RU2744666C1 - Supply air dispenser (sad) (options) - Google Patents

Abstract

FIELD: air conditioning.SUBSTANCE: invention relates to ventilation and air conditioning technology and can be used to distribute supply air to rooms for various purposes. The device for distributing supply air contains an air duct and an air outlet connected to it, located at an acute angle. The air duct is made in the form of an L-shaped element of the air duct network (1), containing a pair of sections (2) located at an angle to each other, and the air outlet element is made in the form of a rectilinear outlet (3), connected by its ends to the sections (2) with an option of communicating with the latter. The branch (3) is installed at an acute angle to each of the sections (2) with the formation of a triangular gap (4) located between the walls of the branch (3) and sections (2). In the wall of the branch (3), from the side of the triangular gap (4), an outlet (5) is made.EFFECT: technical result is to simplify the design of the device for distributing the supply air and ensure a higher intensity of the attenuation of the speed of the supply stream.16 cl, 17 dwg

Description

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

Known is a device for supplying supply air to a room, including a perforated air duct, one of the walls of which is made with holes located along its length, facing the inside of the air duct cavity, having holes located perpendicular to the direction of the air flow (USSR author's certificate for invention No. 352333, publ. . 09.21.1972, Bul. No. 28).

This air diffuser has a rather complex design.

As a prototype, a device for distributing supply air was chosen containing an air duct and connected with it branch pipes located to each other at an angle equal to 20 ° -60 ° (USSR author's certificate for invention No. 866357, publ. 09.23.1981, bull. No. 35 ).

Such a device for distributing supply air does not provide a sufficiently high rate of attenuation of the speed of the supply jets and has a rather complex design and low manufacturability.

The objective of the first embodiment of the invention is to provide such a device for distributing the supply air, which has a simpler design and lower material consumption while ensuring a higher attenuation rate of the supply jet velocity. Additional technical results also include an increase in the intensity of the damping of the speed of the supply jet.

This is achieved by the fact that, in contrast to the known technical solution for improving manufacturability by simplifying the design and reducing material consumption while ensuring a higher attenuation rate of the supply stream velocity, in a supply air distribution device containing an air duct and an air outlet connected to it, located at an acute angle , in this case, the air duct is made in the form of an L-shaped element of the air duct network containing a pair of sections located at an angle to each other, and the air outlet element is made in the form of a rectilinear outlet connected by its ends to the sections with the possibility of communicating with the latter, while the outlet is installed under an acute angle to each of the sections with the formation of a triangular gap located between the walls of the branch and the sections, and in the wall of the branch, from the side of the triangular gap, an outlet is made.

In addition, to increase the intensity of attenuation of the supply jet, the wall of the section is located on the side of the gap, in front of the outlet as a reflective screen, and the axis of the outlet intersects the said wall or the outlet is made round with an internal screw thread for swirling the air flow, and in the wall of the section , on the side of the gap, an additional outlet window is made, the axis of which is located at an obtuse angle to the axis of the outlet, and the outlet window is made round with an internal screw thread for swirling the air flow, and the helical generatrices of the lines of the internal screw threads of the outlet window and the outlet have the same direction for swirling air flows in opposite directions.

An increase in the intensity of attenuation of the supply jet is also facilitated by the fact that the branch is made, with a circular cross-section and corrugated with corrugations of a screw shape for swirling counter air flows in opposite directions or along the length of the branch, an internal screw thread is made for swirling counter air flows in opposite directions.

The essence of the claimed technical solution is illustrated by drawings: Fig. 1 shows a schematic representation of the device (section); in fig. 2 shows a schematic representation of a device with a corrugated air duct (general view).

The device contains an L-shaped element of the airway network 1, consisting of sections 2, a rectilinear outlet 3, a triangular-shaped gap 4, an outlet 5 and an outlet window 6. The device operates as follows. The air streams come from sections 2 of the L-shaped element of the air duct network 1 (in Fig. 1) into the outlet 3, in which the streams collide with each other, forming a resultant supply stream, which flows out through the outlet 5 into the manned room. The collision of flows in branch 3 leads to a decrease in kinetic energy, the losses of which contribute to an intensive attenuation of the speed of the supply (resultant) jet, providing a high intensity of the process of mixing the supply air with the room air. The outlet 5 is made on the side of the triangular gap 4, and the wall of the section 2 is located in front of the outlet 5 in the manner of a reflective screen, and the axis of the outlet 5 intersects the said wall. The wall of the section 2 with such an arrangement of the outlet 5 acts as a reflective screen for the resulting flow, providing a higher intensity of damping of the speed of the supply jet. Also, to increase the intensity of the damping of the speed of the supply jet, the outlet 5 is made round with an internal screw thread for swirling the air flow (not shown in the drawing), and in the wall of section 2, from the side of the gap 4, an additional outlet window 6 is made, the axis of which is located under obtuse angle to the axis of the outlet 5, and the outlet 6 is made round with an internal screw thread for swirling the air flow (not shown in the drawing), and the helical generatrices of the lines of the internal screw threads of the outlet window 6 and the outlet 5 have the same direction for swirling air flows in opposite directions. Also, an increase in the intensity of attenuation of the supply jet is facilitated by the fact that the outlet 3 is made with a circular cross-section and corrugated with corrugations of a screw shape for swirling counter air flows in opposite directions (in Fig. 2) or along the length of the outlet 3, an internal screw thread is made (not shown in the drawing) for swirling counter air flows in opposite directions. In branch 3, the flows are twisted and due to this they extinguish their kinetic energy. In addition, the flows are twisted in different directions and colliding, spending energy on impact and friction.

The task of the second embodiment of the invention is to provide such a device for distributing the supply air, which has a simpler and more technological design and at the same time provides a higher attenuation rate of the supply jet velocity. Additional technical results also include an increase in the intensity of the damping of the supply jet velocity.

This is achieved by the fact that, in contrast to the known technical solution to improve manufacturability by simplifying the design while ensuring a higher attenuation rate of the supply jet, in the supply air dispensing device containing an air duct, an air outlet element communicated with it, located at an angle of at least 20 °, while the air outlet element is made in the form of a U-shaped outlet, consisting of a pair of parallel inlet sections separated by a gap, connected to the wall of the air duct with the possibility of communicating with the latter and located between the inlet sections, an outlet section, in the wall of which, from the side of the gap, an outlet is made, to which the walls of the inlet sections are adjacent, while the inlet sections are located at an angle of 90 ° to the duct, and the wall of the latter is located in front of the outlet in the manner of a reflective screen, and the axis of the outlet intersects the said wall of the duct.

In addition, in order to improve manufacturability by reducing material consumption while ensuring a higher attenuation rate of the supply jet, the axis of the outlet intersects at right angles the wall of the air duct in which, on the side of the gap, an outlet window is additionally made coaxially with the outlet and / or the outlet section is made with a circular cross-section, and from the inside of the outlet section, along the length of the latter, an internal screw thread is made for swirling counter air flows in opposite directions.

An increase in manufacturability by reducing material consumption while ensuring a higher attenuation rate of the supply jet speed is facilitated by the fact that the outlet window and outlet are made round, with internal screw threads with equally directed helical generatrix lines for swirling air flows in opposite directions.

An increase in the intensity of the damping of the speed of the supply jet is achieved by the fact that the outlet section is made with a circular cross-section and corrugated, with screw-shaped corrugations for swirling counter air flows in opposite directions.

The essence of the claimed technical solution is illustrated by drawings: Fig. 3 shows a schematic representation of the device (section); in fig. 4 shows a schematic view of a device with a corrugated outlet section (general view).

The device contains a U-shaped branch 7, a gap 8, parallel inlet sections 9, an air duct 10, an outlet section 11, an outlet 12 and an outlet window 13. The device operates as follows. The air streams come from the air duct 10 to the parallel inlet sections 9 of the U-shaped branch 7 (in Fig. 3), separated by a gap 8, and then to the outlet section 11, in which they collide with each other, forming the resulting inlet stream that flows out through the outlet 12 into gap 8. The collision of flows leads to a decrease in kinetic energy, the losses of which contribute to an intensive attenuation of the speed of the supply (resultant) jet, providing a high intensity of the process of mixing the supply air with the room air. The wall of the duct 10, located on the side of the gap 8, serves as a reflective screen for the supply jet. The abutment of the walls of the inlet sections 9 to the outlet 12 increases the intensity of the supply jet attenuation due to the fact that the said walls function as reflective screens. In the wall of the air duct 10, on the side of the gap 8, an outlet window 13 is additionally made coaxially with the outlet opening 12 to increase the intensity of the damping of the speed of the supply jet. In this case, the collision of counter streams flowing from the outlet 12 and the outlet 13 leads to a decrease in kinetic energy, the losses of which contribute to an intensive attenuation of the speed of the supply (resultant) jet, providing a high intensity of the process of displacement of the supply air with the room air. When the outlet section 11 is made with a circular cross-section and an internal screw thread (not shown in the drawing) for swirling counter air flows in opposite directions, there is an increase in manufacturability due to a decrease in material consumption and the intensity of attenuation of the speed of the supply jet. Also, an increase in manufacturability due to a decrease in material consumption and the intensity of attenuation of the speed of the supply jet is facilitated by the fact that the outlet window 13 and outlet 12 are made round, with internal screw threads (not shown in the drawing), which have equally directed helical generatrix lines for swirling air flows in opposite directions. An increase in the intensity of the damping of the speed of the supply jet can be achieved due to the fact that the outlet section 11 is made with a circular cross-section and corrugated (in Fig. 4), with screw-shaped corrugations for swirling counter air flows in opposite directions. In the outlet section 11, the streams swirl and, due to this, they extinguish their kinetic energy. In addition, the flows are twisted in opposite directions and colliding, spend energy on impact and friction of the oncoming flows.

The objective of the third embodiment of the invention is to create such a device for distributing the supply air, which has a higher attenuation rate of the supply jet velocity while ensuring a higher manufacturability (convenience) of mounting the device in the supply air duct network.

This is achieved by the fact that, in contrast to the known technical solution for increasing the intensity of the damping of the speed of the supply stream while ensuring a higher ease of installation in the network of supply air ducts, in a device for distributing supply air containing an air duct with a pair of connected pipes located at an angle equal to at least 20 ° to each other, while the two nozzles are connected at an angle of 120 ° to each other for air inlet through the end inlet openings, and the air duct is made in the form of an outlet with an end outlet, and the outlet is in communication with a pair of nozzles for air inlet to form a Y-shaped ventilation tee, in which the outlet is located at an angle of 120 ° to each of the pair of air inlet pipes, and the outlet and air inlet pipes are cylindrical, with circular cross-sections, along the length of each of which internal screw threads for closing ducks of air flows, and the threads have the same directional helical generatrix lines or the tee is split, the inlet and outlet pipes are made with a rectangular cross-section, and the axes of the pipes are located in the same plane, and inside the tee there is a hollow perforated insert like an air duct flow divider, in the form cylinder with the possibility of mechanical contact of the cylindrical surface with the ribs formed by the intersection of the nozzles or in the form of a prism with a triangular cross-section or a cross-section in the shape of a Reuleaux triangle and the possibility of mechanical contact of the edges with the ribs formed by the intersection of the nozzles, or in the form of a prism with a cross-section bounded by a deltoid, with the possibility of mechanical contact of the concave faces with the ribs formed by the intersection of the nozzles.

The essence of the claimed technical solution is illustrated by a drawing: FIG. 5 shows a schematic representation of the device (section); in fig. 6 is a schematic view of a device with a cylinder-shaped insert (section); in fig. 7 is a schematic view of a device with a prism-shaped insert with a triangular cross-section (section); in fig. 8 is a schematic representation of a device with a prismatic insert with a deltoid-deltoid cross-section.

The device contains air inlets 14 with end inlets 15, an outlet 16 with an end outlet 17, a cylinder-shaped insert 18, ribs 19, a prism-shaped insert with a triangular cross-section 20, faces 21 and a prism-shaped insert with a cross-section a section limited by a deltoid 22.

The device works as follows.

Counter air flows through the end inlet openings 15 enter the air inlet pipes 14 (in Fig. 5). The air streams collide with each other at the outlet 16 and the resulting supply stream flows through the end outlet 17 into the room. Nozzles 14 and 16 are located at 120 ° angles to each other to form a Y-shaped ventilation tee, in which the outlet 16 is in communication with the air inlets 14. The collision of air currents at an angle of 120 ° to each other in the outlet 16 leads to a decrease kinetic energy. Losses of the kinetic energy of the resulting flow contribute to an intensive attenuation of the speed of the supply jet, providing a high intensity of the process of mixing the supply air with the room air. The execution of the outlet nozzle 16 and air inlet nozzles 14 of cylindrical shape with circular cross-sections and internal screw threads (for swirling air flows), which have the same directed helical generatrix lines (not shown in the drawing) also increases the intensity of the damping of the speed of the supply jet. To increase the intensity of the damping of the speed of the supply stream, the tee can be split, the inlet 14 and outlet 16 pipes are made with rectangular cross-sections, and the axes of the pipes 14 and 16 are located in the same plane, and inside the tee there is a hollow perforated insert similar to the flow divider, in the shape of a cylinder 18 (in Fig. 6) with the possibility of mechanical contact of the cylindrical surface with the ribs 19 formed by the intersection of the pipes 14 and 16 or in the form of a prism (in Fig. 7) with a triangular cross-section 20 (a prism with a cross-section in the shape of a Reuleaux triangle not shown in the drawing) and the possibility of mechanical contact of the faces 21 with the ribs 19 formed by the intersection of the pipes 14 and 16, or in the form of a prism with a cross-section limited by the deltoid 22 (in FIG. 8) with the possibility of mechanical contact of the concave faces 21 with the ribs 19 formed by the intersection nozzles 14 and 16. Opposite walls of the outlet nozzle 16 perform the function and a reflective screen for air flows emanating from the listed hollow perforated inserts, which act as flow dividers, providing a higher attenuation rate of the supply jet velocity. The symmetrical arrangement of nozzles 14 and 16 makes it possible to increase the convenience of installing the device in the supply air duct network.

The objective of the fourth embodiment of the invention is to provide such a device for distributing the supply air, which has a higher adaptability and simpler design while ensuring a higher attenuation rate of the supply jet velocity. Additional technical results also include expanding the functionality in terms of air flow control, and increasing manufacturability by reducing material consumption while ensuring a higher attenuation rate of the supply jet speed.

This is achieved by the fact that, in contrast to the known technical solution to improve manufacturability by simplifying the design while ensuring a higher attenuation rate of the supply jet velocity, in the supply air dispensing device containing the air duct, a duct connected to it and an air outlet element located at an angle equal to not less than 20 ° to each other, a device for distributing supply air containing an air duct and an outlet connected to it, and an air outlet element located at an angle of at least 20 ° to each other, while the outlet is made J-shaped or L-shaped, consisting from separated by a gap and communicated with each other, parallel inlet and outlet sections, while the inlet section is located perpendicular to the air duct and communicated with the latter, and has a greater length, and the outlet section has a shorter length and an end outlet, and the air outlet element is made in the form located in the wall of the exhaust duct windows, the axis of which is located to the axis of the end outlet at an angle of 180 °, while the outlet section is located with the formation of an air gap between the end of the outlet section and the air duct.

In addition, to expand the functionality in terms of air flow control, a guide mounting hole is made in the air duct for the inlet section, which is installed in the guide hole with the possibility of axial movement transversely to the air flow in the air duct and fixing the position with the provision of mechanical contact of the end of the outlet section with the air duct and overlapping the outlet window, and the outlet with cutting off the air flows through the latter.

Improving manufacturability by reducing material consumption while ensuring a higher attenuation rate of the supply jet speed is achieved by the fact that the outlet window and outlet are made round, with internal screw threads with equally directed helical generatrix lines for swirling air flows in opposite directions.

The essence of the claimed technical solution is illustrated by drawings: Fig. 9 shows a schematic view of the device (section); in fig. 10 is a schematic view of a variable air flow device (section).

The device includes a J-shaped or L-shaped branch 23, a gap 24, an inlet 25, an outlet 26, an air duct 27, an end outlet 28, an outlet 29, an air gap 30 and a guide mounting hole 31. The device operates as follows. The air flow enters from the air duct 27 into the inlet section 25 of the L-shaped branch 23 (the J-shaped branch is not shown in the drawing) and then into the outlet section 26 (in Fig. 9). Through the coaxial end outlet 28 and the outlet window 29, made in the wall of the air duct 27, counter currents flow towards each other and collide, merging into the resulting supply stream, which enters the serviced room. The end outlet 28 and the outlet window 29 are separated by an air gap 30. The collision of the flows leads to a decrease in kinetic energy, the losses of which contribute to an intensive attenuation of the speed of the resulting supply jet, providing a high intensity of the process of mixing the supply air with the room air. The maximum intensity of the velocity decay of the resulting inflow jet is observed when the axes of the end outlet 28 and outlet 29 are located at an angle of 180 ° to each other. The air outlet from the outlet 28 (in Fig. 10) can be closed if a guide mounting hole 31 is made in the air duct 27, in which the inlet section 25 is installed with the possibility of axial movement transverse to the air flow in the air duct 27 and fixing the position with providing mechanical contact of the end of the outlet section 26 with the air duct 27 and overlapping the outlet window 29 and outlet 28 with cutting off the air flows through the latter. To increase the intensity of the damping of the speed of the supply jet, the outlet window 29 and the outlet opening 28 are made round, with internal screw threads (not shown in the drawing) and equally directed by helical generatrix lines for swirling air flows in opposite directions. The collision of two counter streams, swirling in opposite directions, and outflowing from the outlet 28 and outlet 29 leads to a damping of the flow velocity and a decrease in kinetic energy, the losses of which contribute to an intensive attenuation of the velocity of the supply (resultant) jet, providing a high intensity of the process of mixing the supply air with room air.

The task of the fifth embodiment of the invention is to provide such a device for distributing the supply air, which has a simpler structure and technological structure, and a lower material consumption, while providing a higher rate of attenuation of the speed of the supply jet.

This is achieved by the fact that, in contrast to the known technical solution, in order to improve manufacturability by simplifying the design and reducing material consumption while ensuring a higher attenuation rate of the supply stream velocity, in a supply air distribution device containing an air duct with a pair of air outlet elements connected to it with the possibility of placing at an angle of at least 20 ° to each other, while the air duct is made in the form of a U-shaped or U-shaped element of the air duct network and includes a pair, separated by a gap, parallel sections and an intermediate connecting section, and the air outlet elements are made in the form of a pair of coaxial outlet holes located on the side of the gap, in opposite walls of parallel sections and essentially with the formation of an angle of 180 ° between the axes of the outlet openings, while the wall of the connecting section adjoins the outlet openings or the air duct is made in the form of an element of the air duct network in the form of a polo th open one and a half, and the air outlet elements are in the form of a pair of outlet openings located in the wall of one and a half, from the side of the gap, and essentially on the concave side of one and a half, and the axes of the outlet openings are located at an angle equal to 20 ° -170 ° to each other.

Also, increasing manufacturability by simplifying the design and reducing material consumption while ensuring a higher attenuation rate of the supply jet speed is achieved by the fact that the outlet holes are made round with internal screw threads, which have equally directed helical generatrices for swirling air flows in opposite directions.

The essence of the claimed technical solution is illustrated by drawings: Fig. 11 is a schematic view of a device for distributing supply air with a U-shaped element of the air duct network (section); in fig. 12 is a schematic view of a supply air distribution device with a U-shaped element of the air duct network (section); in fig. 13 shows a schematic view of a device for distributing supply air with an element of the air duct network in the form of an open one and a half (section)

The device contains a U-shaped element of the airway network or a U-shaped element of the airway network 32, separated by a gap 33, parallel outlet sections 34, an intermediate connecting section 35, outlets 36, a hollow open one and a half 37 with a pair of outlets 38. The device operates as follows. The air streams come from parallel outlet sections 34 of the U-shaped or U-shaped element of the air duct network 32 (in Fig. 11 and Fig. 12) through coaxial outlet openings 36 into a gap 33 located between the outlet sections 34, where the streams collide with each other. another, merging into the resulting supply stream, which enters the serviced room. The collision of flows leads to a decrease in kinetic energy, the losses of which contribute to an intensive attenuation of the speed of the supply jet, providing a high intensity of the process of mixing the supply air with the room air. The abutment of the wall of the connecting section 35 to the outlet openings 36 increases the intensity of the attenuation of the resulting supply jet due to the fact that the said wall serves as a reflective screen. The maximum intensity of the decay of the speed of the supply jet is observed when the axes of the outlet holes 36 are located at an angle of 180 ° to each other. Also, the element of the air duct network can be made in the form of a hollow open one and a half 37 (in Fig. 13) with a pair of outlet openings 38, which are located on the concave side of one and a half 37, while the axes of the outlet openings 38 are located to each other at an angle equal to 20 ° -170 °. The collision of flows leads to a decrease in kinetic energy, the losses of which contribute to an intensive attenuation of the speed of the supply jet, providing a high intensity of the process of mixing the supply air with the room air. Outlets 36 (in Figs. 11 and 12) and 38 (in Fig. 13) can be made circular with internal screw threads (not shown in the drawings), which have the same directed helical generatrix lines for swirling air flows in opposite directions. This design is intended to increase the intensity of the damping of the supply jet, which is achieved when two opposing air currents swirl in opposite directions and their subsequent collision.

The task of the sixth embodiment of the invention is to provide such a device for distributing supply air, which has a higher adaptability due to a simpler design, lower material consumption and a smaller overall size, and at the same time provides a high intensity of the speed of the supply stream damping. Additional technical results include an increase in the intensity of damping of the speed of the supply jet.

This is achieved by the fact that, in contrast to the known technical solution for simplifying the design, reducing material consumption and reducing the overall size while ensuring a high attenuation rate of the supply jet speed, in a supply air distribution device containing a branch pipe and the possibility of supplying air, and placing it at an angle, when In this case, the branch pipe is cylindrical, with a circular cross-section and an end inlet for air supply, and the branch pipe has a flow section and wall thickness variable along the length with the formation of a conical diffuser channel, and from the end of the branch pipe opposite the inlet and along the perimeter of the pipe, longitudinal cutouts are made to form depressions and projections alternating with depressions, and the projections are bent towards the longitudinal axis of the pipe with the formation of reflective screens with a concave surface, from the side of the air flow, and oriented at an angle to the longitudinal axis of the pipe.

In addition, an increase in the intensity of the damping of the supply jet is achieved by the fact that a flow divider in the form of an air-conducting hollow sphere with a perforated wall is installed in the channel, while the sphere is located with the provision of mechanical contact along the perimeter with the wall of the branch pipe and the formation of a gap between the screens and the wall of the sphere.

The essence of the claimed technical solution is illustrated by a drawing: FIG. 14 is a schematic view of the device (section); in fig. 15 is a schematic representation of a longitudinal cut-out branch pipe (view from the side of the end outlet); in fig. 16 shows a schematic view of a hollow perforated sphere in a branch pipe (section).

The device comprises a branch pipe 39, an end inlet opening 40, a conical diffuser channel 41, depressions 42, reflective screens 43, an outlet 44, a hollow perforated sphere 45 and a gap 46 located between the sphere 45 and the reflective screens 43.

The device works as follows.

The air flow enters the branch pipe 39 through the inlet 40 from the supply duct network (in Fig. 14) and then through the outlet 44 the supply stream flows out into the serviced object. Execution from the end of the branch pipe 39 with an outlet 44 and along the perimeter of the branch pipe 39 of longitudinal cuts, forming depressions 42 and protrusions (alternating with depressions 42), and bending of the protrusions towards the longitudinal axis of the branch pipe 39 with the formation of reflective screens 43 with a concave, from the side of the air flow , surface, and oriented at an angle to the axis of the branch pipe 39 (in Fig. 15) creates a loss of kinetic energy by the flow, which increases the intensity of the decay of the speed of the supply jet. Also, an increase in the intensity of attenuation of the speed of the supply jet is facilitated by the fact that the channel of the branch pipe 39 is made with a variable flow section along the length, and the diameter of the channel increases towards the outlet 44 with the formation of a conical diffuser channel 41 (not shown in the drawing). To increase the intensity of the damping of the velocity of the supply stream, a flow divider in the form of an air-conducting hollow sphere 45 with a perforated wall (in Fig. 16) is installed in the branch pipe 39, while the sphere 45 is located with the provision of mechanical contact along the perimeter with the wall of the branch pipe 39 and the formation of a gap 46 between the screens 43 and the wall of the sphere 45. The air flow in the branch pipe 39 is cut by the sphere 45 into separate jets, which collide with each other inside the sphere 45. The collision of the jets at an angle to each other leads to a decrease in the kinetic energy of the resulting flow, which is formed at the exit from the sphere 45, in the gap 46, which contributes to an intensive attenuation of the speed of the supply jet, providing a high intensity of the process of mixing the supply air with the room air. At the exit from the sphere 45, the jets collide with the wall of the outlet nozzle 39, which also serves as a reflective screen for the jets, while the kinetic energy of the jets also decreases.

The objective of the seventh embodiment of the invention is to provide such a device for distributing the supply air, which has a higher attenuation rate of the supply jet velocity.

This is achieved by the fact that, in contrast to the known technical solution for increasing the intensity of the damping of the speed of the supply stream, in the device for distributing the supply air containing an air duct with a pair of connected nozzles located at an angle equal to at least 20 ° to each other, while two pipes are coaxially connected at the ends at an angle of 180 ° to each other to form a straight air duct with opposite end inlets, and the air duct is made in the form of an outlet with an end outlet, and the outlet is in communication with the air duct, while the latter and the outlet are made cylindrical with circular cross-sections, and along the length of the air duct and the outlet pipe, internal screw threads are made for swirling air flows or the pipe is made with a flow section and wall thickness variable along the length to form a conical diffuser channel, while at the end of the pipe and along the perimeter of the latter longitudinal cuts are made with the formation of depressions and protrusions alternating with depressions, and the protrusions are bent towards the longitudinal axis of the branch pipe to form reflective screens with concave surfaces from the side of the air flow and oriented at an angle to the longitudinal axis of the branch pipe.

The essence of the claimed technical solution is illustrated by a drawing: FIG. 17 shows a schematic view of the device (section).

The device contains an air duct 48 with opposed end inlets 49, an outlet 50 with an end outlet 51, depressions 52, baffles 53, a perforated sphere 54 and a gap 55.

The device works as follows.

Opposite air flows enter the air duct 48 from the supply air duct network through opposed end inlets 49 (in Fig. 17) and twist in opposite directions due to the internal screw thread (not shown in the drawing), while the opposing air flows collide with each other, forming the resulting jet, which enters the outlet pipe 50. The collision of the flows leads to a decrease in kinetic energy, the loss of which contributes to the intensive attenuation of the speed of the supply jet. The maximum intensity of the velocity decay of the resulting jet is observed in the rectilinear air duct 48. Further, the resulting jet enters the outlet 50 and flows out into the room through the end outlet 51. Due to the internal screw thread in the outlet pipe 50 (not shown in the drawing), the resulting jet swirls, providing a high intensity of the process of mixing the supply air with the room air. To increase the intensity of attenuation of the supply jet, the branch pipe 50 can be made with a flow section and wall thickness variable along the length to form a conical diffuser channel. Also, to increase the intensity of the damping of the speed of the supply stream from the end of the branch pipe 50 and along the perimeter of the latter, longitudinal cuts can be made with the formation of depressions 52 and protrusions alternating with depressions 52, while the protrusions are bent towards the longitudinal axis of the nozzle 50 with the formation of reflective screens 53 s concave, from the side of the air flow, surfaces, and oriented at an angle to the longitudinal axis of the branch pipe 50. Also, to increase the intensity of the damping of the velocity of the supply stream, a flow divider in the form of an air-conducting hollow sphere 54 with a perforated wall can be installed in the branch pipe, while the sphere 54 is located ensuring mechanical contact along the perimeter with the wall of the branch pipe 50 and the formation of a gap 55 between the screens 53 and the wall of the sphere 54.

Claims (16)

1. A device for distributing supply air, containing an air duct and an air outlet connected with it, located at an acute angle, characterized in that the air duct is made in the form of an L-shaped element of the air duct network containing a pair of sections located at an angle to each other, and the air outlet element is made in the form of a rectilinear outlet, connected by its ends to the sections with the possibility of communication with the latter, while the outlet is installed at an acute angle to each of the sections with the formation of a triangular gap located between the walls of the outlet and sections, and in the wall of the outlet, from the side of the triangular gap , the outlet is made. 2. The device according to claim. 1, characterized in that the wall of the section is located on the side of the gap, in front of the outlet as a reflective screen, and the axis of the outlet intersects the said wall or the outlet is made round with an internal screw thread for swirling the air flow, and in the wall of the section, from the side of the gap, an additional outlet window is made, the axis of which is located at an obtuse angle to the axis of the outlet, and the outlet window is made round with an internal screw thread for swirling the air flow, and the helical generatrices of the lines of the internal screw threads of the outlet window and the outlet have the same direction for swirling air flows in opposite directions. 3. Device according to any one of paragraphs. 1-2, characterized in that the branch is made with a circular cross-section and corrugated with corrugations of a screw shape for swirling counter air flows in opposite directions or along the length of the branch, an internal screw thread is made for swirling counter air flows in opposite directions. 4. A device for distributing supply air, containing an air duct, an air outlet element connected to it, located at an angle of at least 20 °, characterized in that the air outlet element is made in the form of a U-shaped outlet, consisting of a pair of parallel inlet sections separated by a gap, connected to the wall of the duct with the possibility of communicating with the latter and located between the inlet sections of the outlet section, in the wall of which, on the side of the gap, an outlet is made, to which the walls of the inlet sections adjoin, while the inlet sections are located at an angle of 90 ° to the duct, and the wall of the latter located in front of the outlet in the manner of a reflective screen, and the axis of the outlet intersects the above-mentioned wall of the duct. 5. The device according to claim 4, characterized in that the axis of the outlet intersects at right angles the wall of the air duct, in which, from the side of the gap, the outlet window is additionally made coaxially with the outlet and / or the outlet section is made with a circular cross-section, and from the inside of the outlet section, along the length of the latter, an internal screw thread is made for swirling counter air flows in opposite directions. 6. The device according to claim. 5, characterized in that the outlet window and outlet are made round, with internal screw threads with equally directed helical generatrix lines for swirling air flows in opposite directions. 7. The device according to claim. 4, characterized in that the outlet section is made with a circular cross-section and corrugated, with screw-shaped corrugations for swirling counter air flows in opposite directions. 8. A device for distributing supply air, containing an air duct with a pair of nozzles connected with it, located at an angle equal to not less than 20 ° to each other, characterized in that the two nozzles are connected at an angle equal to 120 ° to each other for air inlet through end inlets, and the air duct is made in the form of an outlet with an end outlet, and the outlet is in communication with a pair of air inlets to form a Y-shaped ventilation tee, in which the outlet is located at an angle equal to 120 ° to each of the pair of nozzles for air inlet, and the outlet and air inlet pipes are cylindrical, with circular cross-sections, along the length of each of which there are internal screw threads for swirling air flows, and the threads have similarly directed screw generatrices or the tee is split, inlet and outlet pipes made with rectangular cross-sections with the axes of the nozzles located in the same plane, and inside the tee there is a hollow perforated insert in the form of an air duct flow divider, in the form of a cylinder with the possibility of mechanical contact of the cylindrical surface with the ribs formed by the intersection of the nozzles or in the form of a prism with a triangular cross-section or a cross-section in the shape of a Reuleaux triangle and the possibility of mechanical contact of the edges with the edges formed by the intersection of the nozzles, or in the form of a prism with a cross-section bounded by a deltoid, with the possibility of mechanical contact of the edges with the ribs formed by the intersection of the nozzles. 9. A device for distributing supply air, containing an air duct, a duct connected to it and an air outlet element located at an angle of at least 20 ° to each other, characterized in that the outlet is made J-shaped or L-shaped, consisting of separated by a gap and communicated with each other, parallel inlet and outlet sections, while the inlet section is located perpendicular to the air duct and communicated with the latter, and has a greater length, and the outlet section has a shorter length and an end outlet, and the air outlet element is made in the form of an air duct located in the wall , the outlet window, the axis of which is located to the axis of the end outlet at an angle of 180 °, while the outlet section is located with the formation of an air gap between the end of the outlet section and the air duct. 10. The device according to claim 9, characterized in that a guide mounting hole is made in the air duct for the inlet section, which is installed in the guide hole with the possibility of axial movement transversely to the air flow in the duct and fixing the position with the provision of mechanical contact of the end of the outlet section with the air duct and overlap an outlet window, and an outlet with a cutoff of air flows through the latter. 11. Device according to any one of paragraphs. 9-10, characterized in that the outlet window and outlet are made round, with internal screw threads with equally directed helical generatrix lines for swirling air flows in opposite directions. 12. A device for distributing supply air, containing an air duct with a pair of air outlet elements communicated with it, located at an angle equal to at least 20 ° to each other, characterized in that the air duct is made in the form of a U-shaped or U-shaped element of the air duct network and includes a pair, separated by a gap, parallel sections and an intermediate connecting section, and the air outlet elements are made in the form of a pair of coaxial outlet holes located on the side of the gap, in the opposite walls of the parallel sections and essentially with the formation of an angle of 180 ° between the axes of the outlet holes, when in this case, the wall of the connecting section is adjacent to the outlet openings, or the air duct is made in the form of an element of the air duct network in the form of a hollow open one and a half, and the air outlet elements are in the form of a pair of outlet openings located in the wall one and a half, from the side of the gap, and essentially from the concave side of one and a half , and the axes of the outlet openings are located at a scrap equal to 20 ° -170 ° to each other. 13. The device according to claim 12, characterized in that the outlet openings are made round with internal screw threads, which have the same directed helical generatrix lines for swirling air flows in opposite directions. 14. A device for distributing supply air, containing a branch pipe with the possibility of supplying air and placing it at an angle, characterized in that the branch pipe is cylindrical, with a circular cross-section and an end inlet for air supply, and the branch pipe has a flow section and wall thickness that are variable along the length with the formation of a conical diffuser channel, and longitudinal cuts are made from the end of the branch pipe opposite to the inlet opening and along the perimeter of the branch pipe with the formation of depressions and protrusions alternating with depressions, and the protrusions are bent towards the longitudinal axis of the branch pipe with the formation of reflective screens with concave, from the side of the air flow, surface, and oriented at an angle to the longitudinal axis of the branch pipe. 15. The device according to claim. 14, characterized in that a flow divider in the form of an air-conducting hollow sphere with a perforated wall is installed in the channel, and the sphere is located to provide mechanical contact along the perimeter with the wall of the pipe and the formation of a gap between the screens and the wall of the sphere. 16. A device for distributing supply air, containing an air duct with a pair of connected pipes, located at an angle of at least 20 ° to each other, characterized in that the two pipes are coaxially connected at the ends at an angle of 180 ° to each other to form a straight air duct with opposite end inlets, and the air duct is made in the form of an outlet with an end outlet, and the outlet is connected to the air duct, while the latter and the outlet are cylindrical with circular cross-sections, and along the length of the air duct and the outlet there are internal screw cuts for swirling air flows or the branch pipe is made with a flow section and wall thickness variable along the length to form a conical diffuser channel, and longitudinal cuts are made from the end of the branch pipe and along the perimeter of the latter with the formation of depressions and protrusions alternating with depressions, while the protrusions are bent to the side P the rod axis of the branch pipe with the formation of reflective screens with surfaces concave, from the side of the air flow, and oriented at an angle to the longitudinal axis of the branch pipe, and a flow divider in the form of an air-conducting hollow sphere with a perforated wall is installed in the branch pipe, while the sphere is located with the provision of mechanical contact along perimeter with the wall of the pipe and the formation of a gap between the screens and the wall of the sphere.

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