RU234254U1 - AIR INFILTRATION VALVE - Google Patents

Abstract

The utility model relates to the field of ventilation, primarily ventilation of residential premises, and is intended to regulate the air flow coming from the street into the room. The air infiltration valve includes a wall part of the housing located on the base in the form of a ring, and a rotary cover with a first fastening element with a thread. In this case, in the center of the base, a second fastening element with a thread is made for connection with the first fastening element so that the adjustment of the passing air flow is carried out by turning the said cover. Also, in this case, the wall part of the housing and the cover are made of a closed-cell material. The described utility model ensures an increase in the tightness of the device when the valve is closed.

Description

Field of technology

[0001] The utility model relates to the field of ventilation, primarily ventilation of residential premises, and is intended to regulate the flow of air coming from the street into the premises.

State of the art

[0002] Valves installed on air ducts to regulate the flow of air from the street into the premises are called supply ventilation valves, air intake valves or air infiltration valves. They play an important role in ventilation and air conditioning systems, providing the flow of fresh air into the premises.

[0003] The primary function of air infiltration valves is to regulate the amount of air entering the room from outside. The valves are typically installed on air intake openings or on air ducts through which air enters the system. Their design allows for the possibility of adjusting the opening and closing to achieve the desired air flow. Such valves are also often installed on isolated air ducts intended to provide air flow to individual rooms, i.e., not for general ventilation systems.

[0004] A significant problem with such valves is their low degree of tightness. Because of this, air from the street gets into the room through air gaps even when the valve is completely closed, which is especially problematic during cold weather, since it leads not only to a decrease in the air temperature in the room, but also to freezing of the valve body.

[0005] A supply valve head is known, protected by utility model patent No. RU 112358 U1 (published on 10.01.2012; IPC: F24F 7/10). The proposed device relates to the field of ventilation of residential and civil buildings. The technical task of the utility model is to simplify the design by eliminating the adjustment mechanism in the form of a gear drive with an adjustment handle and a 2-petal damper. The task is solved in that in the proposed model, the supply valve head includes a head housing made of a wall part and a rotary housing cover. The adjustment mechanism is made in the form of mating projections on both parts of the housing, wherein the projections alternate with sectors free of projections. Even with a partial overlap of sectors free of projections, channels for the passage of air are formed. When the sectors of both parts of the proposed device are completely overlapped, free of projections, the air passage channels have a maximum area, i.e. the device is considered completely open. The device is considered completely closed when the projections of the rotating cover completely overlap the sectors free of projections on the wall part of the device. By rotating the cover, a linear decrease or increase in the cross-sections of the air passage channels is achieved, i.e. regulation is performed.

[0006] A device according to patent No. CN 212480188 U (published on 05.02.2021; IPC: B01D 46/10; F16K 25/04; F16K 27/04; F16K 3/08; F16K 3/314; F16K 37/00; F16L 23/02; F16L 23/18; F24F 11/74; F24F 13/28; F24F 7/003) is also known. The new air volume adjustment valve for a fresh air supply system comprises a valve body and a flow rate adjustment structure, the filter structure is located on one side of the valve body, and the flow rate adjustment structure is located in the middle of the inner part of the valve. The first disk, the second disk, the rotating disk, the air supply cylinder, the through hole, the fixing groove, the rotating shaft and the indicating unit are arranged in series in a flow adjustment structure. When the disk rotates, the rotating disk drives the air supply cylinder to rotate, the air supply cylinder drives the second disk to rotate, and therefore the overlapping area of the through holes in the first disk and the second disk can be changed; the air volume adjustment device is simple in structure and convenient in operation, the indicating unit is arranged so that when the indicating unit is rotated to the lower part, the valve is closed, when the indicating unit is rotated to the horizontal position, the valve is open, the valve opening size gradually decreases along with the downward rotation of the indicating unit, so that the air volume and the opening and closing of the valve can be conveniently controlled.

[0007] Another known valve is the technical solution according to patent No. 218296117 U (published on 13.01.2023; IPC: F24F 11/74; F24F 7/04). The utility model discloses an electric aperture-type air flow control valve, which comprises a main body, a blade located on the lower part of the main body, and the lower part of the blade is provided with a row of circular bulges coinciding with and contacting an arcuate groove of a rotating disk. A dial is located at the lower part of the rotating disk through a shell with an arcuate gap, a stepper motor is installed in the shell, and the output shaft of the stepper motor is provided with a first gear. The first gear is in contact with the second gear on the inner circumference of the rotating disk, the first gear drives the rotation of the second gear to adjust the aperture of the electric aperture-type air volume control valve. The diameter of the regulating valve can be judged by the scale mark on the dial, which is indicated by the indicator protrusion on the side of the rotating disk, so as to judge the opening and closing size of the valve. The rosette and the hoop are located under the dial. The aperture type electric air volume regulating valve of the utility model has the advantages of simple structure, light weight, easy installation, high adjustment accuracy, and can perform the air volume adjustment task well.

[0008] In addition, a valve protected by patent No. US 6,991,534 B2 (published on 31.01.2006; IPC: F24F 13/06; F24F 13/062; F24F 13/08) is known. In one aspect of the invention, a ventilation opening is proposed that comprises a housing element and an adjustment element. The housing element comprises a ventilation channel that extends from the inner side to the outer side of the housing element. The housing element also comprises a collar that has a collar passage that extends from the inner side to the outer side of the collar. The collar channel is in fluid communication with the ventilation channel. The adjustment element comprises a head intended for adjustable restriction of air flow through the ventilation channel, and an inwardly protruding stem that has one or more stem parts. The one or more stem parts comprise one or more contact parts that interact with the inner surface of the cuff and that adjustably connect the adjustment element to the housing element. One or more portions of the stem, alone or in combination with the inner surface of the cuff, define one or more cuff openings that pass through the cuff channel. Air passing through the ventilation opening may pass through the collar openings.

[0009] Also known is a technical solution disclosed in application No. US 3,680,471 A (published 01.08.1972; IPC: E06B 7/00; E06B 7/02; F24F 11/04; F24F 13/10; F24F 13/18; F23L 13/00). A regulator for optimal ventilation of any closed space, comprising an air duct formed in an annular housing, part of which at one end of the annular space is closed by a partition, the other part of which is sealed by means of a control valve in the form of a disk having through channels, the disk is located coaxially with the housing and is installed in it with the possibility of rotation, ventilation is carried out due to the use of the difference in air pressure on both sides of the channel.

[0010] In addition, a valve is known according to patent No. RU 66488 U1 (published on 10.09.2007; IPC: F24F 13/08). The supply ventilation valve pertains to ventilation devices and is intended for ventilation of domestic and auxiliary premises, containing an air duct in a pipe, heat and noise insulation, characterized in that two air chambers of different lengths and different diameters are located in the air duct, where one of the chambers has a partition, and the other has a sound-absorbing insert as heat and noise insulation. The technical solution is aimed at improving heat and noise insulation, increasing the operational reliability of the valve. An additional technical effect was manifested due to the design of the air duct of the pipe as a cylindrical one and the placement of a noise damper in one of the air chambers, containing one or more perforated tubes with holes of different diameters.

[0011] The disadvantages of all the above devices are the complexity of the valve design, as well as the lack of sealing sufficient to avoid the formation of air gaps. Thus, they all close when the lid completely covers the openings through which air passes. However, due to the fact that these elements are not made of a sealing heat-insulating material, closing the valve in this way with a disk made of a hard material will inevitably lead to the formation of air gaps. In this regard, even with a completely closed valve, cold air from the street can leak through the resulting gaps. At air temperatures below 0 ° C, this can also lead to the formation of ice inside and on the body of the device (freezing of the entire body). The formation of ice will subsequently lead to an even less tight closing of the valve.

The essence of the utility model

[0012] The objective of this utility model is to create and develop an air infiltration valve that provides increased tightness when the valve is closed.

[0013] This problem is solved by the claimed utility model by achieving such a technical result as increasing the tightness of the device when the valve is closed. The claimed technical result is achieved, including, but not limited to, due to:

making the wall part of the valve body and its cover from closed-cell material;

implementing regulation of the volume of incoming air and closing of the valve by turning the cover.

[0014] More fully, the technical result is achieved by an air infiltration valve, including a wall part of the housing, located on the base in the form of a ring, and a rotary cover with a first fastening element with a thread. In this case, in the center of the base, a second fastening element with a thread is made for connection with the first fastening element so that the regulation of the passing air flow is carried out by turning the said cover. Also, in this case, the wall part of the housing and the cover are made of a closed-cell material.

[0015] Threaded fasteners are required to enable the valve to be opened and closed, and to regulate the air flow passing through it by turning the said cover. The thread allows the cover to be fixed in the required position. It is also important to note that the cover and the wall part of the housing are made of a closed-cell material to achieve the most hermetic closure of the valve. Thus, due to the fact that closed-cell materials have a high degree of hermeticity, as well as high thermal insulation characteristics. This allows, firstly, to prevent the formation of air gaps. In this regard, when the valve is completely closed, cold air from the street will not be able to leak through the gaps. At an air temperature below 0°C, this also helps to avoid the formation of ice inside and on the housing of the device (freezing of the entire housing). Thus, it is the combination of fasteners and the manufacture of the cover and the wall part of the housing from a closed-cell material that allows the technical result declared by this utility model to be achieved. The base is necessary to be able to secure the wall part of the housing to the wall, and its design in the form of a ring is necessary to ensure that air can pass through the hole in the center.

[0016] Foamed polypropylene can be used as a closed-cell material. This will further increase the strength of the structure along with the tightness of the closure.

[0017] An additional sealing ring may be inserted between the cover and the wall part of the housing. An additional sealing ring may also be inserted between the base and the wall. This will further enhance the degree of sealing of the device.

[0018] The wall part of the housing can be made in the form of a ring and include a cavity. A filter material can be inserted into the hole in the center. This will allow additional cleaning of the air before it enters the room. A sponge of the G4 cleaning class can be used as a filter material. This will allow cleaning the air from large dust and small debris. In this case, the sponge can be made of polyurethane foam.

[0019] The first threaded fastener may be a bolt, and the second threaded fastener may be a cylinder with a bolt hole formed therein.

[0020] The cross-section of the cover may be circular, and the diameter of the cover may be larger than the diameter of the opening of the wall part of the housing. This will avoid the formation of air gaps.

[0021] The first threaded fastener may be secured to the cover by means of a locking disk by inserting it into a hole in the locking disk. This will allow the first fastener to be more securely secured to the valve cover.

Description of drawings

[0022] The subject matter of the present application is described point by point and clearly stated in the claims of the utility model. The above-mentioned tasks, features and advantages of the utility model are apparent from the following detailed description, in combination with the attached drawings, which show:

[0023] Fig. 1 shows an isometric view of the air infiltration valve from the cover side with the elements exploded, according to the present utility model.

[0024] Fig. 2 shows an isometric view of the air infiltration valve from the cover side, according to the present utility model.

[0025] Fig. 3 shows an isometric view of the air infiltration valve from the base side, according to the present utility model.

[0026] Fig. 4 shows a longitudinal section of the air infiltration valve in a closed state, according to the present utility model.

[0027] Fig. 5 shows a longitudinal section of the air infiltration valve in a partially open form, according to the present utility model.

[0028] Fig. 6 shows a longitudinal section of the air infiltration valve in a fully open state, according to the present utility model.

[0029] Fig. 7 shows a longitudinal section of an air infiltration valve in a closed state, placed on a wall, with an air duct, according to the present utility model.

[0030] Fig. 8 shows an isometric view of the air infiltration valve with additional elements from the cover side with the elements separated, according to the present utility model.

[0031] Fig. 9 shows a longitudinal section of an air infiltration valve with additional elements in a closed form, according to the present utility model.

[0032] Fig. 10 shows an isometric view of one of the embodiments of the base, according to the present utility model.

[0033] Fig. 11 shows an isometric view of an air infiltration valve with additional elements from the cover side with the elements separated, according to the present utility model.

[0034] These figures are explained by the following positions:

Position 1 - air infiltration valve;

Position 11 - wall part of the body;

Position 12 - base;

Position 13 - rotary cover;

Position 14 - cover fastening element with thread;

Position 15 - threaded base fastening element;

Position 16 - sealing ring;

Position 17 - filter material;

Position 18 - locking disc;

Position 19 - additional fasteners;

Position 2 - air duct;

Position 3 - ventilation grille;

Position 4 - wall.

Detailed description of the utility model

[0035] In the following detailed description of the implementation of the utility model, numerous implementation details are provided to ensure a clear understanding of the present utility model. However, it is obvious to a person skilled in the art how the present utility model 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 unnecessarily complicate the understanding of the features of the present utility model.

[0036] Moreover, it is clear from the above presentation that the utility model is not limited to the given implementation. Numerous possible modifications, changes, variations and replacements of non-essential features of the utility model, preserving the essence and form of the present utility model, are obvious to specialists qualified in the subject area.

[0037] The term "longitudinal section" used in the description of the technical solution means a section along the air flow. The term "cross-section" means a section perpendicular to the air flow. Also used in the description of the technical solution, the term "first fastening element" means a fastening element on the valve cover, and the "second fastening element" means a fastening element on the base.

[0038] Fig. 1 shows an isometric view of the air infiltration valve 1 (hereinafter referred to as the valve) from the side of the cover 13 with the elements exploded, according to the present utility model. The air infiltration valve 1 includes a wall portion of the housing 11, located on the base in the form of a ring 12, and a rotary cover 13, mounted on a fastening element with a thread 14. In this case, a fastening element with a thread 15 is made in the center of the base for connection with the cover 13 so that the regulation of the passing air flow is carried out by turning the said cover 13. Also, in this case, the wall portion of the housing 11 and the cover 13 are made of a closed-cell material. Fig. 2 and Fig. 3 also show an isometric view of the valve 1, but in an assembled state from the side of the cover 13 and from the side of the base 12, respectively.

[0039] In this case, the fastening elements with threads 14, 15 allow for the possibility of opening and closing the valve 1, as well as adjusting the air flow passing through it by turning the said cover 13. The thread allows for the cover 13 to be fixed in the required position. It is also important to note that the manufacture of the cover 13 and the wall part of the housing 11 from a closed-cell material allows for the most hermetic closure of the valve 1 to be achieved. Thus, due to the fact that closed-cell materials have a high degree of hermeticity, as well as high thermal insulation characteristics. This allows, firstly, to prevent the formation of air gaps. In this regard, when the valve is completely closed, cold air from the street will not be able to leak through the gaps. At an air temperature below 0°C, this also allows for the prevention of ice formation inside and on the housing of the device (freezing of the entire housing). Thus, it is the combination of fastening elements 14, 15 and the execution of the cover 13 and the wall part of the housing 12 from a closed-cell material that makes it possible to achieve the technical result declared by this utility model.

[0040] Fig. 4 shows a longitudinal section of the valve 1 in a closed form, according to the present utility model. As can be seen in the Figure, there is no air gap between the cover 13 and the wall portion of the housing 11. In this case, the fastening element 14 of the cover 13 is screwed into the fastening element 15 of the base 12. In this position, due to the absence of air gaps, air does not enter the room. Also, due to the execution of the wall portion of the housing 11 and the cover 13 from a closed-cell material, the connection in the closed position is maximally hermetic, i.e. air leaks from the street into the room are prevented, as well as heat from the room, which is especially important in conditions of low outside air temperatures.

[0041] A closed-cell material is a material that has a structure consisting of many small closed pores that are not interconnected and do not have open channels. The pores in a closed-cell material are separate and isolated, making it impermeable to gases and liquids. This structure gives the material a low density and high thermal insulation capacity.

[0042] In this case, foamed polypropylene (EPP) can be used as a closed-cell material. This will further increase the strength of the structure along with the tightness of the closure. Other closed-cell materials can also be used, for example, foamed polyethylene. Foamed polyethylene has better thermal insulation properties compared to foamed polypropylene, but is less durable. Foamed polypropylene, in turn, has sufficient strength characteristics for the manufacture of valve 1, which is why its use is preferable.

[0043] By turning the cover clockwise (or vice versa), the valve 1 is opened, i.e. the fastening element 14 is extended from the fastening element 15, due to which the cover 13 is moved away from the wall part of the housing 11, forming a gap for the air supply. The size of this air gap determines the volume of air supplied to the room (air flow rate, ^m3 /h). Thus, by turning the cover, the air flow is adjusted. Fig. 5 shows a longitudinal section of the valve 1 in a partially open form, according to the present utility model. As can be seen, in this case the fastening element 14 is not completely screwed into the fastening element 15, and between the cover 13 and the wall part of the housing 11 there is a small air gap.

[0044] Fig. 6 shows a longitudinal section of the valve 1 in a fully open form, according to the present utility model. In this position, a smaller part of the fastening element 14 remains in the fastening element 15, but it is also possible to unscrew it completely, thereby removing the cover 13. In this case, if it is undesirable to completely pull out the cover 13, then it is preferable to install a retainer in the fastening element 14 or the fastening element 15. Despite the fact that the closed-cell material is much lighter than plastic and other materials from which valves are usually made, it is still preferable not to leave the fastening element 14 screwed into the fastening element 15 less than ¹ / ₄ of its length (fastening element 14). Otherwise, under the weight of the cover 13, the fastening element 14 can gradually deform or deform the fastening element 15, including stripping the thread. The specific length to which the retainer must be installed depends on both the weight of the cover 13 and the thickness and material of the fastening element 14.

[0045] Fig. 7 shows a longitudinal section of the valve 1 in a closed form, placed on the wall 4, with the air duct 2, according to the present utility model. This Figure illustrates the use of the valve 1. Thus, when operating the present utility model, it is necessary to secure it to the wall 4, in which the air duct 2 is placed. In this case, the air duct 2 and the valve 1 are placed coaxially. An air intake grille 3 can be placed on the wall 4 on the street side, from where air is taken. This will prevent precipitation, large debris, feathers of birds, animals, etc. from getting into the air duct 2. Thus, this can ensure safer operation of the valve 1. A fan, a filter element, for example, a duct filter, and other elements not shown in Fig. 7 can be additionally placed in the air duct 2.

[0046] Fig. 8 shows an isometric view of the valve 1 with additional elements from the side of the cover 13 with the elements exploded, according to the present utility model. Fig. 9 shows a longitudinal section of the valve 1 with additional elements in a closed form, according to the present utility model. The additional elements shown in Fig. 8 and Fig. 9 can be included in the design all at the same time, separately and in any combination.

[0047] As can be seen in Fig. 8 and Fig. 9, a sealing ring 16 can be additionally inserted between the cover 13 and the wall portion of the housing 11. A sealing ring 16 can also be inserted between the base 12 and the wall 4 on which the valve 1 is installed. This will further enhance the degree of sealing of the valve 1, since it will lead to sealing of areas in which air gaps may form due to uneven surfaces.

[0048] Also, the wall part of the housing 11 can be made in the form of a ring and include a cavity. A filter material 17 can be inserted into the hole in the center. This will allow additional purification of the air before it enters the room. A sponge (sponge filter material) of purification class G4 can be used as the filter material 17. In this case, the sponge can be made of polyurethane foam. In general, a coarse filter (filtration classes G1-G4 (EU1-EU4)) can be used as the filter material 17. Then it will clean the air from fluff, soot, large dust particles, insects, feathers, large plant seeds. As an alternative to the sponge, a filter mesh can also be used, for example, made of nylon, as well as other known filter materials for coarse air purification.

[0049] A bolt may be used as a fastening element with a thread 14 on the cover 13, and a cylinder with a bolt hole made in it may be used as a fastening element with a thread 15 on the base 12. However, other types of fastening elements that have a thread may also be used.

[0050] The cover 13 may have a round shape in cross-section, and the diameter of the cover 13 may be larger than the diameter of the opening of the wall portion of the housing 11. This will avoid the formation of air gaps. A round shape is preferable for both the opening and the cover 13 due to the fact that in this case the probability of the formation of air gaps is reduced (since the edges of the cover 13 and the opening are equidistant from the center), and there is no interception of the corners during the rotation of the cover 13. In this case, the shape of the outer edge of the wall portion of the housing 11 can be made in any form (including polygonal), and not just round.

[0051] The fastening element with thread 14 can be fastened to the cover 13 by means of the fixing disk 18 by inserting it into the opening in the fixing disk 18. This will allow the fastening element 14 to be more securely fastened to the cover 13 of the valve 1. In this case, in order not to violate the tightness of the closure, i.e. so that the edge of the cover 13 overlaps the edge of the opening of the wall part of the housing 11, and so that they touch each other in the closed position, in the case of fastening the fastening element 14 to the cover 13 by means of the fixing disk 18, the diameter of the fixing disk 18 must be smaller than the diameter of the cover 13.

[0052] Fig. 10 shows an isometric view of one of the embodiments of the base 12, according to the present utility model. As can be seen in Fig. 10, the base 12 may additionally include an internal flange onto which the wall portion of the housing 11 is mounted. The geometry of the base 12 itself may include openings to reduce material consumption and lighten the structure. It is also preferable that the design of the base 12 also provides for mounting openings for securing the base 12 to the wall 4. As an alternative to mounting openings, the base may include a thread. In this case, the air duct 2 should also include a thread to secure the base 12 to the edge of the air duct 2.

[0053] Fig. 11 shows an isometric view of the valve 1 with additional elements from the side of the cover 13 with the elements exploded, according to the present utility model. In this Figure, in addition to the previously listed additional elements, one can also see possible elements for mounting and fastening 19 parts of the valve 1 to each other and fastening the base 12 to the wall 4. Thus, the cover 13 can be connected to the fixing disk 18 using screws (or bolts) and plastic clamps. Using the same means, the base 12 can be fixed to the wall part of the housing 11.

[0054] Also, a high degree of tightness and thermal insulation can be achieved by a valve 1 manufactured in the following manner. According to the method, first, a base 12 of the valve 1 is manufactured in the form of a ring with a fastening element with a thread 15 in the center. Then, a wall part of the housing 11 of the valve 1 is manufactured from a closed-cell material. After this, the wall part of the housing 11 is secured to the base 12. Next, a cover 13 of the housing is manufactured from a closed-cell material. A fastening element with a thread 14 is secured to the cover 13 of the housing. Then, the cover 13 is connected to the base 12 by connecting their fastening elements 14, 15 so that the regulation of the passing air flow is carried out by turning the said cover 13, including opening and closing the valve 1.

[0055] The base 12 is necessary for the possibility of fixing the wall part of the housing 11 to the wall 4, and its design in the form of a ring is necessary to ensure the possibility of air passing through the opening in the center. The two contacting parts must be made of a closed-cell material to ensure the hermetic closure of the valve 1. In this regard, the wall part of the housing 11 and the cover 13 are made of it. The fastening element with thread 15 on the base 12 and the fastening element 14 on the cover 13 of the housing are necessary to ensure the possibility of adjusting the air flow passing through the valve 1 by turning the cover 13.

[0056] The elements of the valve 1 made of closed-cell material (cover 13 and wall part of the housing 11) can be manufactured by baking the said material in a press mold. This will further simplify the process of manufacturing the valve 1, including by increasing the production speed of these elements, as well as by reducing the cost of their manufacture. As an alternative option for manufacturing these parts, it is possible to cut these elements from a solid block of closed-cell material or from sheets with subsequent gluing of the layers. However, this option is more labor-intensive and time-consuming, which is why baking in a press mold is the preferred manufacturing option. Also, when gluing such layers, the thermal insulation properties of these elements will deteriorate significantly, which can lead to freezing of the housing of the valve 1.

[0057] It is important to note that each of the previously listed elements of valve 1 can be included in the process of manufacturing valve 1 according to the above-described method.

[0058] Thus, the mold for producing the wall part of the housing 11 may have the shape of a ring with a cavity in the center. In this case, the opening in the center may allow not only for air to pass through, but also for the filter element 17 to be inserted into it. In this case, the filter element 17 may be inserted in the following manner. Before connecting the cover 13 to the base 12, the filter element 17 may be placed on the fastening element 15 of the base 12. For this, the filter element 17 must also include an opening in the center.

[0059] The insertion of the sealing ring 16 between the cover 13 and the wall part of the housing 11 must also be carried out before connecting the cover 13 to the base 12, and the insertion of the second sealing ring 16 can be carried out at any time after the manufacture of the base 12.

[0060] At the stage of fastening the fastening element 14 on the cover 13, a fixing disk 18 can be used. In the center of the disk 18, a hole can be provided for this. Then the fastening element 14 is first inserted into the hole in the disk 18, and then the disk 18 and the cover 13 are connected. They can be connected by means of screws, bolts or bolts with additional plastic clamps, as shown in Fig. 11. The hole in the disk 18 can have a hexagonal molding in order to avoid turning the bolt when tightening the disk 18. The fastening element 14 is pressed by pressing the cover 13 to the disk 18.

[0061] The present application materials present a preferred disclosure of the implementation of the claimed technical solution, which should not be used as limiting other, particular embodiments of its implementation that do not go beyond the scope of the requested scope of legal protection and are obvious to specialists in the relevant field of technology.

Claims (10)

1. An air infiltration valve comprising a wall portion of the housing located on a base in the form of a ring, and a rotary cover with a first fastening element with a thread, wherein a second fastening element with a thread is made in the center of the base for connection with the first fastening element so that the regulation of the passing air flow is carried out by turning the said cover, wherein the wall portion of the housing and the cover are made of a closed-cell material. 2. The valve according to item 1, characterized in that foamed polypropylene is used as the closed-cell material. 3. The valve according to item 1, characterized in that a sealing ring is inserted between the cover and the wall part of the housing. 4. The valve according to item 1, characterized in that a sealing ring is inserted between the base and the wall. 5. The valve according to item 1, characterized in that the wall portion of the housing is made in the form of a ring and includes a cavity, and a filter material is inserted into the opening in the wall portion of the housing. 6. The valve according to item 5, characterized in that a class G4 sponge is used as the filter element. 7. The valve according to item 6, characterized in that the sponge is made of polyurethane foam. 8. The valve according to item 1, characterized in that a bolt is used as the first threaded fastening element, and a cylinder with a bolt hole made in it is used as the second threaded fastening element. 9. The valve according to item 5, characterized in that the cover has a round shape in cross-section, and the diameter of the cover is larger than the diameter of the cavity of the wall part of the body. 10. A valve according to item 1 or 8, characterized in that the first threaded fastening element is secured to the cover using a locking disk by inserting it into an opening in the locking disk.

Images