RU2273914C1 - Lamp module - Google Patents

Abstract

FIELD: disinfection and decontamination of gas and water media with aid of ultraviolet rays.

SUBSTANCE: proposed lamp module that can be used both for media treatment and for self-cleaning of lamp bag has ultraviolet-ray source placed in bag transparent for ultraviolet rays, its outer surface being covered with titanium dioxide based photocatalytic coating whose thickness is between 22 and 120 nm.

EFFECT: enlarged functional capabilities and efficiency of treatment.

1 cl, 1 dwg

Description

The invention relates to the field of manufacturing lamp modules intended for disinfection and purification of gas and water environments using UV radiation.

Currently, various technologies widely use the method of disinfecting various media (water, air, etc.) using ultraviolet (UV) radiation of the bactericidal range from 180 to 315 nm. As a radiation source in installations for the implementation of the disinfection process, a lamp module is used, consisting of a gas discharge UV lamp enclosed in a protective cover made of a material transparent to UV radiation. The material for the lamp covers are mainly quartz or uviole glass, which allow UV radiation to pass through.

For special bactericidal lamps, more than 80% of the intensity of the generated radiation falls on a wavelength of 254 nm, which has the most effective inactivating effect on microorganisms, 9-15% on a wavelength of 185 nm and 4% on a range of 306-380 nm. However, it is known that UV radiation with a wavelength of 185 nm is undesirable, since it forms ozone harmful to humans in air. To prevent this, in the manufacture of lamp bulbs use ozone-free uvolev glass or quartz. Due to the presence of additives of various metals and their compounds in the composition of such glass or quartz, the ozone-forming line of the spectrum is absorbed, and ozone production does not occur. However, together with ozone-forming radiation, quartz with additives absorbs 3-7% of the most effective bactericidal radiation of 254 nm, which reduces the effectiveness of disinfection. In addition, the use of special glass increases the cost of lamps.

During operation of the lamp module in the environment, various contaminants are formed on the surface of the protective covers - both organic and inorganic (for example, deposits of metal salts contained in natural waters, etc.), which reduces their light conductivity. This can cause a significant drop in the intensity of bactericidal radiation and a drop in the radiation dose below the normative level. Therefore, it is necessary to periodically clean the surface of the lamp covers from contamination, for which modern UV disinfection units are equipped with special devices that allow cleaning the covers in various ways - mechanical, chemical, ultrasonic vibrations, which is a difficult technical task, especially for multi-tube systems.

A photocatalytic coating is known, used mainly for window panes, containing a thin layer of titanium dioxide TiO ₂ . The effect of UV radiation on the specified layer causes a photocatalytic effect, which results in the destruction of organic contaminants on the glass. In addition, the coating makes the glass hydrophilic, and water, falling on the glass, does not roll in the form of drops, but spreads over the surface and rinses dirt from it. The coating thickness is from 2 to 20 nm. Due to the properties of the known coating, self-cleaning of the glass occurs, which greatly simplifies and cheapens its operation (EP 1254870, C 03 C 17/245, 2002).

A known installation for water treatment, consisting of a housing in which UV lamps are installed, and equipped with a device for cleaning them, which, rotating, moves along the surface of the lamp bulbs. The cleaning heads of the device are coated with a photocatalytic material based on titanium dioxide. Under the influence of UV radiation of the lamp, a catalytic reaction begins, the products of which clean the surface of the flasks.

A disadvantage of the known device is the availability of a special cleaning device and the complexity of its design, as well as the complexity of the cleaning process, since with successive movement of the heads, only a small part of the lamp surface is activated and cleaned once. For these reasons, the use of this device for multi-tube systems is difficult (EP 1371611, C 02 F 1/32, 2003).

A water treatment plant is also known, in which the effect of photocatalytic oxidation is used for the cleaning and disinfection process. The lamp module, consisting of a UV lamp in a protective case made of quartz glass, is installed inside the housing with inlet and outlet nozzles. Around the lamp module is fixed a flat spiral coated with a photocatalytic coating based on TiO ₂ , which together with the walls of the housing forms a spiral channel for the flow of treated water. A photocatalytic coating is also applied to the inner walls of the housing, the inlet and outlet nozzles. As a result of activation of the coating with UV radiation in the range 254-365 nm, a photocatalytic process occurs, the products of which affect both microorganisms and the contaminants contained in water, destroying them (US 20030209501, C 02 F 1/32, 2003, prototype). The known device allows to increase the area and time of contact of the liquid with active radicals by using the entire internal surface of the installation. UV radiation in this case is used for the process of purification and disinfection of water. The problem of cleaning covers in this case is not solved, in addition, this device cannot be used in multi-tube installations with high performance and in open (caseless) systems.

The technical problem to which the invention is directed is the creation of a universal easy-to-clean lamp module with a wide range of applications, effectively using the UV radiation generated by the lamp and providing high processing efficiency

The essence of the invention lies in the fact that in a lamp module containing a UV radiation source, enclosed in a transparent case for UV radiation, according to the invention, a layer of a photocatalytic coating based on titanium dioxide is applied to the outer surface of the case, the coating thickness being from 22 to 120 nm.

The technical result achieved through the implementation of the invention is as follows:

- the simultaneous use of the UV radiation generated by the lamp and the energy expended on its generation both for the process of processing the medium and for cleaning the lamp covers. UV radiation in this case not only has a bactericidal effect, but also initiates the photocatalytic process, which makes an additional contribution to both the process of water disinfection and the cleaning process of lamp covers.

- increasing the efficiency of use of the UV radiation generated by the lamp in the process of water disinfection and purification due to the possibility of involving previously unused radiation in the spectral ranges: 160–205 nm and 315–380 nm in addition to bactericidal radiation of 205–315 nm, including and ozone-generating radiation;

- increasing the efficiency of disinfection and improving the organoleptic properties of the medium being processed due to the formation of hydroxyl and oxygen active radicals during photocatalysis that destroy both microorganisms and organic and inorganic compounds;

- the implementation of the possibility of cleaning covers without the use of special devices;

- simplifying the design of installations for disinfection of media on the basis of the declared lamp module and reducing the cost of their maintenance, especially essential for multi-tube systems;

- the implementation of the possibility of using UV lamps with glass flasks without absorbing ozone-forming radiation additives, since the absorption of the ozone-forming line of the spectrum is provided by the presence of a photocatalytic layer of a given thickness. Along with this, the efficiency of using bactericidal radiation, which was previously absorbed by the material of the lamp bulb, is increasing;

- the versatility of using the module in all types of systems for treating water with UV radiation.

The choice of the thickness of the applied layer of the photocatalytic coating is due to the fact that the absorption of ozone-forming radiation of 185 nm and the optimal bactericidal radiation yield of 254 nm is not less than 70% for the process of disinfection and cleaning.

The invention is illustrated by the drawing, which shows the lamp module 1 located in the medium to be treated, containing a UV lamp 2 enclosed in a protective cover 3. The electrical contacts of the 4 lamps are protected from water ingress by a seal consisting of a gasket 5, a compression nut 6, a washer 7 Through the specified hermetic seal and hermetic inlet 8, an electric wire 9 is brought to the lamina. A photocatalytic layer 10 of a given thickness is deposited on the outside of the sheath.

Example 1. The lamp module consists of a DB 75 low pressure bactericidal mercury lamp placed in a protective quartz case. The lamp's electrical contacts are protected against water through them with gaskets and compression nuts. A photocatalytic coating of titanium dioxide (anatase) with a thickness of 50 nm is deposited on the outer surface of the case.

The module is placed in the UDV 5/1 water disinfection unit manufactured by NPO LIT with a capacity of 5 m ³ / h. For comparison, a standard lamp module without a photocatalytic coating on a case was placed in the same installation. The units are equipped with a UV radiation intensity sensor, according to the testimony of which pollution of the covers of UV lamps is monitored. The operating time of the lamp module without photocatalytic coating before the scheduled washing of the covers was 1,900 hours, while the optical transmittance of the cover at a wavelength of 254 nm, determined by the sensor, decreased by 20%. For the same time, the optical transmittance of the photocatalytic coated case decreased by only 2-5%, which indicates effective self-cleaning of the cases.

Example 2. The lamp module consists of a gas discharge bactericidal mercury lamp of low pressure, with a bulb made of quartz, transmitting radiation with a wavelength of 185 nm, which is placed in a quartz case, also transparent for radiation of 185 nm. The internal cavity of the cover was filled with argon at atmospheric pressure in order to prevent the formation of ozone from atmospheric oxygen and absorption of radiation of 254 nm. According to the invention, a photocatalytic coating of titanium dioxide with a thickness of 26 nm was applied to the outer surface of the case. The measurements showed that radiation with a wavelength of 185 nm was almost completely absorbed by the photocatalytic layer, and the absorption of radiation with a wavelength of 254 nm was 5%. Thus, due to the use of a UV lamp with a glass bulb made of glass without absorbing additives in the claimed module, the yield of the most active bactericidal radiation with a wavelength of 254 nm increased in the absence of ozone production.

Example 3. For comparison, 3 types of modules were placed in installations for water disinfection UDV 5/1:

- a standard module with an ozone-free lamp DB 75, not emitting at a wavelength of 185 nm, and a quartz case without a photocatalytic coating,

- a lamp module containing a DB 75 ozoneless lamp placed in a quartz case with a photocatalytic coating,

- lamp module according to example 2.

During the operation of the installation, water samples passed through the installation were taken for microbiological analysis. It was found that the excess of the permissible level of the number of indicator microorganisms in water samples occurred for the standard module after 2000 hours of operation; for a module with an ozone-free lamp and photocatalytic coating - after 3500 hours; and for the module according to example 2, after 7000 hours. The results show that the efficiency of the installation increases both due to the use of a photocatalytic coating and due to the contribution of radiation with a wavelength of 185 nm.

Claims (1)

A lamp module containing a UV radiation source enclosed in a case transparent to UV radiation, characterized in that a photocatalytic layer based on titanium dioxide 22-120 nm thick is deposited on the outer surface of the case.