SU1220027A1 - Flash gaseous-discharge lamp - Google Patents

Abstract

This invention relates to gas discharge lighting lamps operating in repetitive flash mode. The purpose of the invention is to increase reliability, light output, mechanical strength and service life while simplifying its manufacture and without increasing its size. The lamp contains a discharge flask (RK) 1 of a quartz tube bent in the form of a flat ring, the ends 2 of which are bent down perpendicular to the plane of the ring downwards. At the ends of the 2 hermetically mounted electronic components. In RK, at least one quartz tube 6 is welded perpendicular to the ring plane and directed downwards. The internal cavity of the tube 6 communicates with the internal volume RK 1 through the opening 7. The tube 6 may, in the manufacture of the lamp, serve as a discharge stamp, in this case, after vacuum processing the lamp, by sealing the tube below the getter 8, form a sealed barrier 9, after which the lamp is sealed. This simplifies the manufacture of lamps. Pumping can proceed: through one or several tubes 6 at once, which speeds up the vacuuming process and increases its quality. The raids formed in RC 1 when the lamp is in operation are deposited in the volumes of the tubes 6 as colder zones, which further increases the light output of the lamp. 1 hp f-ly, 2 ill. C 3 (L | C go yo

Description

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This invention relates to gas discharge lamps; operating in the repetitive flash mode, and attached as a high-intensity light source in the light signal devices for optical location, and so on.

The purpose of the invention is to improve the reliability of j light efficiency, mechanical strength and service life while simultaneously simplifying its manufacture without increasing the dimensions.

Fig, 1 shows a lamp with a single dielectric tube; Fig, 2 - then OK, with three tubes.

A pulse gas discharge lamp contains a discharge tube 1 of a quartz tube bent as a flat ring, the ends 2 of which are bent perpendicularly to the plane of the ring downwards. The gap between the ends 2 of the bulb 1 is mini-male (1-2 mm), therefore there is almost no gap reduces the uniformity of the intensity distribution of the lamp. At the ends 2, hermetically mounted electrode nodes consisting of working electrodes 3, foil current leads A. and conclusions 5 are installed. The ends 2 are firmly fixed in the recesses of the socle (not shown), and on the outer surface of the discharge part of flask 1 there is a connector, electrode (not shown) in the form of a transparent conductive COVERING; wire helix, etc. Flask 1 is filled with xenon. Quartz tubes 6 are welded to it, perpendicular to the plane of the ring and directed downwards. The internal cavity of tubes 6 with sider 1 is connected to the internal volume of flask 1 through holes 7, the diameter of which is smaller than the diameter of the cylindrical getter 8, for example, based on porous titanium with additives. Therefore, the gas absorber 8 is fixed between the wall of the flask 1 with the hole 7 and the septum (jumper) 9 formed when sealing the opening of the tube 6 at a distance from the flask 1, defined by the size of the gas absorber 8 :, The ballast volumes formed during this are small and have little effect on the parameters of the lamp that was discovered during the testing of experimental lamp samples. Tubes 6 with ends 10, which can be open or sealed, depending on the applied mastical mastic, are fixed in the same base as the end, 2

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It is advisable to install holbs 1, gas-absorbers in the electrode areas. Tube 6 may, in the manufacture of a lamp, serve as a stangele, in this case, after vacuum processing, the ampoule, by means of a sealed soldering of the tube 6, below the getter 8, form a hermetic septum 9, after which the lamp is sealed. This simplifies the manufacture of lamps. Pumping can be carried out through several tubes 6 at once, which accordingly speeds up the process of vacuum treatment and improves its quality. The number of tubes 6 depends on the length of the annular flask 15 with a flask with a diameter up to 50 mm high mechanical strength is provided by one tube 6, and with a further increase in the length of flask 1, the number of tubes 6 increases to 2-4, however, the height of the lamp remains unchanged. As in the known device, a reflector can be placed inside the bulb 15, but it is not electrically connected to the surface of the discharge bulb 1, can be made of light metals with high reflectivity (aluminum or titanium alloys) and securely fastened without the need for its insulation. qi m from the body. The lamp on the surface of a high-speed vehicle is usually covered with a protective and color-correcting cap, which determines the aerodynamic characteristics of the vehicle. When using the proposed lamp, this height can be quite small; if ends 2 of flask 1 and tube 6 enter the depressions of the base where they are firmly fixed (the surface of the base is thus protected from overheating by the heat-reflecting coating or the FRIEND1-1M way). It is advisable to dispose the tubes 6 at equal distance from one another and from the junction of its tube 2, although it is possible in some cases. 1-1 metric arrangement of tubes 6, if it is necessary to eliminate the resonance phenomena under the influence of vibrations.

When the lamp is operated with a frequency of 1–2 Hz, the firing 10–5 pulses initiate discharge between the electrodes 3 in the xenon filling the flask 1, and flashes of high intensity light occur. The flask 1 (up to 700 -) impurities released during heating 1: are sensed by getters 8,

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heated to a temperature that provides effective gas absorption. Heating the bulb 1 does not reduce the mechanical strength of the lamp, since the tubes 6 are integrally connected to the bulb 1 and do not have differences in thermal expansion. When testing prototypes, the deposits that form in the flask 1 when the lamp is working (due to evaporation of the wall material, erosion of the electrodes 3, etc.) are deposited in the volumes of the tubes 6 as colder areas, resulting in a transparency of the flask 1 which additionally increases the light output of the lamp.

The power of the proposed lamp can be significant at its minimum height above the attachment plane on a high-speed apparatus, while its mechanical strength is significantly increased compared with the known lamp. More effective gas absorption of impurities in the working gas and complete elimination of the possibility of shunting ignition pulses noBbmiaeT the operational reliability of the lamp, while its luminous efficiency is higher, and the illumination indicatrix is horizontal in the horizontal plane (within the limits of the solid angle necessary for reliable illumination). All this provides an increase of 10

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improvement of the reliability of high-speed aircraft operation, which use light-signal installations with the proposed lamp.

Claims (2)

Invention Formula 1, a pulsed gas discharge lamp containing a tubular discharge flask of optically transparent material, bent in a plane in the form of an open ring, with ends bent at right angles to it in one direction, in which electrode assemblies are hermetically mounted, characterized in that increase reliability, light output, mechanical strength and service life while simplifying manufacture; at least one tube of dielectric material communicating with it is parallel to the flask; ognutym ends of the bulb, on a part length of the tube 25 is formed hermetically cal partition between the latter and the bulb located getter. 20 2. Lamp pop. 1, characterized in that the tubes are evenly placed along the annular bulb relative to one another and to the ends of the flask and are made of the material of the flask. Editor S. Saenko Compiled by V. Gorchakov Tehred L.Oleynik CorrectorM. Sharoshi Order 1324/55 Circulation 643Subscription VNIIPI USSR State Committee for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab. 4/5 Branch P1P Patent, Uzhgorod, st. Project, 4