JP6721862B2 - Lighting equipment - Google Patents

Description

Embodiments of the present invention relate to a lighting device using a plurality of light sources and a plurality of reflectors.

2. Description of the Related Art Conventionally, a lighting device used in, for example, a stadium or a sports facility is installed far away from the lighting area, and illuminates the lighting area from a distance, so that a projector with high output and a narrow light distribution angle is used. Has been.

Even in such an illuminating device, a light source using a light emitting element is adopted. In this illuminating device, a plurality of light sources are arranged in the main body to secure a desired luminous flux, and a plurality of reflectors are arranged to control the light distribution angles of the light emitted from these light sources. ing.

It is known that the luminous efficiency of the light source is better as the size of the light emitting surface of the light source is larger. However, if the size of the light emitting surface of the light source is increased, the aperture diameter of the reflector is also increased, so that the lamp body in which the plurality of reflectors are arranged becomes large. If the number of light sources and reflectors provided in the lamp body is reduced in order to prevent the lamp body from becoming large in size, a desired luminous flux cannot be secured.

Further, there is an illuminating device in which a lens is combined with a reflector or only the lens is used to narrow the light distribution angle. However, when a lens is used, the amount of light leaking to areas other than the illumination area increases, and the illumination rate to the illumination area decreases.

JP, 2005-146233, A

The problem to be solved by the present invention is to provide an illuminating device capable of increasing the illumination rate to the illumination area while suppressing the size increase of the lamp body and securing the luminous flux.

The lighting device of the embodiment includes a lamp body, a plurality of light sources, and a light control unit. The lamp body has an irradiation opening. The light source has a light emitting surface and is disposed inside the lamp body so as to face the irradiation opening. Light control unit, each circular cylindrical, perforated with are formed on parabolic shape widened toward the irradiation opening from the entrance opening facing the light emitting surface, the opening diameter is at least two different reflector However, a reflector with a large opening diameter is arranged in the peripheral area of the irradiation opening, a reflector with a small opening diameter is arranged in the central area of the irradiation opening, and the light emitted from the reflector with a large opening diameter is The beam angle is smaller than the beam angle of the light emitted from the reflector having a small aperture diameter, and these reflectors are arranged in front of the light emitting surface of the light source.

ADVANTAGE OF THE INVENTION According to this invention, it can be expected to increase the illumination rate to the illumination area while suppressing the enlargement of the lamp body and securing the light flux.

It is a front view of the illuminating device which shows one Embodiment. It is a perspective view of an illuminating device same as the above. It is sectional drawing of an illuminating device same as the above. It is a perspective view of the light source of the above-mentioned lighting device.

Hereinafter, one embodiment will be described with reference to FIGS. 1 to 4.

1 to 3 show a floodlight as the lighting device 10. The lighting device 10 includes a lamp body 11, a support body 12 that supports the lamp body 11, and a power supply unit (not shown) for supplying power to the lamp body 11 (light source).

The lamp body 11 includes a main body 15, a light source unit 16 arranged on the rear side of the main body 15, and a light control unit 17 arranged on the front side of the main body 15.

The main body 15 is formed of, for example, a metal material in an annular shape that opens in the front and rear. At the bottom of the main body 15, a wiring box portion 18 in which a power supply cable from a power supply unit is wired is provided.

Further, the light source unit 16 includes a plurality of light sources 20 and a radiator 21 in which the light sources 20 are arranged.

As shown in FIG. 4, the light source 20 is composed of a COB (Chip On Board) module. The light source (COB module) 20 includes a substrate 23, a plurality of light emitting elements (LEDs) 24 mounted on the substrate 23, and a sealing resin 25 containing a phosphor that seals the light emitting elements 24. .. An annular frame-shaped portion 26 is provided on the substrate 23 around the mounting region of the light emitting element 24, and the sealing resin 25 is filled inside the frame-shaped portion 26. The surface of the sealing resin 25 is the light emitting surface 27 of the light emitting portion that emits light, and the light emitting surface 27 is circular and has a predetermined diameter D1.

As shown in FIG. 3, the light source 20 is attached to the front surface of the radiator 21 by the light source holder 28. The light source holder 28 includes a front side holder 29 and a rear side holder 30 that sandwich the substrate 23 from the front and rear, and the front side holder 29 and the rear side holder 30 are held in a sandwiched state by a mounting bracket 31 and are placed on the front surface of the radiator 21. It is installed. A circular light emitting opening 32 is formed in the front holder 29 so as to face the light emitting surface 27 and expand toward the front. The light source holder 28 is provided with a terminal structure that is electrically connected to the substrate 23 and also electrically connects a feeder line that is wired between the light source holder 28 and the wiring box portion 18.

In the present embodiment, six light sources 20 are used, and the five light sources 20 are arranged at equal intervals along the circumferential direction in the peripheral area of the front surface of the radiator 21 (the peripheral area within the irradiation opening 60 of the lamp 11). Then, one light source 20 is arranged in the central area of the front surface of the radiator 21 (the central area within the irradiation opening 60 of the lamp body 11). The same light source 20 is used, that is, the light emitting surface 27 has the same size (diameter D1). In the COB module that is the light source 20, the larger the diameter D1 of the light emitting surface 27 is, the higher the light emission efficiency is. Therefore, it is preferable to use the light emitting surface 27 having the large diameter D1.

The radiator 21 is made of, for example, a metal material. The heat radiator 21 includes a flat plate-shaped base 34 and a plurality of heat radiation fins 35 protruding from the back surface of the base 34. A plurality of light sources 20 are attached to the front surface of the base 34. The radiating fins 35 are arranged along the vertical direction, and a gap is provided between the radiating fins 35 to allow air to flow in the vertical direction. Then, the base 34 is fitted to the rear side of the main body 15 via the packing, and the radiator 21 is fixed to the main body 15 by bolting.

The light control unit 17 also includes a light control section 37, a case 38 that accommodates the light control section 37, and a translucent cover 39 that covers the front surface of the case 38.

The light control unit 37 includes a plurality of reflectors 41 corresponding to each of the light sources 20 and used for light distribution control, and a reflector holder 42 that integrally holds the reflectors 41.

The reflector 41 is made of, for example, a metal material. The reflector 41 has a cylindrical shape that opens in the front-rear direction and is formed in a parabolic shape that expands from the rear side toward the front side. An entrance opening 43 is formed on the rear end side of the reflector 41 so as to face the light emitting surface 27 of the light source 20, and light is exited on the front end side of the reflector 41. ..

On the inner surface of the reflector 41, a reflecting surface 45 formed by a parabolic surface that widens from the rear side to the front side is formed. On this reflecting surface 45, a reflection enhancing film 46 in which a high refractive index film (TiO ₂ ) and a low refractive index film (SiO ₂ ) are laminated is formed. The enhanced reflection film 46 has a high reflection efficiency of reflecting 90% or more (preferably 94% or more) of visible light.

The reflector 41 is divided into a rear entrance-side reflector 47 having an entrance opening 43 and a front exit-side reflector 48 having an exit opening 44, which are integrally combined. A fitting portion 49 is formed at the front end of the incident side reflector 47 to fit the rear end of the exit side reflector 48. A plurality of connecting holes are formed in the fitting portion between the front end (fitting portion 49) of the incident side reflector 47 and the rear end of the outgoing side reflector 48, respectively. The incident-side reflector 47 and the emission-side reflector 48 are coupled by a plurality of coupling members 50 which are mounted in these coupling holes from the inside of the emission-side reflector 48. A flange portion 51 attached to the reflector holder 42 is provided on the outer periphery of the front end of the incident side reflector 47. In a state in which the incident side reflector 47 and the emission side reflector 48 are combined, the reflection surface 45 of the incidence side reflector 47 and the reflection surface 45 of the emission side reflector 48 are configured as a continuous parabolic surface. The reflector 41 may be formed integrally with the incident side reflector 47 and the emission side reflector 48 without being divided.

As the reflector 41, at least two types of reflectors 41 having the same dimension in the front-rear direction but different opening diameters are used. In this embodiment, two types of reflectors 41a having a large aperture diameter (hereinafter referred to as a large aperture diameter reflector) 41a and a reflector having a small aperture diameter (hereinafter referred to as a small aperture diameter reflector) 41b are used. This opening diameter means the exit opening diameter of the exit opening 44.

If the entrance aperture diameter of the entrance aperture 43 of the large aperture reflector 41a is D2a and the exit aperture diameter of the exit aperture 44 is D3a, the entrance aperture diameter D2a is larger than the diameter D1 of the light emitting surface 27, and the exit aperture diameter D3a is the entrance aperture diameter D3a. The relationship is larger than the diameter D2a. The large aperture reflector 41a has, for example, an emission aperture diameter D3a of 164 mm, a 1/10 beam angle of 29.4°, and a 30° efficiency of 79.1.

When the entrance aperture diameter of the entrance aperture 43 of the small aperture reflector 41b is D2b and the exit aperture diameter of the exit aperture 44 is D3b, the entrance aperture diameter D2b is larger than the diameter D1 of the light emitting surface 27, and the exit aperture diameter D3b is incident. The relationship is larger than the opening diameter D2a. The small aperture reflector 41b has, for example, an exit aperture diameter D3b of 140 mm, a 1/10 beam angle of 32.7°, and a 30° efficiency of 83.9.

The entrance aperture diameter D2a of the large aperture reflector 41a is larger than the entrance aperture diameter D2b of the small aperture reflector 41b, and the exit aperture diameter D3a of the large aperture reflector 41a is larger than the exit aperture diameter D3b of the small aperture reflector 41b. It's getting bigger. That is, the large-aperture-diameter reflector 41a has a larger overall diameter (aperture diameter) than the small-aperture-diameter reflector 41b.

The reflector holder 42 includes a disc-shaped attachment plate 53 attached to the case 38, a disc-shaped support plate 54 that supports the plurality of reflectors 41, and a plurality of not-shown coupling plates 54 that connect the support plate 54 to the attachment plate 53. Equipped with a rod. The mounting plate 53 and the support plate 54 are respectively formed with a plurality of insertion holes 55 and 56 through which the rear side of the reflector 41 is inserted. The flange portion 51 of the reflector 41 inserted into the insertion hole 56 is attached to the support plate 54.

Then, each reflector 41 is arranged in front of each light source 20. In the present embodiment, five large aperture reflectors 41a are arranged in front of the five light sources 20 arranged in the peripheral area of the front surface of the radiator 21 (the peripheral area inside the irradiation opening 60 of the lamp 11). One small aperture reflector 41b is arranged in front of one light source 20 arranged in the central area of the front surface of the radiator 21 (the central area within the irradiation opening 60 of the lamp 11).

The case 38 of the light control unit 17 is made of, for example, a metal material, and is formed into a cylindrical shape that opens in the front and rear and expands from the rear side to the front side. At the rear end of the case 38, a mounting portion 59 that is bolted to the front surface of the main body 15 together with the mounting plate 53 is formed. A circular irradiation opening 60 is formed inside the case 38. The radius of the inner peripheral surface of the case 38 is substantially equal to the sum of the radius of the outer peripheral surface of the small aperture reflector 41b and the diameter of the outer peripheral surface of the large aperture reflector 41a.

The light-transmitting cover 39 of the light control unit 17 is made of, for example, transparent glass and is formed into a disc shape. The peripheral portion of the translucent cover 39 is arranged at the front end of the case 38 via the seal material 62, and the translucent cover 39 is fixed to the front end of the case 38 by caulking the front end of the case 38.

In addition, the support body 12 rotatably supports the lamp body 11 and installs the lamp body 11 on an installed portion such as a structure. The support body 12 includes an installation portion 64 and a pair of arm portions 65 bent from both sides of the installation portion 64. The installation unit 64 is fixed to a building or the like with bolts or the like. The tip of the arm portion 65 is rotatably connected to a shaft member protruding from both sides of the main body 15, and rotatably supports the lamp body 11 including the main body 15 around the shaft member. The arm portion 65 is provided with a handle 66 for fastening and fixing the lamp body 11 to the arm portion 65. Then, by loosening the handle 66, the lamp body 11 can be rotated with respect to the arm portion 65, and the light irradiation direction from the lamp body 11 can be adjusted.

Then, in the illumination device 10 configured as described above, when power is supplied to each light source 20 from the power supply unit, each light source 20 emits light, and the light emitted from the light emitting surface 27 of each light source 20 is reflected by the reflector 41. Light that is incident on the inside and the light distribution of which is controlled by each reflector 41 passes through the translucent cover 39 and is applied to a predetermined illumination area.

Further, in the COB module used for the light source 20, the larger the diameter D1 of the light emitting surface 27 is, the higher the light emitting efficiency is. Therefore, in order to improve the fixture efficiency of the lighting device 10, the diameter D1 of the light emitting surface 27 is large. Is preferably used. However, when the diameter D1 of the light emitting surface 27 increases, the light distribution angle tends to widen.

There are projectors that use a lens to narrow the light distribution angle, but when the lens surface shines, the amount of leakage light to areas other than the illumination area to be illuminated increases, and the illumination ratio (light source 20 Of all the light fluxes that reach the illumination area).

It is preferable to use only the reflector 41 without using a lens in order to reduce the amount of leaked light and increase the illumination rate to the illumination area, but it is necessary to use the reflector 41 having a large aperture diameter to narrow the light distribution angle. There is.

In the illumination device 10 of the present embodiment, by using the light source 20 having a large diameter D1 of the light emitting surface 27 and the large aperture reflector 41a having a large aperture diameter in combination, the light distribution angle can be narrowed and the fixture The efficiency (the ratio of the light flux radiated to the outside of the device to the total light flux of the light source 20) is high, and the illumination rate to the illumination area can be increased.

If the large aperture reflectors 41a are used for all the reflectors 41 arranged in the lamp body 11, that is, the reflectors 41 arranged in the central area of the lamp body 11 are also provided with the large aperture reflectors 41a. If it is used, it is necessary to increase the outer diameter of the lamp body 11, and the lighting device 10 becomes large. Further, in order to prevent the outer diameter of the lamp body 11 from increasing, when the light source 20 and the reflector 41 are not arranged in the central region of the lamp body 11, it is possible to secure the luminous flux necessary for the lighting device 10. Sometimes you can't.

In the lighting device 10 of the present embodiment, by arranging the light source 20 and the small-diameter reflector 41b in the central region of the lamp body 11, the lighting device 10 is suppressed while suppressing an increase in the outer diameter of the lamp body 11. The necessary luminous flux can be secured.

Then, according to the illumination device 10 of the present embodiment, by using the two types of reflectors 41 having different opening diameters, that is, by using the large aperture diameter reflector 41a and the small aperture diameter reflector 41b, It is possible to increase the illumination rate to the illumination area while suppressing the size increase and securing the light flux.

In addition, the light sources 20 in the lamp body 11 have the same light emitting surface 27, that is, the same light source 20 is used, so that the light source 20 is shared and the manufacturability of the lighting device 10 is improved. can do.

The light source 20 combined with the small aperture reflector 41b may have a small light emitting surface 27. In this case, the light distribution angle can be narrowed even with the small aperture reflector 41b.

Further, since the number of the large-diameter reflectors 41a in the lamp body 11 is larger than the number of the small-aperture reflectors 41b, the lighting device 10 as a whole can have a narrow light distribution angle and high fixture efficiency.

Further, by disposing a plurality of large aperture diameter reflectors 41a in the peripheral area of the irradiation opening 60 of the lamp body 11 and by disposing a small aperture diameter reflector 41b in the central area, a lamp body of a limited size. A plurality of large aperture reflectors 41a and a plurality of small aperture reflectors 41b can be efficiently and effectively arranged within 11. That is, the small aperture reflector 41b can be disposed by effectively utilizing the dead space formed between the plurality of large aperture reflectors 41a arranged in the peripheral area of the irradiation opening 60 of the lamp body 11. ..

Then, the radius of the inner peripheral surface of the case 38 accommodating the plurality of large-aperture reflectors 41a and the small-aperture reflector 41b is equal to the radius of the outer peripheral surface of the small-aperture reflector 41b and the outer peripheral surface of the large-aperture reflector 41a. This is substantially equivalent to the dimension obtained by adding the diameter, and a plurality of large aperture diameter reflectors 41a and small aperture diameter reflectors 41b can be efficiently and effectively arranged in the lamp body 11.

Moreover, by disposing a plurality of large aperture diameter reflectors 41a in the peripheral area of the irradiation opening 60 of the lamp body 11 and arranging a small aperture diameter reflector 41b in the central area, the distribution by the small aperture diameter reflectors 41b is made. Even if the light angle is wider than the light distribution angle of the large aperture reflector 41a, it is possible to reduce the influence on the light distribution of the entire illumination device 10.

Further, since the reflection surface 45 of the reflector 41 is formed with the reflection increasing film 46 having high reflection efficiency in which a high refraction film and a low refraction film are laminated, the fixture efficiency of the lighting device 10 is increased, and The spread of light distribution is small and the light distribution angle can be narrowed.

Further, since the reflector 41 is made of a metal material, deterioration can be prevented even if the light energy of the light source 20 is large.

In addition, it is possible to efficiently and effectively use the inside of the lamp body 11 by disposing five large aperture diameter reflectors 41a in the peripheral area of the lamp body 11 and one small aperture diameter reflector 41b in the central area. The large-diameter reflectors 41a can be provided in accordance with the output type of the lighting device 10. For example, six or more or four or less large-diameter reflectors 41a are provided in the peripheral area. Good.

Further, the small aperture diameter reflector 41b may be arranged in the peripheral area of the lamp body 11. Further, a plurality of small aperture diameter reflectors 41b may be arranged in the peripheral region of the lamp body 11 and a large aperture diameter reflector 41a may be arranged in the central region.

Further, the number of types of the reflectors 41 having different aperture diameters may be three or more. By combining a plurality of types of reflectors 41, they can be efficiently arranged in the lamp body 11.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the scope of equivalents thereof.

10 lighting equipment
11 lights
20 light sources
27 Light emitting surface
37 Light control unit
41 reflector
43 entrance aperture
46 Reflective film
60 irradiation opening

Claims (4)

A lamp having an irradiation opening;
A plurality of light sources having a light emitting surface and arranged in the lamp body so as to face the irradiation opening;
In each circular cylindrical, said with the entrance opening facing the light emitting surface is formed on the paraboloid which widens toward the irradiation opening, having an at least two different reflector aperture diameter, the The reflector having the large opening diameter is arranged in the peripheral area in the irradiation opening, the reflector having the small opening diameter is arranged in the central area in the irradiation opening, and the reflector having the large opening diameter is The beam angle of the emitted light is smaller than the beam angle of the light emitted from the reflector having the small aperture diameter, and these reflectors are arranged in front of the light emitting surface of the light source. Control unit;
An illuminating device comprising: The lighting device according to claim 1, wherein the light emitting surfaces of the plurality of light sources have the same size. The lighting device according to claim 1 or 2, wherein the number of the reflectors having the large opening diameter is larger than the number of the reflectors having the small opening diameter . The lighting device according to any one of claims 1 to 3 , wherein the reflector has an increased reflection film in which a high refractive film and a low refractive film are laminated.

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