SU1765858A1 - Gas-discharge tube - Google Patents

Abstract

Use: high pressure gas discharge lamps for exterior and interior lighting. The invention: a transition glass coating with a linear expansion coefficient (15-40) and a melting point of 600 - 900 ° C was deposited on the surface of a quartz flask. Thickness of a layer is 3-30 microns. The coating does not transmit short-wavelength UV radiation of the discharge, forming ozone. 1 il.

Description

The invention relates to electrical engineering and can be used in the manufacture of gas discharge lamps in quartz flasks that do not allow shortwave UV radiation.

High and super high pressure gas discharge lamps in quartz flasks, filled with mercury, inert gases and metal halides, are known.

Lamps are used in various areas, mainly for lighting. The quartz lamp bulb transmits short-wave ozonizing ultraviolet radiation if the lamp is not enclosed in an external flask, which limits their use, in particular, in closed rooms without ventilation.

The closest to the technical essence is a high-pressure discharge lamp containing a quartz bushing with an outer coating of titanium oxide, filled with mercury, metal halides and an inert gas 2.

The ozonating shortwave radiation in this lamp is absorbed by a layer of titanium oxide, which makes it possible to use these gas discharge lamps without an outer bulb.

However, a layer of titanium oxide absorbs visible radiation, which leads to a decrease in light output. In addition, the process of coating the flask is rather complicated due to the refractoriness of titanium oxide, which limits the widespread use of these lamps.

The aim of the invention is to increase the light output and simplify the manufacturing technology of gas discharge lamps.

The goal is achieved by the fact that in a gas discharge lamp with hermetically sealed electrodes into it, containing a quartz flask with an outer coating that prevents exit and radiation forming ozone and filled with inert gas, mercury and metal halides, the coating is made in the form of one types of transitional glasses with a linear expansion coefficient in the range of (15 - 40) 10 and temperature

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melting 900 to 600 ° C, with the coating thickness being 3-30 microns.

The invention is illustrated in the drawing.

The outer surface of the quartz bulb 1 of the lamp is covered with a layer of transitional glass 2. Electrodes 3 are hermetically sealed in flask 1, and flask 1 is filled with inert gas, mercury, and metal halides.

When the lamp is in operation, the UV radiation forming ozone passes through the thickness of the wall of the bulb 1 and the layer of transitional glass 2, where it is absorbed and the visible and infrared radiation is almost completely gone.

Due to the low melting point, the transition glass is easily applied to the surface of the flask, for example, by dipping into a slurry. Subsequently, the fixing of the transition glass is carried out using an oxygen-oxygen burner or in a furnace at a temperature close to the melting point of this type of glass used.

Glasses with a low melting point (with a relatively large coefficient of linear expansion) can be fixed on the surface of the flask when the lamp is burning.

The composition of the transitional glass is chosen based on the specific loads on the walls of the quartz bulb. At high specific loads, refractory glass is chosen, and at low loads, more fusible.

The invention was implemented on high pressure mercury lamps with a power of 1 kW.

Two batches of lamps were made, 5 pieces in each batch. The first batch of lamps (control) was manufactured from 0

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with a titanium oxide coating and the second batch according to the invention.

Titanium oxide was fixed at a control batch of lamps at a temperature of 1200–1300 ° C, and fixing of transition glass of type P-3 at a batch of lamps made according to the invention at a temperature of 700–800 ° C.

The average light return for a test lamp consignment was 49.5 lm / W, and for a batch of lamps manufactured according to the invention, 57 lm / W, which is 13% higher than that for a test party lamp.

In addition, the ozone radiation (less than 300 nm) was completely absent in both batches of the lamps.

When the thickness of the transition glass is less than 3 µm, the ozonating short-wave radiation increases, which makes it impossible to use these gas discharge lamps without an outer bulb.

With a transition glass thickness of more than 30 microns, visible and infrared radiation is absorbed by the transition glass layer, which leads to a decrease in light output.

Claims (1)

Invention Formula The discharge lamp is a lamp containing a quartz flask with hermetically sealed electrodes, having an outer coating that prevents the emission of radiation that forms ozone, and is filled with inert gas, mercury and metal halides, in order to increase the light output and simplification of manufacturing technology, the said coating is made of transitional glass with a linear expansion coefficient of 15–10–40 degrees, and a melting point of 600–900 ° C and has a thickness of 3–30 µm.