RU2766301C1 - Bactericidal recirculator for air disinfection - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medical equipment, namely to a bactericidal recirculator for indoor air disinfection from pathogenic microorganisms. Device consists of a closed housing combined with a reflector, inside which there is a source of bactericidal radiation in the form of a mercury discharge lamp, fan for blowing the cleaned air through the internal volume of the housing, the ignition mode control device and the operation of the bactericidal radiation source, wiring accessories for mounting and connecting a bactericidal radiation source to a device for controlling the mode of ignition and operation of the bactericidal radiation source. Recirculator is made in the form of a closed reflector, made with possibility of simultaneously performing functions of a protective housing and an air-conducting channel for disinfected air, from polished anodized aluminum with high coefficient of directed reflection in ultraviolet bactericidal region of radiation, and structurally is made of four coaxial equivalent sectors. Coordinates of points of the reflecting surface of each sector are determined by expressions for coordinate points: X=R*CosA+R*A*SinA, Y=R*SinA-R*A*CosA, Y=R*{CosA*(1-A)+SinA*(1+A)}-X, where: R is the radius of the sweep circle, structurally selected from the condition: R is greater than or equal to the radius of a circle circumscribed around the bactericidal radiation source, A is the angle orienting the corresponding radius vectors, radians. Bactericidal recirculator is made in such a way that the ultraviolet rays emanating from the bactericidal radiation source, after the primary reflection from the reflector, repeatedly fall on the active surface of the reflector, are again reflected, and so forth, excluding uncontrolled falling and their absorption by the bactericidal radiation source and other structural elements of the bactericidal recirculator. Bactericidal recirculator is configured to create a reflector of high volumetric density of the bactericidal radiation flux in the volume of the irradiation chamber, which exceeds the density of the direct radiation flux generated by the bactericidal radiation source itself.

EFFECT: optimizing the design of the device in order to increase the efficiency of the target parameters of the recirculator by using several sources of optical radiation.

8 cl, 10 dwg

Description

The bactericidal recirculator for air disinfection belongs to sanitary and hygienic devices. The alleged invention is aimed at increasing the utilization rate of the bactericidal flow of the radiation source, increasing the bactericidal efficiency and productivity of the recirculator.

The use of bactericidal ultraviolet radiation for air disinfection from pathogenic microflora is known and has become widespread since the middle of the twentieth century. However, a real boom in the widespread use of ultraviolet germicidal radiation opened with the onset of the coronovirus epidemic in the country and around the world. In an extremely short time, hundreds of small, medium and large enterprises for the development and production of bactericidal irradiators, including recirculators, have been created in the country and in the world. Currently, there are several thousand different versions of recirculators in the world. Despite the great diversity, in principle they all work according to a single technology: a source of bactericidal radiation is placed in a closed shell, generating a radiant flux in the wavelength range from 205 to 315 nm, through the end inlets 8 closed shell by a fan, forcibly, or due to natural convention , the air taken from the surrounding space is drawn in. Passing along the lamp generating bactericidal ultraviolet radiation, pathogenic microorganisms contained in the air are exposed to the destructive effect of bactericidal radiation; air purified from living microorganisms is discharged through the outlet into the surrounding space.

Numerous subsequent developments concerned, mainly, giving the device additional functions: a relay for recording the operating time, a timer, a complete set with an additional filter for cleaning air from mechanical impurities, various installation methods, mounting, connection, control, etc., and did not address the issue of increasing the coefficient use of a bactericidal stream in a recirculator.

An example of a typical device design is a recirculator from a Russian manufacturer (1). The device consists of a closed, in the form of a parallelepiped, prefabricated metal case, consisting of a base on which all ballasts and bactericidal (s) and lamp (s) are mounted, and covers painted with white paint, the case is equipped with ends with windows on both ends: an inlet window for the intake of purified air, and an outlet window for the removal of air neutralized from microorganisms to the outside. Inside the housing, an irradiation chamber is formed with a source of ultraviolet bactericidal radiation, equipped with protective screens. A fan is installed on the side of the outlet window, which creates a directed flow of cleaned air inside the chamber, along the radiation source.

The main disadvantages of this device are: low utilization of the bactericidal flux of the radiation source, poor resistance to ultraviolet radiation and low reflectance of white paint in the field of hard bactericidal ultraviolet radiation; the non-optimal shape of the case and the arrangement of the lamp in it lead to large irretrievable losses of the bactericidal flux in the process of its reflection inside the chamber.

Another example is the Philips AIR UF bactericidal recirculator (2). The body of the device is made of a plastic pipe, inside which a bactericidal lamp, a fan and control equipment are placed, inlet and outlet windows for air are placed at the ends. On the inner surface of the housing, along the contour, there is a metal reflector that protects the plastic housing from the destructive effect of ultraviolet radiation on the plastic and increases the degree of reflection of the bactericidal flow.

The disadvantage of this design is that the shape of the reflector is determined by the shape of the housing, that is, it has the shape of a cylinder, which leads to the concentration of the radiant flux reflected by the reflector on the lamp located in the center of the housing. The result is additional irretrievable losses of the active radiation flux.

The closest solution to the solution proposed by the author is the recirculator of the ECO-ORION company (3). The recirculator consists of a housing made in the form of a stainless steel pipe. The ends of the housing are closed with protective shielding lattice covers with windows for the input of the purified air into the zone of irradiation with bactericidal radiation and the output, after processing, into the surrounding space. The housing contains (s) a bactericidal mercury lamp (s) of low pressure with a power of 15 or 30 W and all equipment for controlling the operating modes of the lamp (s). At the outlet end of the housing, in front of the lattice cover, there is a fan that provides forced air drawing through the irradiation chamber, along the lamp, and its output, after radiation treatment, to the outside.

The design is distinguished by high resistance of the body to ultraviolet radiation, which guarantees a long service life of the irradiator fittings. However, the design is not without obvious drawbacks. Steel, even in a polished form, has a low reflectivity in the ultraviolet zone of optical radiation. The cylindrical shape of the body-reflector does not provide the optimal distribution of the radiant flux after reflection, from the point of view of the minimum loss of radiation energy in the process of re-reflections.

The design of a bactericidal recirculator for indoor air disinfection from pathogenic microorganisms dangerous to life and health is proposed. The device is shown in Fig. 1. It consists of a closed housing combined with a reflector 1, inside which is placed a source of bactericidal radiation 2, for example, a mercury discharge lamp, a fan(s) 3 for blowing the air to be cleaned through the internal volume of the chamber, a device for controlling the ignition mode and the operation of the radiation source 4, wiring accessories for mounting and connecting the radiation source to the control device 5.

A distinctive feature of the device is that the reflector of Fig. 2 is made of a material with a high directional reflection coefficient of bactericidal ultraviolet radiation, for example, polished anodized mirror aluminum ALANOD (4), VUV-C (5), etc. and consists of four identically shaped coaxial sectors 10; surfaces of each sector are determined by expressions (6):

X=R*CosA+R*A*SinA; Y=R*SinA - R*A*CosA,

in this case, the X and Y coordinates of the profile points are related by the expression

Y=R*{CosA*(1-A)+SinA*(1+A)} - X,

where:

R is the radius of the circle - sweep, is selected constructively from the condition: R is greater than or equal to the radius of the circle described around the radiation source,

A is the angle orienting the corresponding radius vector, in radians.

Examples of reflector profiles built on the basis of the above formulas with three different radii R1, R2, R3 are shown in Fig. 6, 7, 8, 9, 10.

The given calculated curvilinear profiles are known as involute (6), they represent a development of circles, called evolutes (6). A feature of each pair of profiles is that the tangent to the evolute is the normal to the corresponding point of the involute.

With such a dependence, if a radiation source is placed in the center of the evolute, then all rays coming from the source (evolute) to the reflector (evolute), after reflection from the reflector (evolute), will again fall on the reflector, bypassing the original source. Thanks to this effect, the loss of radiation energy that occurs when they fall, after reflection from the reflector, back to the source is excluded. The ray path is shown in Fig. 7, 8, 9. The rays coming from the source to the reflector are shown by solid lines, and the rays reflected from the reflector are shown by dash-dotted lines. The loss of radiation due to its absorption by lamps and structural elements inside the irradiation chamber, as well as due to the low reflection coefficient of the reflector's ultraviolet radiation, lead to a significant decrease in the utilization factor of the bactericidal radiation flux of the source, low recirculator performance and bactericidal efficiency.

In the proposed design of the device, ultraviolet rays emanating from the radiation source, after the first reflection from the reflector, return again to the active surface of the reflector, etc., bypassing the irretrievable losses from the incidence of rays on the radiation source and other structural elements, which in the proposed design are moved beyond limits of the active zone of the camera; as a result, an increased volumetric density of the bactericidal flux is created in the volume of the irradiation chamber, which significantly exceeds the volumetric radiation density created only by the direct radiation of the source, which has a detrimental effect on pathogenic microorganisms. The objectivity of the conclusion is confirmed by the fact that theoretical studies and practical tests of real devices show that actually existing recirculators provide a utilization rate of the bactericidal lamp flux at the level of 0.3 - 0.5, that is, only 30 -50% of the generated bactericidal ultraviolet radiation is rationally used ( 7).

The reflector is made by stamping or profiling from the same profiles 9, 10 of Figs 2, 3, connected with compression of Figs. 2, variant 2, view A or longitudinal curly strips 11 of Fig. 4, option 1 of FIG. 2. End caps 13 of FIG. 6. The outer profile of the ends 13 corresponds in shape and size to the cross section of the reflector 9 of FIG. 5, which gives it additional rigidity and stability. The secondary windows (openings) 14 are provided for the input of the purified air on one side and the output of the purified air from the other end, and holes for the passage of lamps during their installation.

Covers 7 with lattice windows 8 of FIG. 1, for the inlet of the purified air and the outlet of the purified air, with a rim along the inner contour,

corresponding to the outer contour of the reflector cross-section, so that, after the covers are installed, the edges of the reflector on both sides are clamped, in cross section, between the ends 13 and the covers 7, which additionally stabilizes the design shape of the reflector.

, часть отразившегося потока вновь упадет на отражатель, а другая часть упадет на другие элементы, расположенные внутри камеры, часть на источник излучения, и торцевые зоны камеры. Долю лучистого потока, отразившуюся от отражателя и вновь упавшую на отражатель, обозначим буквой Uoo, величина этого потока составит

, другая часть упадет на торцевые части, лампу(ы) и др. элементы и фактически эта часть потока будет потеряна. Обозначим долю потерянного потока буквой Uоп. Величина этой части потока составит

. Процесс будет продолжаться до тех пор, пока не установится баланс потоков. Соотношение между величиной установившегося в камере лучистого потока и лучистого потока, поступающего от источника излучения, определяется через коэффициент многократных отношения, равный

The operation of the optical system of the recirculator can be represented as the following diagram: the radiant flux from the radiation source with the value Ф falls on the reflector, the reflector reflects the radiant flux with the value

, part of the reflected flow will again fall on the reflector, and the other part will fall on other elements located inside the chamber, part on the radiation source, and the end zones of the chamber. The fraction of the radiant flux reflected from the reflector and again falling on the reflector will be denoted by the letter Uoo, the value of this flux will be

, the other part will fall on the end pieces, the lamp(s) and other elements and in fact this part of the flow will be lost. Let us denote the share of the lost flow by the letter Uop. The value of this part of the flow will be

. The process will continue until the balance of flows is established. The ratio between the value of the radiant flux established in the chamber and the radiant flux coming from the radiation source is determined through the multiple ratio coefficient equal to

where:

Fa is the flow established in the chamber as a result of multiple reflections,

Ф - radiant flux of the radiation source,

- коэффициент отражения отражателя,

- reflection coefficient of the reflector,

Uop - the fraction of the lost radiation flux that fell after reflection from the reflector onto the lamp, the end parts of the chamber and other structural elements inside the irradiation chamber.

It can be seen from the above expression that the radiant flux Fo established in the irradiation chamber, the greater the radiant flux of the radiation source Ф, the higher the reflection coefficient of the reflector p and the smaller the proportion of radiation losses Uop on structural elements inside the irradiation chamber.

The proposed design of the product is aimed at optimizing the design of the device, in order to increase the efficiency of the target parameters of the recirculator, with several sources of optical radiation.

In this case, the bactericidal radiation source is made in the form of a mercury discharge lamp, and the reflector is made of two identical symmetrical halves connected into a single whole by two longitudinal profiles. In addition, to connect the lamps, sockets with fixation on the lamp bases are used, which allows you to install and remove the lamps from the ends without removing or disassembling the reflector. Also, taking into account environmental conditions, the reflector can be mounted in an additional protective housing. The bactericidal recirculator consists of several equivalent blocks assembled into a single structure - batteries, or is made in a monolithic design with several sources of optical radiation.

Bibliographic data:

1. Product catalog of ASTZ OJSC, www.astz.ru

2. Philips product catalog, AIR UF

3. Product catalog of the ECO ORION company

4. Catalog of ALANOD, ALANOD Aluminum - Veredlung GmbH Co. KG

5. Catalog of ALMECO GROUP, Almeko Spa, www.almecogroup.com

6. HANDBOOK ON MATHEMATICS for engineers and students of technical colleges. I.N. BRONSTEIN and K.N. SEMENDYAEV, Moscow "NAUKA", 1986

7. Design and operation of ultraviolet bactericidal installations. A.L. Wasserman, Moscow, House of Light, 2009

8. Fundamentals of lighting engineering, V.V. Meshkov, Moscow, Energy, 1979

Claims (12)

1. Bactericidal recirculator for indoor air disinfection from pathogenic microorganisms, consisting of a closed housing, combined with a reflector, inside which a source of bactericidal radiation is placed, in the form of a mercury discharge lamp, a fan for blowing the air being cleaned through the internal volume of the housing, an ignition mode control device and operation of the bactericidal radiation source, wiring accessories for mounting and connecting the bactericidal radiation source to the control device for the ignition mode and operation of the bactericidal radiation source, characterized in that the recirculator is made in the form of a closed reflector, configured to simultaneously perform the functions of a protective housing and an air duct for disinfected air , made of polished anodized aluminum with a high directional reflection coefficient in the ultraviolet bactericidal radiation region, and is structurally made of four coaxial equivalent sectors ov, the coordinates of the points of the reflective surface of each sector are determined by the expressions for the coordinate points: X=R*CosA+R*A*SinA, Y=R*SinA-R*A*CosA, Y=R*{CosA*(1-A) +SinA*(1+A)}-X, where: R - the radius of the circle of the sweep, is selected constructively from the condition: R is greater than or equal to the radius of the circle described around the source of bactericidal radiation, A is the angle orienting the corresponding radius vectors, radians; the bactericidal recirculator is designed in such a way that the ultraviolet rays emanating from the source of bactericidal radiation, after primary reflection from the reflector, fall again on the active surface of the reflector, are reflected again, etc., excluding uncontrolled fall and absorption by the source of bactericidal radiation and other structural elements of the recirculator bactericidal, at the same time, the bactericidal recirculator is configured to create in the volume of the irradiation chamber of the reflector an increased volume density of the bactericidal radiation flux exceeding the density of the direct radiation flux created by the bactericidal radiation source itself. 2. The recirculator according to claim 1, characterized in that all the constituent elements included in its design are taken out of the active zone of irradiation. 3. The recirculator according to claim 1, characterized in that the reflector is made of two identical symmetrical halves connected into a single whole by two longitudinal profiles. 4. The recirculator according to claim. 1, characterized in that the end faces of the reflector are mounted on both sides of the end, having dimensions along the outer contour corresponding to the dimensions of the inner contour of the reflector assembly and having structural holes for the input of the purified air, the output of the purified air from the other end and lamp installation. 5. The recirculator according to claim 1, characterized in that it is equipped with two identical covers with gratings for air inlet and outlet and with a rim corresponding in shape and size to the outer contour of the reflector, after mounting the edges of the reflector in cross section are sandwiched between the ends and lids. 6. The recirculator according to claim 1, characterized in that to connect the lamps, cap cartridges are used with fixation on the lamp bases, made with the possibility of installing and removing the lamp from the ends without removing or disassembling the reflector. 7. Recirculator according to claim 1, characterized in that the reflector is mounted in an additional protective housing. 8. The recirculator according to claim 1, characterized in that it consists of equivalent blocks assembled into a single structure, or is made in a monolithic design with a source of bactericidal radiation.

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