RU2672672C1 - Source of uv radiation with helium-containing filling - Google Patents

Abstract

FIELD: lighting engineering.SUBSTANCE: invention relates to the field of lighting engineering, in particular low-pressure gas discharge lamps with helium filling, and can be used for high-power ultraviolet emission lamps intended for processing water and air, as well as surfaces. Source of UV radiation consists of a gas-discharge lamp with helium-containing filling, in which as a means for maintaining the concentration of helium in the lamp, a light-permeable surrounding gas-discharge lamp is used, having a casing connected to a source of a gas helium-containing mixture of a given composition, and an outlet for withdrawing this mixture. Casing surrounds the gas discharge lamp in such a way that the lamp is washed by the flow of said gas mixture, the concentration of helium, in which corresponds to the concentration of helium in the discharge lamp. Due to the constant concentration of helium in the washer mixture, the concentration of helium in the lamp is constant.EFFECT: stabilization of the radiation parameters of the source of UV radiation with helium-containing filling and simplification of operating conditions.4 cl, 5 dwg

Description

The invention relates to the field of lighting, in particular to low-pressure gas-discharge lamps with helium filling, and can be used for high-power gas-discharge lamps in the ultraviolet range of radiation intended for the treatment of water and air environments, as well as surfaces.

It is known that the main advantage of using helium as a filling for low-pressure lamps compared to lamps filled with heavier inert gases (argon, neon) is an increase in the linear power of the discharge. However, the main obstacle that restricts the use of helium or its mixture with other gases as filling gas discharge lamps is its high fluidity and the ability to penetrate through the material of the bulb and lamp construction elements, resulting in a decrease in the concentration (partial pressure) of helium in the lamp, leading to a change in its electrical radiation parameters and a decrease in its service life. (Norton F. Helium diffusion through glass. Journal of the American Ceramic Society, 1953, 36 (3), 90-96). Thus, it is known that a traditional low-pressure amalgam UV lamp based on a discharge in a mixture of noble gases Ar, Ne, Kr, or Xe has a life of 12000-16000 h, the specific electric power in the discharge is 1.5-4.5 W / cm and the linear power of UV -radiation 0.4-1.4 W / cm. Sources where helium is used as a buffer gas have significantly higher electrical emitting characteristics (such important as the total flux of UV radiation and power consumption). However, due to the leakage of helium through quartz, the characteristics of such a UV lamp change rapidly. Depending on the characteristics of the lamp (quartz thickness, its grade, pressure and gas composition inside the lamp), its service life is only 50-500 hours.

Therefore, in the art, an important task is to maintain and maintain the required concentration of helium in the bulb of a discharge lamp. This problem, as a rule, is solved by compensating the amount of helium in the lamp bulb using various means.

A known method of preventing leakage of filling gas (in particular helium) from medium-pressure metal halide compact lamps (patent EP 2139024, H01L 61/52, 2009), which describes a radiation source consisting of a burner and a translucent casing filled with gas surrounding it , including helium.

The use of helium, which has high thermal conductivity in comparison with other gases used in such lamps, makes it possible to optimize the temperature regime of the lamp. The casing is made of aluminosilicate glass, high temperature glass or other material with a low helium diffusion rate. A translucent coating may also be applied to the outer and inner surfaces of the casing, also reducing helium leakage. The walls of the casing have a thickness of 0.5-2.0 mm. The result of the use of various coatings and aluminosilicate glass, preventing the leakage of helium is an increase in lamp life from 100 hours. up to 3000 hours.

However, the technical solution described in the analogue, aimed at preserving the helium in the lamp housing necessary for efficient cooling of the burner and extending the lamp life, does not solve the problem of maintaining the helium concentration for a long period due to the finite helium reserves in the lamp housing.

It is also known a device for maintaining helium pressure in an electric vacuum device, which is a quartz ampoule filled with helium, placed in a flask of an electric vacuum device, equipped with a heater, a change in the magnitude of the current through which is determined by the pressure of helium. As a pressure measurement sensor, a thermal manometer is used, the thread of which is inside the device. The device allows you to compensate for the helium consumption during operation of the electrovacuum device and keep its characteristics stable for several hundred hours (USSR Author's Certificate No. 135541, 21g12 / 01, 1959).

The disadvantage of the analogue is the complexity of the design and the technical solution itself, as well as the finiteness of the helium supply in the quartz ampoule.

Closest to the proposed invention is a gas-discharge mercury-free helium lamp of low pressure, the design of which allows you to compensate for the helium pressure in the lamp (USSR Author's Certificate No. 278875, H01J 61/16, 1969).

In order to compensate for the helium losses arising during the burning process of the lamp and thereby increase its service life, a quartz ampoule filled with helium diffusing through quartz and replenishing the helium consumption from the lamp into its surrounding space is introduced into the discharge bulb of the lamp. The ampoule is located inside the lamp along its central axis and is mounted on wire supports welded to the lamp electrodes. The geometric dimensions of the ampoule and the pressure of helium in it should be selected so that the outflow of helium from the ampoule compensates for its consumption.

The disadvantages of the prototype are the complexity of the entire structure, its low reliability, insufficient controllability of the compensation process, the limited time of compensation by the helium supply in the ampoule.

The problem to which the invention is directed, is to create a UV radiation source based on a gas discharge lamp with a helium-containing filling, with stable electrical emission characteristics, a service life of 12000-16000 hours and an increased power of not less than 1.5-2 times compared to traditional amalgam lamps by maintaining a constant concentration of helium.

The technical result of the invention is to stabilize the electrical radiation parameters of the UV radiation source, to achieve the service life of the proposed UV radiation source similar to the life of traditional low pressure amalgam lamps that do not contain helium, as well as the lack of the need for constant monitoring of the concentration of helium inside the source.

The specified technical result is achieved in that the source of UV radiation, including a gas discharge lamp with a helium-containing filling and means for maintaining the concentration of helium in the gas discharge lamp, according to the invention, as a means for maintaining the concentration of helium contains a translucent casing having an inlet connected to a source of a gas helium-containing mixture of a given composition, and the outlet for discharging this mixture surrounding the discharge lamp, so that the lamp is washed by the flow of the specified gas mixture, centration helium content which corresponds to the concentration of helium content of the gas discharge lamp.

The invention is illustrated by drawings, where in FIG. 1 shows a source of UV radiation with a helium-containing filling and with a supported concentration of helium; in FIG. 2, 3 - implementation of the UV source with an open and closed cover; in FIG. 4 - a multi-tube system based on the claimed radiation source, and in FIG. Figure 5 shows a graphical dependence of the power of UV radiation and the power consumption of a source of UV radiation with helium filling, depending on the service life.

The UV radiation source contains a gas discharge lamp 1, equipped with leads 2, to which, with the help of wires and a connector, the necessary lamp power is supplied from the power supply 3. The lamp discharge bulb is filled with a mixture of helium with inert gases. The lamp is enclosed inside a translucent hollow casing 4, connected to a source of a helium-containing gas mixture of a given composition, and having an input 5 for supply and an output 6 for removal of the gas mixture. As a source of helium-containing gas mixture can be used balloon 7, equipped with an adjustable gear 8, and connected, with a casing, for example, using a pipe 9.

For the multi-tube system shown in FIG. 4, the supply of a helium-containing gas mixture is carried out simultaneously from one or more cylinders 7 into the casings 4 of several UV sources simultaneously.

The device operates as follows. In the UV radiation source, lamp 1 is placed in a translucent quartz casing 4, to the input 5 of which through a reducer 8 a helium-containing mixture from a high-pressure cylinder 7 (150-300 atm) is supplied, where the concentration of helium in the cylinder with other gases (for example, air, nitrogen , noble or other gases) is 0.0013-1.3%. The casing surrounds the lamp in such a way that there are gaps between the walls of the lamp discharge bulb and the inner wall of the casing through which the gas mixture passing through the lamp passes. The gas mixture completely fills the casing, constantly washes the lamp during combustion and is discharged through outlet 6. Due to the constant concentration of helium in the washing mixture, a constant concentration of helium in the lamp is ensured. At the same time, monitoring the helium content inside the gas discharge lamp of the UV radiation source is not required.

An example implementation of the invention

The installation for water disinfection with UV radiation UDV 1A-300 uses a UV source based on an amalgam lamp DB300NO. The water temperature is 10-15 ° C. Inside the quartz casing 4, length L ₁ = 1880 mm, outer diameter d ₁ = 34 mm and wall thickness λ ₁ = 2 mm, a low-pressure quartz amalgam UV lamp 1 is located, length L ₂ = 1600 mm and outer diameter d ₂ = 22 mm (wall thickness λ ₂ = 1.4 mm). The lamp is located along the axis of the quartz casing, so that the distance between the lamp and the inner surface of the casing is 4 mm. The material of the quartz casing is quartz of the Raesch RQ205 brand (Germany). The amalgam lamp is made of quartz-free quartz glass of the QSIL Ilmasil PN235 brand (Germany).

The lamp housing has an inlet 5 in the form of a nozzle for introducing gas and an outlet 6 made in the form of a special capillary 10 with a diameter of 0.1 mm through which the gas is discharged. The pressure of the helium-containing mixture at the inlet to the UV radiation source is 0.05 atm. The lamp is connected to the corresponding electronic ballasts (electronic ballasts) by cable 12 through the pressure glands. Electronic ballast L`1 × 350-2222-18LM provides a current of 2.0 A. The lamp is filled with a gas mixture of 50% Ar + 50% He at a pressure of 1 torr. An amalgam based on indium was used as a source of mercury vapor. In the space between the quartz casing and the lamp, a pre-prepared gas mixture of nitrogen and helium enters from the cylinder through the reducer 8 in the ratio: 0.066% He and 99.93% N ₂ .

In the case of making the casing 4 of the lamp open (Fig. 2), the helium-containing mixture, through the inlet 5, enters the casing, and, washing the lamp, passes through the open unsealed end and exits through the capillary 10.

In the case when the casing is made sealed on one side, for uniform gas flow and washing the lamp, a tube 11 located inside the casing and passing along its wall, which is connected to the capillary 10, is used.

After washing the UV source with the indicated gas family for 5 minutes, the lamp lights up. As the lamp flares up, mercury from the amalgam enters the arc discharge and a stable mode of operation with the following characteristics is established: the lamp voltage is 194 V, the consumed electric power is 387 W, the total radiation flux on the 254 nm line is 131 W. The flow rate of the gas mixture was 0.5 l / h. One cylinder of 50 l with a mixture pressure of 15 MPa is enough for about 15,000 hours.

In FIG. 4 shows the test results: the dependence of the electric power and the power of the UV radiation from the source from the operating time for 12000 hours. The decrease in radiation corresponds to the standard for known amalgam lamps - about 20%, and the constancy of the power consumption indicates the constancy of the composition of the gas mixture and the pressure inside the UV lamp.

Thus, due to the design of the proposed source of UV radiation based on a gas discharge lamp with a helium-containing filling, the stability of electrical emitting characteristics and an increase in the power of UV radiation are achieved not less than 1.5-2 times in comparison with the known amalgam lamps that do not contain helium, while the lamp life is not lower than that of standard lamps and is 12000-16000 hours.

Claims (4)

1. A UV radiation source including a gas discharge lamp with a helium-containing filling and means for maintaining the concentration of helium in the gas discharge lamp, characterized in that as a means for maintaining the concentration of helium contains a translucent casing having an input connected to a source of a gas helium-containing mixture of a given composition, and the outlet for discharging this mixture surrounding the discharge lamp so that the lamp is washed by the flow of the specified gas mixture, the concentration of helium in which corresponds to ontsentratsii helium content in the discharge lamp. 2. The UV radiation source according to claim 1, characterized in that the outlet for discharging the gas helium-containing mixture is made in the form of a capillary. 3. The UV radiation source according to claim 2, characterized in that a tube is inserted into the capillary passing along the inner wall of the casing. 4. A multi-tube system based on a UV radiation source according to claim 1, comprising a plurality of UV radiation sources, characterized in that the casings of several UV radiation sources are connected to one or more sources of a gas helium-containing mixture of a given composition.

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