JPH0536380A - Metal halide lamp - Google Patents

Abstract

PURPOSE:To provide metal halide lamp, which has high characteristic, especially, high color rendering and of which color temperature can be set freely and easily and of which manufacture is facilitated. CONSTITUTION:As metal halide lamp, Dy-Tl-Cs group having luminous flux value at 12000 lm, color temperature at 4500K, mean evaluation number Ra of color rendering at 88, and evaluation number R of red color rendering at 85 is used. The surface of a hollow tube 3 of this metal halide lamp is coated with thin film 13. The thin film absorbs 70% of the output of the light having a wave length at 380-500nm, and absorbs 5% of the output of the light having a wave length at 500-600nm among the light emitted by a light emitting tube 1.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to improvement of light output characteristics of metal halide lamps.

[0002]

2. Description of the Related Art Metal halide lamps are known as highly efficient and economical lamps. In recent years, in order to use this metal halide lamp for indoor lighting in stores and the like, there is a demand for compactness and high color rendering. By the way, even if indoor lighting is performed, the type of lamp used varies depending on what kind of lighting effect is expected. Color temperature is one of the major factors in selecting a lamp. For example, a lamp with a low color temperature (2500-3
000K) can create a calm atmosphere, while high color temperature lamps (6000-7000K)
On the contrary, it can create a lively atmosphere outdoors.

Conventionally, the color temperature has been set by utilizing the emission spectrum peculiar to the additive enclosed in the arc tube and changing the type and amount of the substance. For example, Sn-Tl-Na type metal halide lamps are generally used in the low color temperature range, and Dy-Tl type and Dy-Nd type metal halide lamps are generally used in the high color temperature range.

[0004]

However, the former lamp has a drawback that the color rendering property is inferior. Also, Dy-
Some Nd-based metal halide lamps cause flicker when vertically lit in a 50 Hz region using a copper-iron ballast. As described above, in setting the color temperature in the conventional metal halide lamp, a problem peculiar to each type of lamp occurs depending on the set color temperature. Further, since different lamps must be designed and manufactured according to the color temperature to be set, a plurality of manufacturing lines are required. Therefore, much effort is required to improve the reliability and cost of the lamp, which is extremely inconvenient.

The present invention has been made in view of the above circumstances, and provides a metal halide lamp which has high characteristics, particularly high color rendering properties, whose color temperature can be easily set freely, and which is easy to manufacture. It is intended to be provided.

[0006]

DISCLOSURE OF THE INVENTION The present invention for achieving the above-mentioned object is to provide a luminous tube in which DyI ₃ , TlI, and CsI are enclosed, and a heat-resistant hollow tube in which the luminous tube is arranged. A metal halide lamp comprising the arc tube and an outer bulb accommodating the hollow tube, wherein the wavelength of the light emitted from the arc tube is 380 to 380 on the surface of the hollow tube or the outer bulb.
Light output of 500nm is 10 ~ 70%, wavelength is 500 ~ 60
0 to 50% optical output, wavelength 600 to 700 nm
It is characterized in that a thin film for reducing the light output of 0 to 50% is formed.

The color temperature characteristic of the arc tube is 4000.
It is desirable to be ˜5500K.

[0008]

According to the present invention, by forming a thin film on the surface of the hollow tube or the outer sphere with the above-mentioned structure, visible light in a predetermined range of light emitted from the arc tube can be reduced by a predetermined amount. Therefore, for example, a purple-based light output is about 70
%, The color radiated to the outside can be made reddish, and the color temperature can be lowered.

Further, the color temperature characteristic of the arc tube is 4000-5.
Since the arc tube having high characteristics can be used by using the one of 500 K, it is possible to obtain the metal halide lamp of high efficiency and high color rendering type even after the color temperature is adjusted by the thin film.

[0010]

EXAMPLE In this example described below, a thin film having a characteristic of partially absorbing visible light is formed on the surface of a hollow tube of a metal halide lamp in order to change the color temperature. Color lamps for incandescent lamps, daylight type photographic light bulbs and the like are close to such technology. However, in the case of a metal halide lamp, even if a thin film that absorbs visible light is formed, the color temperature can be changed, but characteristics such as color rendering properties and efficiency may deteriorate. For example, in order to make a Dy-Nd type metal halide lamp having a high color temperature a low color temperature, it is necessary to considerably cut a low wavelength part, resulting in a very low efficiency. In addition, even if a visible light is partially cut by using a Sn-Tl-Na-based metal halide lamp, the color rendering property is originally low, so that a high color rendering type lamp cannot be obtained. In order for the metal halide lamp after thin film formation to have a long life, high efficiency, high color rendering, and no flicker, it is necessary to select a light emitting tube that meets the following conditions as the original arc tube. Have a long life. High efficiency.
Average color rendering index Ra is 85 or more, special color rendering index R ₉
~ R ₁₅ is 50 or more. Even a copper-iron type ballast should not cause flicker. In this embodiment, a Dy-Tl-Cs type lamp is used as the original metal halide lamp.

A first embodiment of the present invention will be described below with reference to FIGS.
Will be described with reference to. FIG. 1 is a diagram showing the structure of a metal halide lamp which is a first embodiment of the present invention.

The metal halide lamp shown in FIG. 1 includes an arc tube 1, a hollow tube 3 in which the arc tube 1 is arranged, an outer bulb 5 for housing the arc tube 1, the hollow tube 3 and the like, and an arc tube. 1, a column 7a for supporting the upper part of 1 and a column 7b for supporting the lower part of the arc tube 1, a base 9 and a thin film 13.

Inside the arc tube 1, DyI ₃ , TlI,
In addition to CsI, mercury and argon are enclosed. A pair of electrodes (not shown) are sealed at both ends of the arc tube 1, and a heat insulating film is applied to both ends of the arc tube 1. The arc tube 1 is made of high-purity quartz glass, and both ends thereof are pinch-sealed.

A hollow tube 3 made of quartz glass which is a light-transmitting heat-resistant glass is arranged around the arc tube 1 to prevent the arc tube 1 from bursting. The columns 7a and 7b are made of a conductor and serve as a conductor for fixing the arc tube 1 and supplying electric power to the arc tube.

Hard glass having good heat resistance is used for the outer bulb 5. In addition, the outer bulb 5 is provided with a heat insulator for the arc tube 1 and a getter 17 to increase the degree of vacuum of the outer bulb 5.

In the metal halide lamp of the first embodiment,
A thin film 13 is applied to the surface of the hollow tube 3. FIG. 2 is a diagram showing the light transmission characteristics of the thin film 13. This thin film 13 is shown in FIG.
As shown in, the wavelength of the light emitted from the arc tube 1 is 380 to 5
It absorbs 70% of the light output of 00 nm and 5% of the light output of wavelengths of 500 to 600 nm.

The thin film 13 is a double thin film composed of titanium oxide and silicon oxide, and is obtained by a dip molding method. Specifically, first, the hollow tube 3 whose upper and lower openings are sealed is immersed in a tank containing a titania alkoxide solution and pulled up. By heating at 600 ° C., a thin film of titanium oxide is formed on the hollow tube 3. Next, similarly, the hollow tube 3 is immersed in a tank containing a silica-based alkoxide solution, pulled up, and heated to form a silicon oxide thin film on the titanium oxide. The rate at which the thin film 13 transmits light can be controlled by changing the pulling speed of the hollow tube 3 and changing the thickness of each thin film when forming the thin film.

In this embodiment, the original Dy-Tl-Cs type metal halide lamp before forming the thin film 13 has a luminous flux value of 12000 lm, a color temperature of 4500 K and an average color rendering index (Ra) of 93 and a special color rendering index. Of these, a red evaluation value (R ₉ ) of 85 is used. Further, FIG. 3 shows a spectral characteristic diagram of this original metal halide lamp.

Since the metal halide lamp having the thin film thus formed absorbs violet visible light at a higher rate than the original metal halide lamp having no thin film, the entire emission color is reddish. And the color temperature drops. In fact, the metal halide lamp of this embodiment, Hikaritabachi 11000Lm, color temperature 3300K, Ra88, R ₉ 7
It has the characteristic of 5. This is particularly superior in color rendering properties to the conventional metal halide lamp having a color temperature of about 3000K. Also, the efficiency is slightly lower than that of the original metal halide lamp, but this level is practically no problem.

FIG. 4 and FIG. 5 respectively show the metal halide lamp of this embodiment and the conventional S in the substantially same color temperature range.
It is a figure which shows the luminous flux maintenance curve and color temperature variation curve of an n-Tl-Na type metal halide lamp. From FIGS. 4 and 5, it can be seen that the metal halide lamp of this embodiment has no problem in the luminous flux maintenance characteristics. Moreover, it is clear that the characteristics are fairly stable during the life period.

In this embodiment, the color temperature is changed by using the same arc tube as the conventional one instead of changing the setting of the arc tube, so that the most reliable arc tube can be used. Therefore, excellent properties such as long life, high color rendering, high efficiency, and no flicker can be maintained.
Further, since the manufacturing method can also utilize the conventional manufacturing process of the Dy-Tl-Cs-based metal halide lamp,
Due to the effect of mass production, the manufacturing cost can be considerably reduced.

Next, a metal halide lamp according to a second embodiment of the present invention will be described with reference to FIG. FIG. 6 is a diagram showing the light transmission characteristics of the thin film used in the second embodiment. The same metal halide lamp as that used in the first embodiment was used as the original metal halide lamp before the thin film was formed.

The metal halide lamp of the second embodiment differs from that of the first embodiment in that the wavelength 38
25% optical output from 0 to 500 nm, wavelength 500 to 600
That is, the hollow tube is provided with a thin film capable of absorbing 50% of the optical output of 50 nm and 15% of the optical output of 600 to 700 nm.

Contrary to the first embodiment, the second embodiment absorbs a large amount of red visible light, so that the overall light emission can be made whitish and the color temperature can be increased. You can Actually, luminous flux value is 10,000 lm, color temperature is 60
00K, and a metal halide lamp can be obtained as Ra 90, R ₉ 55. As described above, in the second embodiment, the color temperature of the metal halide lamp can be increased without significantly degrading the characteristics of the lamp. Other functions
The effect is similar to that of the first embodiment.

In each of the above embodiments, the case where a thin film that cuts visible light in a specific range is formed has been described, but the present invention is not limited to this and the wavelength 38
10 ~ 70% light output from 0 ~ 500nm, wavelength 500 ~
Light output of 600nm is 0 to 50%, wavelength is 600 to 700
By forming a thin film that reduces the optical output of nm by 0 to 50%, the color temperature can be freely set without significantly deteriorating the characteristics of the original metal halide lamp.
In addition, considering that there is a high possibility that efficiency will decrease if there is a light emission output that affects the luminous flux in the visible light region cut by the thin film, and that the design of the thin film becomes complicated and practically involved, etc. As the original metal halide lamp before forming the thin film, it is desirable to use a lamp having an average and gentle spectral output over the entire visible light region.

In each of the above embodiments, the case where the dip molding method is used to apply the thin film to the hollow tube has been described, but the present invention is not limited to this.
You may form a thin film using a vapor deposition method etc.

Further, in each of the above embodiments, the case where the thin film is formed on the surface of the hollow tube of the metal halide lamp has been described, but the present invention is not limited to this.
The thin film may be formed on the surface of the outer sphere.

In addition, although the thin film is formed on the outer surface of the hollow tube in the above embodiment, the thin film may be formed on the inner surface of the hollow tube.

[0029]

As described above, according to the present invention, the wavelength of the light emitted from the arc tube on the surface of the hollow tube or the outer bulb is 38
10 ~ 70% light output from 0 ~ 500nm, wavelength 500 ~
Light output of 600nm is 0 to 50%, wavelength is 600 to 700
A metal halide lamp that absorbs visible light radiated to the outside and allows the color temperature to be freely set by forming a thin film that reduces the optical output of nm by 0 to 50% and facilitates the manufacturing process. Can be provided.

[Brief description of drawings]

FIG. 1 is a diagram showing a structure of a metal halide lamp which is a first embodiment of the present invention.

FIG. 2 is a diagram showing light transmission characteristics of a thin film formed on the outer bulb of the metal halide lamp of this example.

FIG. 3 is a characteristic diagram of a spectral output before a thin film is applied to the metal halide lamp of this embodiment.

FIG. 4 shows a metal halide lamp of the first embodiment and a conventional S
It is a figure which shows the luminous flux maintenance factor with respect to the lighting time of an n-T1-Na type metal halide lamp.

FIG. 5: Metal halide lamp of the first embodiment and conventional S
It is a figure which shows the color temperature with respect to the lighting time of an n-T1-Na type metal halide lamp.

FIG. 6 is a diagram showing light transmission characteristics of a light transmitting film formed on the outer bulb of the metal halide lamp according to the second embodiment of the present invention.

[Explanation of symbols]

1 arc tube 3 hollow tubes 5 outer sphere 7a, 7b prop 9 mouthpiece 13 thin film 17 Getter

Claims (2)

[Claims] 1. An arc tube in which DyI ₃ , TlI, and CsI are enclosed, a heat-resistant hollow tube in which the arc tube is arranged, and an outer bulb containing the arc tube and the hollow tube. And a wavelength of 380 to 380 among light emitted by the arc tube on the surface of the hollow tube or the outer bulb.
Light output of 500nm is 10 ~ 70%, wavelength is 500 ~ 60
0 to 50% optical output, wavelength 600 to 700 nm
A metal halide lamp characterized by forming a thin film that reduces the light output of the product by 0 to 50%. 2. The color temperature characteristic of the arc tube is 4000-5.
The metal halide lamp according to claim 1, which has a temperature of 500K.