RU2352868C1 - Air distributor - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: invention relates to ventilation. In the air distributor contains two vertically placed, one in the other, cylindrical, equal in height, air-permeable external and internal circular cowlings, whose lower ends are fastened by a general air-proof bottom. The upper end of the inner cylindrical air-permeable circular cowling is provided with a supply pipe, and the cavity, formed between the inner and outer cylindrical air-permeable circular cowlings from the side of the supply pipe is closed with an airtight cover. On the inner cylindrical air-permeable circular cowling on the airtight bottom is installed a rigid airtight conical divider with the apex directed towards the direction of the supply pipe.

EFFECT: increase in the uniformity of the flow of incoming air, supplied from the air distributor located vertically, throughout its entire length.

9 cl, 10 dwg

Description

The invention relates to ventilation and can be used for uniform distribution of supply air in residential, public and industrial premises using a low-speed flow.

A device for supplying air to a ventilated space according to the patent of the Russian Federation No. 2128314, IPC 6 F24F 7/00, 13/06, which is characterized in that it has an elongated duct between the hole for intake of air and the outlet, and also that the device is adapted for installation in a vertical position on a vertical surface bounding the ventilated space, with an outlet for the supplied air directed downward and adjacent to the bounding surface. The duct between the intake air intake and the exhaust air outlet is formed by a channel open on one side, and the surface on which the device is mounted limits the duct from the open side so that it has a closed section. The lateral edges of the channel are provided with flanges for sealing the channel on the wall of the room. Due to its speed, the air flow passing through the duct has a vertical downward inertia and, leaving the device, falls down along the wall, and due to the Coanda effect it changes direction and spreads along the floor. The air, which was already in the ventilated space, is forced up to the area of the ceiling, and from there it is removed from the room by other means. When using the device according to patent No. 2128314, an area is formed in front of the air distributor, which is characterized by high speed and low temperature. In such an area, people may experience some discomfort at the ankle level due to the movement of the cold stream.

The main disadvantage of the device for supplying air to a ventilated space according to the patent of the Russian Federation №2128314 is the lack of uniformity in the supply of fresh air to the serviced room.

Known air distribution nozzles according to the patent of Russian Federation No. 2031325, IPC F24F 13/06, which contains a housing made in the form of a semi-cylindrical mesh with a longitudinal flat wall and an inlet, a perforated insert having the shape of a truncated half cone facing the inlet with a large base. Supply air is supplied through the inlet to the perforated insert. As the supply air moves along the axis of the perforated insert, the air velocity and air flow at the top of the conical perforated insert decreases, therefore, the air consumption decreases in the lower part of the mesh housing, which reduces the uniformity of the supply air flow along the length of the air distribution nozzle.

The main disadvantage of the known air distribution nozzle according to the patent of the Russian Federation No. 2031325 is the insufficient degree of uniformity of the outflow of supply air along the length of the nozzle, which leads to uneven supply air flow over the height of the room.

Known air distributor according to the patent of the Russian Federation No. 2188986, IPC F24F 13/072, which contains a housing with a pipe for supplying air, lower and upper covers, outer mesh and perforated insert. The housing is cylindrical in shape. The perforated insert is made of truncated double cones, with the large bases of the truncated cones of the perforated insert facing the middle of the body and attached to it in its middle part. Due to the fact that the perforated insert is made of double truncated cones, fastened together by large bases, which are fastened to the middle part of the cylindrical body, and the smaller bases of the truncated cones of the insert are located at the upper and lower covers of the cylindrical body, reduced the uniformity of the outflowing air flow from the air distributor , relative to its length.

The main disadvantage of the known air distributor according to the patent of the Russian Federation No. 2188986 is the insufficient degree of uniformity of the supply air flow along the length of the air distributor, which leads to uneven supply air flow over the height of the served room.

The Halton Hit-AFC air diffuser is also known, which is adopted as the closest analogue and which contains vertically arranged, coaxially mounted, equal in height breathable cylindrical outer front panels and an internal flow stabilizer made in the form of circular shells, the lower ends of which are closed by a sealed bottom, the upper end of the internal air flow stabilizer is equipped with a supply pipe, and the cavity formed between the front panel and the air flow stabilizer is closed g sealed cap. To equalize the air flow supplied by a known air distributor between the outer front panel and the internal air flow stabilizer, a number of dividing, mutually parallel flat rings are installed, coaxial with the internal air flow stabilizer. Flat dividing rings contribute to the discharge of the distributed air in the direction perpendicular to the geometric axis of the front panel, but do not contribute to the alignment of the mass of the distributed air along the length of the entire air distributor. Most likely, dividing flat rings prevent the flow of air mass in the cavity between the front panel and the flow stabilizer, thereby eliminating the equalization of air pressure along the length of the air distributor.

The main disadvantage of the Halton Hit-AFC air distributor is the insufficient uniformity of the supply air flow supplied to the serviced room relative to the length of the air distributor.

The claimed invention has the task to increase the uniformity of the supply air flow into the serviced room by aligning the supply air flow along the length of the vertically arranged air distributor.

An increase in the degree of uniformity of the supply air outflow along the entire length of the air distributor is achieved due to the fact that in the air distributor, which includes at least two vertically arranged, cylindrical one to the other, air-permeable outer and inner circumferential shells, the lower ends of which are fastened by a common sealed bottom, the upper end of the inner cylindrical breathable circular shell is provided with a supply pipe, and a cavity formed between the inner it and the outer cylindrical breathable circular shells on the side of the inlet pipe are closed with a sealed cover, while in the inner cylindrical breathable circular shell on the sealed bottom there is a rigid sealed conical divider with the apex directed towards the inlet pipe.

The outer cylindrical breathable circular shell and the inner cylindrical breathable circular shell can be made circumferentially and arranged coaxially, their lower ends are fastened with a sealed bottom made in the form of a full circle, and a rigid sealed conical divider mounted on the said bottom is made in the form of a round cone and is located coaxially with the indicated shells.

The inner cylindrical breathable circular shell may be closed around the circumference, while the outer cylindrical breathable circular shell is coaxial with the inner cylindrical breathable circular shell and is made in a circular arc of 180 °, a rectangular gutter-shaped sealed wall is attached to its edges with a gap covering the inner cylindrical breathable circular shell, and a rigid hermetic mounted on an airtight bottom Cone-particle distributor is made as a circular cone and is disposed coaxially with the inner cylindrical circumferential breathable shell.

The outer cylindrical breathable circular shell and the inner cylindrical breathable circular shell can be arranged coaxially and each made in a circular arc equal to 180 °, a common flat sealed wall is attached to their edges along the generators, the lower ends of both of these shells and a common flat sealed wall are fastened with a sealed bottom made in the form of one half of a circle, and a rigid sealed conical divider mounted on the indicated bottom is located coaxially with the said shell Kami and is formed as a one-half circular cone, divided into two parts by a plane passing through its axis, the edges of said one half of the circular cone in the generators are fixed to said flat wall sealed.

The outer cylindrical breathable circular shell and the inner cylindrical breathable circular shell can be aligned and each made in a circular arc equal to 90 °, a common corner with a 90 ° angle, an airtight wall, the lower ends of both of these shells and a common corner are attached to their edges sealed walls are fastened with a sealed bottom made in the form of one quarter of a circle, i.e. quadrant, and mounted on the specified bottom of the rigid sealed conical divider is located coaxially with these shells and is made in the form of one quarter of a round cone, bounded by two secant planes passing along the axis of the cone at an angle of 90 ° to each other, while the edges of the specified one quarter of the round cone along generatrixes attached to said common angular sealed wall.

The inner cylindrical breathable circular shell can be made closed in a circle, and the outer cylindrical breathable circular shell is made in a circular arc equal to 90 °, an angular tight wall with an angle of 90 ° is attached to its edges along the generators, with a gap covering the inner cylindrical breathable circular shell, the lower ends of both said shells and the angular sealed wall are fastened with a sealed bottom made in the form of one quarter of a circle, i.e. quadrant, and mounted on the specified bottom of the rigid sealed conical divider is made in the form of a round cone and is located in the inner cylindrical breathable circular shell, coaxially with the inner cylindrical breathable circular shell.

Rigid sealed conical divider can be made of sheet metal and coated with porous material from the inside.

Rigid sealed conical divider can be made of non-metallic material.

The height of the rigid sealed conical divider can be equal to 0.2 of the length of the inner cylindrical breathable circular shell.

Thanks to the invention, a technical result is obtained, namely, the degree of uniformity of the outflow of supply air from a vertically arranged air distributor along its entire length is increased.

Figure 1 shows the first example of the execution of the air distributor with a local section, and figure 2 shows a section aa in figure 1.

Figure 3 shows a second example of the execution of the air distributor with a local section, and figure 4 shows a section bB in figure 3.

Figure 5 shows a third embodiment of a diffuser with a local cut, and figure 6 shows a section bb in figure 5.

In Fig.7 shows a fourth example of the execution of the air distributor with a local section, and Fig.8 shows a section GG in Fig.7.

In Fig.9 shows a fifth example of the execution of the air distributor with a local section, and Fig.10 shows a section DD in Fig.9.

The air distributor includes at least two vertically arranged, cylindrical installed one in another, equal in height to the outer breathable circular shell 1 and the inner breathable circular shell 2 (1, 2), the lower ends of which are fastened by a common sealed bottom 3, the upper end of the inner cylindrical breathable circular shell 2 is provided with a supply pipe 4, and a cavity 5 formed between the inner cylindrical breathable circular shell 2 and the outer cylinder with an air-permeable circular shell 1 on the side of the inlet pipe 4 is closed with a sealed cover 6, while in the inner cylindrical breathable circular shell 2 on the bottom 3 is mounted a tight sealed conical divider 7, the top 8 of which is directed towards the inlet pipe 4. The first example embodiment of the invention is shown in 1 and 2, where the outer cylindrical breathable circular shell 1 and the inner cylindrical breathable circular shell 2 are closed in legs and their lower ends are fastened with a sealed bottom 3, made in the form of a full circle, and mounted on the specified bottom 3 rigid sealed conical divider 7 is made in the form of a round cone and is aligned with the indicated shells 1 and 2. In this case, the rigid sealed conical divider 7 is made from sheet metal, and to reduce noise and vibration, said divider 7 is internally coated with a layer 9 of porous material. The height h of the rigid sealed conical divider 7 is equal to 0.2 length N of the inner cylindrical breathable circular shell 2.

An example of the second embodiment of the invention is shown in FIGS. 3 and 4, where the inner cylindrical breathable circular shell 10 is closed in circumference, while the outer cylindrical breathable circular shell 11 is aligned with the inner cylindrical breathable circular shell 10 and made in a circular arc equal to 180 ° , a rectangular gutter-like tight wall 12 is attached to its edges along the generators, with a gap covering the inner cylindrical breathable circular the side of the barrel 10. The upper end of the inner cylindrical breathable circular shell 10 is provided with a supply pipe 13. The lower ends of the outer cylindrical breathable circular shell 11 and the inner cylindrical breathable circular shell 10, as well as the rectangular trough-like sealed wall 12 are fastened with a sealed bottom 14. A cavity 15 formed between the outer a cylindrical breathable circular shell 11 and an inner cylindrical breathable circular shell 10 is limited to yamougolnoy sealed trough side wall 12 of inlet 13 closed by a cover 16. In the sealed bottom 14 of the inner cylindrical breathable circular shell 10 is mounted airtight rigid divider cone 17 which is formed as a circular cone and is disposed coaxially with the inner cylindrical shell 10 the circular air-permeable.

A third embodiment of the invention is shown in FIGS. 5 and 6, where the outer cylindrical breathable circular shell 18 and the inner cylindrical breathable circular shell 19 are aligned and each made in a circular arc of 180 °, a common flat sealed wall 20 is attached to their edges along the generatrices , the lower ends of both of these shells 18 and 19, as well as a common flat sealed wall 20 are fastened with a sealed bottom 21, made in the form of one half circle, and mounted on the specified tight beggar 21 rigid sealed conical divider 22 is coaxial with the said shells 18 and 19 and is made in the form of one half of a round cone, divided into two parts by a plane extending along its axis, while the edges of the specified one half of the round cone are generatrix attached to said common flat sealed wall 20. The upper end of the inner cylindrical breathable circular shell 19 is provided with a supply pipe 23. A cavity 24 formed between the outer cylindrical breathable circular gull 18 and breathable inner cylindrical circular sidewall 19, as well as limited overall flat sealed wall 20, from the side of inlet 23 closed by a cover 25.

Figures 7 and 8 show a fourth embodiment of the invention in which the outer cylindrical breathable circular shell 26 and the inner cylindrical breathable circular shell 27 are aligned and each made in a circular arc of 90 °, a common corner with an angle is attached to their edges along the generatrices 90 ° sealed wall 28, the lower ends of both of these shells 26 and 27, as well as the common angular sealed wall 28 are sealed with a sealed bottom 29 made in the form of one quarter of a circle, i.e. quadrant, and mounted on the specified bottom of the tight sealed conical divider 30 is located coaxially with the indicated shells 26 and 27 and is made in the form of one quarter of a circular cone bounded by two cutting planes passing along the axis of the cone at an angle of 90 ° to each other, with the edges of the specified one quarter of the circular cone along the generatrix is attached to the aforementioned common angular sealed wall 28. The upper end of the inner cylindrical breathable circular shell 27 is provided with a supply pipe 31. A cavity 32, Called between the outer cylindrical breathable circular shell 26 and the inner cylindrical breathable circular shell 27, and also limited by a common angular sealed wall 28, it is closed by a cover 33 from the inlet pipe 31.

A fifth embodiment of the invention is shown in FIGS. 9 and 10, where the inner cylindrical breathable circular shell 34 is made closed in a circle, and the outer cylindrical breathable circular shell 35 is made in a circular arc of 90 °, an angular sealed wall 36 is attached to its edges along the generatrices with an angle of 90 °, with a gap covering the inner cylindrical breathable circular shell 34, the lower ends of both of these shells 34 and 35 and the corner sealed wall 36 are sealed with sealed bottoms eat 37, made in the form of one quarter of a circle, i.e. quadrant, and mounted on the specified bottom 37, a tight sealed conical divider 38 is made in the form of a round cone and is located in the inner cylindrical breathable circular shell 34 coaxially with the inner cylindrical breathable circular shell 34. The upper end of the inner cylindrical breathable circular shell 34 is provided with a supply pipe 39. Cavity 40 formed between the outer cylindrical breathable circular shell 35 and the inner cylindrical breathable a circular sidewall 34, as well as limited angular hermetic wall 36, from the side of inlet 39 closed by a cover 41.

Rigid sealed conical divider 38 is made of non-metallic material.

The air distributor is low-speed and can be used for displacing ventilation and is designed to supply air directly to the working area of the room with a low air flow rate. In the description of the invention, five examples of its implementation are proposed. In the first example, a description is given of a round cylindrical air distributor, which can be installed in the center of the serviced room, since it delivers supply air simultaneously over the entire circumference. The air distributor presented in the second and third examples can be used as a wall, it is able to supply air to the sector equal to 180 °. In the fourth and fifth embodiments of the invention, an air distributor is provided that can be used as an angular source of supply air. The angular air distributor provides a supply air supply in the room sector equal to 90 °.

The air distributor operates as follows.

In the process of ventilating the serviced room, the supply air to the air distributor is pumped through the supply pipe 4 (Fig. 1, 2), from which the air enters the cavity 42 of the inner cylindrical breathable circular shell 2. Part of the air flow, scattered in the cavity 42, through the inner cylindrical breathable circular the shell 2, enters the cavity 5, formed between the inner cylindrical breathable circular shell 2 and the outer cylindrical breathable circular shell 1. D the carbon part of the air flow coming from the supply pipe 4 reaches the surface of the rigid hermetic conical divider 7, reflected from the rigid hermetic conical divider 7, is scattered through the inner cylindrical breathable circular shell 2, into the cavity 5. Both parts of the air flow enter the cavity 5, interacting, they mix together, equalize the pressure throughout the cavity 5, as a result of which a uniform air mass is formed, which in the form of a uniform flow through the outer cylindrical duhopronitsaemuyu circular shroud 1 is forced into the room to be served. Due to the presence of a rigid sealed conical divider 7 mounted in the inner cylindrical breathable circular shell 2 on the sealed bottom 3, the bottom vortex zone, characterized by reduced air pressure, is excluded. In the presence of a rigid sealed conical divider 7, in that part of the air flow that reaches the surface of the rigid sealed conical divider 7, when meeting with said divider 7, the pressure increases, which helps to equalize the air pressure along the entire length of the cavity 42 in the inner cylindrical breathable circular shell 2. Thus, even in the cavity 42 of the inner cylindrical breathable circular shell 2, the pressure of the air flow is equalized, which then passes the inner cylindrical breathable circular shell 2 enters the cavity 5. In the cavity 5, the pressure in the air mass is finally equalized, since the specified cavity 5 is a space free to move the air mass. Due to the fact that the outer breathable circular shell 1 and the inner breathable circular shell 2 are made round, the supply air to the served room is supplied around the entire circumference of 360 °.

In the air distributor described in the second embodiment of the invention and shown in FIGS. 3 and 4, air is supplied through the supply pipe 13 into the cavity 43 of the inner cylindrical breathable circular shell 10. A part of the air flow dispersed in the cavity 43 through the inner cylindrical breathable circular shell 10 falls into the cavity 15 formed between the inner cylindrical breathable circular shell 10 and the outer cylindrical breathable circular shell 11. Another part along the air coming from the supply pipe 13 reaches the surface of the rigid hermetic conical divider 17, reflected from the rigid hermetic conical divider 17, is scattered and through the inner cylindrical breathable circular shell 10 enters the cavity 15. In the cavity 15, both parts of the air flow, interacting, are mixed mutually, equalize the pressure throughout the cavity 15, resulting in a uniform air mass, which in the form of a uniform flow through the outer cylindrical air aemuyu circular shroud 11 is forced into the room to be served. Due to the presence of a rigid hermetic conical divider 17 mounted in the inner cylindrical breathable circular shell 10 on the sealed bottom 14, the bottom vortex zone, characterized by a reduced air pressure, is excluded. In the presence of a rigid sealed conical divider 17, in that part of the air flow that reaches the surface of the rigid sealed conical divider 17, when meeting with said divider 17, the pressure increases, which helps to equalize the air pressure along the entire length of the cavity 43 in the inner cylindrical breathable circular shell 10. Thus, even in the cavity 43 of the inner cylindrical breathable circular shell 10, the pressure of the air flow is equalized, which then passes through We choose cylindrical breathable inner circumferential shroud 10 enters the cavity 15. In the cavity 15, the pressure in the air mass completely aligned because said cavity 15 is a space free for moving air mass. Due to the fact that the outer cylindrical breathable circular shell 11 is made in a circular arc equal to 180 °, the supply air to the served room is supplied in a sector equal to 180 °. The air distributor presented in the second embodiment of the invention can be used as a wall.

In the air distributor described in the third exemplary embodiment of the invention and shown in FIGS. 5 and 6, air is supplied through the supply pipe 23 into the cavity 44 of the inner cylindrical breathable circular shell 19. A part of the air flow dispersed in the cavity 44 through the inner cylindrical breathable circular shell 19 enters the cavity 24 formed between the inner cylindrical breathable circular shell 19 and the outer cylindrical breathable circular shell 18. Another part of the sweat the air coming from the supply pipe 23 reaches the surface of the rigid hermetic conical divider 22, reflected from the rigid hermetic conical divider 22, is scattered and through the inner cylindrical breathable circular shell 19 enters the cavity 24. In the cavity 24, both parts of the air flow, interacting, are mixed mutually, equalize the pressure throughout the cavity 24, resulting in a uniform air mass, which in the form of a uniform flow through the outer cylindrical air permeability The removable circumferential shell 18 is displaced into the serviced room. Due to the presence of a rigid hermetic conical divider 22 mounted in the inner cylindrical breathable circular shell 19 on the sealed bottom 21, the bottom vortex zone, characterized by a reduced air pressure, is excluded. If there is a rigid sealed conical divider 22 in that part of the air flow that reaches the surface of the rigid sealed conical divider 22, when meeting with the specified divider 22, the pressure increases, which helps to equalize the air pressure along the entire length of the cavity 44 in the inner cylindrical breathable circular shell 19. Thus Thus, even in the cavity 44 of the inner cylindrical breathable circular shell 19, the pressure of the air flow is equalized, which then passes through taking the inner cylindrical breathable circular shell 19, enters the cavity 24. In the cavity 24, the pressure in the air mass finally equalizes, since the specified cavity 24 is a space free to move the air mass. Due to the fact that the outer cylindrical breathable circular shell 18 is made in a circular arc equal to 180 °, the supply air to the served room is supplied in a sector equal to 180 °. The air distributor presented in the third embodiment of the invention can be used as a wall.

In the air distributor described in the fourth embodiment of the invention and shown in FIGS. 7 and 8, air is supplied through the supply pipe 31 into the cavity 45 of the inner cylindrical breathable circular shell 27. Part of the air flow dispersed in the cavity 45 through the inner cylindrical breathable circular shell 27 , falls into the cavity 32 formed between the inner cylindrical breathable circular shell 27 and the outer cylindrical breathable circular shell 26. Another part the outflow of air coming from the supply pipe 31 reaches the surface of the rigid hermetic conical divider 30, being reflected from the rigid hermetic conical divider 30, is scattered and through the inner cylindrical breathable circular shell 27, enters the cavity 32. In the cavity 32, both parts of the air flow, interacting, mix each other, equalize the pressure throughout the cavity 32, resulting in a uniform air mass, which in the form of a uniform flow through the outer cylindrical air passage the annular circumferential shell 26 is forced out into the serviced room. Due to the presence of a rigid sealed conical divider 30 mounted in the inner cylindrical breathable circular shell 27 on the sealed bottom 29, the bottom vortex zone, characterized by a reduced air pressure, is excluded. If there is a rigid hermetic conical divider 30 in that part of the air flow that reaches the surface of the rigid hermetic conical divider 30, when meeting with the specified divider 30, the pressure increases, which helps to equalize the air pressure along the entire length of the cavity 45 in the inner cylindrical breathable circular shell 27. Thus Thus, even in the cavity 45 of the inner cylindrical breathable circular shell 27, the pressure of the air flow is equalized, which then passes through take the inner cylindrical breathable circular shell 27, enters the cavity 32. In the cavity 32, the pressure in the air mass finally equalizes, since the specified cavity 32 is a space free to move the air mass. Due to the fact that the outer cylindrical breathable circular shell 26 is made in a circular arc equal to 90 °, the supply air to the served room is supplied in a sector equal to 90 °. The air distributor presented in the fourth embodiment of the invention can be used as a corner.

In the air distributor described in the fifth exemplary embodiment of the invention and shown in FIGS. 9 and 10, air is supplied through the supply pipe 39 into the cavity 46 of the inner cylindrical breathable circular shell 34. Part of the air flow dispersed in the cavity 46 through the inner cylindrical breathable circular shell 34 enters the cavity 40 formed between the inner cylindrical breathable circular shell 34 and the outer cylindrical breathable circular shell 35. Another part of the sweat and the air coming from the supply pipe 39 reaches the surface of the rigid hermetic conical divider 38, reflected from the rigid hermetic conical divider 38, is scattered through the inner cylindrical breathable circular shell 34, enters the cavity 40. In the cavity 40, both parts of the air flow, interacting, mix each other, equalize the pressure throughout the cavity 40, resulting in a uniform air mass, which in the form of a uniform flow through the outer cylindrical breathable the removable circumferential shell 35 is displaced into the serviced room. Due to the presence of a rigid hermetic conical divider 38 mounted in the inner cylindrical breathable circular shell 34 on the sealed bottom 37, the bottom vortex zone, characterized by a reduced air pressure, is excluded. If there is a rigid hermetic conical divider 38 in that part of the air flow that reaches the surface of the rigid hermetic conical divider 38, when meeting with said divider 38, the pressure increases, which helps to equalize the air pressure along the entire length of the cavity 46 in the inner cylindrical breathable circular shell 34. Thus Thus, even in the cavity 46 of the inner cylindrical breathable circular shell 34, the pressure of the air flow is equalized, which then passes through take the inner cylindrical breathable circular shell 34, enters the cavity 40. In the cavity 40, the pressure in the air mass finally equalizes, since the specified cavity 40 is a space free to move the air mass. Due to the fact that the outer cylindrical breathable circular shell 35 is made in a circular arc equal to 90 °, the supply air to the served room is supplied in a sector equal to 90 °. The air distributor presented in the fifth embodiment of the invention can be used as a corner.

The invention allowed to obtain a technical result, namely, the degree of uniformity of the outflow of supply air from a vertically arranged air distributor along its entire length was increased. The specified technical result provides an increase in the degree of uniformity of the supply air flow into the serviced room.

Claims (9)

1. An air distributor comprising at least two vertically arranged, installed one into the other, cylindrical, equal in height breathable outer and inner circular shells, the lower ends of which are fastened by a common sealed bottom, the upper end of the inner cylindrical breathable circular shell is equipped with a supply pipe, and the cavity formed between the inner and outer cylindrical breathable circular shells on the side of the inlet pipe is closed tight to ryshka, characterized in that in the inner cylindrical breathable circular shell on the bottom mounted rigid sealed conical divider with the apex directed towards the inlet pipe. 2. The air distributor according to claim 1, characterized in that the outer cylindrical breathable circular shell and the inner cylindrical breathable circular shell are made circumferentially and arranged coaxially, their lower ends are fastened with a sealed bottom made in the form of a full circle, and rigid mounted on the specified bottom sealed conical divider is made in the form of a round cone and is located coaxially with the indicated shells. 3. The air distributor according to claim 1, characterized in that the inner cylindrical breathable circular shell is made circumferentially, the outer cylindrical breathable circular shell is aligned with the inner cylindrical breathable circular shell and made in a circular arc equal to 180 ° to its edges along the generatrix a rectangular gutter-like tight wall is attached, with a gap covering the inner cylindrical breathable circular shell, and the mounted one and the sealed bottom of the rigid sealed conical divider is made in the form of a round cone and is located coaxially with the inner cylindrical breathable circular shell. 4. The air distributor according to claim 1, characterized in that the outer cylindrical breathable circular shell and the inner cylindrical breathable circular shell are arranged coaxially and each are made in a circular arc equal to 180 °, a common flat sealed wall is attached to their edges along the generatrices, the lower ends of both said shells and a common flat sealed wall are fastened with a sealed bottom made in the form of one half circle, and a rigid sealed conical mounted mounted on the said bottom l is coaxial with the said shells and formed as a one-half circular cone, divided into two parts by a plane passing through its axis, the edges of said one half of the circular cone in the generators are fixed to said flat wall sealed. 5. The air distributor according to claim 1, characterized in that the outer cylindrical breathable circular shell and the inner cylindrical breathable circular shell are each coaxial and each made in a circular arc of 90 °, a common angular angle of 90 ° is attached to their edges along the generatrices, a sealed wall, the lower ends of both of these shells and a common angular sealed wall are fastened with a sealed bottom made in the form of one quarter of a circle, i.e. quadrant, and mounted on the specified bottom of the rigid sealed conical divider is located coaxially with these shells and is made in the form of one quarter of a round cone, bounded by two secant planes passing along the axis of the cone at an angle of 90 ° to each other, while the edges of the specified one quarter of the round cone along generatrixes attached to said common angular sealed wall. 6. The air distributor according to claim 1, characterized in that the inner cylindrical breathable circular shell is made circumferentially, and the outer cylindrical breathable circular shell is made in a circular arc equal to 90 °, an angular sealed wall is attached to its edges along the generatrix, with an angle of 90 °, with a gap covering a cylindrical breathable circular inner shell, the lower ends of both of these shells and a corner sealed wall are fastened with a sealed bottom made in the form of quarter of a circle, i.e. quadrant, and mounted on the specified bottom of the rigid sealed conical divider is made in the form of a round cone and is located in the inner cylindrical breathable circular shell, coaxially with the inner cylindrical breathable circular shell. 7. An air distributor according to any one of claims 2 to 6, characterized in that the rigid sealed conical divider is made of sheet metal and coated with a porous material from the inside. 8. The air distributor according to any one of claims 2 to 6, characterized in that the rigid sealed conical divider is made of non-metallic material. 9. The air distributor according to any one of claims 2 to 6, characterized in that the height of the rigid sealed conical divider is equal to 0.2 of the length of the inner cylindrical breathable circular shell.

Images