JPH11204083A - Electric discharge lamp made of ceramic - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electric discharge lamp made of a ceramic and free of a back arc phenomenon. SOLUTION: This electric discharge lamp made of a ceramic comprises a bulb 10 having an arc tube 11 and sealing tube parts 12, a pair of electrodes installed on the opposite to each other inside the arc tube 11, electrode structure bodies 20 having the electrodes in the tips and inserted into the sealing tube parts 12, and frit glass 30 filling the outer ends of the sealing tube parts 12 while keeping the electrode structure bodies 20 in the inserted state. Each of the electrode structure bodies 20 comprises an electrode coil 22 wound on the part which is positioned inside the arc tube 11 and a metal coil 27 wound in the part which is positioned inside each sealing tube part 12. The distance L from the end part 27A of the metal coil 27 to the inner end face 12A of each sealing tube part 12, the diameter D [mm] of the sealing tube part 12, the diameter d [mm] of each electrode rod 21 constituting each of the electrode structure bodies 20, and the pressure P [Pa] of the sealed rare gas are so controlled as to satisfy the following: D<=2 [mm]; L/[(D-d)/2]>3.4; and P×[(D-d)2]>2.9 [Pa.m].

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a ceramic discharge lamp having a bulb made of translucent ceramics.

[0002]

2. Description of the Related Art At present, a discharge lamp such as a high-pressure or low-pressure mercury discharge lamp or a metal halide lamp is used as a light source for a backlight of a liquid crystal display device or a light source of an ultraviolet ray processing device. In such a discharge lamp, a pair of electrodes (electrode coils) are disposed opposite to each other in the arc tube portion of the bulb, and a luminous substance composed of mercury, a rare gas, and, if necessary, various metal halides is sealed. ing. The bulb of the discharge lamp is usually formed of quartz glass, has a spherical or elliptical spherical arc tube portion, and a sealing tube portion integrally connected to both ends thereof, and has an electrode at the tip. The rear end of the structure is sealed at the sealing tube to form an airtight sealing structure.

On the other hand, translucent ceramics such as alumina, yttria, yttrium-aluminum-garnet (so-called "YAG"), and zirconia are known as translucent materials, and these have higher mechanical strength than quartz glass. It has the advantage of being large and having a high heat resistant temperature. For this reason, recently, bulbs are made of translucent ceramics,
In particular, ceramic discharge lamps formed of translucent alumina have attracted attention. The bulb of such a ceramic discharge lamp is also provided with an arc tube having a spherical shape, an elliptical spherical shape, or a cylindrical shape.

In such a ceramic discharge lamp, since the bulb is made of a light-transmitting ceramic, a process for forming a hermetically sealed structure in a sealed tube portion is required.
The sealing tube cannot be melt-deformed and, therefore, is filled with a sealing frit glass into a gap between the sealing tube and the electrode structure inserted therein, thereby providing a hermetic seal. A stop structure is formed. However, the heat resistance temperature of the frit glass is not sufficiently high at about 840 ° C., so that it is necessary to prevent the frit glass from being overheated when the discharge lamp is turned on. From such a demand, in the sealing tube part of the ceramic discharge lamp, in order to keep a space between the central part of the arc tube part, which becomes extremely high at the time of lighting, and the hermetically sealed region, the arc tube part is required. Subsequently, a temperature buffer region having an appropriate length is provided.

[0005] However, such a temperature buffering region needs to be of a considerable length in order to obtain a sufficient temperature buffering function, and as a result, between the inner surface of the sealing tube and the electrode structure. Will form a narrow and long gap. However, such an arrangement may cause condensation of the discharge lamp enclosure in the gap. This is because the vapor pressure of the filling of a discharge lamp is generally determined by the temperature of the coldest point where the temperature of the gas in the filling comes into contact with the lowest temperature. This is because, as a result of the provision of the area, the coldest point occurs at the above-mentioned gap. Particularly in metal halide lamps, rare earth metal halides may be sealed in order to improve the color rendering properties, but rare earth metal halides have a lower vapor pressure than other metal halides, and therefore, When condensation occurs in the sealing tube portion, the effective vapor pressure does not reach the height required for light emission in the light emitting tube portion, and as a result, the luminous efficiency of the lamp is low and sufficient color rendering properties cannot be obtained. There is a problem.

[0006] In order to solve such a problem, it is necessary to reduce the gap between the inner surface of the sealing tube and the electrode structure in the temperature buffer region. For this reason, as a means for reducing the gap, a metal coil is wound around a portion (electrode bar) of the electrode structure located in the temperature buffer region, and a portion of the electrode structure (electrode bar) located in the temperature buffer region. It has been proposed that a sleeve be mounted on a metal tube and a metal coil for fixing the sleeve be wound around a portion (electrode bar) located on the side of the arc tube from the sleeve.

[0007]

However, when the gap is reduced by the above-mentioned means, the electrode located at the tip of the electrode structure (in the arc tube) at the start of lighting of the discharge lamp or the like. (Electrode coil)
Is generated from the end of the metal coil located in the sealed tube portion (hereinafter, referred to as a phenomenon).
It is called "back arc phenomenon." ) Occurs, whereby the inner surface of the arc tube portion near the metal coil may be locally heated and damaged. The present invention has been made under such circumstances, and an object of the present invention is to provide a ceramic discharge lamp which does not cause a back arc phenomenon.

[0008]

According to the present invention, there is provided a ceramic discharge lamp comprising: an arc tube portion; and an arc tube portion.
An electrode structure having a bulb (10) having a sealing tube portion (12) integrally and continuously provided with a pair of electrodes disposed in the arc tube portion (11) and having the electrode at the tip end While the (20) is inserted into the sealing tube (12), the tube at the outer end of the sealing tube (12) is filled with a sealing frit glass (30) and hermetically sealed. In a ceramic discharge lamp having a structure formed therein, a rare gas and other luminescent substances are sealed in the bulb, and the electrode structure (20) is provided with an electrode coil in a portion located in the arc tube part (11). (22) is wound,
A metal coil (2) is provided at a portion located in the sealed tube portion (12).
7) is wound, and the distance from the end (27A) of the metal coil (27) on the arc tube side to the inner end surface (12A) of the sealing tube (12) is L, The inner diameter of the portion (12) is D [mm], the diameter of the electrode rod (21) constituting the electrode structure (20) is d [mm], and the pressure of the rare gas is P.
When [Pa] is satisfied, the following formulas (1) to (3) are satisfied.

[0009]

Equation (1) D ≦ 2 [mm] Equation (2) L / [(D−d) / 2]> 3.4 Equation (3) P × [(D−d) / 2]> 2 .9 [Pa · m]

In the present invention, "the inner end face of the sealing tube portion"
Refers to the boundary (surface) between the arc tube portion and the sealing tube portion, and has a bulb whose inner diameter continuously increases from the sealing tube portion toward the arc tube portion (including a spherical or elliptical spherical arc tube portion). In this case, the position (surface) of the straight pipe portion of the sealing pipe portion is 1.1 times the inner diameter (D).

[0011]

The longer the distance (L) from the end of the metal coil on the arc tube side to the inner end surface of the sealing tube, the more the gap between the inner surface of the sealing tube and the electrode structure [ (D−d) / 2]
The back arc phenomenon is less likely to occur as the gas pressure is smaller and the pressure (P) of filling the rare gas is larger. According to the ceramic discharge lamp that satisfies the conditions represented by the above-described formulas (1) to (3), it is possible to reliably prevent the back arc phenomenon, as is clear from the results of the examples described later. This makes it possible to generate an appropriate arc between a pair of electrodes (electrode coils located at the tip of the electrode structure) which are arranged to face each other in the arc tube part.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, a ceramic discharge lamp according to the present invention will be described in detail. <Specific Configuration Example 1> FIG. 1 is an explanatory sectional view showing an example of a ceramic discharge lamp of the present invention, and FIG. 2 is a partially enlarged view of FIG. 1 showing a portion including a sealing tube portion.

The bulb 10 constituting the ceramic discharge lamp has an elliptical spherical arc tube portion 1 surrounding a discharge space.
1 and a sealing tube portion 12 extending continuously from both ends of the light emitting tube portion 11 and formed of translucent ceramics. Here, as ceramics constituting the bulb 10, translucent polycrystalline alumina,
A translucent yttrium-aluminum-garnet polycrystal and a translucent yttria polycrystal can be used, and among these, a translucent alumina polycrystal is particularly preferable. The maximum outer diameter of the arc tube part 11 is 4.0 to 10.0 m.
m, the inner volume is 0.05 to 0.6 cm ³ , the outer diameter of the sealing tube 12 is 1.8 to 2.6 mm, and the length is 28 to 40 mm.

A pair of electrodes are opposed to each other on the arc tube portion 11 of the bulb 10. This electrode is configured by winding an electrode coil 22 around the tip of an electrode rod 21, and an external lead rod 24 is connected to a base end of the electrode rod 21 via an intermediate lead rod 23, and is electrically connected. It is in a connected state. Here, the material of the electrode rod 21 and the electrode coil 22 is tungsten or the like, the material of the intermediate lead rod 23 is niobium or the like, and the material of the external lead rod 24 is platinum or the like. The diameter d of the electrode rod 21 is set to 0.15 to 0.5 mm.

An electrode structure 20 composed of the electrode rod 21, the electrode coil 22, the intermediate lead rod 23 and the external lead rod 24, and a sleeve 26 and a metal coil 27, which will be described later, is used to seal the bulb 10. It is inserted through the tube 12. Specifically, the electrode coil 22 is located inside the arc tube part 11, the distal end of the external lead rod 24 is located outside the bulb, and the base part of the electrode rod 21 and the intermediate lead rod 23 are located in the sealed tube part. 12.

Further, as shown in FIG.
Is provided with a sleeve 26 made of ceramic with the electrode rod 21 inserted therethrough. This sleeve 2
As a material constituting 6, polycrystalline alumina, silica glass or the like can be used, but it is preferable that the material is the same as the material constituting the valve 10. Further, the length of the sleeve 26 depends on the length of the sealing tube portion 12, but is, for example, 4-7.
mm.

The sleeve 26 has an outer diameter of the sealing tube portion 12.
With the inner diameter (D) of the electrode rod 2
It is desirable to have a shape that matches the diameter (d) of unity. In particular, it is preferable that the difference between the outer diameter of the sleeve 26 and the inner diameter (D) of the sealing tube portion 12 is small.
It is desirable that it is 12 mm or less. As a result, the gap between the two becomes sufficiently small, and it becomes possible to reduce the amount of the enclosing material that enters and condenses, and as a result, the vapor pressure of the luminescent substance in the arc tube portion 11 is constantly reduced. It can be maintained at a height necessary for achieving the intended color rendering properties.

A metal coil 27 for fixing the sleeve 26 is wound around a portion of the sealing tube portion 12 located inside (on the side of the arc tube portion) of the sleeve 26. Here, as a material of the metal coil 27, for example, molybdenum or the like is used. The diameter of the metal coil 27 is
For example, it is 0.1 to 0.25 mm, and about 2 to 4 turns is sufficient.

An airtight sealing structure is formed in a portion of the sealing tube portion 12 located outside the sleeve 26. Specifically, the frit glass 30 for sealing is injected into the tube of the sealing tube portion 12, and the outer end of the sleeve 26 (FIG. 2).
The gap between the base end of the electrode rod 21 and the intermediate lead rod 23 protruding from the right end of the sealing tube 12 and the inner surface of the sealing tube 12 is filled, and a frit is placed on the outer end of the sealing tube 12. A glass bead portion 31 is formed so as to protrude outward, and a portion including a connection portion between the intermediate lead bar 23 and the external lead bar 24 is fixed in the bead portion 31 in a buried state. The tip of 24 is in a state of protruding outside from the bead portion 31 of the frit glass. Here, as the sealing frit glass 30, for example, an alumina-silica-rare earth oxide-based glass can be preferably used.

In this ceramic discharge lamp, the inside diameter of the sealed tube portion 12 (the inside diameter D of the straight tube portion) is set to 2 mm or less [condition shown in the above formula (1)], preferably 0.3 mm.
２2 mm. Further, as shown in FIG.
When the distance from the end 27A of the metal coil 27 wound around 1 to the inner end face 12A of the sealing tube is L, L
The value of / [(D−d) / 2] is greater than 3.4, which means that the back arc phenomenon occurs at the start of lighting in the ceramic discharge lamp. This is an indispensable condition for not letting them do. here,
The “inner end surface 12 </ b> A of the sealing tube portion” is a boundary (surface) between the arc tube portion 11 and the sealing tube portion 12, and the size of the bulb 10 increases from the sealing tube portion 12 toward the arc tube portion 11. The inner diameter is 1.1 of the inner diameter (D) in the straight pipe portion of the sealing pipe section 12.
It is a position (plane) that is 1 times. [(D−d) / 2] is
This is the size of the gap G between the inner surface of the sealing tube portion 12 and the electrode rod 21, and the larger this value is, the more easily the back arc phenomenon occurs. The distance (L) is a distance between the metal coil 27 and the inner end surface 12A of the sealing tube portion 12, and the shorter the distance (L), the more easily the back arc phenomenon occurs.

In this ceramic discharge lamp, the total length of the partial length (R) of the electrode rod 21 covered by the sleeve 26 and the metal coil 27 and the distance (L) is equal to the length of the temperature buffer region. Equivalent to. The length of the temperature buffer region is preferably 4 to 8 mm. If the length of the temperature buffer region is excessively large, the overall length of the lamp is unnecessarily large, so that the advantages of the ceramic discharge lamp, which is small and has high luminous efficiency, are diminished. If the length is too small, the required temperature buffering action is not reliably exhibited at the time of lighting, and as a result, the frit glass 30 in the hermetic sealing region may be overheated, and the hermetic sealing structure may be damaged. .

In the arc tube portion 11 of the bulb 10, for example, mercury and a rare gas (for example, argon, xenon, neon-argon) as a buffer gas and, if necessary, for example, as in a normal discharge lamp, Certain metal halides are encapsulated as luminescent materials,
A conventionally known material is used in an appropriate amount. In this ceramic discharge lamp, the product [P × [(D−d) / 2]] of the rare gas sealing pressure and the size of the gap G is larger than 2.9 Pa · m. The condition shown in the above equation (3)] is an essential condition for preventing a back arc phenomenon from occurring at the start of lighting in a ceramic discharge lamp. Here, the sealing pressure (P) of the rare gas is, for example, 6.7 K to 27 KPa (25 ° C.), and the smaller the sealing pressure (P), the more easily the back arc phenomenon occurs.

When the ceramic discharge lamp is turned on, heat generated in the electrodes (electrode coils 22) is transferred to the electrode rods 21 and the intermediate lead rods 2 constituting the electrode structure 20.
3, is transmitted to the hermetic sealing area through the sleeve 26 and the wall of the sealing tube section 12, and the sealing tube section 12 is provided with a temperature buffering area following the arc tube section 11. Since a sufficient temperature reduction is achieved in the temperature buffer region, the frit glass 30 constituting the hermetic sealing structure in the hermetic sealing region is effectively prevented from being overheated, and the sealing structure is damaged. There is no. Moreover, by satisfying the conditions shown in the above formulas (1) to (3), no arc is generated from the end portion 27A of the metal coil 27 (back arc phenomenon) and the arc tube 11 faces the inside of the arc tube portion 11. A normal arc can be generated between the pair of electrodes (electrode coils 22) arranged.

<Specific Configuration Example 2> FIG. 3 is an explanatory cross-sectional view showing a main portion (a portion including a sealing tube portion) in another example of the ceramic discharge lamp of the present invention. Components (the arc tube part 11, the sealing tube part 12, the electrode rod 21, the electrode coil 22, the intermediate lead rod 23, and the frit glass 30) denoted by the same reference numerals as those shown in FIG. 2 are the same as those shown in FIG. It is. In the ceramic discharge lamp of this example, a metal coil 28 is wound around the outer periphery of the electrode rod 21 belonging to the temperature buffer region. This metal coil 28
It is provided to reduce the gap between the inner surface of the sealing tube portion 12 and the electrode structure 20 (electrode rod 21),
As a material of the metal coil 28, for example, molybdenum, tungsten, or the like is used. The diameter of the metal coil 28 is
For example, it is 0.1 to 0.25 mm, and is a tightly wound with a width of about 5 mm.

In this ceramic discharge lamp, the inner diameter of the sealed tube portion 12 (the inner diameter D of the straight tube portion) is set to 2 mm or less [condition shown in the above formula (1)], preferably 0.3 mm.
２2 mm. In addition, as shown in FIG.
When the distance from the end 28A of the metal coil 28 wound around 1 to the inner end face 12A of the sealing tube is L, L
The value of / [(D−d) / 2] is greater than 3.4 [conditions shown in the above equation (2)]. Furthermore, in this ceramic discharge lamp, the rare gas charging pressure (25
° C) and the size of the gap G [P × [(D−d) /
2]] is larger than 2.9 Pa · m [condition shown in the above formula (3)]. By satisfying the conditions shown in the above equations (1) to (3), no arc is generated from the end portion 28A of the metal coil 28 (back arc phenomenon) and the arc tube 11 is opposed to the inside of the arc tube section 11. A normal arc can be generated between the pair of electrodes (electrode coils 22) arranged.

<Specific Configuration Example 3> FIG. 4 is an explanatory cross-sectional view showing a main portion (a portion including a sealing tube portion) in another example of the ceramic discharge lamp of the present invention, and is shown in FIG. (Electrode structure 20, electrode rod 21, electrode coil 22, intermediate lead rod 23, sleeve 26, metal coil 27 and frit glass 30) with the same reference numerals
Are the same as those shown in FIG. The bulb 15 constituting the ceramic discharge lamp includes a cylindrical light emitting tube portion 16 surrounding the discharge space, and a straight tubular sealing tube portion connected to both ends of the light emitting tube portion 16 and extending outward. 17 and is made of translucent ceramics. Here, the outer diameter of the arc tube part 16 is 7.5 to 11.0 m.
m, the inner volume is 0.25 to 1.5 cm, the outer diameter of the sealing tube 17 is 2.0 to 2.6 mm, and the length is 32 to 40 mm.

In this ceramic discharge lamp, the inner diameter (D) of the sealing tube 17 is set to 2 mm or less (the condition shown in the above formula (1)), preferably 0.3 to 2 mm. As shown in FIG. 4, the end 27A of the metal coil 27 wound around the electrode rod 21 extends from the inner end surface 17A of the sealing tube portion (the boundary surface between the arc tube portion 16 and the sealing tube portion 17). ) Is L, the value of L / [(D−d) / 2] is greater than 3.4 [condition shown in the above equation (2)]. Further, in this ceramic discharge lamp, the product [P × [(D−d) / 2]] of the rare gas sealing pressure (25 ° C.) and the size of the gap G is larger than 2.9 Pa · m. [Conditions shown in the above equation (3)]. By satisfying the conditions shown in the above equations (1) to (3), no arc is generated from the end portion 27A of the metal coil 27 (back arc phenomenon), and the arc tube section 1
A normal arc can be generated between a pair of electrodes (electrode coils 22) opposed to each other in the inside 6.

<Specific Configuration Example 4> FIG. 5 is a cross-sectional view for explaining an example of a configuration of a metal halide lamp having a double tube structure provided with the ceramic discharge lamp of the present invention as an inner tube. The metal halide lamp shown in FIG.
It is arranged and configured within.

Inner tube 50 constituting metal halide lamp
Is, for example, a ceramic discharge lamp having the same configuration as that shown in FIG. 1 [however, instead of the intermediate lead rod (23) and the external lead rod (24) shown in FIG. 1, the same material (eg, The lead wire 52 made of niobium) is the electrode rod 2
Electrically connected to one base end].

Outer tube 51 constituting metal halide lamp
Has a pinch seal portion 55 in which a molybdenum foil 54 is embedded at the other end, having an exhaust pipe remaining portion 53 at one end,
It is made of quartz glass or hard glass. The inside of the outer tube 51 is evacuated to a vacuum. In the figure, reference numeral 56 denotes a power supply lead.
Through the molybdenum foil 54 and the internal leads 57,
It is electrically connected to the lead-in wire 52 of the inner tube 50 (the ceramic discharge lamp of the present invention). Reference numeral 58 denotes a getter made of a Zr-Al alloy, which is spot-welded to a support (not shown) provided inside the outer tube 51.

[0031]

Examples <Examples 1 to 5 and Comparative Examples 1 to 3> Under the following conditions, the configuration shown in FIG.
, A metal coil (28) is wound around the portion located in the temperature buffer region, and the sleeve is not mounted], thereby producing an AC-lit metal halide lamp having a total lamp length of 36 mm, a distance between electrodes of 6 mm, and a rated power of 70 W. .

The bulb (10) is made of translucent polycrystalline alumina (average particle diameter: about 30 μm), the maximum outer diameter of the arc tube portion (11) is 8.7 mm, and the thickness of the arc tube portion (11). The thickness is 0.7 mm, and the inner volume of the arc tube part (11) is about 0.5 mm.
3 cm ³ , and the outer diameter of the sealing tube (12) is 8.7 m
m, the length of the sealing tube (12) is 36 mm, and the inner diameter (D) of the sealing tube (12) is 1.0 mm (Examples 1 to 3).
2, Comparative Examples 1-2) or 0.75 mm (Examples 3 to 2)
5, Comparative Example 3) was used.

The electrode structure (20) has a diameter (d)
Is an electrode rod (21) made of a tungsten wire of 0.3 mm (Example 1, Example 3, Example 5, Comparative Examples 1 and 2) or 0.35 mm (Example 2, Example 4, Comparative Example 3). A tungsten wire having a diameter of 0.2 mm is wound around the tip of the electrode (number of turns: 6) to form an electrode coil (22), and a molybdenum wire having a diameter of 0.2 mm is wound around the rear end of the electrode rod (21). (Turns: 4) to form a metal coil (28). Also, the intermediate lead rod (2
3) 0.6mm diameter niobium wire, external lead rod (24)
Used a platinum alloy wire containing 20% iridium having a diameter of 0.4 mm.

In the arc tube part (11), 5.4 mg of mercury
And 4 mg of dysprosium-thallium-sodium complex iodide (DyI ₃ -TlI-NaI), and Table 1 below
In addition, an argon gas is sealed so as to attain the sealing pressure P shown in FIG. 1, and the electrode structure is inserted and arranged in the sealing tube portion (12) so as to obtain the distance L shown in Table 1 below. The lamp of the present invention and a comparative lamp were manufactured by filling a sealing frit glass (30) into the tube at the outer end of the stop tube portion (12) to form a hermetic sealing structure.

For each of the lamps obtained in the examples and comparative examples, a primary voltage of 10
Lighting was performed using a leakage transformer with an igniter (pulse voltage: 5 KV, pulse width: 20 μS) of 0 V-open voltage 240 V and short-circuit current 1.1 A, and the occurrence of a back arc phenomenon was observed. The lamp voltage during normal lighting (lamp input 75 W) is 90 V (rated).
The lamp current is 0.95 A (rated). The results are shown in Table 1 below. In addition, regarding "the presence or absence of a back arc phenomenon" in Table 1, "occurrence" means the case where the back arc phenomenon occurs even once in 20 times, "no occurrence",
This is the case where no back arc phenomenon was observed.

[0036]

[Table 1]

As is evident from the results shown in Table 1, Examples 1 to 3 satisfying all of the conditions shown in the above equations (1) to (3).
According to the lamp No. 5 (the ceramic discharge lamp of the present invention), no back arc phenomenon is observed. On the other hand, the lamp according to Comparative Example 1 in which the value of L / [(D−d) / 2] is 3.4 or less, and P × [(D−d) /
In the lamps according to Comparative Examples 2 and 3 in which the value of [2] was 2.9 or less, occurrence of a back arc phenomenon was observed.

[0038]

According to the ceramic discharge lamp of the present invention, a back arc phenomenon which causes damage to the bulb does not occur at the start of lighting of the discharge lamp.

[Brief description of the drawings]

FIG. 1 is an explanatory sectional view showing one example of a ceramic discharge lamp of the present invention.

FIG. 2 is a partially enlarged view of FIG. 1 showing a portion including a sealing tube portion.

FIG. 3 is an explanatory sectional view showing a main part of another example of the ceramic discharge lamp of the present invention.

FIG. 4 is an explanatory sectional view showing a main part of another example of the ceramic discharge lamp of the present invention.

FIG. 5 is an explanatory cross-sectional view showing an example of a configuration of a metal halide lamp having a double tube structure including the ceramic discharge lamp of the present invention as an inner tube.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Bulb 11 Light emitting tube part 12 Sealing tube part 12A Inner end face of sealing tube part 16 Light emitting tube part 17 Sealing tube part 17A Inner end surface of sealing tube part 20 Electrode structure 21 Electrode rod 22 Electrode coil 23 Intermediate Lead rod 24 External lead rod 26 Sleeve 27 Metal coil 27A End 28 Metal coil 28A End 30 Frit glass 31 Bead 50 Inner tube 51 Outer tube 52 Lead wire 53 Exhaust tube remaining 54 Molybdenum foil 55 Pinch seal 56 Power supply lead 57 Internal Lead 58 Getter

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor: Shoji Miyanaga 1194, Sado, Bessho-cho, Himeji-shi, Hyogo Ushio Electric Co., Ltd. Inside

Claims (1)

[Claims] 1. A bulb (10) comprising a light-transmitting ceramic, having an arc tube portion (11) and a sealing tube portion (12) integrally connected to the arc tube portion (11), A pair of electrodes are arranged opposite to each other in the arc tube part (11), and the electrode structure (20) having the electrode at the tip is inserted into the sealing tube part (12). Department (12)
Frit glass for sealing in the tube at the outer end of the frit (30)
Is filled with a hermetic sealing structure, a rare gas and another luminescent substance are sealed in the bulb, and the electrode structure (20) is formed in the arc tube part (11). The electrode coil (22) is wound around the portion located at the position, and the metal coil (27) is wound around the portion located within the sealing tube portion (12). Arc tube side end (27A)
, A distance from the inner end surface (12A) of the sealing tube portion (12) to L, an inner diameter of the sealing tube portion (12) to D [mm], and an electrode rod (21) constituting an electrode structure (20). The diameter of d [m
m], and the discharge pressure made of a rare gas is P [Pa]. A ceramic discharge lamp characterized by satisfying the following expressions (1) to (3). Formula (1) D ≦ 2 [mm] Formula (2) L / [(D−d) / 2]> 3.4 Formula (3) P × [(D−d) / 2]> 2.9 [Pa]・ M]