RU2796766C1 - Air purification and disinfection device - Google Patents

Abstract

FIELD: air purification; disinfection by means of air filters.

SUBSTANCE: invention is intended for use in places with a requirement for low noise levels. The air purification and disinfection device includes a housing. The housing has at least one air intake hole and at least one air outlet hole. The housing contains a primary filter, a high-efficiency filter, and at least one fan. The fan is of a radial type and is located in such a way that its axis is parallel to the planes of the filters, and the high-performance filter is made with the possibility of disinfection. This allows to achieve effective cleaning and disinfection of air.

EFFECT: among other things invention ensures a low level of noise produced by the fan, as well as the safety and durability of the device due to reliability and simplicity of the device design used.

15 cl, 10 dwg

Description

Technical field

[1] The present invention relates to the field of air purification and disinfection by means of air filters, intended for use in places with a requirement for low noise.

State of the art

[2] Currently, there are many different air purifiers being developed, which are used in many different areas, for example, there are air purifiers for home, office, hospitals, factories, etc. All air purifiers include at least one air intake, according to at least one air outlet, at least one fan and filter block. The filter unit can be used in various filter configurations, depending on the specific task.

[3] In offices, homes and hospitals, the most important factor in an air purifying device is its efficiency, i.e. the ability to purify a large number of harmful substances, the ability to disinfect the air, and also an important factor is its low noise level and low cost. If it is necessary to ensure high purification efficiency from many types of harmful substances in the air, manufacturers of air purification devices include many different types of filters in the filter unit. However, this entails a large load on the fan and, as a result, a high level of noise produced by the device during operation. It also greatly increases the cost of the device.

[4] An air purification device according to patent RU2340360C2 (publ. 10.12.2008; IPC: A61L 9/20) is known, containing a housing, a fan, an air treatment chamber with UV radiation (ultraviolet radiation) containing a source of UV radiation, and HEPA filter. The device also contains means for adjusting the parameters of the air flow (speed, humidity, temperature) and the source of UV radiation (power output and temperature). In addition, the device is provided with a microorganism sensor connected to a data processing device that controls the operation of the air purification device, and a cooling unit for cooling and/or drying the air flow. The disadvantage of this solution is the use of a source of UV radiation for air disinfection. This is ineffective at a high speed of air passing through the body of the device for air disinfection. It can also be dangerous for users, as Some bacteria mutate when exposed to UV radiation. Moreover, air disinfection after a HEPA filter is meaningless, because. The HEPA filter traps all microbes and bacteria that subsequently multiply on it, which reduces the safety of the device as a whole. Another disadvantage is that in the analog, the fan is installed in such a way that the air flow inside the device case forms a turbulent flow. Air turbulence results in high fan noise. Also, a large number of elements in the cleaning device, which do not affect the efficiency of disinfection and air purification, significantly increase the cost of the device, and additional elements located in the path of the air flow also create additional turbulence and pressure drops, leading to a high noise level. Also, an important disadvantage of the device is that the filter elements are not fixed in the housing using clamping mechanisms. In view of this, the sealing of the device may be broken, which will lead to an increase in the passage of uncleaned air to the outlet of the device.

[5] An air-cleaning device is also known according to the application US 518015 A (publ. 09.02.1993; IPC: B03C 3/38). The device includes a housing having an inlet and outlet, and a fan to maintain air flow through the housing from the inlet to the outlet. The first filter element removes particles larger than the specified size from the air entering the housing through the inlet, and the second filter element removes particles of selected chemical compounds from the air that has passed through the first filter element in the direction from the inlet to the outlet. The second filter element forms a chamber which communicates openly with the outlet, and this chamber forms a third filter element in which air is irradiated with ultraviolet light. The disadvantage of this solution is the use of a source of UV radiation for air disinfection. This is ineffective at a high speed of air passing through the body of the device for air disinfection. It can also be dangerous for users, as Some bacteria mutate when exposed to UV radiation. Also, an important disadvantage of the device is that the filter elements are not fixed in the housing using clamping mechanisms. In view of this, the sealing of the device may be broken, which will lead to an increase in the passage of uncleaned air to the outlet of the device.

[6] Also known is patent CN 203442979 U (publ. 02/19/2014; IPC: F24F 1/02; B01D 46/12; B01D 53/86; A61L 9/20; A61L 9/22), which discloses a cleaner air. The air purifier consists of a body, a fan, and an adsorption and decomposition device. The air inlet and the air outlet are provided in the case, and the fan and the adsorption and decomposition device are located in the case. The adsorption and decomposition device comprises a primary filter layer, an effective filter layer of an air filter, a filter layer of activated silicon dioxide, a filter layer with a belt ion filter, a filter layer with activated carbon, a filter layer with a photocatalyst, an ultraviolet sterilization layer and a negative ion layer. The disadvantage of this solution is the use of a source of UV radiation for air disinfection. This is ineffective at a high speed of air passing through the body of the device for air disinfection. It can also be dangerous for users, as Some bacteria mutate when exposed to UV radiation. Moreover, air disinfection after a HEPA filter is meaningless, because. The HEPA filter traps all microbes and bacteria that subsequently multiply on it, which reduces the safety of the device as a whole. Also, a large number of elements in the cleaning device greatly increases the cost of the device, and a large number of filters located in the air flow path also entails a large load on the fan to maintain a stable high speed flow. Because of this, the fan can produce a high level of noise during operation. Also, an important disadvantage of the device is that the filter elements are not fixed in the housing using clamping mechanisms. In view of this, the sealing of the device may be broken, which will lead to an increase in the passage of uncleaned air to the outlet of the device.

[7] Also known is the patent CN 204063339 U (publ. 31.12.2014; F24F 1/02; F24F 11/02), which describes a smart powerful air purifier, arranged in such a way that at the air inlet to the air cleaner through the air duct in the air outlet channel along the airflow direction are the pre-filter cartridge, HEPA filter core and composite activated carbon filter core at the air inlet. The source of UV radiation and the grid of the photocatalyst are located at the air outlet. The air that enters the air inlet from the room passes through three-layer filtration, purification and double sterilization before being discharged from the air outlet, thus forming a circular purifying air flow. The disadvantage of this solution is the use of a source of UV radiation for air disinfection. This is ineffective at a high speed of air passing through the body of the device for air disinfection. It can also be dangerous for users, as Some bacteria mutate when exposed to UV radiation. Moreover, air disinfection after a HEPA filter is meaningless, because. The HEPA filter traps all microbes and bacteria that subsequently multiply on it, which reduces the safety of the device as a whole. Also, a large number of elements in the cleaning device greatly increases the cost of the device, and a large number of filters located in the air flow path also entails a large load on the fan to maintain a stable high speed flow. Because of this, the fan can produce a high level of noise during operation. Also, an important disadvantage of the device is that the filter elements are not fixed in the housing using clamping mechanisms. In view of this, the sealing of the device may be broken, which will lead to an increase in the passage of uncleaned air to the outlet of the device.

[8] A device is also known according to patent KR 101731948 B1 (published on May 2, 2017; IPC: B01D 46/12; B01D 39/00). The air purification device comprises a closing and opening front cover, a housing having an outlet and a suction hole, a pre-treatment filter removably mounted in the rear part of the suction hole. Inside the housing there is a horizontal filter block, which attaches and detaches horizontally; and a blower installed at the top of the horizontal filtering device for air intake and exhaust. In this case, the pre-treatment filter is coated with carbon. Also, the filter unit includes a filter part for removing inorganic gases, which has an environmental filter, an inorganic acid filter, and an environmental filter. In addition, it includes an organic gas removal filter part including two environmental filters, an organic gas filter. The device also includes a deodorizing filter and a particulate filter, which is a hepar filter composed of charged fibers. The disadvantage of the device is that it does not have an air disinfection device, in connection with which bacteria will settle on the filters of the device. This makes the device dangerous for the user, because. if filters need to be replaced after they become clogged, the user will be touching the potentially contaminated filter surface as well as breathing air over bacteria-laden filters. Also, a large number of elements in the cleaning device greatly increases the cost of the device, and a large number of filters located in the air flow path also entails a large load on the fan to maintain a stable high speed flow. Because of this, the fan can produce a high level of noise during operation. Also, an important disadvantage of the device is that the filter elements are not fixed in the housing using clamping mechanisms. In view of this, the sealing of the device may be broken, which will lead to an increase in the passage of uncleaned air to the outlet of the device.

The essence of the invention

[9] The objective of the present invention is to create a compact and economical and reliable device that provides a high level of air purification and disinfection and produces low noise.

[10] This task is achieved due to such a technical result as effective purification and disinfection of air from the harmful substances contained in it, while ensuring a low level of noise produced by the fan, as well as the safety and duration of operation of the device due to the reliability and simplicity of the applied design of the device. This objective is achieved, among other things, but not limited to:

a combination of two types of filters: a primary filter and a high-performance filter with antibacterial impregnation;

the use of a clamping mechanism for fixing filters in the device case;

selection and location of the fan in accordance with the dependence of the noise level on the voltage on the fan.

[11] More fully, the technical result is achieved by an air purification and disinfection device, including a housing in which at least one air intake hole and at least one air outlet hole are made. Inside the case are a primary filter, a high-efficiency filter, and at least one fan. In this case, the fan is of a radial type and is located in such a way that its axis is parallel to the planes of the filters, and the high-performance filter is made with the possibility of disinfection.

[12] At the same time, at least one air intake hole is necessary to take air from outside the filter housing and let it into the housing for subsequent cleaning and disinfection. At least one air outlet is required to remove purified and disinfected air from the device. The primary filter is necessary to clean the air from coarse dust and debris. Its location before the high-efficiency filter is necessary in order to increase the service life of the high-efficiency filter, since otherwise, both small harmful substances and large ones will settle on a highly efficient filter, as a result of which its resource will run out much faster. A high-efficiency filter is necessary to purify the air from small harmful substances in the air, such as fine dust, pollen, animal dander, dust mites and cockroaches, which are the strongest allergens, and a high-efficiency filter traps bacteria and germs. Moreover, the implementation of a high-performance filter with the possibility of disinfection makes it possible to deactivate the captured microbes and bacteria, so that they do not multiply on its surface. This, in turn, makes the device safer for the user when the filter needs to be changed. The fan is necessary to organize the air flow in such a way that it enters the housing through the air intake hole, passes through both filters of the air purification and disinfection device and, after passing through the filters, exits through the air outlet hole. Moreover, the fact that the fan is a fan of a radial type and is located in such a way that its axis is parallel to the planes of the filters is necessary to reduce the noise level produced by the fan. Also, this is facilitated by a small number of internal elements, i.e. filters and other structural elements in the air flow. Fewer filters inside the housing entails a lower pressure drop across the filters and thus a lower fan load.

[13] The disinfection function of the high efficiency filter can be realized by providing the high efficiency filter with antibacterial impregnation. Zinc pyrithione can be used as an antibacterial impregnation. The antibacterial activity of zinc pyrithione is manifested in relation to a number of pathogenic microorganisms (streptococcus, staphylococcus aureus, Pseudomonas aeruginosa and Escherichia coli, Proteus, etc.). Zinc pyrithione reduces the intracellular level of ATP, promotes depolarization of cell membranes, causing deactivation of fungi and bacteria.

[14] The primary filter and the high efficiency filter can be fixed in the body of the device by means of clamping mechanisms. The high efficiency filter pressing mechanism may include a filter frame in the form of a high efficiency filter with an insert cavity. At least two clamping tabs can be attached to the high-efficiency filter frame, which increases the fixing strength. Each of the clamp tabs can be attached to the frame with at least two pop rivets. The primary filter pressing mechanism may include a filter frame in the form of a primary filter with a filter insertion cavity and a pressing frame. The clamping mechanisms of both filters make it possible to avoid gaps between the inner walls of the device housing and the filters, so that the device can have a higher degree of tightness. Consequently, the risk of untreated air passing through is significantly reduced and the efficiency of air purification and disinfection is increased.

[15] It is also possible to use a combination of a radial fan and filters such that when cleaning 100 m ³ /h of air, the noise level does not exceed 40 dB.

[16] Distribution grids can be provided in each of the air inlet and outlet openings. They allow you to avoid getting into the body of the device large debris that can quickly clog filters or disable other elements of the device.

[17] A high efficiency filter of at least E11 (H11) class can be used. This class of filter allows you to purify the air from 95% of harmful substances. Higher filtration classes allow you to achieve an even greater degree of air purification.

[18] The device for air purification and disinfection can be made with a removable service panel. This makes it easier to replace filters when they are clogged, as well as to facilitate the repair of the device as a whole.

[19] Most of the area of the inner surface of the housing can be made with a seal. The seals not only provide a higher degree of sealing of the device, which increases the efficiency of air purification, but also contributes to noise reduction.

[20] Air inlets and air outlets can be provided on opposite sides of the housing. At the same time, the planes of the openings for air intake and air outlet can be parallel to the planes of the filters and the fan axis. This avoids the formation of turbulence in the air flow into the case, which reduces the degree of air turbulence and the load on the fan. As a result, this reduces the noise level produced by the fan during operation.

Description of drawings

[21] FIG. 1 is a schematic view of an air purification and disinfection device according to the present invention (in section).

[22] FIG. 2 is a schematic view of an air purification and decontamination device according to the present invention with an illustration of the air flow (in section).

[23] FIG. 3 shows a graph of the dependence of the sound pressure level on the voltage on the fan.

[24] FIG. 4 is a schematic view of an air purification and disinfection device according to the present invention with clamping mechanisms (in section).

[25] FIG. 5 is a schematic view of the pressure mechanism of the high efficiency filter (side view).

[26] FIG. 6 is a schematic view of the pressure mechanism of the high efficiency filter (3D view).

[27] FIG. 7 is a schematic view of the closed primary filter pressure mechanism (3D view).

[28] FIG. 8 shows a schematic view of the primary filter pressure mechanism in open form (3D image).

[29] FIG. 9 is a schematic view of an air purification and disinfection device according to the present invention with additional elements (in section).

[30] FIG. 10 is a schematic view of an air purification and disinfection device according to the present invention with additional elements (3D view).

Detailed description

[31] In the following detailed description of the implementation of the invention, numerous implementation details are provided to provide a clear understanding of the present invention. However, it will be obvious to one skilled in the art how the present invention can be used, both with and without these implementation details. In other cases, well-known methods, procedures and components are not described in detail so as not to obscure the features of the present invention.

[32] In addition, from the foregoing it is clear that the invention is not limited to the above implementation. Numerous possible modifications, alterations, variations, and substitutions that retain the spirit and form of the present invention will be apparent to those skilled in the art.

[33] FIG. 1 shows a schematic diagram of an air purification and disinfection device according to the present invention. The device includes a housing 1 , which has at least one air intake hole 2 and at least one air outlet hole 3 . At the same time, a primary filter 4 , a high-efficiency filter 5 and a fan 6 are located inside the housing 1 . As a fan 6, a radial fan is used, and it 6 is located in such a way that its axis 7 is parallel to the planes of the filters 4 , 5 . The high efficiency filter 5 is also designed to be disinfected.

[34] The air intake hole 2 is necessary for air intake from the street or from the room into the housing 1 of the air purification and disinfection device, and the air outlet 3 is necessary for the removal of purified air from the housing 1 . The shape of the holes 2 , 3 can be made in the form of any flat geometric figure. However, the size of the openings 2 , 3 must be selected according to the load on the fan 6 . So, if the holes 2 , 3 are too narrow, the load on the fan 6 will increase and, as a result, the noise level produced by the fan 6 during operation will increase. In this case, the size of the holes 2 , 3 depends both on the dimensions of the housing 1 and on the dimensions of the fan 6 , in particular, on the dimensions of the inlet and outlet openings of the radial fan. The fan 6 then rotates in such a direction that air is introduced into the housing 1 through the air intake 2 , as shown in FIG. 2. After that, the air passes successively through the primary filter 4 and through the high efficiency filter 5 . Further, the already purified air is discharged from the body 1 of the device through the air outlet 3 .

[35] The primary filter 4 may also be referred to as pre-filters or coarse filters. Such filters trap particles larger than 10 µm, such as fluff , soot, coarse dust particles, insects, feathers, large plant seeds, etc. its resource will not quickly end due to clogging with small debris and coarse dust. Filters class G1(EU1), G2(EU2), G3(EU3), G4(EU4) can be used.

[36] High Efficiency Filter 5 (or HEPA/EPA filters) are designed to clean the air of particles larger than 0.3 microns, including the finest highly allergenic dust (PM2.5), fungal spores, pollen, smog particles and other small particles . Viruses and bacteria also settle on filters of this class, however, due to the high-performance filter 5 with the possibility of air disinfection, viruses and bacteria that have settled on it will be deactivated. As a result, the filter 5 will not be dangerous to the user if it is necessary to replace it, and this also prevents the possibility of proliferation of bacteria on its surface. The filter material of the high-efficiency filter 5 itself is folded like an accordion, i. corrugated, forming a rectangular parallelepiped in the zeroth approximation.

[37] The primary filter 4 can be made in various flat shapes. Firstly, it can be made as a roll of non-woven fabric filters. Secondly, it can be made as a panel filter with polyester or glass fiber as the filter material. Thirdly, the primary filter 4 can also be made in the form of a cassette filter, i. filter with pleated material for increased filtration area.

[38] E11 (H11) high efficiency filter 5 or higher can be used, where the high efficiency filter captures 95% of harmful substances in the air. If an even higher degree of purification is required, a high-efficiency filter of class H12 that captures 99.5% of harmful substances, class H13 that captures 99.95% of harmful substances, or class H14 that captures 99.995% of harmful substances can be used. The choice of class depends on the scope of the filter and on the specific task. Thus, the highly efficient filter 5 in the design of the device according to the present invention makes it possible to purify the air from at least 95% of harmful particles and substances contained in the air.

[39] As a high-performance filter 5 , a framed (for tightness, strength, and holding the filter material in a folded state) fibrous material, folded in the form of an accordion and/or folded in multilayers, can be used. The fibers often have a diameter of 0.5-6.5 microns, and the distance between them is usually 5-50 microns. The fibers can be made from paper and fiberglass, and the frame can be metal, plastic, etc. The capture of 5 small particles by a high-performance filter is associated with two processes: adhesion and autohesion. Adhesion is the interaction of dust with the depositing surface, in the described case with the fibers of a high-efficiency filter 5 . Due to adhesion, the first layer of dust appears on clean fibers. Autohesion (or "stickiness") is the interaction of dust particles with each other. Due to autogenous interaction, the particles continue to layer on each other, forming multilayer conglomerates on the fibers. The nature of adhesion and autohesion lies in the molecular interaction of particles with each other and with fibers (van der Waals forces). These forces appear at a distance of one to several hundred particle diameters. For the smallest particles, the attraction to the fiber and the dust layer is so strong that the particles reliably settle on the fibers of the high-efficiency filter 5 .

[40] Decontamination can be achieved by making the high efficiency filter 5 impregnated with antibacterial. As an antibacterial impregnation, for example, zinc pyrithione can be used. Zinc pyrithione activated has anti-inflammatory, antibacterial and antifungal activity. A similar effect will be achieved when silver particles or ions are used if they are injected into the non-woven structure of a high-efficiency filter 5 . However, the injection of particles and silver ions significantly increases the cost of the device. In addition, a decontamination effect can be achieved by applying a physical antibacterial layer to the airflow front surface of the high efficiency filter 5 . The antibacterial layer may also be based on zinc pyrithione.

[41] At the same time, it is important to note that there can be more than one holes, both for air intake 2 and for air outlet 3 , in the housing 1 . So, for example, in Fig. 1 shows an air purification and disinfection device with one air intake 2 and one air outlet 3 . On FIG. 2, in turn, shows a variant with two air outlets 3 and one air intake 2 . In this case, it is preferable to carry out in the case 1 the number of fans is the same as the number of air outlets 3 .

[42] Also, in order to avoid turbulences in the body 1 of the device, and, as a consequence, to reduce the noise level, it is preferable to provide holes 2 , 3 on opposite sides of the body 1 . In this case, it is also preferable that the planes of the holes 2 , 3 be parallel to both the planes of the filters 4 , 5 and the axis of the fan 7 . Due to this arrangement, the air in the process of passing through the housing 1 will not form turbulence. Due to this, the noise level produced by the fan 6 and the device as a whole will also be reduced.

[43] In FIG. 3 shows a plot of sound pressure level (SPL) versus fan 6 performance using this device. As can be seen from the graph, in the range from 0 to 200 m ³ /h, SPL does not reach a value above 50 dB, which is comparable in volume to a quiet conversation. With a capacity of up to 150 m ³ /h, the SPL does not even reach 40 dB, which is comparable in volume to a whisper. Thus, the combination of filters 4 , 5 with a fan 6 of a radial type and their mutual arrangement allows for cleaning up to 150 m ³ /h of air not to exceed the noise level of 40 dB.

[44] In FIG. 4 shows a schematic view of the air purification and disinfection device with clamping mechanisms ( 41 , 42 , 51 ) of filters ( 4 , 5 ). The clamping mechanisms ( 41 , 42 , 51 ) of both filters ( 4 , 5 ) prevent gaps between the inner walls of the device housing 1 and the filters ( 4 , 5 ), so that the device can have a higher degree of tightness. Consequently, the risk of untreated air passing through is significantly reduced and the efficiency of air purification and disinfection is increased.

[45] In FIG. 5 and FIG. 6 is a schematic side view and three-dimensional view of the pressure mechanism of the high efficiency filter, respectively. The pressure mechanism of the high efficiency filter 5 includes a filter frame 51 in the form of a high efficiency filter 5 with a cavity for inserting the filter 5 . At least two presser tabs 511 can additionally be attached to the filter frame 51 . They 511 can be located on two opposite sides of the filter frame 51 . The clamp tabs 511 can be of various shapes, however, it is important that they are firmly attached to the filter frame 51' , for example by means of two rivets 512' , and at the same time press the high efficiency filter 5 to securely fix it in the frame 51' . For example, the clamp tab 511 can be made in the form of a flat figure such as a rectangle, one half of which will be superimposed on the side wall of the filter frame 51 , and the second folded in such a way that the angle of this bend provides pressure on the high-efficiency filter 5 . The end of the clamp tab 511 folded towards the high efficiency filter 5 can also be folded away from the high efficiency filter while maintaining the pressure of the filter 5 against the frame 51' . This avoids damage to the nonwoven structure of the high efficiency filter 5 from the sharp corners of the fold tab 511 . The fold tab 511 can also be shaped as a flat rectangle, circle, oval, and other known flat geometric shapes. Also, to fasten the clamp tongues 511 to the filter frame 51, holes must be made in the clamp tongues 511 corresponding to the number and parameters of the selected fasteners (in case the fastening is not carried out with glue). However, it is important to observe the bends described above in order to achieve the tightness of the device and the reliability of fixing the high-performance filter 5 in the filter frame 51 . Moreover, more than two presser tabs 511 can be attached to the filter frame 5 .

[46] In addition to pop rivets 512, other fastening methods, such as screws, glue, adhesive sealant, nails, and other known fasteners, can be used to fasten the clamp tabs 511 to the filter frame 51 . At the same time, it is also important that the sharp end of the fastening element (when using screws and nails) does not damage the non-woven structure of the high-efficiency filter 5 . This can be avoided by choosing screws and other fasteners shorter than the wall thickness of the filter frame 51 or by bending/grinding/blunting the sharp end of the fastener used. It is preferable to use at least two fasteners, such as blind rivets 512 , because when using one fastener, the clamp tabs 511 can rotate around it, gradually damaging the threads and their own fastening holes, which reduces the reliability of fixation and service life. However, more fasteners can also be used.

[47] In FIG. 7 and in FIG. 8 shows a schematic view of the pressure mechanism ( 41 , 42 , 43 ) of the primary filter 4 in closed and open form, respectively. The clamping mechanism ( 41 , 42 , 43 ) of the primary filter 4 includes a filter frame 41 made in the form of a primary filter 4 with a cavity for filter insertion, and a clamping frame 42 . The filter frame 41 and the pressure frame 42 can be attached to each other along one of the edges of the frames 41' , 42' by means of a fastener 43' . The fastening element 43 must be chosen so that it allows the clamping frame 42 to be opened and closed in such a way that the clamping mechanism opens and closes "like a book". For example, hinges similar to door hinges can be used as fastener 43 . In the cavities of the frames 41' , 42, lattice-like structures can be made, for example, from the same material as the frames 41' , 42' . Lattice structures also make it possible to increase the reliability of fastening of the primary filter 4 within 41 , 42 . On at least one of the edges of the frame 41' , other than the face with the fastener 43' , at least one clamp tab as described above, or at least one rivet in another form, can also be placed. This can make the filter frame 41 pressed against the pressure frame 42 more tightly and securely.

[48] The clamping mechanisms ( 41 , 42 , 51 ) shown in FIG. 5-8, in contrast to conventional filter frames, provide greater tightness of filters 4 , 5 and the device as a whole. This, in turn, increases the efficiency of air purification. In the case of conventional filter frames, there may be gaps (leaks) between the filter and the body of the device, which will lead to an increase in the passage of uncleaned air to the outlet of the device and a decrease in the overall filtration efficiency. Also, by pressing down on the filter material, the likelihood that the filter material will come off the frame during operation (for example, when large debris enters at high speed) is reduced. Thus, thanks to the clamping mechanisms ( 41 , 42 , 51 ), the strength of the filter itself ( 4 , 5 ), including the filter material, also increases.

[49] The clamping mechanisms ( 41 , 42 , 51 ) also described are simple in design compared to the frames commonly used to fix filters. Such frames are usually made of a complex shape, in particular, their cross section has a large number of bends, which are often deformed during operation under air pressure. Frames with simple cross-sectional shapes, such as U-shaped ones, in turn, do not provide airtight and are even more deformed during operation, forming large gaps. Thus, the clamping mechanisms ( 41 , 42 , 51 ) are simpler in design, and at the same time retain the tightness and reliability of the device, including its filters 4 , 5 .

[50] FIG. 9 shows a schematic view of an air purification and disinfection device with additional elements. The device includes a housing 1 , which has at least one air intake hole 2 and at least one air outlet hole 3 . At the same time, a primary filter 4 , a high-efficiency filter 5 and a fan 6 are located inside the housing 1 . As a fan 6, a radial fan is used, and it 6 is located in such a way that its axis 7 is parallel to the planes of the filters 4 , 5 . The high efficiency filter 5 is also designed to be disinfected. The primary filter 4 is located in the housing 1 in the clamping mechanism, including the filter frame 41 and the clamping frame 42 . The high-performance filter 5 is fixed in the housing 1 by means of a clamping mechanism including the filter frame 51 . Seals 81 are made on the side walls of the housing 1 , and a seal 82 is made on the upper wall of the housing.

[51] The side wall seals 81 may be provided on each of the side walls of the housing 1 or on a portion thereof. Seals 81 and 82 endow the air purification and disinfection device both with a higher degree of tightness and contribute to noise reduction. The seals 81' , 82 can be made in the form of layers of a material that provides tightness and noise reduction. For example, rubber, foam, resin, and other materials can be used as such a material. In this case, the layers must match the geometry of the walls and cover (top wall) of the device. Also, they 81 , 82 can be made in the form of tapes, which are fixed in the corner parts of the inner surface of the housing 1 . Additionally, other sealing elements, made in the form of tapes and not shown in the Figures, can be placed between the inner surface of the walls of the housing 1 and the clamping mechanisms ( 41 , 42 , 51 ) of the filters ( 4 , 5 ) at the joints. This also makes it possible to further increase the degree of sealing of the device and, as a result, the efficiency of air purification.

[52] In FIG. 10 shows a schematic view of an air purification and disinfection device with additional elements in the form of a three-dimensional image. The device includes a body 1 , which has two holes for air intake 2 and two holes for air outlet 3 . At the same time, a primary filter 4 , a high-efficiency filter 5 and two fans 6 are located inside the case 1 . As a fan 6, a radial fan is used, and each of them 6 is located in such a way that its axis 7 is parallel to the planes of the filters 4 , 5 . The high efficiency filter 5 is also designed to be disinfected. The primary filter 4 is located in the housing 1 in the clamping mechanism, including the filter frame 41 and the clamping frame 42 . The high-performance filter 5 is fixed in the housing 1 by means of a clamping mechanism including the filter frame 51 . Seals 81 are made on the side walls of the housing 1 , and a seal 82 is made on the upper wall of the housing. Distribution grids 10 are made on the air intake openings 2 and on the air outlet openings 3 . And the body 1 of the device is made with a removable service panel 9 .

[53] Removable service panel 9 is designed to facilitate the process of replacing filters 4 , 5 in case of clogging, as well as for repair work. It can consist not only of one side wall of the body 1 , but also, for example, of two or three adjacent side walls.

[54] The air distribution grilles 10 on the air inlets 2 and outlet 3 protect the device from getting into the housing 1 of large debris that can damage the internal components of the device. They also protect against moisture ingress.

[55] The air purification and disinfection device can include both all additional elements at the same time, and in any combination thereof, depending on the specific task or user needs.

[56] The present application materials provide a preferred disclosure of the implementation of the claimed technical solution, which should not be used as limiting other, private embodiments of its implementation, which do not go beyond the requested scope of legal protection and are obvious to specialists in the relevant field of technology.

Claims (15)

1. An air purification and disinfection device, including a housing in which at least one air intake and at least one air outlet are made, and inside the housing there are a primary filter, a high-efficiency filter and at least one fan, and the fan is a radial type fan and is located in such a way that its axis is parallel to the planes of the filters, and the high-efficiency filter is made with the possibility of disinfection. 2. Air purification and disinfection device according to claim 1, characterized in that the high-performance filter is made with antibacterial impregnation. 3. An air purification and disinfection device according to claim 2, characterized in that zinc pyrithione is used as an antibacterial impregnation. 4. The air purification and disinfection device according to claim 1, characterized in that the primary filter and the high-performance filter are fixed in the device body by means of clamping mechanisms. 5. The air purification and disinfection device according to claim 4, characterized in that the high-efficiency filter pressing mechanism includes a filter frame made in the form of a high-efficiency filter with a cavity for filter insertion. 6. An air purification and disinfection device according to claim 5, characterized in that at least two clamping tabs are attached to the filter frame. 7. An air purification and disinfection device according to claim 6, characterized in that each clamping tab is attached to the filter frame by means of at least two rivets. 8. The air purification and disinfection device according to claim 4, characterized in that the pressure mechanism of the primary filter includes a filter frame made in the form of a primary filter with a cavity for filter insertion, and a pressure frame. 9. An air purification and disinfection device according to claim 1, characterized in that such a combination of a radial fan and filters is used that when cleaning 100 m ³ / h of air, the noise level does not exceed 40 dB. 10. An air purification and disinfection device according to claim 1, characterized in that distribution grilles are made in each of the air intake and outlet openings. 11. An air purification and disinfection device according to claim 1, characterized in that a high-efficiency filter of at least E11 (H11) class is used. 12. Device for cleaning and disinfecting air according to claim 1, characterized in that the body of the device is made with a removable service panel. 13. The device for cleaning and disinfecting air according to claim 1, characterized in that most of the area of the inner surface of the housing is made with a seal. 14. An air purification and disinfection device according to claim 1, characterized in that the air intake holes and the air outlet holes are made on opposite sides of the housing. 15. An air purification and disinfection device according to claim 14, characterized in that the planes of the air intake and air outlet holes are parallel to the planes of the filters and the fan axis.

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