RU25413U1 - BACTERICIDAL IRRADIATOR - Google Patents

Description

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Bactericidal irradiator

to the application for a utility model. A utility model relates to sanitation and hygiene and can be used in working, domestic and medical premises, as well as at home using ultraviolet radiation to create normal sanitary conditions. It is known that there are two types of irradiators: an open type irradiator in which the source of ultraviolet radiation (bactericidal lamp) does not have an opaque shell; - a closed type irradiator in which the source of ultraviolet radiation is placed in an opaque shell. The irradiators of the first type are intended for the treatment of surfaces and indoor air only in the absence of people. The irradiators of the second type are designed to disinfect only indoor air and can be operated in the presence of people. The irradiators of the second type are of interest, since only they can work (subject to certain safety measures) in home conditions.

case in which the source of ultraviolet

radiation and a fan, bactericidal, gas-discharge mercury-quartz lamps of low pressure are used as a source of ultraviolet radiation (see USSR author's certificate 810243, 1981). However, the known technical solution does not provide sufficient efficiency of disinfecting the premises due to the uneven processing of the circulating air flow and does not allow people to be in the room due to the presence of ozone in the air, formed under the influence of ultraviolet radiation during the operation of the bactericidal lamp.

Closest to the claimed utility model is a bactericidal irradiator, comprising a housing with an irradiation chamber, a fan, reflective armature, an ultraviolet radiation source located in the irradiation chamber in the form of at least one bactericidal lamp, ballasts, fasteners and attachments to the mains, at least one bactericidal lamp, (see RF patent 2092191 publ. 10.10.1997). The disadvantages of the known technical solutions are the insufficiently high efficiency of the source of the bactericidal emitter, not intended for processing indoor air in the presence of people.

The useful model is aimed at increasing the efficiency of the source of bactericidal radiation due to the gas-dynamic unit made in the form of a labyrinth made of a material transparent to bactericidal radiation, for example, in the form of transparent quartz tubes of arbitrary shape located in the irradiation chamber with the formation of the labyrinth, increasing the efficiency of des (air contamination for multiple exposures of disinfected air flowing through the labyrinth of the irradiation chamber optically transparent to bactericidal radiation MPa and coatings with a reflective layer of the radiation chamber, ensuring a comfortable stay of people in the disinfected room by reducing the noise of the fan located in a separate chamber, simplifying the design by reducing the size of the irradiator while maintaining the given performance. with an irradiation chamber, a fan, reflecting armature, an ultraviolet radiation source placed in the irradiation chamber in the form of, at least , of one bactericidal lamp, ballasts, fasteners and attachments to the supply network of at least one bactericidal lamp, is equipped with a gas-dynamic unit made in the form of at least one quartz transparent tube of arbitrary shape, optically transparent for long-wave ultraviolet radiation up to 300 nm, located in the irradiation chamber with the formation of a labyrinth for the flow of disinfected air with the aim of repeatedly irradiating the air from at least one bactericidal lamp, elem ntami for suppressing electromagnetic interference in the radio frequency range, wherein the housing is further divided into an inlet chamber and an outlet, a fan disposed in the inlet chamber.

full of round section. The fan can be made

pressure head. The surface of the irradiation chamber may be coated with a reflective layer.

The source of ultraviolet radiation can be placed in a chamber with a labyrinth for the flow of disinfected air formed by at least one tube that is optically transparent for ultraviolet radiation from a bactericidal lamp with a wavelength of up to 300 n m ,,, .- -

The proposed combination of structural elements provides effective disinfection of the air flow by ultraviolet radiation in the irradiation chamber, and the presence of an inlet chamber helps to reduce the noise, which is especially important when the device is used in medical facilities.

Pa fig. 1 shows a General view of the bactericidal irradiator.

The bactericidal irradiator comprises a housing 1 with an inlet and outlet chambers 2, 3 and an irradiation chamber 4. The pressure fan 5 is placed in the inlet chamber 2. In the irradiation chamber 4, an ultraviolet radiation source 6 is arranged in the form of one or more bactericidal lamps provided with an inner coating. The gas-dynamic unit is made in the form of one or several transparent quartz tubes 7, for example of circular cross section, located in the irradiation chamber 4 with the formation of a labyrinth through which disinfected air flows.

d (i6m bactericidal lamp, elements for suppressing electromagnetic interference in the radio frequency range (not shown in Fig.). The surface of the radiation chamber 4 can be coated with a reflective layer. The bactericidal lamps can be placed in quartz tubes 7. The labyrinth can also include glass partitions (not shown in Fig.) The bactericidal irradiator operates as follows: Air taken from the room through the inlet chamber 2 is supplied by the fan 5 to the irradiation chamber 4, where, passing through the labyrinth formed by the transparent using quartz tubes 7, and having received a large dose of ultraviolet radiation from a bactericidal lamp, it is disinfected, enters the outlet chamber 3 and then enters the room, providing constant recirculation. a source of ultraviolet radiation can be used ozone-free low-pressure mercury lamps.The idea of a new approach to the design of a bactericidal irradiator follows from the following Microorganisms relate to cumulative photobiological receivers; therefore, bactericidal efficacy should be proportional to the product of irradiation by time, i.e. determined by dose. However, the nonlinear characteristic of the photobiological receiver limits the possibility of wide variation to the values of irradiation and time with the same bactericidal efficacy. Within the permissible error, the ratio of irradiation and time can be changed in the range of 510 multiple variations. From this position the following was made

conclusion: By increasing the exposure time of the microorganism while maintaining a certain selected value of irradiation (power of the bactericidal lamp), the bacteriological efficiency of the ultraviolet radiation source can be increased.

Claims (5)

1. A bactericidal irradiator, comprising a housing with an irradiation chamber, a fan, reflective armature, an ultraviolet radiation source in the form of at least one bactericidal lamp, a ballast, mounting parts and attachments to the supply network of at least one bactericidal lamp, characterized in that it is equipped with a gas-dynamic unit made in the form of at least one quartz transparent tube of arbitrary shape, optically transparent for ultraviolet radiation for another wave up to 300 nm, located in the irradiation chamber with the formation of a labyrinth for the flow of disinfected air to repeatedly irradiate the air from at least one bactericidal lamp, with elements for suppressing electromagnetic interference in the radio frequency range, the housing being further divided into inlet and outlet chambers and the fan is located in the intake chamber.  2. The bactericidal irradiator according to claim 1, characterized in that at least one quartz tube, necessary for the formation of the labyrinth through which disinfected air flows, is made of circular cross section.  3. The bactericidal irradiator according to claim 1, characterized in that the fan is made pressure.  4. The bactericidal irradiator according to any one of claims 1 to 3, characterized in that the surface of the irradiation chamber is coated with a reflective layer. 5. The bactericidal irradiator according to any one of claims 1 to 4, characterized in that the source of ultraviolet radiation is placed in a chamber with a labyrinth for the flow of disinfected air formed by at least one tube that is optically transparent for ultraviolet radiation of a bactericidal lamp with a wavelength of up to 300 nm.