JPH0554855A - Metal halide lamp - Google Patents

Abstract

PURPOSE:To provide a metal halide lamp in which tungsten is prevented from attaching to the tip of an electrode or even if the tungsten attaches to the tip localization of the tungsten is prevented. CONSTITUTION:An electrode 3 is sealed at the tip portion of a light-emitting tube bulb 1 and an iodide and a bromide of rare earth element, mercury, and rare gas are sealed inside the bulb and an electrode coil 5 is wound to the tip of the axis of the electrode. The tip of the electrode axis 4 is formed into a spherical portion 41 and the diameter d1 of the spherical portion 41 is larger than the diameter d2 of the root portion 42 of the electrode axis. Because the diameter d1 of the tip portion of the electrode axis is larger than the diameter d2 of the root portion, the temperature of the tip portion can be lowered so as to prevent attachment of tungsten to the tip portion or prevent growth of tungsten attaching thereon. Because the tip portion is spherical, the temperature distribution of the end portion becomes uniform and the attaching thereto is not localized and so the rate at which the interelectrode distance shortened is lowered.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a small metal halide lamp, and more particularly to improvement of life characteristics.

[0002]

2. Description of the Related Art Since metal halide lamps are discharge lamps with high efficiency and high color rendering properties, they have been conventionally used for wide area lighting such as roads, open spaces, stadiums, etc. It is also being used in floodlights such as projectors.

With the spread of such spread, this kind of lamp has come to be used in combination with a device such as a reflecting mirror, and therefore, this kind of lamp as a light source is for facilitating the control of light. It is desired to be close to a point light source. Therefore, this type of metal halide lamp is being shortened, that is, downsized. However, downsizing the lamp generally increases the tube wall load and tends to increase the temperature of the arc tube.

On the other hand, this type of lamp uses S as a luminescent metal in order to obtain higher efficiency and color rendering.
It has been devised to encapsulate rare earth metals such as c, Dy, Tm, and Ho as halides such as iodine I and bromine Br.

However, in such a small metal halide lamp using a halide of a rare earth metal, blackening easily occurs on the tube wall at an early stage. In other words, especially when using iodine as the halogen, the lamp filled, for example, ScI ₃ as a light-emitting metal, quartz (SiO ₂₎ of the arc tube material and the ScI ₃ reacts, SiI ₄ and Sc ₂
Generates O ₃ . This reaction is more likely to occur as the tube wall load is higher and the arc tube temperature is higher, and thus is more likely to occur in the small metal halide lamp.

When SiI ₄ is generated by the above reaction, it adheres to the tip of the electrode and forms a low melting point alloy of tungsten W and silicon Si with tungsten W which constitutes the electrode. Since this alloy has a low melting point, it is subjected to electron impact and scattered from the tip of the electrode. The scattered low-melting-point metal adheres to the inner surface of the bulb and is blackened to absorb visible light, thereby lowering the luminous flux maintenance factor.

When SiI ₄ adheres to the tip of the electrode to form a low melting point alloy with tungsten W and when the low melting point alloy is scattered, the tip of the electrode is corroded and the shape is deformed, resulting in an arc spot. It may also cause instability in the occurrence position of.

In order to prevent such a problem, when bromine Br is mixed in addition to iodine I as a halogen, bromine is combined with tungsten W adhering to the tube wall and tungsten of the low melting point alloy of silicon Si to form an electrode. It has been found that the tube wall is purified, the blackening of the tube wall is prevented, and the luminous flux maintenance factor is improved.

[0009]

However, in this case, when the temperature of the electrode tip is partially high, the tungsten W returned from the tube wall is deposited on the electrode tip because it tries to adhere to the high temperature location, There is a problem that this gradually grows and the tip of the electrode gradually expands, the distance L between the electrodes is shortened, and the lamp characteristics are greatly changed. The temperature of the electrode tip is determined by the lamp current and the diameter of the electrode shaft. If the lamp current is constant, the smaller the diameter of the electrode shaft, the higher the temperature of the electrode tip.

Therefore, in order to prevent the tungsten W from adhering to the tip of the electrode and prevent the development of the adhered tungsten W, the electrode shaft may be thickened to lower the temperature of the electrode tip.

However, if the tip portion of the electrode shaft is enlarged, the temperature of the entire tip portion is lowered, but a temperature difference occurs at the tip portion of the electrode shaft, and arc spots are intensively generated at high temperature points. Adheres and deposits, which gradually grows and expands.

The present invention has been made in view of the above circumstances. An object of the present invention is to prevent tungsten W from adhering to the tip of an electrode and to prevent local concentration even if it adheres. , A metal halide lamp having improved life characteristics.

[0013]

In order to achieve the above-mentioned object, the present invention encloses an electrode at the end of an arc tube bulb, in which iodide and bromide of rare earth metal, mercury, and a rare gas are contained. In a metal halide lamp in which a gas is enclosed and the electrode is formed by winding an electrode coil around the tip of an electrode shaft, the tip end of the electrode shaft is a spherical portion, and the diameter d ₁ of this spherical portion is the diameter d of the root portion. It is characterized by making it larger than ₂ .

[0014]

According to the present invention, since the diameter d ₁ of the electrode shaft tip is larger than the diameter d _{2 of the} root, the temperature of the electrode tip can be lowered and the tungsten W is prevented from adhering to the electrode tip. However, the development of the attached tungsten W can be prevented. Moreover, since the tip portion has a spherical shape, the heat radiation on the surface becomes the radiation direction and the heat radiation increases, and the temperature distribution at the tip portion can be made even close to each other. However, the adhesion points will not be concentrated in one place. Since the tip of the electrode shaft has a spherical surface, even if tungsten W is attached, it is attached to the entire surface of the spherical surface together with the fact that the above temperature distribution is uniform, and only the tip is locally attached. Since it does not adhere, the distance between the electrodes is reduced.

[0015]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below based on an embodiment shown in the drawings.

The drawing shows a small metal halide lamp with a rated output of 2 KW, and 1 is an arc tube bulb, which is made of transparent quartz glass. The valve 1 has a substantially elliptical shape, for example, an inner diameter of 40 mm in the major axis direction and an inner diameter of about 36 mm in the minor axis direction.

Sealing tubes 2 and 2 are joined to both ends of the valve 1, respectively. These sealing tubes 2 and 2 are made of translucent quartz glass or hard glass, and are fused to both ends of the bulb 1.

Electrodes 3 and 3 are sealed in the sealing tubes 2 and 2. The electrodes 3 and 3 are configured by attaching an electrode coil 5 to the tip of an electrode shaft 4 described later. These electrodes 3 and 3 are exposed in the bulb 1, and the tips of the electrode shafts 4 and 4 are opposed to each other in the bulb 1 with a predetermined interelectrode distance L, for example, 30 mm.

The base end of the electrode shaft 5 is welded to a first metal foil conductor 6 made of molybdenum or the like, and the first metal foil conductor 6 is joined to an intermediate lead wire 7 made of molybdenum or the like. There is. The intermediate lead wire 7 is welded to a second metal foil conductor 8 made of molybdenum or the like, and the second metal foil conductor 8 is joined to an outer lead wire 9 made of molybdenum or the like.

The one metal foil conductor 6, the intermediate lead wire 7, the second metal foil conductor 8 and the outer lead wire 9 as described above are crushed in the sealing pipes 2 and 2 within the sealing pipes 2 and 2. By sealing, it is hermetically sealed. The external lead wires 9, 9 are connected to a cap (not shown) attached to the ends of the sealing tubes 2, 2. The structure of the electrode 3 is shown in FIG.

The electrode shaft 4 is entirely thoria (ThO ₂ )
Is formed of tungsten W (tritan), the tip portion is a spherical surface portion 41, and the root portion connected to this is a shaft portion 42.

The diameter d ₁ of the spherical portion 41 the diameter d ₂ of the root portion 42
It is formed larger (d ₁ > d ₂ ), and the root portion 42 is formed.
While the diameter d ₂ of the spherical surface 41 is about 1.8 to 2.3 mm, the diameter d ₁ of the spherical surface portion 41 is about 2.2 to 2.6 mm. The electrode coil 5 is made of tungsten W (tritan) containing thoria (ThO ₂ ) and has a wire diameter of 1.5 to
It is wound 6 to 7 times with a length of about 2.0 mm. The arc tube bulb 1 is filled with a rare earth metal halide and a rare gas such as mercury and argon.

The rare earth metal halide is, for example, Dy.
Br₃Is 4 mg, HoBr₃Is 4 mg, TmBr₃Is 4 mg,
HgBr₂10 mg, CsI 12 mg, HgI₂Is 3 mg
It is said that. Mercury Hg is 100 mg and argon is
Enclosed in 100 Torr. And this Metal Harai
When the lamp is lit at 2kW, the lamp current I_LBut
It becomes 19.0 amps. Therefore, the lamp current I_LAnd electric
Diameter d of the spherical portion 41 at the tip of the polar axis 4₁The relationship with₁ ² = 0.25I_L  Has become. Metal halide lamp with such a configuration
The operation will be described.

In the electrode shaft 4 of the above embodiment, the diameter d ₁ of the spherical portion 41 formed at the tip is formed to be, for example, about 2.2 to 2.6 mm, and the diameter (2. Since it is larger than 0 mm), it is possible to suppress the temperature rise of the electrode tip.

Therefore, it is possible to reduce the tendency of bromine to combine with the tungsten W adhering to the tube wall and the tungsten of the low melting point alloy of silicon Si to be deposited on the tip portion 41 of the electrode. Prevent it from growing and growing.

Since the tip portion 41 has a spherical shape, heat is emitted in the radiation direction, which increases the amount of heat radiation and makes the temperature distribution of the tip portion 41 evenly close. be able to. Therefore, tungsten that tends to adhere intensively to high temperature
Attempts to adhere to the substantially entire surface of the spherical portion 41 having a substantially uniform temperature distribution, and the concentration is not concentrated at one place. Since the electrode shaft tip 41 has a spherical surface, the tungsten W
Will adhere to the entire surface of the spherical surface. For this reason, tungsten is prevented from locally adhering to the tip of the electrode shaft, so that the inter-electrode distance L is prevented from becoming short, and fluctuations in lamp characteristics are prevented. Further, since the deposition of tungsten on the electrode tip portion 41 is reduced, the root portion 4 of the electrode shaft is
The ratio of being carried from 2 decreases, and the thinness of the electrode shaft also decreases. Because of this, the life is longer than before. An experiment was conducted to confirm the effect of the configuration of the present invention, and the results are shown in Table 1.

[0027]

[Table 1]

From the results shown in Table 1 above, in the conventional case where the electrode shaft is formed of a single shaft having the same thickness, the tungsten W is deposited on the tip of the electrode, and the turn-off voltage increases and the turn-off easily occurs. It was

On the other hand, as in the present invention, the electrode shaft 4
The tip portion 41 has a spherical shape, and the diameter d of the spherical portion 41₁To
Diameter d of root 42₂If it is larger,
Accumulation of tungsten W is less likely to occur
It did not happen. Therefore, the life of the lamp is extended.
confirmed. The diameter d of the electrode shaft tip portion 41₁And lamp
Current I_LThe relationship (current density) is 0.12 · I_L<D₁ ² <0.47 · I_L  The range of is desirable.

That is, d ₁ ² Is 0.12 · I _L or less, the current density becomes high, the temperature of the electrode shaft tip portion 41 rises, the amount of tungsten W deposited on the tip increases, and the inter-electrode distance L shortens. Conversely, d ₁ ² Is 0.47 · I _L or more, the temperature of the entire tip portion is too low, and it tends to disappear.

Furthermore, when bromine Br is mixed in addition to iodine I as a halogen, as described above, bromine is combined with tungsten W adhering to the tube wall and tungsten of the low melting point alloy of silicon Si to form an electrode. A returning action is caused, so that the tube wall is purified, blackening of the tube wall is prevented, and the luminous flux maintenance factor is improved. In this case, the ratio Br / I of the bromine atom Br to the iodine atom I is preferably in the range of 1-5.

When the ratio Br / I of bromine to iodine is less than 1, the initial purpose of mixing bromine Br cannot be achieved, and there is a phenomenon that the arc becomes thick and the color temperature lowers. When Br / I exceeds 5, bromine directly reacts with the tungsten at the electrode tip and the root, adheres to the tube wall, and the luminous flux maintenance factor decreases. The present invention is not limited to the above embodiment. That is, the spherical shape of the tip portion 41 of the electrode shaft 4 may be a vertically long or horizontally long ellipsoidal sphere, in addition to a perfect sphere.

[0033]

As described above, according to the present invention, since the diameter d _{1 of the} tip of the electrode shaft is made larger than the diameter d _{2 of the} root, the temperature of the tip of the electrode can be lowered, and the tip of the electrode is made of tungsten. Can be prevented from adhering, and the development of adhered tungsten can be prevented. Moreover, since the tip portion has a spherical shape, the temperature distribution of the tip portion can be made evenly close to each other, and even if tungsten is attached, the attachment point is not concentrated in one place, so that the distance between the electrodes is shortened. Is reduced. For this reason, the lamp characteristic does not fluctuate over a long period of time, and the life is extended.

[Brief description of drawings]

FIG. 1 shows an embodiment of the present invention, (A) is a sectional view of a metal halide lamp, and (B) is a sectional view showing a structure of an electrode thereof.

[Explanation of Codes] 1 ... Valve, 2 ... Sealing tube, 3 ... Electrode, 4 ... Electrode shaft, 5 ...
Electrode coil, 6, 8 ... Metal foil conductor, 7 ... Intermediate lead wire,
9 ... External lead wire, 41 ... Spherical end of electrode shaft, 42 ...
The base of the electrode shaft.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Hideki Ito Inventor Hideki Ito 4-28, Mita, Minato-ku, Tokyo Inside Toshiba Lighting & Technology Corporation

Claims (2)

[Claims] 1. An electrode is sealed at the end of an arc tube bulb, and a rare earth metal iodide and bromide, mercury, and a rare gas are sealed in the bulb, and the electrode has an electrode coil at the tip of an electrode shaft. In a metal halide lamp formed by winding, the tip of the electrode shaft is spherical, and the diameter d _{1 of} this spherical portion is
The metal halide lamp is characterized in that the diameter is larger than the diameter d ₂ of the root part. 2. A spherical portion formed at the tip of the electrode shaft
Diameter d₁(Mm) is the lamp current I_L(Ampere)
In the case of 0.12 · I_L<D₁ ² <0.47 · I_L  The metal halley according to claim 1, characterized in that
Drump.