RU123577U1 - LOW PRESSURE DISCHARGE LAMP - Google Patents

Abstract

1. A low-pressure discharge lamp containing a tubular glass flask filled with mercury and inert gas vapors, at the ends of which there are electrodes mounted on current leads of glass legs welded into a flask, on the inner surface of which a phosphor layer is applied, and caps for supplying electrical energy to electrodes, characterized in that mercury is enriched in the isotope Hg at least 2 times or in heavy isotopes and mercury has an average atomic weight greater than the average atomic weight of natural mercury, or an average atomic weight that exceeds the average atomic weight of natural mercury by more than 0.5 % .2. Low pressure discharge lamp according to claim 1, characterized in that the diameter of the tubular glass bulb is 5-40 mm. A low pressure discharge lamp according to claim 1, characterized in that the tubular glass bulb has two or more tubular channels connected in a multi-channel structure. Low pressure discharge lamp according to claim 1, characterized in that the tubular glass bulb has a bifilar shape. Low pressure discharge lamp according to claim 1, characterized in that the tubular glass bulb is made of quartz glass. Low pressure discharge lamp according to claim 1, characterized in that the tubular glass bulb is made of uviol glass, which transmits resonance radiation and visible discharge radiation. A low pressure discharge lamp according to claim 1, characterized in that the tubular glass bulb is made of black uviol glass, which transmits the resonance radiation of mercury and absorbs the visible radiation of the discharge. Low pressure discharge lamp according to claim 1, characterized in that the tubular glass bulb is made

Description

The utility model relates to lighting engineering and can be used in the production of linear, compact and other forms of low-pressure mercury discharge lamps (with a mercury vapor pressure of the order of 1 Pa and an inert gas pressure or an inert gas mixture of 50 ÷ 1000 Pa), including fluorescent ones.

Known arc discharge devices, including fluorescent lamps [Patent No. 4.527.086 USA, H01J 61/42, 61/20. Arc discharge device with improved isotopic mixture of mercury / Maya J. - Publ. 02.07.85.], Consisting of a tubular glass flask, electrodes at the ends of the flask mounted on the current leads of glass legs welded into the flask, a phosphor layer on the inner surface of the flask, a filling consisting of mercury vapor and inert gas, socles for supplying electrical energy to the electrodes. Unlike arc discharge devices (fluorescent lamps) with enriched mercury according to [Patent No. 4.379.252 USA.], It is proposed in [Patent No. 4.527.086 USA.] To increase the radiant flux of the resonance line 253.7 nm (luminous efficiency of the luminescent lamps), use mercury enriched in the ¹⁹⁶ Hg isotope (up to 2.73% and up to 1.572%), but this is achieved by reducing the proportion of heavy isotopes ( ²⁰⁰ Hg, ²⁰¹ Hg, ²⁰² Hg, ²⁰⁴ Hg) to 34.5%, while less expensive mercury enrichment methods are used (centrifugation, gas diffusion, mass spectroscopy, etc.).

The disadvantages of the known solutions are time-consuming enrichment methods, significantly increasing the price of enriched mercury, and a slight increase in discharge efficiency.

The technical result consists in increasing the efficiency of generation of resonance mercury radiation by an arc discharge and providing an increase in the productivity of the applied methods for enrichment of natural mercury.

The technical result is achieved by the fact that the low-pressure discharge lamp contains a tubular glass flask filled with mercury and inert gas vapors, at the ends of which there are electrodes mounted on the current leads of glass legs welded into a flask, on the inner surface of which a phosphor layer is applied, and socles for supplying electrical energy to the electrodes. There are three options for implementing the technical result: 1) in a discharge lamp, mercury is enriched in heavy isotopes with an average atomic weight greater than the average atomic weight of natural mercury; 2) in a discharge lamp, mercury is enriched in ²⁰² Hg isotope not less than 2 times; 3) enriched mercury with an average atomic weight exceeding the average atomic weight of natural mercury by more than 0.5% is used in the discharge lamp. The diameter of the tubular glass flask is 5-40 mm. A tubular glass bulb has two or more tubular channels connected in a multi-channel structure. The tubular glass bulb has a bifilar shape. The tubular glass bulb is made of quartz glass. The tubular glass flask is made of uvolev glass, which transmits resonant radiation and visible discharge radiation. The tubular glass flask is made of black uviole glass, which transmits resonant radiation of mercury and absorbs visible radiation of the discharge. The tubular glass flask is made of black uvolev glass, transmitting radiation in the range 300–400 nm and absorbing visible discharge radiation. A phosphor layer is deposited on the inner surface of the tubular glass bulb, converting the radiation of 253.7 and 184.9 nm mercury into visible radiation. A phosphor layer is deposited on the inner surface of the tubular glass bulb, converting the radiation of 253.7 and 184.9 nm mercury into ultraviolet radiation in the range from 300 to 400 nm.

Figure 1 shows the design of a low-pressure discharge lamp in a tubular glass bulb with a diameter of 5 to 40 mm; figure 2 - low-pressure discharge lamp, on the inner surface of the flask which has a phosphor layer; figure 3 - low-pressure discharge lamp, the bulb of which has 2 or more tubular channels connected in a multi-channel design; figure 4 - discharge lamp low pressure, the bulb of which has a bifilar shape.

A low-pressure discharge lamp (Fig. 1) consists of a tubular glass bulb 1 filled with mercury and inert gas vapors, at the ends of which there are electrodes 2 mounted on current leads 3 of glass legs 4 welded into a bulb 1, on the inner surface of which there is a phosphor layer 5 (figure 2), and socles 6 for supplying electrical energy to the electrodes 2. The diameter of the tubular glass bulb 1 is 5-40 mm (figure 1, 2). The tubular glass flask 1 has two or more tubular channels connected in a multi-channel structure (figure 3). The tubular glass flask 1 has a bifilar shape (Fig. 4). Low-pressure discharge lamps intended for direct replacement of incandescent lamps have a compact tubular glass bulb 1 (Fig. 4), to the housing 7 of which a threaded base 8 is rigidly attached to connect the discharge lamp to the mains. The tubular glass flask 1 is made of quartz glass. The tubular glass flask 1 is made of uvolev glass transmitting resonant radiation and visible discharge radiation. The tubular glass flask 1 is made of black uviole glass, transmitting resonant radiation of mercury and absorbing visible radiation of the discharge. The tubular glass flask 1 is made of black uvolev glass, transmitting radiation in the range 300–400 nm and absorbing visible discharge radiation. A phosphor layer 5 is deposited on the inner surface of the tubular glass bulb 1, which converts the radiation of 253.7 and 184.9 nm mercury into visible radiation. A phosphor layer 5 is deposited on the inner surface of the tubular glass bulb 1, which converts the radiation of 253.7 and 184.9 nm mercury into ultraviolet radiation in the range from 300 to 400 nm.

Arc discharge lamp low pressure operates as follows. When a supply voltage is applied to an low-pressure arc discharge lamp, an arc discharge is ignited in it, under the influence of which mercury atoms are excited and emit resonant lines of 184.9 and 253.7 nm. In the case of application for the manufacture of a bulb lamp of quartz or uvolev glass (Fig. 1), the resonant and visible radiation of mercury enters the surrounding space. In the case of applying for the manufacture of a lamp bulb black uvolev glass transmitting radiation in the range 300 ÷ 400 nm (Fig. 1), the visible radiation of mercury is absorbed by this glass. When coating the inner surface of the flask with a phosphor (Fig.2-4), the latter converts the resonant radiation of mercury (253.7 and 184.9) into visible radiation.

There are three options for implementing the technical result: 1) in a discharge lamp, mercury is enriched in heavy isotopes with an average atomic weight greater than the average atomic weight of natural mercury; 2) in a discharge lamp, mercury is enriched in ²⁰² Hg isotope not less than 2 times; 3) enriched mercury with an average atomic weight exceeding the average atomic weight of natural mercury by more than 0.5% is used in the discharge lamp.

The increase in efficiency in this case, confirmed by calculations and experiments, is associated with an increase in the probability of emission of photons and the concentration of mercury atoms at the levels 6 ¹ p ₁ and 6 ³ p ₁ ] responsible for the generation of resonant radiation of mercury (lines 184.9 and 253.7, respectively nm).

Compared with the known solution, the proposed solution improves the efficiency of the generation of resonant mercury radiation by an arc discharge (lines 184.9 and 253.7 nm) while increasing the productivity of the applied methods for enriching natural mercury with heavy isotopes, which are contained in large quantities in natural mercury.

Claims (10)

1. A low-pressure discharge lamp containing a tubular glass flask filled with mercury and inert gas vapors, at the ends of which there are electrodes mounted on the current leads of glass legs welded into a flask, on the inner surface of which a phosphor layer is applied, and socles for supplying electrical energy to electrodes, characterized in that the mercury ²⁰² Hg isotope is enriched in at least 2 times or heavy isotopes, and mercury has an average atomic weight greater than the average atomic weight of natural mercury, or the average atomic weight greater than the average atomic weight of natural mercury is greater than 0.5%. 2. The low-pressure discharge lamp according to claim 1, characterized in that the diameter of the tubular glass bulb is 5-40 mm. 3. The low-pressure discharge lamp according to claim 1, characterized in that the tubular glass bulb has two or more tubular channels connected in a multi-channel structure. 4. The low-pressure discharge lamp according to claim 1, characterized in that the tubular glass bulb has a bifilar shape. 5. The low-pressure discharge lamp according to claim 1, characterized in that the tubular glass bulb is made of quartz glass. 6. The low-pressure discharge lamp according to claim 1, characterized in that the tubular glass bulb is made of uviole glass that transmits resonant radiation and visible discharge radiation. 7. The low-pressure discharge lamp according to claim 1, characterized in that the tubular glass bulb is made of black uviole glass that transmits resonant radiation of mercury and absorbs visible radiation of the discharge. 8. The low-pressure discharge lamp according to claim 1, characterized in that the tubular glass bulb is made of black uviole glass, transmitting radiation in the range of 300-400 nm and absorbing visible discharge radiation. 9. The low-pressure discharge lamp according to claim 1, characterized in that the tubular glass flask is made of black uviole glass, on the inner surface of which a phosphor layer is deposited, converting the radiation of 253.7 and 184.9 nm mercury into ultraviolet radiation in the region of 300 up to 400 nm. 10. The low-pressure discharge lamp according to claim 1, characterized in that a phosphor layer is deposited on the inner surface of the tubular glass bulb, converting the radiation of 253.7 and 184.9 nm mercury into visible radiation.