SU898540A1 - High-pressure gas-discharge tube - Google Patents

Description

(5) HIGH PRESSURE DISCHARGE LAMP

Claims (2)

This invention relates to high-pressure discharge lamps operating in mercury vapor and metal halides for use in lighting open spaces, domestic and industrial premises. High-pressure arc burners made of transparent heat-resistant material containing electrodes and filled with inert materials are known. gas (mainly argon), mercury and metal halides. During the operation of such lamps, it first evaporates with all the mercury, and then, when a certain temperature is reached, the halides are evaporated. The metal halide molecules are diffusion and convection transferred to the high-temperature arc zone, where they dissociate. The metal atoms are excited, ionized and create emission spectral lines. Diffun is back to the outside of the discharge to the walls, the metal atoms collide with the metal halopenides. In order to increase the radiation power of the atoms; metal additives it is necessary to increase the temperature of the wall of the discharge tube 1, however, an increase in the wall temperature significantly reduces the service life of the gas discharge lamp burner. The presence of such a temperature limit, a, caused by the thermochemical properties of the wall material, makes it impossible to obtain the required concentrations of metal atoms in the discharge due to the low vapor pressure of this additive at this temperature, which allows a long service life of the burner. Quartz burner with two electrodes, filled with an inert gas for ignition, with mercury and halide metal compounds in an amount sufficient to form a liquid layer in the lower part of go3. 89 reel., In which the capillary system is immersed 2. However, the known lamps have insufficient service life due to the chemical interaction of the electrode material with the material of the capillary system. The aim of the invention is to increase lamp life. C. This goal is achieved by the fact that, in a burner made of heat-resistant light-transmitting material containing electrodes and filled with inert gas, mercury and halo, with genides of metals in an amount sufficient to form a liquid layer into which the capillary system is immersed, the electrode located in the lamp's working position in the lower part of the burner, it is made with a through hole, the lower part of which is connected to the upper end of the capillary system. The capillary system is made in the form of a spiral with tightly wound coils. The drawing shows the proposed burner, a section. The burner 1 is made of quartz glass, contains electrodes 2 with capillary systems 3 inserted in them, which connect the electrode regions to the discharge zone k. The burner is filled with argon, mercury and halides Nal, TM, 1п1 in the solid state. During operation, the arc discharge in argon is first ignited, the temperature of the burner 1 wall starts to rise and mercury evaporates. After evaporation of the mercury, the temperature of the wall of the burner 1 rises to 650 ° C, and all metal halides go into liquid state. In the lower electrode portion of the burner 1, a liquid layer () 5 of the melt of metallobium halides is formed. The upper end of the capillary system 3 is heated by electrode 2 to a temperature of about 1300-1too C. Next, the molten metal halide melt rises along the Ziv capillary system of its upper part, which has a significantly higher temperature than the temperature of the burner wall 1, evaporates through electrode 2, which is hollow, with the formation of a jet of vapor of metal genides directed into the high-temperature zone of the arc discharge .4. Further, the metal halide molecules disintegrate into atoms and participate in the emission process. Halide pairs with respect to the walls of the burner 1 are supersaturated and, therefore, condense on them, and then under the force of gravity flow onto the walls of the burner 1 into a liquid layer (puddle) 5. Capillary System 3 may be made of alumina or of thin tungsten wire, which is a core of a certain diameter. Thus, the vapor pressure of metal haogenides in the proposed design is determined by the temperature of the upper, highly heated part of the capillary system and can be from units to hundreds of millimeters of mercury. To form a liquid layer (puddle), the wall temperature should only slightly exceed the melting point of the most refractory halide. Therefore, in the case of filling the burner with halides Nal, Til, In I, the wall temperature can be lower for conventional burners in the proposed design. Since the evaporation of halides comes from a small area defined by the diameter of the capillary, it has the character of a directional jet and, thus, the possibility of steam emission in different directions is excluded. Claim 1. Gas discharge high-pressure lamp, operating in a vertical position, containing a burner of heat-resistant light-transmitting material with electrodes installed at opposite ends, filled with inert gas and vapor of metals and their compounds in an amount sufficient to form a liquid layer in the bottom parts of the burner, and the capillary system, immersed by the lower end in the liquid layer, which is due to the fact that, in order to increase the service life, the electrode located in the working position of the lamp in the lower part of the burner is made with a through hole, the lower part of which is connected to the upper end of the capillary system. Lamp Pop, 1, is different. what is capillary? 58985 406 The theme is made in the form of a spiral with dense. Weymouth D. Gas Discharge Lamps but wound coils. M, Energie, 1977o Information sources, 2. The patent of France G 1463568. taken into account during examination. H 01 J, .1966.