main body 2 and an arm 4.

The fixture body 2 is a case body that houses a large number of light source units 5 that form a light emitting unit, and is formed in a thin rectangular box shape in a plan view. A substantially rectangular (approximately square in this embodiment) exit opening 7 is formed on the front surface of the instrument main body 2, and a front cover 9 is watertightly fixed to the exit opening 7.
The appliance main body 2 is formed by die-cast molding of a high thermal conductive material such as an aluminum alloy, and a heat radiating portion 6 is provided on the back surface of the appliance main body 2. As shown in FIG. 2B, the heat radiating portion 6 includes a large number of heat radiating fins 6A extending in one direction, and these heat radiating fins 6A are integrally molded with the instrument main body 2. As a result, the heat of the light source unit 5 is efficiently dissipated from the fixture main body 2 and the heat radiating fins 6A.
Further, a power supply box 12 is provided on the back surface of the appliance main body 2, and various wirings such as a power line for transmitting external power are connected to the power supply box 12.

The arm 4 is a member fixed to the installation location of the instrument main body 2, and is formed in a U shape. By connecting the tip portions 18 at both ends to the side surface of the instrument main body 2, the instrument main body 2 can be attached. Hold it at the installation location. Further, the tip 18 of the arm 4 is connected to the instrument body 2 with a bolt 20, so that the instrument body 2 is rotatably supported by the arm 4.
The arm 4 is provided with an operation handle 22 that can be freely rotated so that the arm 4 is non-rotatably fixed to the instrument body 2 by manually rotating the operation handle 22. It is configured.

FIG. 3 is a cross-sectional view of the LED luminaire 1, and FIG. 4 is an exploded view of the LED luminaire 1.
The instrument main body 2 includes a storage case 8 and a cover case 10 that is mounted so as to be overlapped with the storage case 8. Flange 11A and 11B are formed in each of the housing case 8 and the cover case 10, and by screwing these flanges 11A and 11B, the two are inseparably connected.

As shown in FIG. 4, the fixture body 2 contains four front cover fixing brackets 28, 16 light source units 5, and four reflector fixtures 30.
The front cover fixing bracket 28 is a member provided for each side of the rectangular front cover 9 and fixing the front cover 9 to the exit opening 7. As shown in FIGS. 3 and 4, the front cover fixing bracket 28 includes a fixing piece 28A extending along one side of the front cover 9, and the fixing piece 28A has an exit opening 7 as shown in FIG. With a gap 29 between the edge portion 7A and the edge portion 7A of the device, the device body 2 is screwed and fixed. The front cover 9 is fixed by arranging the edge 9A of the front cover 9 in the gap 29 and sandwiching the edge 9A.

Further, as shown in FIG. 3, the front cover fixing bracket 28 extends between the inner side surface 2A of the instrument main body 2 and the light source unit 5 along the inner side surface 2A, and is a plate-shaped auxiliary reflecting portion that covers the inner side surface 2A. It is equipped with 28B. The auxiliary reflecting portion 28B is formed on a reflecting surface whose surface 28B1 located at least inside the instrument body 2 reflects light, and this surface 28B1 reflects light from the light source unit 5 toward the inner surface 2A of the instrument body 2. By doing so, the efficiency of the equipment is improved. The front cover fixing bracket 28 of the present embodiment is an L-shaped bent metal plate, and is made of a metal plate having a surface coating or the like that enhances the light reflection function.

As shown in FIG. 4, the light source unit 5 includes an LED mounting substrate 34 on which a plurality of LEDs 40 are mounted, and a reflector 36 on which a reflector 42 is formed for each LED 40, and these are stacked to form an instrument main body. It is provided on the bottom surface of 2.

FIG. 5 is a plan view showing a state in which only one light source unit 5 is arranged in the storage case 8 of the fixture main body 2.
As shown in the figure, the bottom surface of the instrument main body 2 is provided with a plurality of installation surfaces 38 formed by partitioning the bottom surface with the same size and shape (substantially rectangular in the present embodiment). Further, the LED mounting substrate 34 is formed in a size that fits in the installation surface 38, and is fixed to each installation surface 38 with an adhesive or the like. Then, by arranging the reflector 36 on each of the LED mounting boards 34, the light source unit 5 composed of the LED mounting board 34 and the reflector 36 is arranged on each installation surface 38.
Further, on the edge of each installation surface 38, convex portions 39 are provided at a plurality of locations surrounding the installation surface 38, and the reflector 36 is roughly positioned on the installation surface 38 by these convex portions 39. Further, each reflector 42 of the reflector 36 is also accurately positioned with respect to each LED 40 of the LED mounting substrate 34, which will be described later.
Then, the reflector 36 arranged on the LED mounting substrate 34 is fixed by the reflector fixture 30.
The installation surface 38 is integrally formed with the instrument body 2, and the heat of the LED 40 is transferred to the outer surface of the instrument body 2 and the heat radiating portion 6 through the LED mounting substrate 34 and the installation surface 38, and is dissipated from each. ..

FIG. 6 is a diagram showing the configuration of the reflector fixture 30, and FIG. 7 is a diagram showing a usage state of the reflector fixture 30.
The reflector fixture 30 is an instrument for fixing a plurality of reflectors 36 to the instrument body 2.
Here, if each reflector 36 is fixed to the instrument main body 2 by screwing or the like, fixing work is required for all the reflectors 36, and the assembly work becomes complicated. In addition to this, since it is necessary to secure a space for screwing around each reflector 36, it becomes difficult to arrange the individual reflectors 36 densely, and the amount of light per unit area is increased. It becomes difficult to raise the size, and the size of the LED lighting fixture 1 is increased.
On the other hand, in the present embodiment, the plurality of reflectors 36 can be densely arranged by the reflector fixture 30.
Specifically, the reflector fixing tool 30 fixes these reflectors 36 by pressing the plurality of reflectors 36 against the instrument main body 2. This eliminates the need for screwing spaces around the individual reflectors 36 and allows the respective reflectors 36 to be densely arranged.

The configuration of the reflector fixture 30 will be described in detail. As shown in FIG. 6, the reflector fixture 30 includes an outer frame plate 44 constituting an outer frame and an inner plate provided in the outer frame plate 44. It includes a 46 and a screw plate 48 that is screwed to the instrument body 2.
The outer frame plate 44 is an outer frame member having a dimensional shape that surrounds a plurality of reflectors 36 arranged in a predetermined arrangement manner along the outer edge of the reflectors 36. In the present embodiment, the outer frame plate 44 is It constitutes a substantially rectangular outer frame in plan view.

The predetermined arrangement mode is a mode in which the plurality of reflectors 36 are arranged most densely, and is determined depending on the outer shape of the reflector 36. As shown in FIG. 4, the outer shape of the reflector 36 of the present embodiment is a substantially rectangular parallelepiped, and therefore a grid-like arrangement mode is used as the predetermined arrangement mode. If the outer shape of the reflector 36 is cylindrical, a staggered arrangement is used in the predetermined arrangement mode, and if the outer shape of the reflector 36 is a hexagonal cylinder, the predetermined arrangement mode is honeycomb-shaped. Arrangement mode is used.

As shown in FIG. 7, the middle plate 46 is a plate material extending between the reflectors 36 and partitioning the inside of the outer frame plate 44 according to the outer shape of the reflector 36. Then, the inside of the outer frame plate 44 is partitioned by the middle plate 46, so that the arrangement space 50 of each reflector 36 is formed inside the outer frame plate 44.

The screw fixing plate 48 is provided on the outer frame plate 44 and is a member for screwing and fixing the outer frame plate 44 to the instrument main body 2. In the present embodiment, the screw fixing plate 48 is provided inside the outer frame plate 44. .. As shown in FIG. 5, the instrument main body 2 is formed with screw fastening portions 52 at a plurality of locations on the bottom surface and the inner side surface thereof, and the screw fastening plates 48 are screwed and fixed to these screw fastening portions 52. To.

Then, in the reflector fixture 30, the outer frame plate 44 and the middle plate 46 are configured to engage with each reflector 36 and press these reflectors 36 against the instrument main body 2 to fix them. Has been done. That is, a plurality of convex portions 54 (see FIG. 8) projecting outward are provided on the outer surface 36A of each reflector 36, and each convex portion 54 is an outer frame plate 44 of the reflector fixture 30. By being pressed by either the middle plate 46 or the middle plate 46, each reflector 36 is pressed against the instrument body 2 and fixed.

In the reflector fixture 30 of the present embodiment, the outer frame plate 44 and the middle plate 46 extending along the outer shape of the plurality of reflectors 36 have a thin plate thickness d1 (FIG. 6) and have a thin plate thickness d1 (FIG. 6). Each plate surface is provided so as to be substantially parallel to the outer surface 36A of the reflector 36.
As a result, the gap between the reflectors 36 pressed by the reflector fixture 30 (the space for extending the middle plate 46) is narrowed, so that each of the reflectors 36 can be arranged more densely.
Further, when a plurality of reflector fixtures 30 are arranged side by side, the gap between the reflectors 36 pressed by the different reflector fixtures 30 (the space for extending the outer frame plate 44) is also narrowed. .. Therefore, even when the number of reflectors 36 included in the LED lighting fixture 1 is large, these reflectors 36 can be fixed in a densely arranged state by using an appropriate number of reflector fixtures 30.

By the way, in the reflector fixing tool 30, as described above, the reflector 36 is arranged in the arrangement space 50 partitioned by the outer frame plate 44 and the middle plate 46. In the reflector fixture 30, the arrangement space 50 is formed to be slightly larger than the external dimensions of the reflector 36 in consideration of the dimensional tolerance of the reflector 36. Therefore, the reflector 36 can be accommodated and pressed into each of the arrangement spaces 50 of the reflector fixture 30 without the outer frame plate 44 and the middle plate 46 being caught by the reflector 36.

In the LED lighting fixture 1 of the present embodiment, the reflector fixture 30 only fixes each reflector 36, and the accurate positioning of the reflector 36 is performed as follows.

8A and 8B are views showing the configuration of the reflector 36, FIG. 8A is a front view, FIG. 8B is a side view, FIG. 8C is a rear view, and FIG. 8D is a bottom view. is there.
As shown in the figure, a plurality of concave reflecting mirrors 42 are formed on the front surface of the reflector 36, and an opening 42A on which the LED 40 is arranged is provided on the back surface of each reflecting mirror 42. .. The back surface of the reflector 36 of the present embodiment engages with the LED mounting substrate 34, so that the reflector 36 is positioned with respect to the LED mounting substrate 34, whereby the reflector 42 is accurate with respect to the LED 40. It is designed to be positioned at. Hereinafter, the configuration will be described in detail.

FIG. 9 is a partially enlarged cross-sectional view showing an arrangement mode of the LED mounting substrate 34 on the instrument main body 2.
The LED mounting substrate 34 is a substantially rectangular substrate having a size that fits in the installation surface 38, and a plurality of LEDs 40 are mounted at equal intervals on the mounting surface 34A, and an engaging piece 43 is provided.

The LED 40 constitutes a planar light source having a light emitting surface 40A having a substantially circular shape in a plan view. In the present embodiment, the LED 40 uses a COB type LED having extremely high brightness (high output). Compared with the case of using the SMD type LED, the LED luminaire 1 having the same output can be configured with a smaller number of LEDs 40. As a result, the installation area of the LED 40 can be reduced and the size of the LED lighting fixture 1 can be suppressed as compared with the case of using the SMD type LED. Further, since the COB type LED has a smaller thermal resistance than the SMD type LED, it is not necessary to excessively improve the heat dissipation performance of the LED lighting fixture 1.

The engaging piece 43 is a member that engages with the reflector 36. The engaging piece 43 is a member of a ridge extending in the vicinity of the edge of the LED mounting substrate 34 over substantially the entire circumference of the edge, and a plurality of fitting pieces 43A are included in a part of the engaging piece 43. It is formed integrally.

On the other hand, as shown in FIG. 8C, an insertion recess 59 into which the engaging piece 43 is inserted is formed on the back surface of the reflector 36, and the LED mounting substrate 34 is formed on the back surface of the reflector 36. A plurality of fitting portions 59A to be fitted to the fitting piece 43A of the above are provided.
These fitting portions 59A are positioning portions for positioning the reflector 36 with respect to the LED mounting substrate 34, and when the fitting portion 59A is fitted to the fitting piece 43A, the reflector 36 is reflected with respect to the LED mounting substrate 34. The body 36 is positioned. In particular, in the LED luminaire 1, the optical axis K (FIG. 13) of the reflector 42 provided on the reflector 36 is accurately arranged at the center of the light emitting surface 40A of the LED 40, which is a planar light source.

In assembling the LED lighting fixture 1, after assembling the light source unit 5 by fitting the LED mounting substrate 34 and the reflector 36, the LED mounting substrate 34 of the light source unit 5 is attached to the installation surface 38 of the fixture main body 2. It may be fixed to.

FIG. 10 is a partially enlarged cross-sectional view of the LED lighting fixture 1 showing the engagement state between the LED mounting substrate 34 and the reflector 36.
As shown in the figure, the LED mounting substrate 34 reflects so that the mounting surface 34A of the LED mounting substrate 34 comes into surface contact with the back surface of the reflector 36 (that is, the surface provided with the opening 42A of the reflector 42). It is inserted into the back surface of the body 36, and the periphery of the LED 40 is closed by the opening 42A of the reflector 42. As a result, the loss of light of the LED 40 is suppressed, and the light of the LED 40 can be efficiently emitted from the reflector 42.

The surface contact between the reflector 36 and the LED mounting substrate 34 will be described in detail. In the reflector 36, a portion that comes into surface contact with the mounting surface 34A is configured as a surface contact portion 60.
On the other hand, as shown in FIG. 9, the mounting surface 34A of the LED mounting substrate 34 is provided with a heat conductive region 62 having thermal conductivity at an appropriate position avoiding the wiring pattern, and the reflector 36 is provided with a heat conductive region 62. The surface contact portion 60 makes surface contact with these heat conductive regions 62.
As a result, the heat of the LED mounting substrate 34 is transferred to the reflector 36 through the heat conductive region 62, and the temperature rise of the LED mounting substrate 34 is suppressed.
In particular, in the present embodiment, since the LED mounting substrate 34 is inserted and housed in the back surface of the reflector 36, heat is likely to be trapped between the reflector 36 and the mounting surface 34A, but this heat is transferred to the reflector. Efficient heat dissipation can be achieved by using 36.

The thermal conductive region 62 is formed by, for example, a land electrode. Further, a foil or plate made of a highly thermally conductive material such as copper or aluminum may be used for the thermally conductive region 62.

The surface contact portion 60 of the reflector 36 is formed of a material having high thermal conductivity and high heat resistance such as aluminum, and the thermal resistance between the thermal conductive region 62 of the LED mounting substrate 34 and the surface contact portion 60. Is suppressed, and heat is efficiently transferred from the heat conductive region 62 to the surface contact portion 60.

Further, on the back surface of the reflector 36, the periphery of the surface contact portion 60 is recessed more than the surface contact portion 60 so as to provide a gap between the circuit pattern of the mounting surface 34A of the LED mounting board 34 and the mounting components. (See FIG. 12), the electrical insulation between the LED mounting substrate 34 and the reflector is maintained by this gap.

Here, if the entire reflector 36 is formed of a material having high thermal conductivity and high heat resistance such as metal, the weight of the reflector 36 increases. Since a large number of reflectors 36 are provided on the LED luminaire 1, the weight of the LED luminaire 1 is also significantly increased, and in order to install the LED luminaire 1 on the existing luminaire, the luminaire is reinforced. Construction will be required.
If the entire reflector 36 is made of resin or the like, the weight increase of the reflector 36 and the LED lighting fixture 1 can be suppressed, but the heat dissipation performance of the LED mounting substrate 34 deteriorates.
Therefore, in the present embodiment, the heat dissipation performance of the LED mounting substrate 34 is improved while suppressing the increase in weight as follows.

FIG. 11 is an exploded view of the reflector 36 viewed from the front side, and FIG. 12 is an exploded view of the reflector 36 viewed from the back side.
As shown in these figures, the reflector 36 is configured to be separable in a plurality of stages (three stages in the present embodiment) in the direction of the optical axis K (FIG. 13) of the reflector 42, and is a first-stage part. It is composed of 64, a second-stage part 66, and a third-stage part 68. The first stage part 64 of these is arranged closest to the LED mounting board 34. In the present embodiment, the first stage part 64 is a part that engages with and contacts the LED mounting substrate 34, and includes an engaging structure with the LED mounting substrate 34 and a surface contact portion 60.
In the present embodiment, the first stage part 64 is made of a material having high thermal conductivity and high heat resistance such as aluminum, and the second stage part 66 and the third stage part 68 are made of a resin material such as polycarbonate. It is made of lightweight material. As a result, an increase in the amount of increase is suppressed as compared with the case where all of the reflector 36 is made of metal or the like, and the heat dissipation performance of the LED mounting substrate 34 is suppressed as compared with the case where all of the reflector 36 is made of a resin material or the like. Can be improved.

In the reflector 36, as shown in FIG. 12, a plurality of bosses 74 are provided on the back side of the third stage part 68, and are formed on the second stage part 66 and the first stage part 64. By inserting the boss 74 into the fitting insertion hole 76 (FIG. 11), these first-stage to third-stage parts 64, 66, and 68 are assembled.

In the present embodiment, the reflector 36 may be made lighter by forming the first stage part 64 with a resin material having high thermal conductivity.

Next, the reflector 42 will be described.
FIG. 13 is a cross-sectional view showing the configuration of the reflector 42 provided on the reflector 36.
The reflector 42 is a reflection type light distribution control body that converts the light of the LED 40 into so-called medium-angle parallel light. Along with the division of the reflector 36, the reflector 42 is also divided into three stages in the direction of the optical axis K. That is, the reflector 42 is formed by the first reflector portion 64A of the first stage part 64, the second reflector portion 66A of the second stage part 66, and the third reflector portion 68A of the third stage part 68. It is configured.
The light distribution of the reflector 42 can be changed by changing the number of stages thereof.

Specifically, the reflecting surface composed of both the first reflecting mirror unit 64A and the second reflecting mirror unit 66A is a radial surface that makes the light of the LED 40 arranged in the opening 42A into medium-angle parallel light. It is formed. On the other hand, the reflecting surface of only the first reflecting mirror portion 64A is formed as a parabolic surface for narrow-angle parallel light.
Therefore, when narrow-angle light distribution is required, the second stage part 66 including the second reflector unit 66A is removed, and only the first reflector unit 64A, or the first reflector unit 64A and the third reflector By forming the reflector 36 together with the portion 68A, the reflector 42 controlled at a narrow angle can be formed.

The third reflector unit 68A limits the cutoff angle α of the direct light emitted from the reflector 42, and has a predetermined length in the direction of the optical axis K from the emission opening 66A1 of the second reflector unit 66A. It constitutes a reflective surface that extends in a cylindrical shape.
More specifically, in sports lighting (particularly, ball game lighting such as baseball in which the ball is small and rises to a high position), it is possible to reduce the glare of the LED lighting fixture 1 in order to ensure the visibility of the ball. desirable. Therefore, in this reflector 42, by providing the third reflector portion 68A, the cutoff angle α is reduced as compared with the case where the third reflector portion 68A is not used, and the emission of direct light is suppressed. As a result, glare is reduced.
The reflector 42 of the present embodiment is designed to have a cutoff angle α of about 20 degrees.
Further, by using the reflector 42 as the light distribution control body of the LED 40, the diffused light is suppressed as compared with the configuration in which the light distribution is controlled by the lens, so that the glare is also reduced.

The reflector 36 may be configured by removing the third-stage part 68 including the third reflector portion 68A, depending on the purpose of lighting.

In the LED luminaire 1, even when the reflector 36 is used with the third-stage parts 68 removed, or with the second-stage and third-stage parts 66 and 68 removed, the following As described above, it can be fixed by the same reflector fixture 30. That is, as shown in FIGS. 11 and 12, each of the first to third stage parts 64, 66, and 68 constitutes the convex portion 54 (that is, from the mounting surface 34A of the LED mounting substrate 34). The first to third convex portions 64B, 66B, and 68B (protruding at the same height position) are provided. As a result, the same reflector fixture 30 can be used for fixing the reflector 36 regardless of the number of stages of the reflector 36.

By the way, when the reflector 42 includes the cylindrical third reflector portion 68A, the reflector 42 becomes deeper in the direction of the optical axis K as compared with the configuration of only the first and second reflector portions 64A and 66A. , The surface treatment for forming a reflective surface such as vacuum vapor deposition on the reflective surface tends to be uneven.
In the present embodiment, as described above, the reflector 42 is divided into a plurality of stages, and the inventors further describe the dimensions and shapes of the first to third reflectors 64A, 66A, and 68A as follows. It has been found that unevenness of surface treatment can be suppressed by setting to. That is, in each of the first to third reflectors 64A, 66A, and 68A, the angle β of the opening end F on the light incident side with respect to the opening surface E on the light emitting side is 50 degrees or less, preferably 45 degrees or less. The shape.
As a result, it is possible to perform surface treatment on the reflecting surfaces of the first to third reflecting mirror portions 64A, 66A, and 68A while suppressing unevenness, and a high-quality reflecting mirror 42 can be obtained.

Further, in the present embodiment, the size of the light emitting surface 40A of the LED 40, that is, the diameter φ1 of the opening 42A of the reflector 42 is limited to about 12 mm, and the depth of the reflector 42 controlled to the medium angle is equal to or more than a predetermined value. It is suppressed. In the present embodiment, the diameter φ2 of the opening surface E on the light emitting side of the reflecting mirror 42 is about 36 mm.

According to the above-described embodiment, the following effects are obtained.
In the LED luminaire 1 of the present embodiment, the reflector 36 is provided with a fitting portion 59A as a positioning portion that engages with the LED mounting substrate 34 and positions the reflector 42 at a predetermined position with respect to the LED 40. ing.
As a result, the reflector 42 can be positioned more accurately with respect to the LED 40 as compared with the configuration in which the reflector 36 is positioned based on the fixed position on the instrument body 2.

In the LED luminaire 1 of the present embodiment, since the LED 40 is a planar light source having a light emitting surface 40A, it is possible to increase the output and reduce the size as compared with the SMD type LED. Further, by positioning the fitting portion 59A, the optical axis of the reflecting mirror 42 can be accurately positioned at the center of the light emitting surface 40A, so that the light of the LED 40 can be accurately distributed.

In the LED luminaire 1 of the present embodiment, the mounting surface 34A of the LED mounting substrate 34 comes into contact with the surface of the reflector 36 where the opening 42A of the reflector 42 is provided (that is, the back surface of the reflector 36). It was configured. As a result, since the periphery of the LED 40 is closed by the opening 42A of the reflecting mirror 42, the loss of the light of the LED 40 is suppressed, and the light of the LED 40 can be efficiently emitted from the reflecting mirror 42.

In the LED luminaire 1 of the present embodiment, the reflector 36 is configured to include a surface contact portion 60 that is in surface contact with the heat conductive region 62 and heat is transferred from the heat conductive region 62.
As a result, the heat of the LED mounting substrate 34 can be efficiently dissipated by using the reflector.

In the LED lighting fixture 1 of the present embodiment, the surface contact portion 60 of the reflector 36 makes surface contact at a position avoiding the wiring pattern of the mounting surface 34A of the LED mounting substrate 34, so that the reflector 36 and the LED mounting substrate 34 are in surface contact with each other. Electrical insulation can be achieved.

In the LED lighting fixture 1 of the present embodiment, a plurality of fitting pieces 43A to be fitted to the positioning portion of the reflector 36 are provided on the edge portion of the LED mounting substrate 34. By fitting the reflector 36 and the LED mounting substrate 34, both the reflector 36 and the LED mounting substrate 34 are accurately positioned in a coupled state.

In the LED lighting fixture 1 of the present embodiment, the reflector 36 is composed of first-stage to third-stage parts 64, 66, 68 that can be separated in the direction of the optical axis K of the reflector 42, and the first-stage to first-stage parts are formed. At least one of the three-stage parts 64, 66, 68 is made of a different material.
As a result, various functions (for example, heat dissipation and light weight) can be added to the reflector 36 by combining the materials of each part.

In the LED lighting fixture 1 of the present embodiment, among the first to third stage parts 64, 66, 68, the first stage part 64 arranged closest to the LED mounting substrate 34 is the other second and third stage parts 64, and It is made of aluminum, which is a material having higher thermal conductivity than the third-stage parts 66 and 68, and has a configuration in which the heat of the LED mounting substrate 34 is transferred.
As a result, the heat of the LED mounting substrate 34 can be transferred to the reflector 36 to dissipate heat, and the weight of the second and third stage parts 66 and 68 can be reduced by using, for example, a resin material.

In the LED lighting fixture 1 of the present embodiment, among the first to third stage parts 64, 66, 68, the third stage part 68 is arranged farthest from the LED mounting substrate 34 along the direction of the optical axis K. The third reflector portion 68A constituting the reflector 42 is formed in a tubular shape having a predetermined length.
As a result, the cutoff angle α of the direct light emitted from the reflector 42 can be limited, and glare can be reduced.

In the LED luminaire 1 of the present embodiment, the light distribution angle of the reflector 42 is variable according to the combination of the first to third stage parts 64, 66, 68, so that the LED luminaire can be used in a wide range of applications with different light distribution. 1 can be used.

The LED lighting fixture 1 of the present embodiment includes a reflector fixture 30 that fixes each of the plurality of reflectors 36 to the fixture body 2, and the reflector fixture 30 surrounds the plurality of reflectors 36 and the fixture body. An outer frame plate 44 fixed to 2 and a plate-shaped middle plate 46 provided inside the outer frame plate 44, extending between a plurality of reflectors 36 and engaging with the reflector 36, are provided. , The plate surface of the middle plate 46 is provided parallel to the outer surface 36A of the reflector 36.
As a result, the gap between the reflectors 36 (the space for extending the middle plate 46) is narrowed, so that each of the reflectors 36 can be arranged densely, and the LED lighting fixture 1 can be miniaturized.

In the LED lighting fixture 1 of the present embodiment, since the outer frame plate 44 has a plate shape in which the plate surface is provided parallel to the outer surface 36A of the reflector 36, a plurality of reflector fixtures 30 are arranged side by side. In this case, the gap between the reflectors 36 pressed by the different reflector fixtures 30 (the space for extending the outer frame plate 44) is also narrowed. Therefore, even when the number of reflectors 36 included in the LED lighting fixture 1 is large, these reflectors 36 can be fixed in a densely arranged state by using an appropriate number of reflector fixtures 30.

In the LED lighting fixture 1 of the present embodiment, a convex portion 54 pressed against the fixture main body 2 by the middle plate 46 is formed on the outer surface 36A of the reflector 36. As a result, since the plurality of reflectors 36 are pressed and fixed to the instrument body 2, no space for screwing is required around the individual reflectors 36, and the respective reflectors 36 can be densely arranged. ..

In the LED lighting fixture 1 of the present embodiment, the reflector 36 is composed of first-stage to third-stage parts 64, 66, 68 which can be separated in the direction of the optical axis K of the reflector 42. The light distribution angle of the reflector 42 can be changed according to the combination of the first to third stage parts 64, 66, 68, and the first to third stage parts 64, 66, 68. Each of the above is provided with a convex portion 54 at the same height position from the LED mounting substrate 34.
As a result, the same reflector fixture 30 can be used for fixing the reflector 36 regardless of the combination of the first-stage to third-stage parts 64, 66, 68.

It should be noted that the above-described embodiment is merely an example of one aspect of the present invention, and can be arbitrarily modified and applied without departing from the gist of the present invention.

Although floodlighting has been illustrated as an example of a luminaire, the present invention can be applied to any luminaire provided with a light emitting element and a reflector having a reflector for controlling the light of the light emitting element.

Further, although the LED 40 is illustrated as an example of the light emitting element, another light emitting element such as an organic EL may be used.
By combining light emitting elements having different light emitting colors in a lighting fixture, so-called full-color lighting may be enabled. As the light emitting element, a blue LED and a phosphor are provided, and a light emitting element that outputs red, green, and blue light can also be used by making the phosphor different.
When configuring a lighting fixture that performs full-color lighting, it is desirable to provide a control mechanism that controls the output of each color and suppresses color unevenness.

1 LED lighting equipment (lighting equipment)
2 Instrument body 5 Light source unit 6 Heat dissipation part 7 Exit opening 9 Front cover 28 Front cover fixing bracket 28A Fixing piece 28B Auxiliary reflector 30 Reflector fixture 34 LED mounting board (mounting board)
34A mounting surface 36 reflector 36A outer surface 40 LED (light emitting element)
40A light emitting surface 42 reflector 42A opening 43 engaging piece 43A fitting piece 44 outer frame plate (outer frame member)
46 Middle plate 48 Screw-on plate 54 Convex part 59 Insertion recess 59A Fitting part (positioning part)
60 Surface contact part 62 Thermal conductivity area 64, 66, 68 1st to 3rd stage parts 64A, 66A, 68A 1st to 3rd reflector parts 64B, 66B, 68B 1st to 3rd convex parts 66A1 Exit opening E Aperture surface F Aperture end K Optical axis d1 Plate thickness α Cutoff angle β angle

Claims (4)

A mounting board on which multiple light emitting elements are mounted and
In a lighting fixture in which a plurality of reflectors having a reflector for controlling the light of the light emitting element are housed in the fixture body.
A reflector fixture for fixing each of the plurality of reflectors to the instrument body is provided.
The reflector fixture is
An outer frame member that surrounds the plurality of reflectors and is fixed to the instrument body,
A plate-shaped middle plate provided inside the outer frame member, extending between the plurality of reflectors, and engaging with the reflectors is provided.
A lighting fixture characterized in that the plate surface of the middle plate is provided parallel to the outer surface of the reflector. The lighting fixture according to claim 1, wherein the outer frame member has a plate shape in which the plate surface is provided parallel to the outer surface of the reflector. The lighting fixture according to claim 1 or 2, wherein a convex portion pressed against the fixture main body by the middle plate is formed on the outer surface of the reflector. The reflector is
It is configured so that it can be separated into a plurality of parts in the optical axis direction of the reflecting mirror, and the light distribution angle of the reflecting mirror can be changed according to the combination of the plurality of the parts.
Each of the plurality of parts is provided with the convex portion at the same height position from the mounting board.
The lighting equipment according to claim 3.

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