SU1677738A1 - Gas discharge lamp - Google Patents

Abstract

The invention relates to the electrical industry, in particular to fluorescent lamps and high pressure lamps. The purpose of the invention is to increase the light output and the life of the lamps. The gas discharge lamp is a tubular flask 1 with hermetically sealed from the opposite ends of the electrode units 2. The flask 1 is filled with a mixture of metal vapors with inert gases. A sealed cylinder 3 is coaxially located inside the tubular bulb 1. Its diameter is 0.3-0.65 of the diameter of the flask, and the length is 0.7-0.9 interelectrode distance, there is a reflective coating on the inner surface of the cylinder a phosphor layer is applied. Inside the cylinder is a getter. 2 hp f-ly, 1 ill.

Description

The invention relates to the electrical industry and can be used in the manufacture of gas-discharge light sources, in particular fluorescent lamps and high-pressure lamps.

The purpose of the invention is to increase the light output and lamp life.

The drawing shows the proposed lamp, the overall appearance.

The lamp is a tubular flask 1 with electrode assemblies sealed at opposite ends 2. Inside the flask 1, a hermetic cylinder 3 is coaxially mounted, a reflective coating 4 is applied to the inner surface, and a phosphor layer 5 to the outer surface (in the case of low-pressure fluorescent lamps ). Inside the cylinder there is a getter in the form of a washer 6.

The performance of the proposed design is as follows.

Due to the presence in the flask of a sealed cylinder located coaxially, it is possible to use the surface layer of the discharge as the source of radiation, which is more efficient than the inner layers. In addition, due to the presence of a reflecting layer on the inner surface of the sealed inner cylinder, which, due to the tightness of the cylinder, has almost constant parameters during the lamp life, the luminous efficiency due to reflection of radiation from the inner part of the wall layer increases. This allows maximum utilization of the discharge radiation. This design allows for maximum efficiency in reflective VI x | vj s oo

This layer does not degrade the discharge parameters, since, due to the tightness of the inner cylinder, direct contact of the plasma with it is excluded. For fluorescent lamps, when luminous flux is formed by converting radiation with a phosphor layer, a phosphor layer is deposited on the outer surface of the inner cylinder, thereby increasing the luminous flux of the lamps without increasing the power. In addition, the presence of a phosphor layer on the outer surface of the inner cylinder and its absence on the outer tube of the bulb allows the lamp to be assembled with ultraviolet and visible radiation, which is very effective for irradiating targets. The presence of phosphors allows the creation of lamps with different, predetermined chromaticity.

The presence of an internal cylinder allows for the required density of discharge due to a decrease in its luminescence at a lower discharge density than that of lamps of the existing design. And this leads to an increase in the light output of the lamp.

Due to the presence inside the hermetic inner cylinder of the getter, which absorbs the harmful gaseous fractions emitted from the elements of the lamp design and worsens its working atmosphere during the service life, the discharge stability and service life of the lamps increase.

The sealing of the sealed cylinder inside the burner is carried out by known methods with the help of metal extensions, taps, hollow washers, etc.

The limits of the ratios of the diameters of the inner sealed cylinder and the tube-flask (burner) are chosen from the following considerations. The lower limit of 0.3 is taken from the considerations of obtaining the effectiveness of the proposed design, because, as studies have shown, the introduction of an inner cylinder of a smaller diameter leads to a slight positive effect and therefore in practice it is not advisable to use it.

The upper limit is determined by the technical possibility of using the proposed design. As the ratio increases, the gap between the cylinders decreases, which leads to instability of the discharge, spontaneous shutdown.

This makes it impossible to operate the lamps.

The ratio of the hermetic cylinder to the interelectrode gap is determined as follows. The lower limit is the efficiency of use, since reducing the length of the cylinder does not adversely affect the discharge, but reduces the above-mentioned positive effect.

The upper limit is limited by technical feasibility, since at a ratio greater than 0.9, the distance between the cylinder and the electrodes becomes sufficiently small. This leads when working lamps to

the melting of the cylinder from a highly heated electrode or the closure of the discharge through this cylinder. Both leads to the exit of lamps out of build.

Dimensions of the actual lamp design

For example, the lamp type DRL 400 following. The burner diameter is 200 mm, the interelectrode distance is 70 mm. Consequently, the dimensions of the inner cylinder are as follows: length 56 mm, diameter 14 mm.

Claims (3)

1. A gas discharge lamp containing a tubular flask with hermetically mounted electrode nodes at opposite ends, filled with a mixture metal vapor with inert gases, characterized in that, in order to increase the light output and service life, a sealed cylinder of an optically transparent material with a reflective coating on the side inner surface, having a diameter and length of 0.3, is coaxially mounted -0.65 bulb diameter and, 0.7-0.9 its interelectrode distance. 2. Lamp according to claim 1, characterized in that a phosphor layer is deposited on the outer side surface of the cylinder. 3. The lamp in PP.1 and 2, characterized in that it is located inside the cylinder getter.