SU940253A1 - Method of manufacturing gas-discharge lamp with quartz bulb - Google Patents

Description

(54) METHOD OF MANUFACTURING GAS DISCHARGE LAMPS WITH QUARTZ BULB

The invention relates to methods for the manufacture of gas discharge lamps with a quartz bulb, and more specifically to the degassing of quartz cylinders under machine pumping conditions, and can be applied to enterprises producing quartz lamps of pulsed and continuous action. There are known methods for the manufacture of instruments in a quartz shell, including the degassing of a quartz bulb during a pumping operation by heating in a vacuum. Quartz glass contains only a small amount of adsorbed gases on the surface, which are easily removed during heating, and the deep gases begin to be released only at the red-hot temperature - and above, to which the flask is heated in electric or gas furnaces l. However, in the conditions of machine pumping, when the lamp time at the flask decontamination position is limited, the known methods are very difficult to apply due to the length of time required to achieve a high temperature of the quartz flask in the furnace and the difficulty of uniform heating of tubular lamps of large dimensions. A close technical essence of the invention is a method of manufacturing gas-discharge lamps, including heating a lamp filled with an inert gas to the degassing temperature and pumping out fz. However, when using such a method, when pumping quartz lamps on an evacuated semiautomatic device, difficulties arise due to the need to quickly heat the entire surface of the quartz bulb to the outgassing temperature (about 110 ° C), due to the distribution of impurity gases emitted from the flask walls the inert gas flask is the release of the walls

flasks from harmful gases (according to the well-known principle of flushing with an inert gas). Fast heating of the flask to such high temperatures is possible only with direct heating of the flask with heat-producing gas burners, however it is very difficult to ensure uniform heating of the entire surface of the flask (both in length and circumference) to approximately the same temperature. For this, the burner system must be very complicated both constructively and in setting up, and the heating of the parts of the flask adjacent to the leads is made difficult by the possibility of overheating of the leads and hermetic lead-in wires due to the proximity of the burner flame to them. Such overheating leads to oxidation of these parts of the lamp, to depressurization and, as a result, to an increase in the scrap rate. In a known manner, the outer surface of the flask is heated, while overheating of the inner surface of the flask is important to ensure high lamp quality. When changing the type of lamp (i.e., changing the dimensions), the entire heating system requires readjustment, and in the case of large-sized tubular quartz lamps (0.5-1 m more), it is almost impossible to ensure uniform and fast heating of the bulb using known methods, which prevents mechanization the process of pumping out such lamps. The purpose of the invention is to provide a quick and uniform heating of the entire inner surface of the quartz bulb while staying in the position of exhausting the semi-mat, simplifying the heating system, reducing changeover operations while changing the lamp dimensions, simplifying the maintenance of the semi-automatic pumping machine, the ability to process large-sized tubular lamps on it, and increase reliability and durability of manufactured lamps. This goal is achieved by the 36-position carousel pumped out in the method of manufacturing the gas discharge of a semi-automatic pulsed tubular lamps with a quartz bulb, including quartz lamps of the type IFP-800 that heat the lamp filled with inert-At one position with semi-automatic gas to temperature The out-of-lamp lamp is 15 seconds, which ensures the flask and evacuation, the lamp gives a significant increase in pronounced gas with an inert gas to a supply pressure as compared to a manual 1.5-5 atm, and heating is carried out by pumping at posts. Brewed lamps of the lower part of the lamp constituting 0.3-0.7 flask lengths, up to 1150-1200s.

With this method, the compressed inert gas in the lamp.

large heat conductivity and mobility, plays the role of a heat transfer agent the more efficiently, the greater its pressure, and heat from the hot portion of the flask is quickly carried throughout

flask, providing a quick and uniform heating of the inner surface of the flask, from which impurities evolve dissolve in an inert gas, the density of which is for many pores. Pumping is carried out on a cove more density of impurities, followed by pumping. In addition, the rate of heat propagation is increased due to convection flows in compressed gas, uniform heating of the inner surface of the flask (along the length and circumference) to 10501100 ° C is ensured regardless of uniformity of external heating of the flask, and the possibility of overheating of the lamp leads is eliminated the ends of the lamp means heating, for example the flame of a gas burner. It is significant that the flask is mainly heated from the inside with a hot compressed gas, which most effectively ensures the absence of harmful impurities in the working volume of the lamp during operation, i.e. entails an increase in the lighting characteristics of manufactured lamps and their service life. When pumping out on a semiautomatic device, changing the type of lamp under the conditions of serial production requires only minimal changeover of the burner system, since there is no need to warm the flask from the outside along its entire length and circumference. Moreover, pumping out on a semi-automatic tubular quartz lamps of large dimensions, in this case a uniform heating The flask is easily reached by external heating of the flask at several sites along its length.

Claims (1)

Claim 1. A method of manufacturing gas discharge lamps with a quartz bulb, including heating the lamp filled with an inert gas to the degassing temperature and pumping, characterized in that, in order to increase the reliability and durability of the manufactured lamps, the lamp is filled with inert gas to a pressure of 1.5 "5 bar and heating is carried out in the lower part of the lamp, component 0.3-0.7 of the length of the bulb, up to 1150-1200 ° C.