JPH07312204A - Electric discharge lamp and its manufacture - Google Patents

Abstract

PURPOSE:To shorten processing time so as to provide a long-life electric discharge lamp superior in its impact resistance and vibration resistance. CONSTITUTION:A light emitting tube 1 is provided with a pair of electrodes 5, 6 in its inside, an elliptic light emitting part 2 forming an electric discharge space, and sealing parts 3, 4 at both ends of the light emitting part 2. Light emitting metal is sealed in the inside of the light emitting part 2 in a form of halogenide. Molybdenum foils 7, 8 are sealed in the sealing parts 3, 4 respectively, electrodes 5, 6 are connected to one ends of the molybdenum foils 7, 8, and external lead wires 9, 10 are connected to the other ends respectively. Unsealed parts 11, 12 are linked to the nonemitting part sides of the sealing parts 3, 4. An outer tube 13 covers the light emitting tube 1 and holding parts 23, 24 of the outer tube 13 contact with the sealing parts 3, 4. The side faces 35, 36 of glass rings 31, 32 formed in the unsealed parts are welded and integrated with end faces 33, 34 of the outer tube 13 respectively.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a discharge lamp used for automobile headlights and the like and a method for manufacturing the same.

[0002]

2. Description of the Related Art In a conventional discharge lamp, a glass ring is formed in a non-sealed portion of an arc tube, the arc tube is put in an outer tube, and a predetermined portion of the outer tube is heated and softened to make a glass ring. There is a structure in which the outer peripheral surface and the inner peripheral surface of the outer tube are joined together to integrate the envelope and the outer tube (Japanese Patent Publication No. 5-65978). Such a discharge lamp has a problem in impact resistance and vibration resistance because the discharge lamp becomes relatively heavy due to the increase in the total length of the outer tube and the contact area of the joint portion is small.

Further, there is a structure in which a light emitting tube is put in an outer tube, the light emitting portion is covered with the outer tube, and the end portion of the outer tube is sealed by a sealing portion (Japanese Patent Laid-Open No. 5-234568). Issue). In the discharge lamp having such a structure, when the glass of the outer tube and the sealing portion are melted and integrated, the sealing portion of the arc tube that has been processed once is processed again by heat during the processing of this integration. Therefore, the airtightness between the molybdenum foil, which is the introduction foil sealed in the sealing portion, and the glass in the sealing portion, that is, the airtightness inside the sealing portion is impaired, causing a leak, which is a disadvantage. In addition, a crack due to thermal strain is generated by a heat cycle while the lamp is on. Further, when only the outer tube is melted and covers the sealing portion, there is a problem with respect to shock resistance and vibration resistance because the glasses are only in contact with each other.

Then, there is a structure in which the arc tube is put in an outer tube, and the outer tube covers the light emitting section and the sealing section, and the end portion of the outer tube is connected to the non-sealing section (Japanese Patent Laid-Open No. H11 (1999) -264242). 6-20645). The discharge lamp having such a structure is described in Japanese Patent Publication No.
As in Japanese Patent Laid-Open No. 65978, the discharge lamp becomes relatively heavy due to the increase in the total length of the outer tube, and further, there is a problem with respect to shock resistance and vibration resistance because the contact area of the joint portion is small.

Further, in each of the above-mentioned conventional examples, the outer tube is directly heated by the flame of the burner and the like, but the unsealed portion and the sealed portion inside the outer tube are not directly heated. It takes a long time to melt the part and the workability is poor. In addition, there is a problem in that it is difficult to visually confirm that the outer tube, the non-sealed portion, and the sealed portion are melted and completely welded.

[0006]

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned conventional problems, and shortens the heating time during processing to improve workability, as well as impact resistance and impact resistance. It is an object of the present invention to provide a long-life discharge lamp excellent in vibration resistance and a method for manufacturing the discharge lamp.

[0007]

DISCLOSURE OF THE INVENTION The discharge lamp of the present invention comprises:
A light emitting part having a pair of electrodes inside, a sealing part continuously provided at both ends of the light emitting part, and a disc-shaped bulging part, and continuously provided on the side opposite to the light emitting part of the sealing part. An arc tube having a non-sealed portion having a tubular shape, and an outer tube provided so as to cover the arc tube, and at least one end of the outer tube,
The sealing portion or the sealing portion and the non-sealing portion are in contact with each other, and the side surface of the bulging portion is welded to the end surface of the outer tube. Further, the method for manufacturing a discharge lamp of the present invention has a light emitting part having a pair of electrodes inside, a sealing part continuously provided at both ends of the light emitting part, and a disk-shaped bulging part, and At least one end of the outer tube is provided with an arc tube having a tube-shaped non-sealing section continuously provided on the side opposite to the light emitting section of the sealing section, and an outer tube provided so as to cover the arc tube. A method for manufacturing a discharge lamp, wherein the side surface of the bulging portion is welded to an end surface of the outer bulb, the outer bulb being in contact with the sealing portion, or the sealing portion and the non-sealing portion. At least one end of which is softened by heating, the sealing portion,
Or after contacting over the sealed portion and the non-sealed portion, a predetermined region of the non-sealed portion is heated to a softening point,
The bulging portion is formed in the non-sealing portion by applying a compressive force to the glass softened in the axial direction toward the light emitting portion, and the side surface of the bulging portion and the end surface of the outer tube are heat-welded. The arc tube and the outer tube are integrated.

[0008]

With this structure, the time required for welding can be shortened, and it can be confirmed that the disc-shaped bulging portion and the outer tube are reliably welded and integrated in appearance.

[0009]

EXAMPLE A discharge lamp A which is an example of the present invention will be described below.
Will be described with reference to the drawings.

In the discharge lamp A of the embodiment of the present invention shown in FIGS. 1 and 2, the arc tube 1 has an ellipsoidal shape which has a pair of electrodes 5 and 6 made of, for example, tungsten inside and forms a discharge space. The light emitting section 2 and the sealing sections 3 and 4 are provided at both ends of the light emitting section 2. Inside the light emitting portion 2, a light emitting metal such as sodium and scandium is enclosed in the form of a halide together with xenon and mercury. Sealing part 3,
4, electrodes 5 and 6 are connected to one end and external lead wires 9 and 10 are connected to the other ends, and molybdenum foils 7 and 8 are respectively sealed as introduction foils. Non-sealing portions 11 and 12 in the shape of circular tubes are continuously provided on the side opposite to the light emitting portions of the sealing portions 3 and 4. The circular tube-shaped outer tube 13 that blocks the ultraviolet light emitted from the arc tube 1 during lighting covers the arc tube 1, and the holding portions 23 and 24 of the outer tube 13 contact the sealing portions 3 and 4. ing. Outer tube 13 and side surfaces 35 and 36 of glass rings 31 and 32, which are disk-shaped bulging portions formed in unsealed portions 11 and 12, respectively.
The arc tube 1 and the outer tube 13 are integrated by welding the end surfaces 33 and 34 of the above. This makes it possible to obtain the discharge lamp A having excellent impact resistance and vibration resistance.

Next, a method for manufacturing the above-described discharge lamp according to one embodiment of the present invention will be described. As shown in FIG. 3, an arc tube 1 and an outer tube 13 manufactured by a normal manufacturing method.
Is attached to an ordinary glass lathe 14. The lathe 14 has a headstock 15 on one side and a tailstock 16 on the other side. The headstock 15 has a collet chuck 17 for mounting the non-sealing portion 11, and the tailstock 1
6 has a collet chuck 18 for attaching the non-sealing portion 12. The arc tube 1 is fixed by inserting the non-sealing portion 11 into the collet chuck 17 and inserting the non-sealing portion 12 into the collet chuck 18.
It is installed in 4. In the outer tube 13, the arc tube 1
The outer tube 13 is fixed to the outer tube fixing base 19. The outer tube fixing base 19 is provided on the tailstock 16 of the lathe 14 and rotates together with the tailstock 16 about the shaft 20. On the other side of the headstock 15, the non-sealing portion 11
A nitrogen supply pipe 21 for flowing a nitrogen gas to and a nitrogen discharge pipe 22 for discharging the nitrogen gas are connected.
A burner 25 and a processing jig 26 are provided adjacent to the holding portion 23 of the outer tube 13, and the burner 25 includes the holding portion 23.
The localized fixing area 27 on the peripheral surface is heated by the flame 28. Further, the processing jig 26 is provided so as to be movable vertically to the shaft 20.

As shown in FIG. 4, the arc tube 1 fixed to the lathe 14 rotates together with the lathe 14 as the lathe 14 rotates about the shaft 20, and the outer tube 13 is fixed. The outer tube fixing base 19 also rotates about the shaft 20. Nitrogen gas is caused to flow into the non-sealing portion 11 while rotating the lathe 14. Then, while flowing the nitrogen gas, the arc tube 1 turns into the lathe 1.
While slowly rotating around the shaft 20 by 4, the flame 28 heats the fixing region 27 of the holding portion 23 until the quartz in the fixing region 27 reaches the softening point. Although the processing jig 26 is stationary during this heating operation, when the quartz in the fixing region 27 is sufficiently softened, the processing jig 26 moves vertically toward the shaft 20 and slowly presses the fixing region 27. Compress it. By this operation, the holding portion 23 and the sealing portion 3 are brought into contact with each other. After the holding portion 23 and the sealing portion 3 come into contact with each other, the above-described operation is performed by the sealing portion 4 of the arc tube 1 and the holding portion 24 of the outer tube 13.
Repeatedly for the sealing part 4 and the holding part 2.
4 can be contacted.

As shown in FIG. 5, the holding portion 2 of the outer tube 13
After bringing the non-sealing parts 11 and 12 into the collet chucks 17 and 18, respectively, after bringing the non-sealing parts 11 and 12 into contact with each other, the outer pipe fixing base 19 holding the outer pipe 13 is fixed. Get rid of. Non-sealing part 1 while rotating the lathe 14
Nitrogen gas is flowed into 1. Then, while flowing the nitrogen gas, while the arc tube 1 is slowly rotated around the shaft 20 by the lathe 14, the region 30 is heated by the flame 28 until the quartz in the region 30 reaches the softening point, and the tailstock is heated. By moving 16 to the left in the direction of the axis 20 and applying a compressive force to the softened region 30, a disk-shaped glass ring 31 is formed,
The side surface 35 of the glass ring 31 and the end surface 33 of the holding portion 23 of the outer tube 13 are integrated by heating and welding with a flame 28. After the side surface 35 of the glass ring 31 and the end surface 33 of the holding portion 23 of the outer tube 13 have been welded, the above-described operation is performed by the side surface 36 of the glass ring 32 and the end surface 3 of the holding portion 24 of the outer tube 13.
4 is repeated, so that the arc tube 1 and the outer tube 1
3 can be firmly integrated. At the time of this integration, since the flame 28 directly hits the side surfaces 35 and the end surfaces 33, and the side surfaces 36 and the end surfaces 34 of the glass rings 31, 32, respectively, the welding, that is, the arc tube 1 and the outer tube 13 are integrated in a short time. In addition, it is possible to easily confirm that they are welded by the appearance.

In the case of forming a discharge lamp, as shown in FIG. 6, the outer tube 38 is provided with an exhaust tube 37 for evacuating the inside of the outer tube 38 and filling with an inert gas. After welding the side surfaces 35, 36 of 31, 32 and the end surfaces 33, 34 of the outer pipe 38, respectively, the outer pipe 38 is evacuated or filled with an inert gas through the exhaust pipe 37, and the exhaust pipe 37 is squeezed or The inside of the outer tube 38 may be sealed by using the method described above.

FIG. 7 shows a discharge lamp device B for a headlamp, which is an application example using the discharge lamp A which is one embodiment of the present invention.
Is shown.

The non-sealing portion 11 of the discharge lamp is inserted into and supported by the base 39, and the external lead wire 9 is connected to an insulating coated electric wire 40 penetrating through the base 39 and led out to the side opposite to the discharge lamp. The external lead wire 10 of the discharge lamp is connected to one end of a power supply line 41.
The other end of is connected to an insulating coated electric wire 42 which penetrates the base 39 and is led out to the side of the base 39 opposite to the discharge lamp. The power supply line 41 is covered with a ceramic sleeve 43. The base 39 has a lid 44 made of ceramic. The lid 44 is fixed by thermally deforming the pin 45 of the base. This makes it possible to obtain a long-life discharge lamp device B for a headlamp, which is excellent in impact resistance and vibration resistance.

[0017]

As described above, according to the present invention, the time required for heating can be shortened, and it can be recognized from the appearance that the glass ring and the outer tube have been reliably welded, and therefore workability is improved. It is possible to provide a long-life discharge lamp which is improved, has a shorter overall length and a lighter weight, and has excellent shock resistance and vibration resistance, and a method for manufacturing the same.

[Brief description of drawings]

FIG. 1 is a front view of a discharge lamp A which is an embodiment of the present invention.

FIG. 2 is an exploded perspective view of the same.

FIG. 3 is an explanatory view of a method for manufacturing a discharge lamp A which is an embodiment of the present invention.

[FIG. 4] Similarly, an explanatory diagram

[FIG. 5] Similarly, an explanatory diagram

FIG. 6 is an explanatory view when an exhaust pipe is used as a glass tube for blocking ultraviolet rays.

FIG. 7 is a partially cutaway front view of a headlamp discharge lamp device B as an application example using a discharge lamp A according to an embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Arc tube 3,4 Sealing part 11,12 Non-sealing part 13 Outer tube 31,32 Glass ring 33,34 End surface of outer tube 35,36 Side surface of glass ring

Claims (3)

[Claims] 1. A light emitting part having a pair of electrodes inside, a sealing part continuous with both ends of the light emitting part, and a disc-shaped bulging part, and an anti-light emitting part of the sealing part. An arc tube having a tube-shaped non-sealing portion continuously provided on the side, and an outer tube provided so as to cover the arc tube, wherein at least one end of the outer tube has the sealing portion, or A discharge lamp which is in contact with the sealed portion and the non-sealed portion, and a side surface of the bulging portion is welded to an end surface of the outer tube. 2. A light emitting portion having a pair of electrodes inside, a sealing portion continuously provided at both ends of the light emitting portion, and a disc-shaped bulging portion, and an anti-light emitting portion of the sealing portion. An arc tube having a tube-shaped non-sealing portion continuously provided on the side, and an outer tube provided so as to cover the arc tube, wherein at least one end of the outer tube has the sealing portion, or A method of manufacturing a discharge lamp in which the side surface of the bulging portion is welded to an end surface of the outer tube, which is in contact with the sealed portion and the non-sealed portion, and at least one end portion of the outer tube is softened by heating. Then, after contacting over the sealing portion or the sealing portion and the non-sealing portion, a predetermined region of the non-sealing portion is heated to a softening point, and glass softened in the axial direction toward the light emitting portion. The bulging portion is formed in the non-sealing portion by applying a compressive force to the bulging portion. A method of manufacturing a discharge lamp, characterized in that the arc tube and the outer tube are integrated by heating and welding the side surface of the portion and the end surface of the outer tube. 3. The outer tube of the outer tube is pressed against the sealed section or the sealed section and the unsealed section by a processing jig while heating and softening the end section of the outer tube. The method for manufacturing a discharge lamp according to claim 2, wherein one end portion is brought into contact with the sealing portion or the sealing portion and the non-sealing portion.