JPS6226144B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a high pressure discharge lamp, and more particularly to an arc lamp having a novel sealing mechanism between an envelope and a window.

In any arc lamp, various parts of the interior are placed at different potentials in response to some electrodes. Therefore, it is necessary to insulate each part so as to maintain electrical insulation between these parts. For example, US Patent Nos. 3,876,908, 3,852,629,
The conventional high-pressure arc lamp described in No. 3808496 uses a ceramic cylinder that divides the envelope into an anode portion and a cathode portion, and the peripheral surface of the insulator is used as part of the exterior of the envelope. use. As a result of this construction, the design, operation, and use of arc lamps is subject to a number of severe constraints.

One such severe constraint is related to the temperatures and internal pressures to which ceramics and ceramic-to-metal joints are subjected. Ceramic cylinders or rings so used are subject to tensile stresses primarily due to the high pressure gas filling of the arc lamp, with the result that the anode and cathode sections tend to be pushed apart. The metal brazed to the ceramic joints of these conventional arc lamps also produces tensile or shear stresses. Depending on the properties of the brazing alloy and metal components, the stresses within the joint must be kept below safe tolerances. This stress is thermally affected and limits the operation of the arc lamp and associated cooling system.

Another severe constraint is the ambient environment in which arc lamps are operated. Moisture, dirt, grease, fingerprints, etc. can significantly degrade the insulating properties of ceramics, especially under high voltage starting conditions. Additionally, exposed ceramic can crack under impact.

Additionally, failure of the metal-to-ceramic seal or ceramic in a high-pressure arc lamp can pose a hazard to nearby personnel or equipment.

Another conventional arc lamp, described in U.S. Pat. No. 3,715,613, uses a ceramic cylinder with a concave surface to accommodate a metal disk supporting an anode structure. The outer surface of this cylinder is brazed to the inner surface of the neck of the envelope. Therefore, this neck, which is a metal ring, creates compressive and shear stresses at one end of the cylinder due to the internal gas pressure, while the outer wall of the cylinder, which is brazed to the inner surface of the neck, creates compressive and shear stresses at one end of the cylinder due to the internal gas pressure. Shear stress is generated by

Another feature of arc lamps is that they have optical windows that must withstand very large pressure differences between the outside and the inside of the arc lamp, ensuring an effective seal of such windows. Obtaining a device is the subject of the invention. Conventional window seals for such arc lamps, as shown, for example, in U.S. Pat. I brazed the legs and then brazed them to the window/cathode subassembly. Although this window sealing technique provided an improved seal, it is not as good as the sealing mechanism detailed below in accordance with the present invention.

An arc lamp utilizing the window sealing system of the present invention includes a seal configured to compress a ceramic insulator and an associated brazing material.
This is constructed by placing the ceramic between a radially outwardly projecting flange of the inner cylindrical member of the arc lamp body and a radially inwardly projecting flange of the arc lamp's outer cylindrical member. Ru. The two cylindrical members are coaxial and overlap each other. Internal pressure within the envelope exerts a compressive force on the ceramic.

In an arc lamp having such a structure, the present invention particularly aims to provide a sealing mechanism between the window on the front side of the arc lamp and the metal surrounding member surrounding the window by using knife edge brazing. This creates compressive stress in the direction across the bond between the metal that makes up the sealing mechanism and the sapphire that makes up the window, as well as in the thickness direction of the window itself. It seeks to reduce the high tensile stresses that can be imposed on windows by contained high pressure gases.

An object of the present invention is to provide an arc lamp that has higher performance than conventional lamps, can be manufactured at a lower cost, and is safe and durable.

A more specific object of the present invention is to provide a sealing mechanism between a window and a surrounding metal enclosure for obtaining a sturdy arc lamp as described above.

According to a feature of the invention, the sealing mechanism is constituted by an annular thin edge member, preferably made of Kovar alloy, having a first edge portion and a second edge portion; The first edge portion is preferably secured by brazing to the peripheral edge of the outer surface of the window, and the second edge portion projects radially inwardly from a metal enclosure surrounding the window inside the arc lamp envelope. It is preferably fixed to the flange portion by brazing. For brazing the first edge to the window, it is desirable to metallize the periphery of the outer surface of the window. In the present invention, the thin edge member may have a thickness to width ratio of 1:5 or greater and does not necessarily have to be a sharp or thin edge.

Next, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 shows the entire high-pressure beam shot arc lamp including a sealing device according to the present invention.
The cathode 10 is mounted in the front part of the arc lamp adjacent to the window 11. The cathode 10 is supported and fixed at the center of a metal support 12. Getter 13 is installed to remove contaminant gases from the gas fill within the arc lamp. The strut 12 is secured near its outer end to a metal enclosure or ring 14. A reflector 16 is suspended from the metal ring 14. The exterior of the front portion of the arc lamp is a cylindrical sheath 18 made of a high strength metal alloy, such as stainless steel.

A first edge of an annular sealing ring 21, which is a thin edge member, is brazed to the periphery of the outer surface of window 11, which is preferably made of sapphire. The ring 21 is preferably made of Kovar alloy. The outer peripheral edge of the window to be brazed to the first edge is preferably metallized as described above.

The metal ring 14 has a flange 14' projecting inwardly from the inner periphery of its front end, and the second edge of the sealing ring 21 is brazed to the inner surface of the flange 14'. In this way, the window 11 and the metal ring 14 surrounding it are separated by the sealing ring 2.
They are joined to each other only through 1, and are separated from each other at other parts. The advantages of such window-to-metal bonding are discussed below.

Although the window 11 is subjected to the same bending moments in its plane as a conventional arc lamp window, the outer peripheral area or rim portion of the window 11, along with the window-to-metal joint, is subjected to compressive loads, resulting in reduced tensile stresses. Because the ultimate strength of sapphire against compressive forces is much greater than its ultimate strength against tensile forces, the illustrated sealing mechanism of the present invention can withstand much greater internal pressures than conventional sealing schemes with sapphire windows of the same thickness. Endure. The circumferential seal using the conventional method became impossible to seal at 84Kg/ ^cm2 , but
The compressive load type window sealing mechanism according to the present invention has a weight of 150 kg/
Tests have confirmed that sealing is not impossible even at cm ² . When the outer peripheral surface 19 of the window 11 is exposed to the internal gas pressure, a compressive stress is generated in the diametrical direction of the window, and as a result, the breakage resistance is increased. Also, the braze between window 11 and sealing ring 21 is compressed by high internal gas pressure. Thus, the present invention allows the use of higher internal pressures or thinner sapphire windows while maintaining the same structural strength as conventional arc lamps.

Continuing with the other parts of the arc lamp shown in FIG. 1, the anode 22 is supported at the rear of the arc lamp. Fixed around the anode 22 is an outer cylinder 28 made of a high strength alloy. The front outer cylinder 18 and the rear outer cylinder 28, which constitute the outer envelope of the arc lamp, are attached to a ring 25 made of high-strength ceramic.
8 and 28 are connected. Sealing ring 29 made of Kovar alloy, for example
is used to seal the ceramic ring 25 to the anode outer cylinder 28 and the cathode outer cylinder 18 to form a sealed envelope. Cathode outer cylinder 18 and anode outer cylinder 2
8 is formed in a shape that compresses the ceramic ring 25 and protects the ceramic ring 25 from contamination and impact. This is accomplished by forming the cathode sheath 18 with an inwardly projecting flange 30 and the anode sheath 28 with an outwardly facing flange 32. The flanges overlap each other so as to cut out a common radius area about centerline 34. Ceramic ring 25
occupies this common radius region. The internal pressure thus serves to keep the envelope together. Because the cathode sleeve 18 overlaps the ceramic ring 25 from the outside, the ceramic ring 25 is protected from contamination that could cause short circuits and from damaging impacts. Even if a ceramic ring were to break, its fragments would not harm nearby people or equipment for the same reason. Further, even if the ceramic ring or its seal fails, the cathode outer cylinder 18 and the anode outer cylinder 28 are prevented from being separated by the flanges 30 and 32.

Typical ceramics used above have a tensile to compressive strength ratio of greater than 10 to 1. Therefore, the ceramic ring exhibits much greater strength against compressive stress resulting from the high-pressure gas filling of gas lamps than conventional products that are subject to tensile stress.

When manufacturing a ceramic ring 25 to be brazed, it is only necessary to polish its flat end faces, which is easier than when manufacturing a round surface to be brazed. Similarly, outer cylinders 18 and 2
Rather than brazing to the round surfaces of flanges 30 and 32, it is sufficient to simply braze to the flat surfaces of flanges 30 and 32. The seal is a knife edge braze which is subjected to almost pure compressive stress.

FIG. 2 shows for reference another example of a sealing ring 29, in which double coaxial rings 29' and 29'' are used instead of a single ring 29. As another example of the sealing mechanism of the present invention for sealing the window 11 to the ring 14, the third
A double sealing ring 21', 21'' is shown in the figure.

When assembling the arc lamp of FIG. 1, the brazing operations necessary to seal the cathode sheath 18 to the anode sheath 28 are first performed. The ring 14 supporting the window 11 and the cathode 10 is brazed to the cathode outer cylinder 18 as the last thing to be brazed. The arc lamp is then filled with xenon through opening 36 to high pressure. Opening 36 is then sealed.

[Brief explanation of the drawing]

FIG. 1 is a sectional view of one embodiment of a high-pressure arc lamp including a sealing mechanism according to the present invention, and FIG. 2 is a partial sectional view showing another embodiment of the ceramic seal portion of the arc lamp of FIG. , FIG. 3 is a partial cross-sectional view of another embodiment of the window sealing mechanism according to the present invention. DESCRIPTION OF SYMBOLS 11... Window, 14... Metal ring (metallic surrounding member), 14'... Flange portion, 21... Sealing ring (thin edge member), 18, 28... Outer enclosure.

Claims (1)

[Scope of Claims] 1. An arc lamp having a metal enclosing member and a window, the outer surface of the window forming part of the outer surface of an envelope for containing gas at atmospheric pressure or higher, A sealing mechanism is provided for forming an airtight seal between the metallic enclosure member and the window, the sealing mechanism comprising a thin edge member disposed between the metallic enclosure member and the window. the thin edge member is in contact with the window only where a first edge thereof abuts a peripheral edge of the outer surface of the window, and the thin edge member is separated from the window and the metal enclosure member; . The arc lamp, wherein the second edge portion of the thin edge member abuts a flange portion projecting radially inward from the metal surrounding member. 2. The arc lamp according to claim 1, wherein a peripheral edge of the outer surface of the window is metallized, and the first edge portion of the thin edge member is brazed to the metallized portion. arc lamp. 3. The arc lamp according to claim 1, wherein the second edge portion of the thin edge member is brazed to the inwardly protruding flange portion of the metal surrounding member. 4. The arc lamp according to claim 2, wherein the outer surface of the window is circular and the thin edge member is annular. 5. The arc lamp according to claim 2, wherein the thin edge member is made of Kovar alloy.