SU691959A1 - Burner for a high pressure arc lamp - Google Patents

Description

(54) HIGH-PRESSURE ARCH LAMP

The invention relates to gas-discharge sources of radiation, and more preferably, to high-pressure arc lamps with metal fumes and halides of metals used for general illumination, as well as in photochemistry, medicine, agriculture, etc.

. High pressure arc lamp burners, made of transparent heat-resistant material, containing electrodes and filled with inert gas, metal vapors, and metal halides ij are known. In the known device, in order to increase the temperature of the burner ends, the electrode areas are shaped with the smallest possible cooling surface and various heat-insulating coatings are used. However, these measures, in a number of cases, are not enough. For example, in narrow burners with long electrodes, in burners with small discharge currents, the temperature difference across the burner wall remains significant, i.e., comparable

with absolute temperature values of the walls.

The closest to the technical essence of the proposed invention is a burner which shuts off a discharge tube with high-pressure metal vapors, has a closed, tubular sheath of transparent heat-resistant dense polycrystalline ceramics, an inert gas, two electrodes, a small amount of mercury and an alkali metal in which to increase the temperature of the cold areas at the ends of the discharge tube, a heat-insulating layer of metals with a high melting point, low vapor pressure and good 2 conductivities. The increase in the temperature of the end of the nozzle tube achieved in this case is about 50 ° C. Thus, despite some effect, the temperature difference in the center and on the edges of the tube is significant and is 450 ° C at a rather low temperature.

ends, equal, while in the central zones it is equal.

The purpose of the invention is to reduce the darkening of the flask with a lifetime by increasing the temperature in the electrode areas of the burner.

The goal is achieved by the fact that in a known high pressure arc lamp burner containing electrodes with current leads and a sealed flask of transparent heat-resistant material filled with an inert gas, metal vapors and metal halides, the new burner is equipped with two heat-conducting heat-material materials, located inside the coba and completely covering the lateral surface of the electrodes.

The drawing shows a general view of a high pressure arc lamp burner with a local axial section for a better view of the design. The burner consists of a quartz bulb 1, which has a leg 2 with current leads 3 at the ends. The heat conductor 4 covers the electrode 5. To the right of the burner image there is a graph showing the temperature distribution of the wall of the near-electrode burner region of a 250 W lamp without the heat conductor 4 — curve b, and with a tungsten heat conductor 4, whose wall thickness is 2 mm wound - curve 7.

Burner arc lamp works as follows. The energy supplied to the sections of the heat conduit nearest to the plasma due to heat conduction and radiation of the plasma and the upper end of the electrode is absorbed by the upper conduit of the heat conductor and transferred through the heat conduit by heat conduction to the lower end of the heat conductor located in the over-electrode area. Thus, an additional amount of energy is supplied to the e-electrode area by eliminating overheating of the wall at the level of the electrode end. For greater effect

the heat conductor must have a maximum thermal conductivity and wall thickness, which the burner design only allows.

The heat pipe completely encloses the electrode and therefore prevents particles of the electrode material formed on the burner wall from dissolving the electrodes, thereby reducing the darkening of the burner walls.

The presence of heat lines inside the burner completely covering the electrodes increases the temperature of the walls of the burner and the over-electrode area, levels the temperature field and reduces the darkening of the walls of the burner in the near-electrode area. All this leads to an increase in the luminous efficiency of the lamp and a decrease in the decrease in the luminous flux with its service life.

Claims (2)

1. Rokhlin G, N. Gas-discharge light source. M., Energie, 1966, S. 513527 .. 2. Patent SSCHA N9 3716743, cl. 313/220, 1973 (prototype). / 4 5 / / % 7 500 W shd J250 then Ch.