JPH117918A - Molybdenum foil glass sealing part and electric lamp provided therewith - Google Patents

Abstract

PROBLEM TO BE SOLVED: To decrease a danger in which glass is cracked at a molybdenum foil end by sealing at a bulb power supply part of an electric lamp a molybdenum foil of a rectangular plane on which a lead wire and an electrode are welded, and sharpening in wedge shape an end partitioned by both side edges opposite to this molybdenum foil. SOLUTION: In an electric lamp provided with a power supply part of a bulb having a molybdenum foil glass sealing part, a glass based compression sealing part 1 for a quarts glass based quartz bulb consists of a molybdenum foil sealed with air tightness in a glass of the compression sealing part 1 and an electrode pin 6 intruded into an internal chamber of the bulb. A lead wire 3 and the electrode pin 6 are welded to a molybdenum based molybdenum foil, the molybdenum foil continuously decreases from a center toward both side edges, an end part 4c partitioned by a cutting edge 4b on both ends thereof is sharpened in wedge shape, and a welding point 7 between an electrode pin 5 and the molybdenum foil of the lead wire 3 is removed from the end part 4c.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a molybdenum foil glass sealed portion and an electric lamp having the molybdenum foil glass sealed portion.

[0002]

BACKGROUND OF THE INVENTION Molybdenum foil glass enclosures are required, for example, for the hermetic power supply in quartz glass bulbs of high pressure discharge lamps and halogen lamps. Here, quartz glass is defined as having a silicon dioxide content of at least 95.
Refers to glass that is weight percent. The quartz glass of the glass sphere has a much smaller coefficient of thermal expansion than the power supply projecting from the glass sphere, usually made of molybdenum wire used to supply electrical energy to the illuminant located inside the glass sphere Therefore, it is not possible to hermetically enclose the power supply line directly in the quartz glass of the glass bulb without taking additional measures. For example, when the glass bulb warms up while the lamp is turned on, the molybdenum power supply line thermally expands about 10 times as much as the surrounding quartz glass. The resulting mechanical stress causes the quartz glass to crack. However, using a very thin molybdenum foil with sufficient ductility to produce a hermetic power supply for the glass spheres, although the thermal expansion of quartz glass and molybdenum is different, which creates mechanical stress. Can be. For this purpose, the opposing ends of the molybdenum foil are usually welded with molybdenum leads, respectively, and the resulting structural unit is such that one lead penetrates into the interior of the glass bulb, The other lead is positioned at the end of the glass bulb to be sealed such that it protrudes from the glass bulb. The quartz glass at the glass bulb end is then melted and the glass bulb end is pressed hermetically onto a structural unit consisting of molybdenum foil and leads, for example by means of a pressing jaw. As a result, the molybdenum foil is completely embedded in the quartz glass at the end of the glass bulb. That is, the power supply portion composed of the lead wire and the molybdenum foil is hermetically sealed at the end of the glass bulb in the region of the molybdenum foil.

The molybdenum foil encapsulation thus fulfills two different functions here. That is, the encapsulation is used, firstly, to electrically connect the illuminant disposed inside the glass bulb to a lead wire protruding from the glass bulb, and secondly, to ensure a hermetically sealed chain of the glass bulb. Molybdenum foil is usually cut from stock tape. The molybdenum foil thus has a rectangular plane defined by two side edges and two cutting edges extending perpendicular thereto. The surface of the molybdenum foil is usually convexly curved, i.e. the thickness of the molybdenum foil decreases continuously from its center towards the side edges.

[0004] In US Pat. No. 4,587,454, a molybdenum foil glass enclosure having a molybdenum foil whose surface has been roughened by sandblasting to prevent cracking of the glass is known. The molybdenum foil has a lancet-shaped cross-section, i.e., the thickness of the molybdenum foil decreases continuously from its maximum thickness at its center to both edges extending longitudinally at right angles to the molybdenum foil cutting edge. doing.

[0005] DE 2947230 describes a molybdenum foil glass enclosure for sealing glass spheres made of at least 95% by weight of quartz glass. Molybdenum foils containing 0.25-1% by weight yttrium oxide have been utilized to reduce the occurrence of cracks in the glass.

[0006] It has been found that cracks in the glass surrounding the molybdenum foil glass enclosure cannot always be reliably prevented by the above-described measures in the prior art. It has been found that the glass surrounding the molybdenum foil frequently cracks, especially at the edges defined by the cutting edges of the molybdenum foil.

[0007]

It is an object of the present invention to provide a molybdenum foil glass enclosure which does not have the disadvantages mentioned above. The aim is to reduce the risk of cracking of the glass, especially at the molybdenum foil edges defined by the cutting edges. Another object of the invention is to provide a lamp having a better seal in the area of the power supply.

[0008]

According to the present invention, there is provided, in accordance with the present invention, at least one molybdenum foil having at least one end defined by a cutting edge;
Molybdenum foil comprising a glass body containing at least one molybdenum foil in a gas-tight manner and containing at least one molybdenum foil by weight and one or more metal pins or wires connected to the at least one molybdenum foil. In the glass enclosure, at least one end defined by the cut edge of the at least one molybdenum foil is formed in a wedge shape. Further, according to the present invention, an electric lamp including one or a plurality of glass spheres, a light-emitting body sealed in the glass sphere, and a power supply unit includes the above-described molybdenum foil glass-sealed part. Particularly advantageous embodiments of the invention are described in the respective dependent claims.

In the molybdenum foil glass enclosure according to the present invention, at least one end defined by the cutting edge of the molybdenum foil enclosed in the glass is formed in a wedge shape. By this treatment, the curl formed on the cutting edge when the molybdenum foil is cut from the stock tape is erased again, and the curl generated during this cutting causes a crack or a crack in the glass surrounding the molybdenum foil. I will not let you. The wedge shape of the molybdenum foil edge defined by the cutting edge is advantageously formed by rolling the molybdenum foil. This rolling process smoothes the emergency bounce at the cutting edge of the molybdenum foil.
At least one molybdenum foil of the molybdenum foil glass enclosure according to the invention is defined by two cutting edges and two side edges extending perpendicular thereto, and has a lancet-shaped cross-section parallel to the cutting edges. Have. Thereby, the molybdenum foil has a convexly curved surface which reduces the mechanical stress in the molybdenum foil glass enclosure. The molybdenum foil glass enclosure according to the invention can be advantageously applied, in particular, to hermetically seal the power supply to the glass bulb of the lamp.

[0010]

BRIEF DESCRIPTION OF THE DRAWINGS The invention is explained in more detail below with reference to an advantageous embodiment shown in the drawing.

FIG. 1 shows a squeeze seal 1 for a quartz glass bulb 2 in an electric lamp with a glass bulb power supply with a molybdenum foil glass enclosure according to the invention. The power supply comprises a lead wire 3 projecting from the glass bulb 2, a molybdenum foil 4 hermetically sealed in the quartz glass of the squeeze seal 1, and electrode pins 6 entering the inner chamber 5 of the glass bulb 2. I have. The lead wires 3 and the electrode pins 6 are also made of molybdenum, and these are both welded to the molybdenum foil 4. The molybdenum foil 4 has a rectangular flat surface, and its edges are formed by cutting edges 4b on both sides located opposite to each other and both side edges 4a extending in the longitudinal direction AA perpendicular to these cutting edges 4b. .
The cutting edge 4b is formed when the molybdenum foil 4 is cut from the stock tape. The surface of the molybdenum foil 4 is curved in a convex shape, that is, the thickness thereof is from the center of the molybdenum foil to both side edges 4.
Since it decreases continuously toward a, the molybdenum foil 4 has a lancet-shaped cross section parallel to its cutting edge 4b (see FIG. 4). Cutting edge 4 of molybdenum foil 4
The end 4c defined by b is pointed in a wedge shape.
In order to obtain this wedge shape, the molybdenum foil tip 4c is rolled before welding the molybdenum foil 4 to the lead wire 3 and the electrode pin 6. A welding point 7 between the electrode pin 6 and the molybdenum foil 4 or between the lead wire 3 and the molybdenum foil 4 is removed from the wedge-shaped foil end 4c. The drawings in FIGS. 1 to 4 are shown schematically rather than to scale. The thickness of the molybdenum foil 4 is about 20 μm at the center of the molybdenum foil.
It is. The diameter of the lead wire 3 and the electrode pin 6 is at least 20 times larger than the thickness of the molybdenum foil.

In order to form a molybdenum foil glass enclosure, a rectangular piece of molybdenum foil 4 is cut from a molybdenum tape wound on a storage roll. The molybdenum tape is already convexly curved, i.e. its thickness decreases continuously from the center of the tape toward the side edges. Thus, the molybdenum foil 4 also has a convex curved portion. The molybdenum foil edge 4c is sharpened in a wedge shape by rolling to remove the curl at the cutting edge 4b of the molybdenum foil 4. The ends of the molybdenum foil 4 are welded outside the wedge-shaped area 4c to the lead wires 3 or the electrode pins 6, also made of molybdenum. The structural units 3, 4, 6 thus produced are introduced into the glass bulb to be hermetically sealed. Subsequently, the quartz glass 1 is softened at the end of the glass bulb by heating, and is pressed against the molybdenum foil 4 by, for example, a pressing jaw.
After the quartz glass 1 is cooled, the lead wires 3 and the electrode pins 6
And a structural unit composed of the molybdenum foil 4 forms a power supply portion for the glass bulb 2 hermetically sealed at the glass bulb end at the portion of the molybdenum foil 4.

[Brief description of the drawings]

FIG. 1 is a schematic plan view of a power supply section of a glass sphere provided with a molybdenum foil glass enclosure section according to the present invention.

FIG. 2 is a schematic side view of a power supply unit of the glass sphere in FIG.

FIG. 3 is a partially enlarged cross-sectional view of a power supply unit taken along line AA in FIG. 1;

FIG. 4 is a partially enlarged cross-sectional view of a power supply unit along a line BB in FIG. 1;

[Explanation of Signs] 1 Press-sealed portion (glass body) 2 Glass ball 3 Lead wire 4 Molybdenum foil 4a Molybdenum foil side edge 4b Molybdenum foil cutting edge 4c Molybdenum foil end 6 Electrode pin

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Rotar Former Germany 12359 Berlin Bachbergstrasse 10 a (72) Inventor Dirk Grundmann Germany 10115 Berlin Linienstrasse 95 (72) Inventor Joachim Omke Germany 12169 Berlin Menkenstrasse 3

Claims (6)

[Claims] 1. At least one molybdenum foil (4) having at least one end (4c) defined by a cutting edge (4b) and at least one molybdenum foil comprising at least 95% by weight of silicon dioxide (1). 4) comprises a glass body (1) hermetically sealed and one or more metal pins (6) or metal wires (3) connected to at least one molybdenum foil (4). The molybdenum foil glass, wherein at least one end (4c) defined by a cut edge (4b) of the at least one molybdenum foil (4) is formed in a wedge shape in the molybdenum foil glass enclosure. Enclosure. 2. The at least one molybdenum foil (4) is defined by two cutting edges (4b) and two side edges (4a) extending perpendicular to the cutting edges, with respect to the cutting edges (4b). 2. The molybdenum foil glass enclosure according to claim 1, wherein the molybdenum foil glass enclosure has a lancet-shaped cross section in parallel. 3. The molybdenum foil glass enclosure according to claim 2, wherein both ends of the at least one molybdenum foil (4) defined by the cut edges (4b) are formed in a wedge shape. 4. An electric lamp comprising one or a plurality of glass spheres, a luminous body sealed in the glass sphere, and a power supply section, wherein the one or more molybdenum according to claim 1 is provided. An electric lamp having a foil glass enclosure. 5. An electric lamp comprising one or more glass spheres, a luminous body sealed in the glass spheres, and a power supply having at least one molybdenum foil glass enclosure according to claim 1. 1) is a hermetically sealed end of the glass bulb (2), and is a metal pin (6) or a metal wire (3).
Is a power supply unit for supplying energy to the luminous body. 6. At least one end (4) defined by a cutting edge (4b) of at least one molybdenum foil (4).
The method for producing a molybdenum foil glass-enclosed portion according to claim 1, wherein the wedge shape of (c) is formed by rolling.