RU2737265C1 - Air distributor (versions) (vr) - Google Patents

Abstract

FIELD: ventilation and air conditioning.

SUBSTANCE: invention discloses versions of air distributors having simple design and low material consumption while providing high rate of attenuation of inlet jets and high uniformity of air distribution. According to one of versions, proposed is air distributor containing air duct and connected to it element made in form of air-conducting insert, in form of single-cavity hyperboloid (1) with open for air passage opposite end bases (2), along length and perimeter of which channel diffusers (3) are uniformly distributed, wherein hyperboloid (1) is located in gap between pair, coaxially aligned sections (4) of supply air duct (5), and end bases (2) of hyperboloid (1) are connected to ends of said sections (4) located on the side of the gap, wherein sections (4) of supply air duct (5) are cylindrical with round cross sections. In other versions, the air distributor uses a nozzle made in the form of cylinder (6) or sphere (12, 17) with honeycomb diffusers (8, 16, 21). Cylindrical sections of air ducts are connected to inner ends of part of cellular diffusers.

EFFECT: invention can be used for distribution of supply air to premises for various purposes.

8 cl, 4 dwg

Description

The invention relates to ventilation and air conditioning and can be used to supply supply air to various rooms and objects.

Known is an air distributor containing a housing and a divider placed between its side walls, characterized in that in order to simplify the design and expand the control range, the divider is made in the form of a honeycomb block of variable volume fixed on the side walls of the housing, and the latter are rotary (USSR Author's Certificate for invention No. 821861, F24F 13/06, publ. 15.04.81, bull. No. 14).

This air diffuser does not provide a high attenuation rate for the supply jets.

As a prototype, an air distributor was chosen containing a spherical honeycomb nozzle connected to the air duct, in which the honeycombs are made in the form of diffusers with radial walls, and the nozzles are connected to the air duct using a pipe connected to the inner ends of the honeycomb (USSR author's certificate No. 1314198, F24F 13 / 06, publ. 30.05.87, bull. No. 20).

Such an air distributor has a complex structure and high material consumption.

The technical task of the first embodiment of the device is to create such an air distributor, which has a simpler design, lower material consumption while ensuring a higher attenuation rate of the speed of the supply jets and high uniformity of air distribution. Additional technical tasks include increasing the manufacturability and the intensity of the damping of the speed of the supply jets.

This is achieved by the fact that, in contrast to the known technical solution to improve manufacturability by simplifying the design and reducing material consumption by eliminating the branch pipe while ensuring a higher attenuation rate of the supply jets and high uniformity of air distribution, in an air distributor containing an air duct and an element associated with it in the form a body of revolution, including duct diffusers, and the possibility of connecting the element to the duct and connecting to the ends, while the element is made in the form of an air duct insert, in the form of a single-cavity hyperboloid with opposite end bases open for air passage, duct diffusers are evenly distributed along the length and perimeter , while the hyperboloid is placed in the gap between the pair of coaxially oriented sections of the supply air duct, and the end bases of the hyperboloid are attached to the ends of the said sections located on the side of the gap, and the sections of the supply air the ducts are cylindrical with circular cross-sections.

An increase in manufacturability is also achieved by the fact that the outer diameters of the supply air duct sections are equal to the diameters of the end bases of the hyperboloid.

An increase in manufacturability by reducing material consumption while ensuring a higher attenuation rate of the velocity of the supply jets is achieved by the fact that the diffusers have circular cross-sections, and from the inside of each of the diffusers there is an internal screw thread for swirling the air flow, and the screw threads have the same directed helical generatrix lines.

In addition, an increase in the intensity of the damping of the velocity of the supply jets is achieved by the fact that the axes of each pair of diffusers, symmetrically located relative to the plane of symmetry, intersecting the longitudinal axis of the single-sheet hyperboloid in the central part of the latter at a right angle, intersect each other at an angle.

The essence of the claimed technical solution is illustrated by a drawing: FIG. 1 shows a general view of the device (section).

The device contains a single-cavity hyperboloid 1 with end bases 2 and channel diffusers 3 open for air passage, and sections 4 of the supply air duct 5.

The device works as follows.

The supply air flow enters the single-cavity hyperboloid 1 through the end base 2 from the section 4 of the supply air duct 5 (in Fig. 1) and part of the air flow is removed from the hyperboloid through the other end base 2 to another section 4 of the supply air duct 5. Along the perimeter and length of the single-cavity hyperboloid 1 duct diffusers 3 are evenly distributed, which ensure the division of the air flow into separate supply jets. A single-cavity hyperboloid 1 is placed between a pair of coaxially oriented sections 4 of the supply air duct 5, and the end bases 2 of a single-cavity hyperboloid 1 are attached to the ends of the said sections 4, which are cylindrical and have essentially circular cross-sections. To increase the manufacturability, the outer diameters of the sections 4 of the supply air duct 5 can be made equal to the diameters of the end bases 2 of the hyperboloid 1. To increase the intensity of the attenuation of the speed of the supply jets, the diffusers 3 can be made with circular cross-sections, and from the inside of each of the diffusers 3 an internal screw thread can be made for swirling the air flow (not shown in the drawing), while the screw threads have the same directed helical generatrix lines. Also, the intensity of the velocity decay of the supply jets can be increased if the axes of each pair of diffusers 3, symmetrically located with respect to the plane of symmetry, intersecting the longitudinal axis of the single-sheet hyperboloid 1 in the central part of the latter at right angles, intersect each other at an angle. The concave shape of the outer surface of hyperboloid 1 ensures the collision of the supply jets with each other at an angle, while collisions lead to a decrease in the kinetic energy and an intensive attenuation of the speed of the supply jets, and the merger of the supply jets leads to the formation of a resultant flow consisting of a large number of small-scale vortices, the energy of which is dissipated indoors, providing a high intensity of the process of mixing the supply air with the room air.

The technical task of the second embodiment of the device is to create such an air distributor, which has a simpler design, lower material consumption while ensuring a high attenuation rate of the speed of the supply jets and a high uniformity of air distribution. Additional technical tasks include increasing operational reliability by reducing material consumption.

This is achieved by the fact that, in contrast to the known technical solution for increasing manufacturability by simplifying the design and reducing material consumption by eliminating the branch pipe while ensuring high attenuation of the speed of the supply jets and high uniformity of air distribution, in an air distributor containing an air duct and a honeycomb nozzle associated with it in the form body of revolution, including honeycomb diffusers with radially located side walls, and the ability to connect the nozzle to the air duct, and attach to the inner ends of a part of the honeycomb diffusers, while the nozzle is made in the form of a cylinder with open opposed end bases, along the length and perimeter of which the honeycomb diffusers are evenly distributed , while the cylinder is installed with the coverage of a pair, coaxially oriented, sections of the supply air duct along the perimeters of the latter, and forming an end gap covered by a cylinder, and the sections of the supply air duct are cylindrical, with circular cross-sections, and the cylindrical sections of the air duct are connected to the inner ends of one part of the honeycomb diffusers with the possibility of mechanical contact, and the other part of the honeycomb diffusers is in communication with the end gap.

In addition, an increase in operational reliability by reducing material consumption is achieved by the fact that grooves or grooves are made in the air duct sections, on the side of contact with the cylinder, with the formation of mesh corrugation, and on the side of the inner ends of the honeycomb diffusers connected to the air duct sections, cutouts are made to form between the last pointed projections in the form of teeth to fix the position of the cylinder.

The essence of the claimed technical solution is illustrated by a drawing: FIG. 2 shows a general view of the device (section).

The device contains a cylinder 6 with open end bases 7, honeycomb diffusers 8, sections 9 of the supply air duct 10 and end gap 11.

The device works as follows.

The supply air flow enters the end gap 11 from section 9 of the supply air duct 10 (in Fig. 2) and part of the air flow is removed from the gap 11 through another section 9 of the supply air duct 10. Honeycomb diffusers 8 are evenly distributed around the perimeter and length of the cylinder 6, which provide dividing the air flow into separate supply jets that flow into the service facility. The cylinder 6 has open opposed end bases 7 and is located with overlap of the end gap 11, and coverage along the perimeters of the sections 9 of the supply air duct 10. The sections 9 of the air duct 10 are cylindrical with circular cross-sections. To exclude the possibility of displacement of the cylinder 6 relative to the sections 9 of the air duct 10 in the sections 9 of the air duct 10, from the side of contact with the cylinder 6, grooves or grooves are made with the formation of mesh corrugation (not shown in the drawing), and from the side of the inner ends of the honeycomb diffusers 8 connected to sections 9 of the air duct 10, cutouts are made to form between the last pointed projections in the form of teeth (not shown in the drawing) to fix the position of the cylinder 6.

The technical task of the third embodiment of the device is to create such an air distributor, which has a simpler design, lower material consumption while ensuring a high attenuation rate of the speed of the supply jets and high uniformity of air distribution.

This is achieved by the fact that, in contrast to the known technical solution for increasing manufacturability by simplifying the design and reducing material consumption by eliminating the branch pipe while ensuring high attenuation of the speed of the supply jets and high uniformity of air distribution, in an air distributor containing an air duct and a honeycomb nozzle associated with it in the form a sphere, including honeycomb diffusers with radially located side walls, and the ability to connect the nozzle to the air duct, and attach to the inner ends of a part of the honeycomb diffusers, while the sphere is installed to cover a pair, coaxially oriented, sections of the supply air duct along the perimeters of the latter, and forming an end gap closed a sphere, and sections of the air duct are connected to the inner ends of one part of the honeycomb diffusers, and the other part of the honeycomb diffusers is in communication with the end gap.

The essence of the claimed technical solution is illustrated by a drawing: FIG. 3 shows a general view of the device (section).

The device contains a sphere 12, sections 13 of the supply air duct 14, an end gap 15 covered by a sphere 12 and honeycomb diffusers 16.

The device works as follows.

The supply air flow enters the end gap 15 from the section 13 of the supply air duct 14 (in Fig. 3) and a part of the air flow is removed from the gap 15 through another section 13 of the supply air duct 14. The honeycomb diffusers 16 provide the separation of the air flow into separate supply jets flowing into service object. The sphere 12 is placed with overlap of the end gap 15 and coverage along the perimeters of the sections 13 of the supply air duct 14, while the sections 13 of the air duct 14 are connected to the inner ends of a part of the honeycomb diffusers 16.

The technical task of the fourth variant of the design of the device is to create such an air distributor, which has a simpler design, lower material consumption while ensuring a high attenuation rate of the speed of the supply jets and high uniformity of air distribution.

This is achieved by the fact that, in contrast to the known technical solution for increasing manufacturability by simplifying the design and reducing material consumption by eliminating the branch pipe while ensuring high attenuation of the speed of the supply jets and high uniformity of air distribution, in an air distributor containing an air duct and a honeycomb nozzle associated with it in the form sphere, including honeycomb diffusers with radially located side walls, and the possibility of connecting the nozzle to the air duct, and attaching to the ends, while the sphere is made in the form of an insert installed in the gap between the pair, coaxially oriented, sections of the supply air duct, while the ends of the said sections located from the side of the gap, connected to the insert with the possibility of mechanical contact with the latter and communication with a part of the honeycomb diffusers located on opposite sides of the insert, and the sections are cylindrical with circular cross sections, and the diameter of the avki exceeds the diameters of the sections.

The essence of the claimed technical solution is illustrated by a drawing: FIG. 4 shows a general view of the device (section).

The device contains a spherical insert 17, a gap 18, sections 19 of the supply air duct 20 and honeycomb diffusers 21. The device operates as follows. The supply air flow enters the spherical insert 17 from the section 19 of the supply air duct 20 (in Fig. 4) through the honeycomb diffusers 21 communicated with this section 19. One part of the air flow flows out through a part of the honeycomb diffusers 21 into the serviced object, and the other part of the air flow through honeycomb diffusers 21, communicated with another section 19, enters the supply air duct 20. A spherical insert 17 is installed in the gap 18 between the ends of the sections 19 of the supply air duct 20, and the honeycomb diffusers 21 provide separation of the air flow. The ends of the sections 19 located on the side of the gap 18 are attached to the spherical insert 17 with the possibility of communicating with a part of the honeycomb diffusers 21 located on the opposite sides of the spherical insert 17, while the sections 19 are cylindrical with circular cross-sections, and the diameter of the spherical insert 17 exceeds the diameters of the sections nineteen.

Claims (8)

1. An air distributor containing an air duct and an associated element in the form of a body of revolution, including duct diffusers, and the possibility of connecting the element to the air duct and attaching to the ends, characterized in that the element is made in the form of an air duct insert, in the form of a single-cavity hyperboloid with open for air passage by opposite end bases, along the length and perimeter of which channel diffusers are evenly distributed, while the hyperboloid is located in the gap between a pair of coaxially oriented sections of the supply air duct, and the end bases of the hyperboloid are attached to the ends of the above sections located on the side of the gap, and the sections of the supply air duct are made cylindrical with round cross-sections. 2. An air distributor according to claim 1, characterized in that the outer diameters of the sections of the supply air duct are equal to the diameters of the end bases of the hyperboloid. 3. Air distributor according to one of paragraphs. 1-2, characterized in that the diffusers have circular cross-sections, and from the inside of each of the diffusers an internal screw thread is made for swirling the air flow, and the screw threads have the same directed helical generatrix lines. 4. Air distributor according to one of paragraphs. 1-3, characterized in that the axes of each pair of diffusers, symmetrically located relative to the plane of symmetry, intersecting the longitudinal axis of the single-sheet hyperboloid in the central part of the latter at right angles, intersect each other at an angle. 5. An air distributor containing an air duct and a honeycomb nozzle associated with it in the form of a body of revolution, including honeycomb diffusers with radially located side walls, and the ability to connect the nozzle to the air duct, and attach to the inner ends of a part of the honeycomb diffusers, characterized in that the nozzle is made in the form cylinder with open opposed end bases, along the length and perimeter of which honeycomb diffusers are evenly distributed, while the cylinder is installed to cover the pair, coaxially oriented sections of the supply air duct along the perimeters of the latter, and forming an end gap covered by a cylinder, and the sections of the supply air duct are made cylindrical, with round cross-sections, and the cylindrical sections of the air duct are connected to the inner ends of one part of the honeycomb diffusers with the possibility of mechanical contact, and the other part of the honeycomb diffusers is in communication with the end gap. 6. The air distributor according to claim 5, characterized in that grooves or grooves are made on the side of the contact with the cylinder on the side of contact with the cylinder, on the side of the inner ends of the honeycomb diffusers connected to the sections of the air ducts, cutouts are made to form between the latter , pointed protrusions of the type of teeth for fixing the position of the cylinder. 7. An air distributor containing an air duct and a honeycomb nozzle associated with it in the shape of a sphere, including honeycomb diffusers with radially located side walls, and the ability to connect the nozzle to the air duct, and attach to the inner ends of a part of the honeycomb diffusers, characterized in that the sphere is installed to cover the pair , coaxially oriented sections of the supply air duct along the perimeters of the latter, and forming an end gap covered by a sphere, and the air duct sections are connected to the inner ends of one part of the honeycomb diffusers, and the other part of the honeycomb diffusers is in communication with the end gap. 8. Air distributor containing an air duct and a honeycomb nozzle associated with it in the form of a sphere, including honeycomb diffusers with radially located side walls, and the ability to connect the nozzle to the air duct, and attach to the ends, characterized in that the sphere is made in the form of an insert installed in the gap between a pair of coaxially oriented sections of the supply air duct, while the ends of the said sections located on the side of the gap are connected to the insert with the possibility of mechanical contact with the latter and communication with a part of the honeycomb diffusers located on opposite sides of the insert, the sections being cylindrical with circular cross-sections, and the diameter of the insert exceeds the diameters of the sections.

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