JPH03203107A - Lighting apparatus - Google Patents

Abstract

PURPOSE:To prevent an increase in temperature of a lamp body and miniaturize the lamp body by providing an optical multilayered film which reflects infrared rays and permeates visible lights on a lamp bulb surface, and forming the lamp body by a polyamide resin having a heat conductive filler mixed therein. CONSTITUTION:When a lamp 17 is lighted, among the lights radiated from a filament 20, visible lights are permeated through an optical multilayered film provided on the surface of a bulb 19, reflected by the reflecting surface 33 of a lamp body 6, and radiated from a lighting opening 7. On the other hand, infrared rays are reflected into the lamp 17 by the optical multilayered film on the surface of the bulb 19, and their radiation out of the lamp 17 is prevented to some extent. Although the reduced infrared rays emitted to the reflecting surface 33 from the lamp 17 heats the lamp body 6, this heat is rapidly moved and released out of the lamp body 6 due to the high heat conductivity of the lamp body 6 having a heat conductive filler charged therein, and thus an increase in temperature of the lamp body 6 is prevented.

Description

[Detailed Description of the Invention] [Object of the Invention] (Industrial Application Field) The present invention relates to lighting equipment such as spotlights or downlights, and is suitable for use in indoor flood lighting devices such as stores or residences. Concerning what can be done.

(Prior Art) Conventionally, lighting fixtures such as spotlights are known that use, for example, a halogen lamp as a light source and reflect light from the lamp by a reflective surface of a reflector plate. and,
In conventional lighting equipment of this type, the lamp bulb was simply made of glass, and was structured to transmit not only visible light but also infrared rays. Conventionally, in lighting equipment such as spotlights in which the reflective plate and the like are made of plastic, a structure has been adopted in which the reflective plate and the like are made of a thermosetting resin or a resin mixed with glass fiber.

(Problem to be solved by the invention) However, with the above conventional structure, especially when a halogen lamp with a large amount of infrared radiation is used as a light source, the infrared rays emitted from the tungsten filament pass through the bulb and are directed to the reflector. As a result, this reflector is roasted and becomes hot. Therefore, the reflector is required to have a large heat capacity and high heat resistance, and when the reflector is made of plastic, even if it is made of thermosetting resin or resin mixed with glass fiber, the shape of the reflector due to temperature changes. This poses a problem in that it is difficult to miniaturize the reflector. Moreover, in combination with the high output of infrared rays, the thermal conductivity of plastic is poor, so heat tends to get trapped inside the plastic reflector, making it even more difficult to downsize the reflector and increase the output of the lamp. It had become a thing.

The present invention has been made in view of the above-mentioned problems, and can prevent a lamp body having a reflective surface from heating up, and can reduce the size of a lamp body even if it is made of plastic. The object of the present invention is to provide a lighting device that can increase the output of a lamp.

[Structure of the invention]

(Means for Solving the Problems) The lighting equipment of the present invention includes a lamp such as a halogen lamp,
In order to achieve the above object, the lamp is equipped with a lamp body having a reflective surface facing the lamp and having an irradiation opening formed in the front surface.
The lamp has a cloudy optical multilayer film formed on the bulb surface that reflects infrared rays and transmits visible light, and the lamp body is made of polyamide resin mixed with a thermally conductive filler such as magnesium oxide or aluminum nitride. This is what I did.

(Function) In the lighting device of the present invention, visible light among the light emitted from the filament in the lamp passes through the optical multilayer film on the bulb surface of the lamp and reaches the reflective surface of the lamp body facing the lamp. It is reflected and emitted from the illumination aperture at the front of the lamp body. On the other hand, most of the infrared rays are reflected into the lamp by the optical multilayer film on the bulb surface, and radiation to the outside of the lamp is prevented to some extent.

In addition, the attenuated infrared rays emitted from the lamp to the reflective surface heat the lamp body, but this heat is absorbed because the lamp body is made of polyamide resin mixed with a thermally conductive filler. , it moves quickly and is emitted outside the lamp. In this way, infrared rays transmitted from the lamp to the lighting body are reduced, and heat is dissipated quickly.
Temperature rise in the lamp body, especially at the reflective surface portion, is reduced, the output of the lamp is high, and even if the lamp body is made of a small plastic cutout, the lamp body does not suffer from black damage.

(Example) The configuration of an example of the lighting fixture of the present invention will be described with reference to the drawings. The lighting fixture in this example is a spotlight.

In FIG. 1, 1 is an instrument main body, and this instrument main body I is:
It is made of plastic, for example, and consists of a substantially cylindrical shade part 2 with both front and rear end surfaces open, and a lamp body support part 3 integrally formed radially on the rear surface of the shade part 2.

Reference numeral 6 denotes a lamp body, and the lamp body 6 is integrally formed with a reflecting plate part 8 which has a substantially hemispherical shape and has a lower irradiation amount on the front surface, and which projects rearward from the center of the rear end of this reflecting plate part 8. It consists of a roughly cylindrical socket receptacle (1 part 9). A plurality of locking grooves 10 extending in the axial direction of the outer peripheral surface are formed on the outer peripheral surface of this socket mounting portion 9, which has a front end surface open and a rear end surface closed. The inner tip portions of each lamp support portion 3 of the fixture body 1 are engaged with each other.

As a result, the lamp body 6 is attached to the appliance body 1 with the reflector part 8 covered by the shade part 2 of the appliance body 1. The lamp body 6 has a support shaft 12 attached to the tip of a support 11 that is attached to a structure such as a ceiling surface at the rear of the socket attachment part 9 that protrudes rearward from the appliance body 1.
It is installed so that its orientation can be adjusted.

The lamp body 6 is made of polyamide resin mixed with a thermally conductive filler such as magnesium oxide (MgO1 or aluminum nitride (AIN)).Specifically, for example, MgO It is a resin filled with 70 to 80% filler.

Further, a lamp socket 16 is held in the socket mounting portion 9 of the lamp body 6, and this lamp socket 16
A lamp 17 such as a halogen lamp that serves as a light source is installed on the front side of the
is installed. This lamp 17 contained in the lamp body 6 has a cap 18 attached to the lamp socket 16.
It consists of a bulb 19 made of translucent glass or the like fixed to this base 18, and a tungsten filament 20 built into this bulb 19. The bulb 19 is opposed to the inner surface of the reflector portion 8 of the lamp body 6.

Note that a stepped portion 21 is formed in the lamp body 6 between the reflecting plate portion 8 and the socket mounting portion 9. And this stepped part 2
1, an annular heat shielding partition plate 2 made of aluminum or the like;
2 are fitted and fixed with a ring spring 23,
The bulb 19 of the lamp 17 projects forward from a lamp insertion hole 24 formed in the center of the partition plate 22.

As shown in FIG. 3, the reflective plate portion 8 of the lamp body 6 has an undercoating 32 applied to the inner surface of a base body 31 made of plastic, and a reflective surface is formed on the surface of the undercoating 32. A light reflective film layer 33 made of aluminum or the like is formed, and a light-transmitting coating layer 34 made of silicon oxide (SiL) or the like is formed on the surface of this reflection film layer 33.

Further, as shown in FIG. 2, the bulb 19 of the lamp 17 has an optical multilayer film 42, which is a light selective reflection function film, formed on the outer surface of a base body 41 made of glass. This optical multilayer film 42 includes, for example, a low refractive index film layer 43 made of a low refractive index material such as silicon oxide (Si(h)), and a high refractive index film layer made of a high refractive index material such as titanium oxide (TiO2). 44 are alternately laminated, and transmit light having a wavelength shorter than a certain wavelength due to interference, reflect infrared rays, and transmit visible light.

Next, the operation of this embodiment will be explained.

When the lamp 17, which is the light source of a spotlight attached to the ceiling of a structure, is turned on, the visible light emitted from the filament 20 in the lamp 17 is as shown by the arrow in the figure. Visible light passes through the transparent optical multilayer film 42 on the surface of the bulb 19 of the lamp 17 and is reflected by the reflective film layer 33 of the lamp body 6, and the desired amount of radiation from the front surface of the lamp body n7 is transmitted. It is radiated in the direction of. On the other hand, most of the infrared rays unnecessary for illumination are reflected into the lamp 17 by the optical multilayer film 42 on the surface of the bulb 19.
A certain amount of radiation to the outside is 1L. Much of the infrared radiation reflected into the lamp 17 returns to the filament 2o and is absorbed. Further, the attenuated infrared rays emitted from the lamp 17 to the reflective surface heat the lamp body 6, but this heat is absorbed by the thermal conductivity of the lamp body 6 filled with a thermally conductive filler. Due to its height, it moves quickly and is emitted outside the lamp body 6.

In this way, the infrared rays transmitted from the lamp 17 to the lamp body 6, particularly its reflection plate portion 8, are reduced, and the heat is quickly dissipated, thereby preventing the temperature of the reflection plate portion 8 of the lamp body 6 from rising. It will be IL.

Therefore, even if the lamp body 6 is made of small plastic, the lamp body 6 will not be blackened, will be safe, and will have improved durability. Of course, black damage to the instrument body 1 can also be prevented. That is, for example, even if the light source is a halogen lamp 17 that emits a large amount of infrared radiation, the temperature of the lamp body 6 can be reduced, and even a lamp body 6 having a shape that was previously difficult can be made of plastic. The lamp body 6 made of plastic can be made smaller than before. Along with this, it is also possible to increase the output of the lamp 17.

In addition, in the above embodiment, the reflector part 8 and the socket mounting part 9
Although the light body 6 is formed as an integrated lamp body 6, the reflecting plate portion and the socket mounting portion may be separate bodies.

Further, in the above embodiment, the optical multilayer film 42 was formed on the surface of the bulb 19 of the lamp 17, but the optical multilayer film may be formed on the back surface of the bulb.

Furthermore, the lamp is not limited to a halogen lamp, and may be a high-intensity discharge lamp or the like.

〔Effect of the invention〕

According to the present invention, an optical multilayer film that reflects infrared rays and transmits visible light is formed on the bulb surface of the lamp facing the reflective surface of the lamp body, and the lamp body is made of polyamide mixed with a thermally conductive filler. Since it is made of resin, it is difficult for infrared rays to be transmitted to the lamp body, and the lamp body that is heated by infrared rays radiates heat quickly, which prevents the lamp body with a reflective surface from becoming hot. In addition to improving durability, the degree of freedom in the shape of this lamp increases, making it possible to downsize the lamp and also increase the output of the lamp, even if the lamp is made of plastic. become.

[Brief explanation of drawings]

FIG. 1 is a sectional view of a lighting fixture showing an embodiment of the present invention, FIG. 2 is an enlarged sectional view of a portion of the lamp, and FIG. 3 is an enlarged sectional view of a portion of the reflector of the lamp. It is. 6. Lamp body, 7. Irradiation aperture, 17. Lamp, 19.
- Bulb, 33... Light reflective film layer forming a reflective surface, 42...
Optical multilayer film. 37-

Claims (1)

[Claims] (1) Comprising a lamp and a lamp body having a reflective surface facing the lamp and having an irradiation opening formed in the front surface, the lamp having an optical multilayer film on the bulb surface that reflects infrared rays and transmits visible light. A lighting equipment, wherein the lamp body is formed of a polyamide resin mixed with a thermally conductive filler.