JPH11144511A - Shield beam type lamp device - Google Patents

Abstract

(57) [Problem] To provide a shield beam type lamp device which has a small change in color temperature of a lamp and a long service life even when the lamp is operated for a long time. SOLUTION: Light emitting tube 11 made of translucent alumina ceramic
A metal halide lamp 10 in which at least an alkali metal halide is sealed in a light-emitting space surrounding portion 12; and a sealed envelope 20 for accommodating the metal halide lamp 10 in a vacuum internal space S. Further, in a shield beam type lamp device in which a metal light reflecting film 21 for reflecting light from the metal halide lamp 10 is formed, the total area of the light reflecting surfaces in the sealed envelope 20 is SM (cm ² ), Assuming that the area of the outer surface of the luminous space surrounding portion 12 of the luminous tube 11 in SL 10 is SL (cm ² ) and the rated lamp power of the metal halide lamp 10 is PW (W), the following expression (1) is satisfied. Formula (1) (PW × SM) / SL ≦ 7900

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a shield beam type lamp device used as, for example, a light source for general illumination, and more particularly to a shield beam type lamp device provided with a metal halide lamp having an arc tube made of translucent alumina ceramic. About.

[0002]

2. Description of the Related Art In general, a metal halide lamp can be configured to have a high light emission efficiency, a small size, a high color temperature and a good color rendering property. It is suitable as a light source for indoor or outdoor illumination, and other light sources for general illumination. However, in the metal halide lamp, the state of the color temperature at the time of lighting is easily affected by the ambient temperature. Therefore, when a metal halide lamp is used as a light source for general illumination, a sealed beam type lamp device in which the metal halide lamp is housed in a sealed envelope having a metal light reflecting film formed on the inner surface is used. ing.

[0003] As the arc tube of a metal halide lamp, a tube made of quartz glass has conventionally been used. However, when an alkali metal halide such as lithium halide or sodium halide is used as the light-emitting substance, the mobility of the alkali metal ion with respect to the quartz glass is large. Leaks to the outside through the arc tube, and as a result, the composition of the luminescent substance in the arc tube changes, resulting in a change in the color temperature of the lamp and an excessive proportion of the halogen component, making it difficult to turn on the lamp. Or For these reasons, there is a problem that a long service life cannot be obtained in a metal halide lamp in which an alkali metal halide is sealed.

On the other hand, recently, translucent ceramics have begun to be used as a material for forming an arc tube of a discharge lamp. For example, Japanese Unexamined Patent Publication Nos. 8-102299 and 8-236076 disclose translucent ceramics. There is disclosed a shield beam type lamp device provided with a discharge lamp having an arc tube made of conductive ceramic. Since the translucent ceramic has a lower mobility of alkali metal ions than quartz glass, the metal halide lamp having the translucent ceramic arc tube has a long service life.

[0005] However, it has been found that the following problems arise when a shield beam type lamp device is constructed using such a metal halide lamp. When the light from the metal halide lamp is applied to the metal light reflection film of the sealed envelope, photoelectrons are emitted from the metal light reflection film. When the photoelectrons adhere to and accumulate on the outer surface of the arc tube of the metal halide lamp, an electric field is generated on the tube wall of the arc tube, and this electric field makes it easier for alkali metal ions to move with respect to the arc tube. . As a result, as the lighting time elapses, the alkali metal ions leak to the outside via the arc tube, and as a result, the color temperature of the lamp changes. As a result, a long service life of the lamp cannot be obtained.

[0006]

DISCLOSURE OF THE INVENTION The present invention has been made based on the above circumstances, and its object is to provide:
It is an object of the present invention to provide a shielded-beam type lamp device in which a change in the color temperature of the lamp is small even when the lamp is operated for a long time and a long service life can be obtained.

[0007]

SUMMARY OF THE INVENTION A sealed beam type lamp device according to the present invention has an arc tube made of a translucent alumina ceramic, and at least an alkali metal halide is sealed in a light emitting space surrounding portion of the arc tube. A metal halide lamp, and a closed envelope that forms a vacuum internal space and houses the metal halide lamp in the internal space, and reflects the light from the metal halide lamp to the closed envelope. In a shielded beam type lamp device having a metal light reflecting film formed thereon, the total area of the light reflecting surface in the sealed envelope is SM (cm ² ), and the area of the outer surface of the light emitting space surrounding portion of the arc tube in the metal halide lamp. the SL (cm ^2), when the rated lamp power metal halide lamp was PW (W), to and satisfies the following formula (1) . Formula (1) (PW × SM) / SL ≦ 7900

[0008]

The amount of photoelectrons generated from the metal light reflecting film of the sealed envelope is determined by the total area SM of the light reflecting surface in the sealed envelope and the lamp power PW of the metal halide lamp.
Increases substantially in proportion to. In the sealed beam lamp device of the present invention, by satisfying the above expression (1), the amount of photoelectrons generated from the metal light reflecting film is reduced by the area of the outer surface of the light emitting space surrounding portion of the light emitting tube. On the other hand, since it is relatively small, generation of an electric field in the light emitting space surrounding portion of the light emitting tube is suppressed. As a result, even when the metal halide lamp is turned on for a long time, the alkali metal ions do not easily move to the arc tube, so that the alkali metal ions rarely leak to the outside through the arc tube.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a shield beam type lamp device according to the present invention will be described in detail. FIG. 1 is an explanatory sectional view showing a configuration of an example of a shield beam type lamp device of the present invention. This shield beam type lamp device includes a metal halide lamp 10 and a sealed envelope 20 that houses the metal halide lamp 10 in an internal space S.

More specifically, in the metal halide lamp 10, a translucent alumina ceramic arc tube 11 having sealing portions 13 formed at both ends of a substantially spherical light emitting space surrounding portion 12 is provided. Sealing part 13 of tube 11
And a pair of rod-shaped electrodes 14 made of tungsten, which are arranged so as to extend along the tube axis direction of the arc tube 11 and to be disposed in the light-emitting space surrounding portion 12 so as to face each other. . A light-emitting substance containing a rare gas, mercury, and an alkali metal halide is sealed in the light-emitting space surrounding portion 12 of the light-emitting tube 11.

In the closed type envelope 20, a light reflecting portion 22 is formed by forming a metal light reflecting film 21 made of, for example, aluminum on the inner surface of a base made of, for example, hard glass.
And a light-transmitting portion 23 made of hard glass and provided so as to hermetically close the opening of the light reflecting portion 22. The interior space S of the sealed envelope 20 is evacuated to a vacuum state of, for example, 1 × 10 ⁻³ Torr or less. Reference numeral 24 denotes a remaining portion of the exhaust pipe of the sealed envelope 20, and 25 denotes a metal ferrule, which is hermetically fused to the bottom of the light reflecting portion 21 of the sealed envelope 20.

Electrode 1 in metal halide lamp 10
4 is fixed to the distal end of a support lead wire 15 made of molybdenum or nickel, for example, by welding. The support lead wire 15 is brazed to the inner bottom of the ferrule 25. As a result, it is held in the ferrule 25. A contact member 16 is provided on the outer bottom of the ferrule 25, whereby the support lead wire 15 is electrically connected to the contact member 16 via the ferrule 25. Each of the supporting lead wires 15 is fixed to each other by a fixing member 17 in which a metal wire 19 is provided at both ends of a columnar glass piece 18.

In the sealed beam type lamp device of the present invention, the metal light reflecting film 21 in the closed type envelope 20 is used.
Is SM (cm ² ), the area of the outer surface of the luminous space surrounding portion 12 of the arc tube 11 in the metal halide lamp 10 is SL (cm ² ), and the rated lamp power of the metal halide lamp 10 is PW ( W),
It is necessary to satisfy the following expression (1). Formula (1) (PW × SM) / SL ≦ 7900

By satisfying the above expression (1), the generation of an electric field in the luminous space surrounding portion 12 of the arc tube 11 in the metal halide lamp 10 is suppressed, so that the metal halide lamp 10 is turned on for a long time. Also,
Alkali metal ions do not easily move with respect to the arc tube 11. The value of (PW × SM) / SL is 790
When the value exceeds 0, generation of an electric field in the light emitting space surrounding portion 12 of the light emitting tube 11 in the metal halide lamp 10 due to photoelectrons generated from the metal light reflecting film 21 is not suppressed, and therefore, when the lighting time elapses. As a result, the alkali metal ions leak to the outside through the light emitting space surrounding portion 12 of the light emitting tube 11, so that the color temperature of the metal halide lamp 10 changes and a long service life cannot be obtained.

In the above-mentioned shield beam type lamp device, by turning on the metal halide lamp 10, the light from the metal halide lamp 10 is transmitted directly or through the metal light reflecting film 21 of the closed envelope 20. It is radiated from the part 23 to the outside. At this time, the sealed envelope 2
The light from the metal halide lamp 10 is irradiated on the metal light reflection film 21 of the first metal light reflection film 21 so that the metal light reflection film 2
1 generate photoelectrons, and the amount of photoelectrons generated from the metal light reflecting film 21 of the sealed envelope 20 depends on the light emitting space surrounding portion 12 of the light emitting tube 11 of the metal halide lamp 10.
Relative to the area of the outer surface of the
The generation of an electric field in the light emitting space surrounding portion 12 is suppressed, and even when the metal halide lamp 10 is turned on for a long time, alkali metal ions rarely leak to the outside via the light emitting tube 11. A long use life can be obtained with little change in the color temperature of the lamp.

Although the embodiment of the present invention has been described above, the present invention is not limited to the above-described shield beam type lamp device, and various changes can be made. For example, in order to obtain anti-glare properties, the light-transmitting portion 2
A glare-cut light reflecting member made of aluminum may be provided between the inner surface of the third or the metal halide lamp 10 and the light-transmitting portion 23 of the sealed envelope 20. In this case, since photoelectrons are also generated from the glare-cut light reflecting member, the area of the reflecting surface of the glare-cut light reflecting member is added to the area SM as a part of the light reflecting surface.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a specific embodiment of the shield beam type lamp device of the present invention will be described. <Examples 1 to 4> A shield beam type lamp device was manufactured according to the configuration shown in FIG. 1 and under the conditions shown in Table 1 below. For these shield beam type lamp devices, a metal halide lamp was continuously turned on, and a change in color temperature after 6000 hours was examined. Table 1 shows the results.

[0018]

[Table 1]

In Table 1, the total area SM of the light reflecting surface (the reflecting surface of the metal light reflecting film) in the sealed envelope is represented by the diameter φ of the opening of the light reflecting portion and the height (light) of the light reflecting portion. The distance was calculated from the distance from the bottom of the reflector to the opening) H using the following approximate expression. Also, the color temperature change of the lamp is 200K.
Above, there is a practical problem.

[0020]

## EQU1 ## SM = π × (φ / 2) ² × (1 + H / φ)

As is clear from the results in Table 1, Example 1
According to the shielded-beam type lamp devices according to Nos. To 4, even after the lighting time of the lamp elapses 6000 hours, the color temperature change of the lamp is less than 200 K, and it was confirmed that a long service life was obtained.

<Comparative Example 1> A shield beam type lamp having a value of (PW × SM) / SL of 12000 was manufactured, and a metal halide lamp was continuously turned on for these shield beam type lamp devices. When the change in color temperature was examined, it was 270K.

[0023]

According to the shield beam type lamp device of the present invention, the amount of photoelectrons generated from the light reflecting surface in the closed type envelope is smaller than the area of the outer surface of the light emitting space surrounding portion of the arc tube in the metal halide lamp. Therefore, generation of an electric field in the light emitting space surrounding portion of the light emitting tube is suppressed, and even if the lamp is operated for a long time, alkali metal ions are less likely to leak outside through the light emitting tube. Has a small change in color temperature and a long service life.

[Brief description of the drawings]

FIG. 1 is an explanatory sectional view showing a configuration of an example of a shield beam type lamp device of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Metal halide lamp 11 Arc tube 12 Emission space surrounding part 13 Sealing part 14 Electrode 15 Supporting lead wire 16 Contact member 17 Fixing member 18 Glass piece 19 Metal wire 20 Hermetic envelope 21 Metal light reflection film 22 Light reflection part 23 Translucent part 24 Exhaust pipe remaining part 25 Ferrule S Internal space

Claims (1)

[Claims] 1. A metal halide lamp having a light emitting tube made of translucent alumina ceramic, wherein at least an alkali metal halide is sealed in a light emitting space surrounding portion of the light emitting tube, and a vacuum inner space is formed. A sealed-beam type envelope device, comprising: a sealed-type envelope for accommodating the metal halide lamp in a space; wherein the sealed-type envelope is formed with a metal light-reflecting film for reflecting light from the metal halide lamp. In the above, the total area of the light reflecting surfaces in the sealed envelope is defined as SM (cm
² ) When the area of the outer surface of the luminous space surrounding portion of the arc tube of the metal halide lamp is SL (cm ² ), and the rated lamp power of the metal halide lamp is PW (W), the following expression (1) is satisfied. Characterized shield beam type lamp device. Formula (1) (PW × SM) / SL ≦ 7900