RU181244U1 - VENTILATION VENTILATION VALVE VALVE - Google Patents

Abstract

This utility model relates to forced ventilation devices used for air exchange between the environment and residential or industrial premises, or structures. The claimed valve can be used to provide natural ventilation of residential premises or the internal space of industrial buildings and structures for various purposes when it is installed on the outlet of a slotted ventilation channel made in the design of a window unit, door unit or made in the wall of a building to ensure regulation of air flow from the external media through said through ventilation duct. The ventilation valve of the fresh air ventilation system includes a hollow body and a movable air flow control unit located therein. The hollow valve body contains upper and lower flat bases, interconnected by end walls and the rear side wall, and on the front side the body is made open, and a longitudinal slot is made on the rear side wall of the body. The air flow control unit includes a movable bar and a driven flap adjacent to each other with flat surfaces. The flap on the adjacent flat surface is provided with protrusions, and the bar on the reciprocal flat surface is made with inclined guide grooves, while the transverse size and height of the flap protrusions correspond to the width and depth of the grooves of the bar. The upper and lower flat bases of the housing are made with longitudinal samples in the entire length of the bases from the front of the housing. The strap on the side is provided with a latch handle, which is configured to be inserted into a longitudinal slot on the rear side wall of the housing. The bar and the flap on adjacent flat surfaces and on opposing surfaces of their contact with the housing are equipped with anti-friction protrusions. The technical result is a simplification of the design while improving the usability of the ventilation valve of the supply ventilation by reducing friction between the moving parts of the device, as well as expanding the range of ventilation valves.

Description

This utility model relates to forced ventilation devices used for air exchange between the environment and residential or industrial premises, or structures. The claimed valve can be used to provide natural ventilation of residential premises or the internal space of industrial buildings and structures for various purposes when it is installed on the outlet of a slotted ventilation channel made in the design of a window unit, door unit or made in the wall of a building to ensure regulation of air flow from the external media through said through ventilation duct.

During the operation of industrial or residential premises, the content of carbon dioxide in the air inside a closed room increases over time due to, among other things, the breathing of people in the room. The increased content of carbon dioxide in the air of the room affects the well-being and productivity of people, therefore, the air in the room should be replaced with fresh air from the environment by ventilation or ventilation. When airing by opening and closing the casement windows, a problem arises in that drafts arise and noise, dust and other contaminants can enter the room with the outside air. In addition, the cost of heating or cooling the room increases, and people in the room may feel discomfort due to drafts and sudden changes in temperature and become sick.

Thus, there is a need to provide controlled air exchange with the environment without opening the shutters of the window unit while maintaining the comfort and safety of operation of the room.

The prior art ventilation valve for supply ventilation (see patent RU 2605375 C2, IPC E06B7 / 02, published December 20, 2016) contains a hollow body and a movable flow control unit located therein. A disadvantage of the known technical solution is the complexity of the installation, requiring a through hole in the window unit.

As the closest analogue (prototype) of the claimed fresh air ventilation valve, the ventilation valve of the fresh air ventilation device for window units made of polymeric materials, disclosed in the patent specification BY7522 (IPC F24F13 / 18, published on 08/30/2011) is selected. The known ventilation valve is made with the possibility of installation from the inside on the sash of the window unit and includes a hollow body containing upper and lower flat bases with longitudinal samples, as well as two end walls and a rear side wall. In the cavity of the casing there is a movable unit for regulating the air flow, which includes a movable bar and a driven flap adjacent to each other by flat surfaces. The flap on the adjacent flat surface is provided with protrusions, and the bar on the reciprocal flat surface is made with inclined guide grooves, and the transverse size and height of the flange protrusions correspond to the width and depth of the grooves of the bar. Longitudinal samples on the upper and lower flat bases of the housing are made short with jumpers between adjacent samples. These jumpers create a whistling noise when air passes through the valve.

The disadvantages of this technical solution are the insufficient level of noise isolation. In addition, when adjusting the air flow, considerable efforts have to be made to move the movable plate inside the valve body due to the high coefficient of friction due to the tight fit of the entire contact surface of the movable plate and the driven flap to each other and to the inner sides of the bases of the ventilation valve body, which is negative affects the ease of use and reliability of the ventilation valve of the supply ventilation.

The technical problem to which this true utility model is directed is to create a fresh air ventilation valve with high reliability and ease of use.

The technical result achieved by using the claimed utility model is to simplify the design while improving the usability of the ventilation valve of the supply ventilation by reducing friction between the moving parts of the device, as well as expanding the range of ventilation valves.

The technical result is achieved due to the fact that the ventilation valve of the supply ventilation system includes a hollow body and a movable air flow regulation unit located therein. The hollow valve body contains upper and lower flat bases, interconnected by end walls and the rear side wall, and on the front side the body is made open, and a longitudinal slot is made on the rear side wall of the body. The air flow control unit includes a movable bar and a driven flap adjacent to each other with flat surfaces. The flap on the adjacent flat surface is provided with protrusions, and the bar on the reciprocal flat surface is made with inclined guide grooves, while the transverse size and height of the flap protrusions corresponds to the width and depth of the grooves of the bar. The upper and lower flat bases of the housing are made with longitudinal samples in the entire length of the bases from the front of the housing. The strap on the side is provided with a latch handle, which is configured to be inserted into a longitudinal slot on the rear side wall of the housing. The bar and the flap on adjacent flat surfaces and on opposing surfaces of their contact with the housing are equipped with anti-friction protrusions.

The presence of anti-friction protrusions allows to reduce friction between the moving parts of the valve and thereby reduce the effort required to adjust the flow area of the ventilation duct, which increases ease of use. Existence of the handle latch provides simplicity and reliability of assembly, and ease of adjustment of the ventilation valve. Performing samples along the entire length of the valve body increases the area of the passage section of the ventilation channel and thereby ensures a low noise level when air passes through the valve.

When installing the valve indoors as a ventilation channel for air passage, preferably, a cavity is used between the frame and the sash of the window unit, called a false lock.

To facilitate mounting the ventilation valve on the window unit and improve its noise-proofing properties, the case of the ventilation valve can be equipped with a self-adhesive sealant adjacent to the window unit along the sample along the entire length of the case, and the case with at least two adjacent to the sash of the window unit protrusions. The projections of the housing are made at the ends with flanges, on which holes are made for attaching the ventilation valve to the sash of the window unit. To ensure exact matching of the samples of the ventilation valve with the outlet of the ventilation channel and to avoid bending of the ventilation valve body, its body on the abutment side of the window casement can be equipped with one or more additional protrusions, also made at the ends with flanges with holes for attaching the ventilation valve to the window casement block.

The protrusions of the flap interacting with the bar can be made of cylindrical shape with a diameter of at least 2 mm, which eliminates their breakdown during operation of the ventilation valve. Anti-friction protrusions can be made in the form of embossed strips with a height of 0.05 to 0.3 mm and a width of 0.1 to 0.5 mm, oriented parallel to the direction of movement of the bar relative to the valve, parallel to the direction of movement of the bar relative to the body and parallel to the direction of movement of the valve relative to the body. In other words, the anti-friction protrusions on the surface of the shutter in contact with the bar are evenly distributed and are made parallel to the guide grooves. The antifriction protrusions on the surface of the shutter in contact with the housing are evenly distributed and are made in the transverse direction. The surface of the strip in contact with the housing is provided with at least one anti-friction protrusion made in the longitudinal direction. By means of anti-friction protrusions, the friction surface area between the parts of the ventilation valve is reduced, and therefore, the friction force, which prevents the movement of the bar and the shutter, is reduced.

Further, the present utility model is illustrated by the following drawings.

In FIG. 1 shows a ventilation valve in general.

In FIG. 2 shows a top view of a vent valve body and an air flow control unit in an exploded state.

In FIG. 3 shows a bottom view of the vent valve body and the air flow control unit in disassembled condition.

In FIG. 4, as an example of installation, a cross-sectional ventilation valve mounted on a window unit is shown.

According to the present utility model, the fresh air ventilation valve 1 (see FIG. 1) is configured to install a window unit on the leaf 2, as shown by way of example in FIG. 4 indoors at the outlet of the slotted ventilation duct for air passage.

The arrow in FIG. Figure 4 shows the path that air passes through the slotted ventilation channel, coming from the external environment (street) into the room. As the ventilation channel 3 for the passage of air, a cavity is preferably used between the frame 4 and the sash 2 of the window unit, called false-backlash. It is also possible embodiment of the ventilation channel by milling, drilling or teething frame or sash window unit. However, this option is less preferable, because it violates the integrity of the window block structure. To allow air to pass through the ventilation duct in the false clearance in the areas indicated in FIG. 4 by positions 5 and 6, either a replacement of the standard sealant sections on the sash 2 and on the window unit frame 4 is required with thinner ones corresponding to the length of ventilation valve 1 in length, or complete removal of these sealant sections. It is also possible to remove portions of the seal and simultaneously mash the sash 2 and frame 4 of the window unit with the removal of their sections corresponding to the size of ventilation valve 1 in length and width, in order to increase the flow area of the ventilation duct.

In FIG. 2 and 3 show in detail the design of the ventilation valve 1 in the disassembled state. The valve comprises a hollow body 7, including upper and lower flat bases (not indicated by positions in the drawing), interconnected by end walls and the rear side wall (also not indicated by positions). On the front side adjacent to the sash 2 of the window unit, the housing 7 is made open, while the upper and lower flat bases of the housing 7 are made with longitudinal samples 8 in the entire length of the bases on the side of contact with the sash 2 of the window unit. The lower base of the housing 7 at the edges is made with two main mounting tabs 9 and one or more additional mounting tabs 10 for mounting (depending on the length of the valve body). The mounting tabs 9 and 10 are provided at the ends with flanges. Flanges are made with holes (for example, for self-tapping screws) for fastening the ventilation valve 1 to the sash 2 of the window block. It is desirable that the mounting tabs 9 and 10 have a thickness of 2 mm or more, which eliminates their breakdown during installation and operation.

Inside the housing 7 is placed a movable unit for controlling the air flow, which includes a movable bar 11 and a driven flap 12, adjacent to each other with flat surfaces. The flap 12 on the flat surface facing the plank 11 is provided with protrusions 13, and the flap 11 on the reciprocal flat surface is made with inclined guide grooves 14, and the transverse size and height of the protrusions 13 of the flap 12 correspond to the width and depth of the grooves 14 of the flange 11. The protrusions 13, preferably made of cylindrical shape with a diameter of not less than 2 mm to prevent breakage during operation.

To install and ensure the movement of the airflow control unit in the housing 7, a longitudinal slot 15 is made in its rear side wall, and the movable bar 11 is provided with a latch handle 16 on the side face that can be inserted into the longitudinal slot 15 on the rear side wall of the housing 7 due to the flexibility and elasticity of the material of the housing 7. The range of movement of the handle-latch 16 and, therefore, the strap 11 is limited by the length of the slot 15. The position of the handle-latch 16 at one end of the slot 15 corresponds to the extreme location july of the protrusions 13 of the shutter 12 in the grooves 14 of the bar 11, in which the shutter 12 is completely inside the housing 7 and does not overlap the clearance of the sample 8. The position of the handle-latch 16 at the opposite end of the slot 15 corresponds to another extreme location of the protrusions 13 of the shutter 12 in the grooves 14 of the bar 11 in which the shutter 12 is pulled out of the housing 7 and completely covers the clearance of the sample 8. To reduce the friction during movement of the shutter 12 and to reduce the forces exerted by the user on the latch handle 16, the strap 11 and the shutter 12 are provided with adjacent flat surfaces to each other, as well as on opposing surfaces where they come into contact with the housing 7, antifriction protrusions indicated by 17, 18 and 19. Antifriction protrusions 17, 18 and 19 can be made in the form of relief strips from 0.05 to 0.3 mm and a width of 0.1 to 0.5 mm. The anti-friction protrusions 18 on the surface of the shutter 12 in contact with the bar 11 are evenly distributed and are made parallel to the guide grooves 14. The anti-friction protrusions 19 on the surface of the shutter 12 in contact with the housing 7 are evenly distributed and are made in the transverse direction. And the surface of the strip 11 in contact with the housing 7 is provided with at least one anti-friction protrusion 17, made in the longitudinal direction. Thus, the anti-friction protrusions 17, 18 and 19 are oriented respectively parallel to the direction of movement of the strip 11 relative to the housing 7, parallel to the direction of movement of the strip 11 relative to the valve 12 and parallel to the direction of movement of the valve 12 relative to the housing 7.

To prevent air from passing through the adjacency zone of the housing 7 to the sash 2 of the window block, as well as to facilitate the installation of the ventilation valve 1, its casing 7 from the side adjacent to the window block is equipped with a self-adhesive seal 20 located along the sample 8 along the entire length of the casing 7.

The ventilation valve of fresh air ventilation operates as follows. The arrow in FIG. Figure 4 shows the path that air passes through the slotted ventilation channel, coming from the external environment (street) into the room. Air from the street enters the ventilation duct 3, passing through the slit 6 of the window block, formed by reducing the thickness or removing the seal. The ventilation channel 3 is formed by a cavity between the frame 4 and the sash 2 of the window unit. At the outlet of the ventilation channel 3, air passes through a slot 5 of the window block formed by a reduced or removed seal, and through samples 8 in the base of the housing 7 of the ventilation valve 1 and enters the ventilated room. In this case, the bore of the air supply channel is smoothly controlled by moving the shutter 12. The shutter 12 is moved by the interaction of the protrusions 13 located on the shutter 12 and the guide grooves 14 located on the bar 11 into which these protrusions 13 are inserted. The bar 11 is set in motion by the user by moving the latch handle 16. Since the guide grooves 14 are tilted and the longitudinal movement of the flap 12 is limited by the housing 7 of the ventilation valve 1, moving the latch handle 16 in the slot 15 along the housing 7 leads to a lateral movement of the flap 12, which completely opens, or partially or completely blocks samples 8 in the housing 7 of the ventilation valve 1, thereby changing the cross section of the air supply channel into the room. The incoming air provides air exchange in the room in conjunction with the ventilation channels of the exhaust ventilation, including with mechanical motivation, or other exhaust ventilation systems.

The design of the claimed ventilation valve for supply ventilation when installed on window units is characterized by ease of assembly, installation and operation, requires a minimum of mechanical effort when moving the latch handle to control air flow, and thereby provides high reliability and ease of use.

It should be noted that in a similar way the claimed valve can be installed at the outlet of any slotted ventilation channel for regulating the flow of air.

The claimed valve can be used to provide natural ventilation of both residential premises and the interior space of offices and other industrial premises, buildings and structures for various purposes, including can be used in the construction of greenhouses and pavilions when it is installed at the exit of slotted ventilation ducts. Slotted channels can be made not only in window blocks, but also in door blocks or in the walls of buildings and structures, in particular under window sills and in other places, with the possibility of air inflow from the external environment. And with any installation method, the claimed valve provides high reliability and ease of use due to its reliability and low friction between the moving parts of the device. The claimed valve expands the range of ventilation valves.

Claims (15)

1. The ventilation valve of the supply ventilation, including a hollow body and a movable air flow control unit disposed therein, wherein the hollow valve body contains upper and lower flat bases connected to each other by end walls and the rear side wall, and on the front side the body is open and a longitudinal slot is made on the rear side wall of the body, the air flow control unit includes a movable bar and a driven flap adjacent to each other with flat surfaces, the shutter on the adjacent flat surface is provided with protrusions, and the strip on the reciprocal flat surface is made with inclined guide grooves, while the transverse size and height of the protrusions of the shutter corresponds to the width and depth of the grooves of the strip, characterized in that the upper and lower flat bases of the housing are made with longitudinal samples in the entire length of the bases from the front of the housing, the strip on the side is provided with a latch handle, which is configured to be inserted into a longitudinal slot on the rear side wall of the housing, however, the bar and the flap on adjacent flat surfaces and on opposite surfaces of their contact with the housing are equipped with anti-friction protrusions. 2. The ventilation valve according to claim 1, characterized in that it is made with the possibility of installation on the sash of the window unit indoors. 3. The ventilation valve according to claim 2, characterized in that for fastening to the casement of the window unit, the lower base of the ventilation valve body is provided with mounting protrusions with flanges on which holes for mounting are made. 4. The ventilation valve according to claim 2, characterized in that the housing adjacent to the window unit is equipped with a self-adhesive sealant located along the sample along the entire length of the housing. 5. The ventilation valve according to claim 1, characterized in that the antifriction protrusions on the surface of the damper in contact with the bar are evenly distributed and are made parallel to the guide grooves. 6. The ventilation valve according to claim 1, characterized in that the antifriction protrusions on the surface of the damper in contact with the housing are evenly distributed and are made in the transverse direction. 7. The ventilation valve according to claim 1, characterized in that the surface of the strip in contact with the housing is provided with at least one antifriction protrusion made in the longitudinal direction. 8. The ventilation valve according to claim 1, characterized in that the antifriction protrusions are embossed strips with a height of 0.05 to 0.3 mm and a width of 0.1 to 0.5 mm.

Images