RU2737859C1 - Air distributor (vr) (versions) - Google Patents

Abstract

FIELD: ventilation and air conditioning.SUBSTANCE: invention discloses versions of air distributors having simple design while providing high rate of attenuation of inlet jets and high uniformity of air distribution. According to one of versions, proposed is air distributor, comprising two rectilinear supply ducts, in the wall of each of which is located along the outlet, separated by a gap and oriented opposite to each other, and possibility of arrangement of a shield connected to the outlet opening. Boxes are coaxially connected to each other at ends to form straight-line air duct (1), comprising a pair of opposed end inlet openings (2) and a pair of opposite flat walls (3), in which pair of opposed outlet openings (5) separated by gap (4) is located, each of which is made cut, with an edge bent relative to plane of flat wall on outer side of air duct (1) to form abutting on outlet (5) flat reflective shield (6), oriented at right angle to air duct axis (1) or at acute angles to air duct (1) axes and outlet (5) with partial overlapping of the latter.EFFECT: invention can be used for distribution of supply air to premises for various purposes.33 cl, 18 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 an air distributor containing a housing divided by longitudinal partitions into a middle and two end boxes with inlet end pipes and outlet longitudinal slots, in which the inlet pipes of the end ducts are located at the end opposite to the inlet pipe of the middle box (USSR author's certificate for invention No. 987319, publ. . 07.01.1983, Bulletin No. 1).

This air diffuser has a rather complex design.

As a prototype, an air distributor was selected containing two parallel supply ducts with outlets and a screen, and the ducts are placed with a gap between them, the outlets are made in oppositely located walls of the boxes, and the screen is in the form of a semi-cylindrical flap covering each pair of opposite holes located in the gap between the boxes (USSR author's certificate for invention No. 1153205, publ. 04/30/1985, Bul. No. 16).

Such a device for distributing supply air does not provide a sufficiently high rate of attenuation of the speed of supply jets, uniformity of air distribution and does not meet the requirements of high manufacturability.

The objective of the first embodiment of the invention is to provide such an air distributor that has a simpler design and at the same time provides a higher attenuation rate of the speed of the supply jets and a higher uniformity of air distribution.

This is achieved by the fact that, in contrast to the known technical solution, in an air distributor containing two rectilinear supply ducts, in the wall of each of which is located along the outlet, separated by a gap and oriented opposite to each other, and the possibility of placing a shield associated with the outlet, in this case, the ducts are coaxially connected to each other at the ends to form a rectilinear air duct including a pair of opposed end inlet openings and a pair of opposite flat walls, in which a pair of gap-separated opposed outlet openings are located, each of which is cut through, with an edge bent relative plane of the flat wall to the outer side of the air duct with the formation of a flat baffle adjacent to the outlet, oriented at right angles to the axis of the air duct or at sharp angles to the axes of the air duct and outlet with partial overlap of the latter.

The essence of the claimed technical solution is illustrated by a drawing: FIG. 1 shows a schematic view of an air distributor (section).

The device contains a straight air duct 1 with a pair of opposed end inlet holes 2, a pair of opposed flat walls 3, a gap 4, a pair of opposite outlet holes 5 and a flat baffle 6.

The device works as follows.

Counter air flows into the air duct 1 enter through the end inlet holes 2 (in Fig. 1), in which they collide with each other, forming two resulting jets flowing out through the outlet holes 5, separated by a gap 4, into the serviced room. Outlet holes 5 are made in opposite walls 3 of the air duct 1 in the form of cuts with edges bent relative to the planes of flat walls 3 to the outer side of the air duct 1, with the formation of flat baffles 6 adjacent to the outlet openings, each of which is oriented at right angles to the axis duct 1 or at acute angles to the axes of the duct 1 and the corresponding outlet 5 with partial overlap of the latter. The collision of flows in the duct 1 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 direction of the resulting jet, formed after the collision of the opposing jets, when the air leaves the outlet 5 alternately changes due to the fact that in the air duct 1, one counter flow is alternately compressed by another, which generates a breakdown of vortex structures, leading to the appearance of a stable self-oscillating resultant flow directed alternately in different directions from the axis of the outlet 5. Therefore, the supply jet periodically collides with the baffle 6 and loses kinetic energy, which contributes to an increase in the intensity of the attenuation of the speed of the supply jet.

The task of the second embodiment of the invention is to create such an air distributor, which has a simpler design and smaller overall dimensions, and at the same time provides a higher attenuation rate of the supply (resultant) jet velocity and a higher uniformity of air distribution.

An additional technical result is a higher rate of attenuation of the speed of the supply (resulting) jet.

This is achieved by the fact that, in contrast to the known technical solution, in an air distributor containing a supply box with an outlet located in the wall, a shielding element with a curved surface associated with the gap and the possibility of placing an outlet covered by the shielding element with the formation of a pair of opposed outlet openings, in this case, the element is made in the form of a hollow open one and a half with a pair, separated by a gap, end inlet holes and an outlet one and a half located in the wall, while the box is made in the form of an air duct with a flat wall located on the side of the gap, in which the outlet is located, and the one and a half is connected the ends to the flat wall with the possibility of communicating with the air duct by means of the end inlet openings, and the outlet one and a half is located on the side of the gap, opposite to the air duct outlet.

Also, an increase in the intensity of attenuation of the speed of the supply (resultant) jet is achieved by the fact that one and a half is made corrugated, with screw-shaped corrugations for swirling counter air flows in opposite directions.

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

The device contains a hollow open one and a half 7 with a pair, separated by a gap 8, end inlet holes 9, an outlet 10 in the wall of one and a half 7, an air duct 11 with a flat wall 12 located on the side of the gap 8 and an outlet 13 located in the wall 12.

The device works as follows.

The air flows come from the supply air duct 11 through the end inlet openings 9 to one and a half 7, in which they collide (in Fig. 2), losing kinetic energy, and then the jet through the outlet 10 flows into the gap 8. The direction of the jet formed after the collision air flows alternately changes due to the fact that in one and a half 7 there is an alternating compression of one counter flow by another, which generates a breakdown of vortex structures, leading to the emergence of a stable self-oscillating flow directed alternately in different directions from the axis of the outlet 10. air from the outlet 10 will quickly decay, losing its initial kinetic energy, and the intensity of the jet velocity decay will increase. In the flat wall 12 of the air duct 11, located on the side of the gap 8, an opposed outlet 13 is located coaxially with the outlet 10. The jets emanating from the outlet openings 13 and 10 collide and merge, forming a resultant supply jet, losing kinetic energy, which further increases the intensity of the attenuation of the supply (resulting) jet. To increase the intensity of attenuation of the supply (resultant) jet, one and a half 7 can be made corrugated, with screw-shaped corrugations for swirling counter air flows in opposite directions.

The objective of the third embodiment of the invention is to provide an air distributor that has wider functionality in terms of air flow control while ensuring a higher attenuation rate of the supply jets and higher uniformity of air distribution.

Additional technical results also include an increase in the intensity of damping of the speed of supply jets and operational reliability.

This is achieved by the fact that, in contrast to the known technical solution, in an air distributor containing, separated by a gap, two rectilinear supply ducts, in each of which there is a shielding element connected with the gap with a cylindrical surface and the possibility of placing, covered by the latter, pairs of opposite outlet openings, while the boxes are made in the form of coaxially oriented rectilinear cylindrical pipes with circular cross-sections and the same outer diameters, with the formation of an end gap between them, while a pair of opposed openings for air outlet are located at the ends of the pipes, on the side of the end gap, and a pair end opposed openings for air inlet are located at opposite ends of the branch pipes, and the shielding element is made in the form of an adjusting cylindrical nozzle with a circular cross-section and an internal screw thread along the length of the nozzle, while along the perimeter of the nozzle a pair of opposed outlet openings is made, and along the length of each of the nozzles an external screw thread is made with the same direction of the helical generatrix lines, and the nozzle has a thread with a helical generatrix line in the same direction as the helical generatrix lines in the threads of the nozzles, and the nozzle is installed on the nozzles with overlapping the end gap, ensuring communication of the outlet openings with the gap and forming a movable threaded connection, in which the nozzle can move along the nozzles when turning, and overlap the outlet openings with one of the nozzles to control the air flow rate.

In addition, to increase the intensity of damping of the speed of the supply jets, the outlets are made round with internal screw threads for swirling air flows or diffuser.

Also, to increase the intensity of damping of the speed of the supply jets, along the length of each of the nozzles, internal screw threads are made with the same direction of the helical generatrices for swirling counter air flows in opposite directions.

In addition, in order to increase the intensity of damping of the speed of the supply jets, the helical generatrix lines of the internal screw threads of the branch pipes have the same direction as the direction of the helical generatrix line of the nozzle thread.

To increase operational reliability, the longitudinal axes of the branch pipes are oriented horizontally.

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

The device contains coaxially oriented rectilinear cylindrical nozzles 14, end gap 15, a pair of opposed air outlet openings 16, a pair of opposed air inlet openings 17, an adjusting cylindrical nozzle 18 and a pair of opposed outlet openings 19.

The device works as follows.

Air flows come from the network of supply air ducts through the end opposed openings for air inlet 17 into the branch pipes 14 (in Fig. 3) and then through the opposed openings for air outlet 16 counter air flows enter the gap 15, in which these flows collide with each other. The gap 15 is closed by an adjusting nozzle 18 with a pair of opposed outlet openings 19. Air flows, when colliding with each other, lose kinetic energy, and the inflow (resultant) jets flow into the room through the outlet openings 19 in opposite directions. In this case, each of the inflow (resultant) jets formed when air leaves the corresponding outlet 19 will quickly decay, losing its initial kinetic energy. The nozzle 18 forms a movable threaded connection with the nozzles 14 (not shown in the drawing), in which the nozzle 18 can move along the nozzles 14 when turning and overlap the outlet openings 19 with one of the nozzles 14 to control the air flow rate. To increase the intensity of damping of the speed of the supply jets, the outlet holes 19 can be made round with internal screw threads (not shown in the drawing) for swirling air flows or diffuser (not shown in the drawing), also along the length of each of the nozzles 14, internal screw threads can be made (not shown in the drawing) with the same direction of the helical generatrix lines for swirling counter air flows in opposite directions, and the helical generatrix lines of the internal screw threads of the branch pipes 14 have the same direction with the direction of the helical generatrix line of the thread of the nozzle 18. The increase in operational reliability is achieved by the fact that the longitudinal the axes of the branch pipes 14 are located horizontally.

The objective of the fourth embodiment of the invention is to create an air distributor that has broader functionality in terms of stabilizing the flow rate of the supply jets at variable air flow rates and in terms of visual indication of the air flow rate, while ensuring a higher attenuation rate of the supply jets speed with a higher uniformity of air distribution ...

Additional technical results also include an increase in the intensity of damping of the speed of supply jets and operational reliability.

This is achieved by the fact that, in contrast to the known technical solution, in an air distributor containing, separated by a gap, two rectilinear supply ducts, in each of which there is a through-hole, a shielding element connected with the gap and the possibility of placing outlet openings covered by the element, while ducts are made in the form of coaxially oriented branch pipes with the formation of an end gap between them, while a pair of opposed openings for air outlet are located at the ends of the branch pipes, from the side of the end gap, and a pair of end opposite openings for air inlet are located at opposite ends of the branch pipes, and the shielding element made in the form of a nozzle covering the outer perimeters with overlapping the end gap, while the nozzle is made of an elastic material with a porous structure and open air-permeable pores communicated with the gap to form outlet openings, and the nozzle is installed on the nozzle ah with the possibility of elastically deformable contact with the latter.

In addition, to increase the rate of attenuation of the speed of the supply jets, the nozzles are cylindrical with circular cross-sections, and along the length of each of the nozzles, internal screw threads are made with equally directed helical generatrix lines for swirling counter air flows in opposite directions.

Also, to increase operational reliability, intersecting grooves or grooves with the formation of mesh corrugation are made on the nozzles, on the side of contact with the nozzle, and / or the longitudinal axes of the nozzles are oriented horizontally.

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

The device contains coaxially oriented straight pipes 20, end gap 21, a pair of opposed openings for air outlet 22, a pair of opposite end openings for air inlet 23, elastic nozzles 24 with outlet openings 25.

The device works as follows.

Air flows come from the network of supply air ducts through the end opposed openings for air inlet 23 into the branch pipes 20 (in Fig. 4) and then through the opposed openings for air outlet 22 counter air flows enter the gap 21, in which these flows collide with each other. The gap 21 is closed by an elastic nozzle 24 with outlet openings 25. Air flows, when colliding with each other, lose kinetic energy, and the supply (resultant) jets flow into the room through the outlet openings 25. In this case, each of the supply (resultant) jets formed when the air leaves from the corresponding outlet 25, will rapidly decay, losing its initial kinetic energy. The nozzle 24 is made of an elastic material with a porous structure and open air-permeable pores communicated with the gap 21. The open air-permeable pores form the outlet openings 25, and the nozzle 24 is installed with the possibility of enclosing the nozzles 20 and elastically deformable contact with the latter. With an increase in the dynamic pressure (air flow rate) acting on the nozzle 24, the total flow area of the outlet openings 25 increases, which leads to stabilization of the outflow velocity of the supply jets. The deformation of the nozzle 24 thus provides a visual indication of the air flow rate. To increase the rate of attenuation of the speed of the supply jets, the branch pipes 20 can be made cylindrical, with circular cross-sections, and along the length of each of the branch pipes 20 there are internal screw threads (not shown in the drawing) with equally directed helical generatrix lines for swirling counter air flows in opposite directions ... To increase the operational reliability on the nozzles 20, on the side of contact with the nozzle 24, intersecting grooves or grooves can be made with the formation of mesh corrugation (not shown in the drawing) and / or the longitudinal axes of the nozzles 20 are oriented horizontally.

The task of the fifth embodiment of the invention is to create such an air distributor, which has a more technological and simpler design while ensuring a higher attenuation rate of the speed of the supply jets with a higher uniformity of air distribution.

Additional technical results also include an increase in the intensity of damping of the speed of the supply jets.

-образного тройника, состоящего из прямолинейного воздухопровода с каналом круглого поперечного сечения, парой торцевых оппозитных выпускных отверстий и присоединенного к воздухопроводу, цилиндрическим патрубком круглого поперечного сечения с торцевым выходным отверстием с возможностью сообщения последнего с проходным отверстием воздухопровода, а другим концом патрубок присоединен к подводящему воздуховоду с возможностью сообщения с проходным отверстием последнего с образованием зазора между воздуховодом и воздухопроводом, причем продольная ось патрубка сориентирована перпендикулярно продольной оси воздухопровода для отражения потока воздуха вогнутым экранирующим участком стенки воздухопровода, расположенным оппозитно выходному отверстию патрубка, при этом патрубок выполнен с переменными по длине проходным сечением и толщиной стенки с образованием конического диффузорного канала.This is achieved by the fact that, in contrast to the known technical solution, in an air distributor containing a shielding element with a cylindrical surface, an inlet air duct with a passage hole located in the wall and the possibility of placing a straight air duct with a passage hole located in the wall and male shielding element, a pair of outlet openings, while the element is made in the form

-shaped tee, consisting of a rectilinear air duct with a circular cross-sectional channel, a pair of end opposite outlets and connected to the air duct, a cylindrical circular cross-section pipe with an end outlet with the possibility of communicating the latter with the air duct opening, and the other end of the branch pipe is connected to the supply air duct with the ability to communicate with the through hole of the latter with the formation of a gap between the air duct and the air duct, and the longitudinal axis of the nozzle is oriented perpendicular to the longitudinal axis of the air duct to reflect the air flow by a concave shielding section of the air duct wall located opposite to the outlet of the nozzle, while the nozzle is made with a variable length of flow section and wall thickness to form a conical diffuser channel.

To increase the intensity of the velocity attenuation of the supply jets, the air duct is made in the form of a Venturi pipe with a pair of opposed conical diffusers, separated by a cylindrical neck and a circular cross section, to which a branch pipe is connected.

In addition, to increase the intensity of the decay of the velocity of the supply jets, along the length of each of the diffusers and the throat, internal screw threads are made with equally directed helical generatrices for swirling air flows or from the ends of the diffusers, and along the perimeter of each of the latter longitudinal cuts are made with the formation of depressions and protrusions alternating with depressions, and the projections are bent towards the longitudinal axis of the corresponding diffuser 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 diffuser.

The essence of the claimed technical solution is illustrated by drawings: FIG. 5 shows a schematic view of the air distributor (section); in fig. 6 is a schematic representation of an air distributor with a venturi-shaped air duct; in fig. 7 - view A in FIG. 6.

The device contains a straight air duct 26 with a pair of end opposed outlet openings 27, a cylindrical pipe 28 with an end outlet 29, a through-hole 30 in the air duct 26, a supply air duct 31, a through-hole 32, a gap 33 between the air duct 31 and the air duct 26, a concave shielding wall section 34 air duct 26, conical diffuser channel 35, conical diffuser 36, cylindrical throat 37, cavity 38 and baffle 39.

The device works as follows.

-образный вентиляционный тройник. Поток воздуха в воздухопроводе 26 разделяется на две приточные струи, истекающие в объект обслуживания в противоположных направлениях через торцевые оппозитные выпускные отверстия 27. Патрубок 28 присоединен к воздухопроводу 26 с возможностью сообщения с проходным отверстием 30 воздухопровода 26 и к подводящему воздуховоду 31 с возможностью сообщения с проходным отверстием 32 воздуховода 31 с образованием зазора 33 между воздуховодом 31 и воздухопроводом 26. Продольная ось патрубка 28 сориентирована перпендикулярно продольной оси воздухопровода 26 для отражения потока воздуха вогнутым экранирующим участком стенки 34 воздухопровода 26, расположенным оппозитно выходному отверстию 29 патрубка 28. При этом патрубок 28 выполнен цилиндрическим с круглым поперечным сечением и переменными по длине проходным сечением, и толщиной стенки с образованием конического диффузорного канала 35. В диффузорном канале 35 скорость потока воздуха и кинетическая энергия потока снижаются ввиду увеличения проходного сечения канала. Потери кинетической энергии способствуют повышению интенсивности затухания скорости приточных струй, обеспечивая высокую интенсивность процесса смешения приточного воздуха с воздухом помещения. Удар потока воздуха при контакте с вогнутым экранирующим участком стенки 34 воздухопровода 26 дополнительно снижает кинетическую энергию потока, что приводит к повышению интенсивности затухания скорости приточных струй. Для усиления упомянутого технического результата воздухопровод 26 может быть выполнен в форме трубы Вентури (на фиг. 6) с парой оппозитных конических диффузоров 36, разделенных цилиндрической горловиной 37 круглого поперечного сечения, к которой присоединен патрубок 28. Для повышения интенсивности затухания скорости приточных струй, по длине каждого из диффузоров 36 и горловине 37 выполнены внутренние винтовые нарезки с одинаково направленными винтовыми образующими линиями для закрутки потоков воздуха (не показаны на чертеже) или с торцов диффузоров 36 и по периметру каждого из последних выполнены продольные вырезы с образованием впадин 38 и выступов, чередующихся с впадинами 38, а выступы отогнуты в сторону продольной оси соответствующего диффузора 36 с образованием отражательных экранов 39 (на фиг. 7) с вогнутыми, со стороны потока воздуха, поверхностями, и сориентированных под углом к продольной оси диффузора 36.The air flow from the supply air duct 31 enters the branch pipe 28 and then through the end outlet opening into the air duct 26 (in Fig. 5). Branch pipe 28 with air duct 26 form

-shaped ventilation tee. The air flow in the air duct 26 is divided into two supply jets flowing into the service object in opposite directions through the end opposed outlets 27. The branch pipe 28 is connected to the air duct 26 with the possibility of communicating with the passage opening 30 of the air duct 26 and to the supply air duct 31 with the possibility of communication with the passage opening 32 of the air duct 31 with the formation of a gap 33 between the air duct 31 and the air duct 26. The longitudinal axis of the nozzle 28 is oriented perpendicular to the longitudinal axis of the air duct 26 to reflect the air flow with a concave shielding section of the wall 34 of the air duct 26, located opposite the outlet opening 29 of the nozzle 28. In this case, the nozzle 28 is made cylindrical with a circular cross-section and variable along the length of the flow section, and wall thickness with the formation of a conical diffuser channel 35. In the diffuser channel 35, the air flow velocity and kinetic energy of the flow decrease due to an increase in the flow the bottom section of the channel. Losses of kinetic energy contribute to an increase in the intensity of the damping of the speed of the supply jets, providing a high intensity of the process of mixing the supply air with the room air. The impact of the air flow in contact with the concave shielding section of the wall 34 of the air duct 26 further reduces the kinetic energy of the flow, which leads to an increase in the intensity of the decay of the velocity of the supply jets. To enhance the aforementioned technical result, the air duct 26 can be made in the form of a Venturi pipe (in Fig. 6) with a pair of opposed conical diffusers 36, separated by a cylindrical neck 37 of circular cross-section, to which a branch pipe 28 is connected. To increase the intensity of the damping of the velocity of the supply jets, along the length of each of the diffusers 36 and the throat 37 are made with internal screw threads with equally directed helical generatrix lines for swirling air flows (not shown in the drawing) or from the ends of the diffusers 36 and along the perimeter of each of the latter longitudinal cuts are made with the formation of hollows 38 and protrusions alternating with depressions 38, and the protrusions are bent towards the longitudinal axis of the corresponding diffuser 36 to form reflective screens 39 (in Fig. 7) with concave surfaces on the side of the air flow and oriented at an angle to the longitudinal axis of the diffuser 36.

The task of the sixth embodiment of the invention is to provide such an air distributor that has a higher attenuation rate of the speed of the supply jets while ensuring a higher uniformity of air distribution.

Additional technical results also include expanding the functionality in terms of air flow control, increasing operational reliability and the intensity of damping of the speed of the supply jets.

This is achieved by the fact that, in contrast to the known technical solution, in an air distributor containing two rectilinear supply ducts with a pair of through holes located in the walls of the ducts, a shielding element with a cylindrical surface and the possibility of placing a pair of opposed outlet openings covered by the element, the element being made in the form of a rectilinear cylindrical air duct with a circular cross-section and a pair of opposite end outlet openings, in the wall of which a pair of through holes is made coaxially to each other, while the ducts are coaxially connected to each other at the ends to form a straight air duct with a pair of opposite end inlet openings and a pair of coaxially oriented round guide passages for the air duct, located in the opposite walls of the air duct, and the air pipe is installed in the guide passages in such a way that the passage openings of the air duct are located inside the air gadfly and communicated with the inlet openings, while along the length of the air duct, an internal screw thread is made for swirling air flows or from the ends of the air duct, and along the perimeter of the latter, longitudinal cuts are made to form depressions and protrusions alternating with depressions, and the protrusions are bent towards the longitudinal axis of the air duct with the formation of reflective screens with a concave surface on the side of the air flow, and oriented at an angle to the axis of the air duct.

To expand the functionality in terms of air flow control, the air duct has the ability to move axially across the duct with cut-off of air flows through the air duct openings.

Also, to increase the operational reliability, the air duct is located horizontally or installed in the guide holes of the air duct with the possibility of fixing the position.

In addition, to increase the intensity of the velocity attenuation of the supply jets, the air duct is made cylindrical with a circular cross-section, and along the length of the air duct, an internal screw thread is made for swirling air flows in opposite directions.

The essence of the claimed technical solution is illustrated by drawings: FIG. 8 shows a schematic view of the air distributor (section); in fig. 9 - view B in Fig. 8.

The device contains a straight cylindrical air duct 40 with a pair of opposed end outlets 41 and a pair of through holes 42, a straight air duct 43 with a pair of opposite end inlets 44 and a pair of coaxially oriented round guide through holes 45 for the air duct 40, cavities 46 and reflective screens 47.

The device works as follows.

Counter air flows from the network of supply air ducts through opposed end inlets 44 enter the air duct 43 and then through the through holes 42 enter the air line 40 (in Fig. 8), in which they collide with each other, forming the resulting supply jets flowing through the opposite end outlets 41 in opposite directions. The collision of flows in the air duct 40 leads to a decrease in their kinetic energy, the loss of which contributes to the intensive attenuation of the speed of each of the supply jets, providing a high intensity of the process of mixing the supply air with the room air. The air duct 40 is installed in the guide passage holes 45 in such a way that the passage holes 42 of the air duct 40 are located inside the air duct 43 and communicate with the inlet holes 44. An internal screw thread (not shown in the drawing) is made along the length of the air duct 40 to swirl air flows or from the ends of the air duct 40 and along the perimeter of the latter, longitudinal cuts are made with the formation of depressions 46 and projections alternating with depressions 46, and the projections are bent towards the longitudinal axis of the air duct 40 to form reflective screens 47 (in Fig. 9) with a concave surface on the side of the air flow, and oriented at an angle to the axis of the air duct 40. The presence of screens 47 increases the intensity of damping of the speed of the supply jets. To expand the functionality in terms of air flow control, the air duct 40 has the ability to axially move transversely to the air duct 43 with cutting off the air flows through the passage holes 45 of the air duct 40. To increase the operational reliability, the air duct 40 is located horizontally or installed in the guide holes 45 of the air duct 43 with the possibility of fixing the position ... To increase the rate of attenuation of the speed of the supply jets, the air duct 43 can be made cylindrical, with a circular cross-section, and along the length of the air duct 43, an internal screw thread (not shown in the drawing) can be made for swirling air flows in opposite directions.

The task of the seventh embodiment of the invention is to provide such an air distributor that has a higher attenuation rate of the speed of the supply jets while ensuring a higher uniformity of air distribution.

Additional technical results also include expanding the functionality in terms of air flow control, increasing operational reliability and the intensity of damping of the speed of the supply jets.

This is achieved by the fact that, in contrast to the known technical solution, in an air distributor containing two rectilinear supply ducts, in the wall of one of which there is a passage opening, a shielding element, a passage window with the possibility of placement in the wall, and the possibility of ensuring parallelism, and placement of a pair of male shielding element, opposite outlet openings, while the ducts are coaxially connected to each other at the ends to form an air duct with a pair of opposite end inlet openings and a horizontally oriented flat wall with a passage hole located in the latter, and the shielding element is made in the form of a straight air duct with a pair of end opposite outlet openings, and a pair of horizontally oriented, opposite parallel walls with a passage window made in one of the latter, the axis of which crosses the opposite wall at a right angle to form a reflective screen, while the air duct is installed parallel to the air duct, and horizontally located walls with the passage window and the passage opening are longitudinally adjacent to each other to ensure communication of the passage opening with the passage window.

To improve operational reliability, the air duct is installed above the air duct.

In addition, to increase the intensity of the velocity attenuation of the supply jets from the ends of the air duct 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 air duct with the formation of reflective screens oriented at an angle to the longitudinal axis of the air duct ...

Also, to expand the functionality in terms of air flow control, the air duct has the ability to move longitudinally relative to the duct with overlapping the through hole and cutting off the air flow in the air duct.

The essence of the claimed technical solution is illustrated by drawings: FIG. 10 is a schematic view of an air distributor (section); in fig. 11 is a view B in FIG. ten.

The device comprises an air duct 48 with a pair of opposite end inlet openings 49 and a passage opening 50, and a straight air pipe 51 with a pair of opposite end outlet openings 52 and a passage window 53, a cavity 54 and a baffle 55.

The device works as follows.

Air flows from the network of supply air ducts through opposed end inlets 49 enter the air duct 48 (in Fig. 10), in which the opposing air flows collide with each other, forming the resulting flow. The collision of flows leads to a decrease in kinetic energy and increases the intensity of the decay of the speed of the resulting flow, which enters the rectilinear air duct 51 through the passage opening 50 and the passage window 53 communicated with each other. at the same time, kinetic energy and being divided into two supply jets, flowing into the serviced room through end opposed outlet openings 52 in opposite directions. The through hole 50 is located in the flat wall of the air duct 48, oriented horizontally, and the through hole 53 is located in the flat wall of the air duct 51, also oriented horizontally. In this case, the air duct 51 is installed parallel to the air duct 48, and the horizontally located walls are longitudinally adjacent to each other to ensure communication of the through hole 50 with the through window 53. To increase the operational reliability, the air duct 51 is installed above the air duct 48. To increase the intensity of the velocity decay of the supply jets from the ends of the air duct 51 and along the perimeter of the latter, longitudinal cuts are made to form depressions 54 and projections alternating with depressions 54 (in Fig. 11), and the projections are bent towards the longitudinal axis of the air duct 51 to form reflective screens 55 oriented at an angle to the longitudinal axis of the air duct 51. To expand the functionality in terms of air flow control, the air duct 51 has the ability to move longitudinally relative to the air duct 48 with overlapping the passage opening 50 and cutting off the air flow in the air duct 51.

The task of the eighth embodiment of the invention is to provide such an air distributor that has a simpler design while ensuring a higher attenuation rate of the speed of the supply jets and a higher uniformity of air distribution.

Additional technical results also include an increase in the intensity of damping of the speed of supply jets and operational reliability.

This is achieved by the fact that, in contrast to the known technical solution, in an air distributor containing a supply air duct with a through-hole located in the wall, a shielding element, an opposed through-hole with the possibility of placement in the wall and the possibility of placing, covered by the shielding element, a pair of opposite outlets, while in the wall of the supply air duct, a through hole is additionally made with the formation of a pair of coaxially located opposed through holes, and the element is made in the form of an elastic nozzle enclosing the air duct around the perimeter with the possibility of elastically deformable contact with the latter and installed with overlap of a pair of opposite through holes communicated with the nozzle made around the perimeter , with a chute open from the side of the duct wall, while the through holes are located opposite to the shielding wall of the chute, and on the outside of the nozzle there is a pair of coaxial outlet openings communicated with the chute and, the axes of which are located perpendicular to the axes of the opposed passage holes.

In addition, in order to increase the intensity of the damping of the speed of the supply jets, the outlet openings are made as diffuser and / or the outlet openings are made of the same shape and size, and the through openings are of the same shape and size.

Also, to increase operational reliability, intersecting grooves or grooves with the formation of mesh corrugation are made on the wall of the air duct, from the side of contact with the nozzle, and / or the air duct is oriented horizontally.

The essence of the claimed technical solution is illustrated by a drawing: FIG. 12 shows a schematic view of the air distributor (section).

The device contains a supply air duct 56 with a pair of coaxially (opposed) through holes 57, an elastic nozzle 58 with a groove 59 and a pair of coaxial (opposed) outlet holes 60.

The device works as follows.

The air flows from the supply air duct 56 through the coaxially located passage holes 57 enter the groove 59 of the elastic nozzle 58 (in Fig. 12), in which the counter air flows collide with each other, forming two resulting flows. The collision of streams leads to a decrease in kinetic energy and increases the intensity of the decay of the speed of the resulting streams, which flow through the outlets 60 into the manned room in opposite directions. Each of the air streams hits the shielding wall of the trough 59, located opposite to the passage opening 57, while losing kinetic energy and splitting into two streams, which collide with another pair of air streams, forming two resulting streams. The collision of flows leads to an increase in the intensity of attenuation of the supply jets. The elastic nozzle 58 surrounds the air duct 56 with the possibility of elastically deformable contact with the latter and overlaps the opposed passage holes 57, which are in communication with the groove 59 made around the nozzle 58, open from the side of the wall of the air duct 56. The passage openings 57 are located opposite the shielding wall of the groove 59, and a pair of coaxial outlet openings 60 communicated with the chute 59 is placed on the outside of the nozzle 58, while the axes of the outlet openings 60 are located perpendicular to the axes of the opposed passage openings 57. To increase the intensity of the velocity attenuation of the supply jets, the outlet openings 60 can be made diffuser and / or the outlets 60 may be the same shape and size and the through holes 57 the same shape and size. To increase operational reliability, intersecting grooves or grooves (not shown in the drawing) can be formed on the wall of the duct 56, on the side of contact with the nozzle 58, to form a mesh corrugation, and / or the duct 56 can be oriented horizontally.

The objective of the ninth embodiment of the invention is to create an air distributor that has a simpler design while ensuring a higher attenuation rate of the supply jets, a higher uniformity of air distribution and wider functionality in terms of air flow control.

Additional technical results also include an increase in the intensity of damping of the speed of supply jets and operational reliability.

This is achieved by the fact that, in contrast to the known technical solution, in an air distributor containing a rectilinear supply air duct with a passage hole located in the wall, a shielding element with a cylindrical surface, an opposed passage opening with the possibility of placing in the wall and the possibility of placing, covered by the shielding element, pairs of opposed outlet holes, while the supply air duct is cylindrical, with a circular cross-section, and in the wall of the air duct an additional passage hole is made to form a pair of coaxially located in the wall of opposed passage holes, and the element is made in the form of an elastic cylindrical nozzle with a circular cross-section, covering the air duct along the perimeter with the possibility of elastically deformable contact with the latter and a pair of opposed through holes installed with overlap, and along the perimeter of the nozzle an inner annular channel is made with a pair communicated with the latter, coaxial x inlet openings open from the side of the air duct wall and communicated with the passage openings of the air duct, while the inlet openings are located opposite to the shielding wall of the channel, and on the outside of the nozzle there is a pair of coaxial outlet openings communicated with the channel, the axes of which are perpendicular to the axes of the inlet openings, in this case, the nozzle is installed with the possibility of rotation relative to the air duct with overlapping passage and inlet holes.

In addition, in order to increase the intensity of damping of the speed of the supply jets, the outlet openings are made of diffuser and / or the outlet openings are made of the same shape and size, the through openings are of the same shape and size, and the inlet openings are of the same shape and size.

Also, to increase operational reliability, the air duct is oriented horizontally or the nozzles are installed on the air duct with the ability to fix the position.

The essence of the claimed technical solution is illustrated by a drawing: FIG. 13 shows a schematic view of the air distributor (section).

The device contains a supply cylindrical air duct 61 with a pair of coaxially (opposed) through holes 62, an elastic cylindrical nozzle 63 with an inner annular channel 64, a pair of coaxial (opposed) inlet holes 65 and a pair of coaxial (opposed) outlet holes 66.

The device works as follows.

The air flows from the supply cylindrical air duct 61 through the coaxially located passage holes 62 and the coaxially located inlet holes 65 enter the inner annular channel 64 of the elastic cylindrical nozzle 63 (in Fig. 13), in which the counter air flows collide with each other, forming two resulting flows ... The collision of streams leads to a decrease in kinetic energy and increases the intensity of the decay of the speed of the resulting streams that flow through the outlets 66 into the manned room in opposite directions. Each of the air streams strikes the shielding wall of the inner annular channel 64, located opposite to the inlet opening 65, while losing kinetic energy and splitting into two streams that collide with another pair of air streams, forming two resulting streams. The collision of flows leads to an increase in the intensity of attenuation of the supply jets. The cylindrical nozzle 63 surrounds the air duct 61 with the possibility of elastically deformable contact with the latter and is installed with overlap of a pair of opposed passage holes 62. Along the perimeter of the nozzle 63 there is an inner annular channel 64 with a pair of coaxial inlet holes 65 communicated with the latter, open from the side of the air duct wall 61 and communicated with the passage openings 62 of the air duct 61. On the outside of the nozzle 63, a pair of coaxial outlet holes 66, the axes of which are located perpendicular to the axes of the inlet holes 65, are made in communication with the inner annular channel 64, the nozzle 63 being mounted with the possibility of rotation relative to the air duct 61 with overlapping passage 62 and inlet 65 holes for air flow control. To increase the rate of attenuation of the speed of the supply jets, the outlet openings 66 can be made of diffuser and / or the outlet openings 66 can be made of the same shape and size, the passage openings 62 - the same shape and size, and the inlet openings 65 - the same shape and size. To increase the operational reliability, the air duct 61 can be oriented horizontally or the nozzles 63 can be installed on the air duct with the possibility of fixing the position.

The task of the tenth embodiment of the invention is to provide such an air distributor that has a simpler design while ensuring a high attenuation rate of the speed of the supply jets and a higher uniformity of air distribution.

Additional technical results also include an increase in the intensity of damping of the speed of the supply jets.

-образной крестовины, включающей подводящий патрубок с торцевым входным отверстием и трех, сообщенных с подводящим патрубком, выпускных патрубков с торцевыми выпускными отверстиями, причем с торцов выпускных патрубков и по периметру последних выполнены продольные вырезы с образованием впадин и выступов, чередующихся с впадинами, а выступы отогнуты в сторону продольной оси соответствующего выпускного патрубка с образованием отражательных экранов, сориентированных под углом к оси выпускного патрубка.This is achieved by the fact that, in contrast to the known technical solution, in an air distributor containing a shielding element covering the outlet openings and the possibility of placing a supply air duct with a through hole, the element being made in the form

-shaped crosspiece, including a supply pipe with an end inlet and three outlet pipes with end outlets connected with the inlet pipe, and longitudinal cuts are made from the ends of the outlet pipes and along the perimeter of the latter, with the formation of depressions and protrusions alternating with depressions, and the protrusions bent towards the longitudinal axis of the corresponding outlet to form reflective screens oriented at an angle to the axis of the outlet.

In addition, to increase the intensity of attenuation of the supply jets, the cross is made detachable, the inlet and outlet nozzles are made with rectangular cross-sections, and the axes of the said nozzles are located in one plane, and a hollow perforated insert is installed inside the cross, like an air-line flow divider, in the form of a prism with cross-section limited by the astroid, with the possibility of mechanical contact of the concave faces with the ribs formed by the intersection of the nozzles and / or each of the outlet nozzles is made with a channel having a flow section and wall thickness variable along the length to form a diffuser channel.

The essence of the claimed technical solution is illustrated by drawings: FIG. 14 is a schematic view of an air distributor (section); in fig. 15 is a view D in FIG. 14; in fig. 16 schematically shows an air distributor with an insert (section).

The device contains a supply pipe 67 with an end inlet 68, three outlet pipes 69 with end outlets 70, cavities 71, reflective screens 72, a hollow perforated insert 73 and diffuser channels 74.

The device works as follows.

-образную крестовину. С торцов выпускных патрубков 69 и по периметру последних выполнены продольные вырезы с образованием впадин 71 и выступов, чередующихся с впадинами 71 (на фиг. 15), а выступы отогнуты в сторону продольной оси соответствующего выпускного патрубка 69 с образованием отражательных экранов 72, сориентированных под углом к оси выпускного патрубка 69. Потоки воздуха соударяются с отражательными экранами 72, что приводит к снижению кинетической энергии и повышает интенсивность затухания скорости приточных струй. Для повышения интенсивности затухания скорости приточных струй крестовина выполнена разъемной, подводящий 67 и выпускные 69 патрубки выполнены с прямоугольными поперечными сечениями, причем оси упомянутых патрубков 67 и 69 расположены в одной плоскости, а внутри крестовины установлена полая перфорированная вставка 73 (на фиг. 16) по типу воздухопроводного рассекателя потока, в форме призмы с поперечным сечением ограниченным астроидой, с возможностью механического контакта вогнутых граней с ребрами, образованными пересечением патрубков 67 и 69 и/или каждый из выпускных патрубков 69 выполнен с каналом, имеющим переменные по длине проходное сечение и толщину стенок с образованием диффузорного канала 74. В диффузорных каналах 74 снижается скорость потоков воздуха, а вставка 73 обеспечивает в подводящем патрубке 67 столкновение струй под углом друг к другу, а в выпускных патрубках 69, струи ударяются и отражаются от стенок диффузорных каналов 74. Это приводит к снижению кинетической энергии потоков и повышению интенсивности затухания скорости приточных струй.The air flow from the network of supply air ducts enters through the end inlet 68 into the supply pipe 67 and then into the outlet pipes 69 connected with the latter (in Fig. 14), from which the supply jets flow through the end outlets 70 into the manned room. The inlet 67 and the outlet 69 form

-shaped crosspiece. From the ends of the outlet pipes 69 and along the perimeter of the latter, longitudinal cuts are made with the formation of depressions 71 and projections alternating with depressions 71 (in Fig. 15), and the projections are bent towards the longitudinal axis of the corresponding outlet pipe 69 with the formation of reflective screens 72, oriented at an angle to the axis of the outlet pipe 69. The air flows collide with the reflective screens 72, which leads to a decrease in kinetic energy and increases the intensity of the decay of the velocity of the supply jets. To increase the intensity of the damping of the speed of the supply jets, the crosspiece is made detachable, the inlet 67 and outlet 69 pipes are made with rectangular cross-sections, and the axes of the said pipes 67 and 69 are located in the same plane, and a hollow perforated insert 73 (in Fig. 16) is installed inside the crosspiece along type of air flow divider, in the form of a prism with a cross-section bounded by an astroid, with the possibility of mechanical contact of the concave faces with the ribs formed by the intersection of the pipes 67 and 69 and / or each of the outlet pipes 69 is made with a channel having a flow section and wall thickness variable along the length with the formation of a diffuser channel 74. In the diffuser channels 74, the speed of air flows decreases, and the insert 73 ensures that the jets collide at an angle to each other in the inlet pipe 67, and in the outlet nozzles 69, the jets hit and are reflected from the walls of the diffuser channels 74. This leads to decrease in kinetic energy flows and an increase in the intensity of damping of the speed of the supply jets.

The task of the eleventh embodiment of the invention is to create an air distributor that has a higher adaptability due to a simpler design and a smaller overall size and at the same time provides a high attenuation rate of the supply jets and a higher uniformity of air distribution.

Additional technical results also include an increase in manufacturability by reducing the overall size while ensuring a high rate of attenuation of the speed of the supply jets and an increase in the rate of attenuation of the speed of the supply jets.

-образного тройника, включающего прямолинейный воздухопровод с каналом круглого поперечного сечения, парой торцевых оппозитных выпускных отверстий и круглым проходным отверстием, расположенным в стенке, и присоединенный к воздухопроводу, цилиндрический подводящий патрубок круглого поперечного сечения с оппозитными торцевыми входным и выходным отверстиями, причем патрубок установлен в круглом проходном отверстии воздухопровода с возможностью сообщения последнего с выходным отверстием патрубка и образованием зазора между выходным отверстием и оппозитной стенкой воздухопровода, при этом продольная ось патрубка сориентирована перпендикулярно продольной оси воздухопровода с образованием вогнутого экранирующего участка стенки воздухопровода, расположенного оппозитно выходному отверстию патрубка, а патрубок выполнен с переменными по длине проходным сечением и толщиной стенки с образованием конического диффузорного канала.This is achieved by the fact that, in contrast to the known technical solution, in an air distributor containing a shielding element with a cylindrical surface and the possibility of placing a rectilinear supply air duct with a through-hole, a straight air duct with a through-hole located in the wall, covered by the shielding element, a pair of outlet openings, and a connected with an element, a gap, while the element is made in the form

-shaped tee, including a straight air duct with a circular cross-sectional channel, a pair of end-face opposed outlets and a round bore located in the wall, and connected to the air duct, a cylindrical supply pipe of a circular cross-section with opposite end inlet and outlet openings, and the pipe is installed in a circular through-hole of the air duct with the possibility of communicating the latter with the outlet of the pipe and the formation of a gap between the outlet and the opposed wall of the air duct, while the longitudinal axis of the pipe is oriented perpendicular to the longitudinal axis of the air duct with the formation of a concave shielding section of the wall of the air duct, located opposite to the outlet of the pipe, and the pipe is made with variable flow section and wall thickness along the length to form a conical diffuser channel.

In addition, to improve manufacturability by reducing the overall size while ensuring a high rate of attenuation of the velocity of the supply jets, longitudinal cuts are made from the ends of the air duct and along the perimeter of the latter with the formation of depressions and protrusions alternating with depressions, and the protrusions are bent towards the longitudinal axis of the air duct with the formation of reflective screens with concave surfaces from the side of the air flow, and oriented at an angle to the longitudinal axis of the air duct.

Also, to increase the intensity of damping of the speed of the supply jets, an internal screw thread is made along the length of the air duct for swirling air flows.

The essence of the claimed technical solution is illustrated by drawings: FIG. 17 is a schematic view of an air distributor (section); in fig. 18 is a view D in FIG. 17.

The device contains a straight air duct 75 with a pair of end opposed outlets 76 and a round bore 77, a cylindrical inlet 78 with opposed end inlet 79 and outlet 80 openings, a gap 81 between the outlet 80 and the opposed wall of the air duct 75, cavities 82 and reflective screens 83 ...

The device works as follows.

-образный тройник. Прямолинейный воздухопровод 75 имеет канал круглого поперечного сечения и круглое проходное отверстием 77, расположенное в стенке. Воздухопровод 75 присоединен к цилиндрическому подводящему патрубку 78, имеющему круглое поперечное сечение, причем патрубок 78 установлен в круглом проходном отверстии 77 воздухопровода 75 с возможностью сообщения последнего с выходным отверстием 80 патрубка 78 и образованием зазора 81 между выходным отверстием 80 и оппозитной стенкой воздухопровода 75, при этом продольная ось патрубка 78 сориентирована перпендикулярно продольной оси воздухопровода 75 с образованием вогнутого экранирующего участка стенки воздухопровода 75, расположенного оппозитно выходному отверстию 80 патрубка 78. Патрубок 78 выполнен с переменными по длине проходным сечением и толщиной стенки с образованием конического диффузорного канала (не показан на чертеже). Поток воздуха отражается от вогнутого экранирующего участка стенки воздухопровода 75, расположенного оппозитно выходному отверстию 80 патрубка 78 и теряет кинетическую энергию, что обеспечивает высокую интенсивность затухания скорости приточных струй. Для повышения интенсивности затухания скорости приточных струй с торцов воздухопровода 75 и по периметру последнего могут быть выполнены продольные вырезы с образованием впадин 82 и выступов, чередующихся с впадинами 82 (на фиг. 18), а выступы отогнуты в сторону продольной оси воздухопровода 75 с образованием отражательных экранов 83 с вогнутыми, со стороны потока воздуха, поверхностями, и сориентированных под углом к продольной оси воздухопровода 75. Потоки воздуха соударяются с отражательными экранами 83 и отражаются, что приводит к снижению кинетической энергии и повышает интенсивность затухания скорости приточных струй. Для повышения интенсивности затухания скорости приточных струй по длине воздухопровода 75 выполнена внутренняя винтовая нарезка (не показана на чертеже) для закрутки потоков воздуха.The air flow from the network of supply air ducts enters through the end inlet 79 into the cylindrical inlet 78 and then into the rectilinear air duct 75 connected with the latter (in Fig. 17), from which the supply jets flow through the end opposite outlets 76 into the serviced room in the opposite directions. The cylindrical inlet 78 and the straight air duct 75 form

-shaped tee. The rectilinear air duct 75 has a circular cross-sectional duct and a circular passageway 77 located in the wall. The air duct 75 is connected to a cylindrical inlet 78 having a circular cross-section, and the nozzle 78 is installed in the circular through-hole 77 of the air duct 75 with the possibility of communicating the latter with the outlet 80 of the nozzle 78 and the formation of a gap 81 between the outlet 80 and the opposite wall of the air duct 75, when the longitudinal axis of the branch pipe 78 is oriented perpendicular to the longitudinal axis of the air duct 75 with the formation of a concave shielding section of the wall of the air duct 75, located opposite to the outlet opening 80 of the branch pipe 78. The branch pipe 78 is made with a variable length of flow section and wall thickness with the formation of a conical diffuser channel (not shown in the drawing ). The air flow is reflected from the concave shielding section of the wall of the air duct 75, located opposite to the outlet opening 80 of the branch pipe 78 and loses kinetic energy, which provides a high rate of attenuation of the velocity of the supply jets. To increase the rate of attenuation of the speed of the supply jets from the ends of the air duct 75 and along the perimeter of the latter, longitudinal cuts can be made with the formation of depressions 82 and protrusions alternating with depressions 82 (in Fig. 18), and the protrusions are bent towards the longitudinal axis of the air duct 75 with the formation of reflective screens 83 with concave surfaces on the side of the air flow and oriented at an angle to the longitudinal axis of the air duct 75. Air flows collide with reflective screens 83 and are reflected, which leads to a decrease in kinetic energy and increases the intensity of the speed of the supply jets. To increase the rate of attenuation of the speed of the supply jets along the length of the air duct 75, an internal screw thread (not shown in the drawing) is made to swirl the air flows.

Claims (33)

1. An air distributor containing two rectilinear supply ducts, in the wall of each of which it is located along the outlet, separated by a gap and oriented opposite to each other, and the possibility of placing a shield associated with the outlet, characterized in that the ducts are coaxially connected to each other at the ends with the formation of a rectilinear air duct, including a pair of opposite end inlet openings and a pair of opposite flat walls, in which a pair of opposed outlet openings separated by a gap are located, each of which is perforated, with an edge bent relative to the plane of the flat wall to the outer side of the air duct to form an adjacent outlet a flat baffle, oriented at right angles to the axis of the duct or at sharp angles to the axes of the duct and outlet, partially overlapping the latter. 2. An air distributor containing a supply box with an outlet located in the wall, a shielding element with a curved surface associated with the gap and the possibility of placing an outlet covered by the shielding element with the formation of a pair of opposed outlet holes, characterized in that the element is made in the form of a hollow open one and a half with a pair separated by a gap of the end inlet holes and an outlet one and a half located in the wall, while the duct is made in the form of an air duct with a flat wall located on the side of the gap, in which the outlet is located, and the one and a half is connected with its ends to the flat wall with the possibility of communication with the air duct through the end inlets , and the outlet one and a half is located on the side of the gap, opposite to the outlet of the air duct. 3. An air distributor according to claim 2, characterized in that the one-and-a-half is made corrugated, with screw-shaped corrugations for swirling counter air flows in opposite directions. 4. An air distributor containing, separated by a gap, two rectilinear supply ducts, in each of which there is a shielding element connected with the gap with a cylindrical surface and the possibility of placing, covered by the latter, a pair of opposed outlet openings, characterized in that the ducts are made in in the form of coaxially oriented rectilinear cylindrical nozzles with circular cross-sections and the same outer diameters, with the formation of an end gap between them, while a pair of opposed air outlet holes are located at the ends of the nozzles, from the end gap, and a pair of end opposed air inlet holes are located on opposite ends of the nozzles, and the shielding element is made in the form of an adjusting cylindrical nozzle with a circular cross-section and an internal screw thread along the length of the nozzle, while a pair of opposed outlet holes is made along the perimeter of the nozzle, and along the length not each of the nozzles has an external screw thread with the same direction of the helical generatrix lines, and the nozzle has a thread with a helical generatrix line in the same direction as the helical generatrix lines in the threads of the nozzles, and the nozzles are installed on the nozzles with overlapping the end gap, ensuring communication of the outlet openings with a gap and the formation of a movable threaded connection, in which the nozzle has the ability to move along the nozzles when turning and overlap the outlet openings with one of the nozzles to control the air flow. 5. Air distributor according to claim 4, characterized in that the outlet openings are round with internal screw threads for swirling air flows or diffuser. 6. Air distributor according to one of paragraphs. 4, 5, characterized in that along the length of each of the nozzles, internal screw threads are made with the same direction of the helical generatrix lines for swirling counter air flows in opposite directions. 7. Air distributor according to claim 6, characterized in that the helical generatrix lines of the internal screw threads of the branch pipes have the same direction as the direction of the helical generatrix line of the thread of the nozzle. 8. Air distributor according to one of paragraphs. 4-7, characterized in that the longitudinal axes of the pipes are oriented horizontally. 9. An air distributor containing, separated by a gap, two rectilinear supply ducts, in each of which there is a through hole, a shielding element connected with the gap and the possibility of placing the outlet openings covered by the element, characterized in that the ducts are made in the form of coaxially oriented nozzles with the formation between them end gap, while a pair of opposed openings for air outlet are located at the ends of the nozzles, on the side of the end gap, and a pair of end opposite openings for air inlet are located at opposite ends of the nozzles, and the shielding element is made in the form of a nozzle covering the nozzles along the outer perimeters with overlapping the end gap, while the nozzle is made of an elastic material with a porous structure and open air-permeable pores communicated with the gap with the formation of outlet holes, and the nozzle is installed on the nozzles with the possibility of elastically deformable contact with the latter mi. 10. Air distributor according to claim 9, characterized in that the nozzles are cylindrical with circular cross-sections, and along the length of each of the nozzles, internal screw threads are made with equally directed helical generatrix lines for swirling counter air flows in opposite directions. 11. Air distributor according to one of paragraphs. 9, 10, characterized in that on the nozzles, on the side of contact with the nozzle, intersecting grooves or grooves are made with the formation of mesh corrugation. 12. An air distributor containing a shielding element with a cylindrical surface, a supply air duct with a passage hole located in the wall and the possibility of placing a straight air duct with a passage hole located in the wall, and, covered by the shielding element, a pair of outlet openings, characterized in that that the element is made in the form

-shaped tee consisting of a rectilinear air duct with a circular cross-section channel, a pair of end opposed outlet openings and a cylindrical circular cross-section pipe connected to the air duct with an end outlet with the possibility of communicating the latter with the air duct opening, and the other end of the branch pipe is connected to the supply air duct with the ability to communicate with the through hole of the latter with the formation of a gap between the air duct and the air duct, and the longitudinal axis of the pipe is oriented perpendicular to the longitudinal axis of the air pipe to reflect the air flow by a concave shielding section of the wall of the air duct located opposite to the outlet of the pipe, while the pipe is made with variable lengths of flow section and wall thickness with the formation of a conical diffuser channel. 13. An air distributor according to claim 12, characterized in that the air duct is made in the form of a Venturi tube with a pair of opposed conical diffusers separated by a cylindrical neck and a circular cross-section, to which the branch pipe is connected. 14. An air distributor according to claim 13, characterized in that along the length of each of the diffusers and the throat, internal screw threads are made with equally directed helical generatrices for swirling air flows or from the ends of the diffusers and along the perimeter of each of the latter there are longitudinal cuts with the formation of depressions and protrusions alternating with depressions, and the protrusions are bent towards the longitudinal axis of the corresponding diffuser 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 diffuser. 15. An air distributor containing two rectilinear supply ducts with a pair of through holes located in the walls of the ducts, a shielding element with a cylindrical surface and the possibility of placing a pair of opposed outlet openings covered by the element, characterized in that the element is made in the form of a rectilinear cylindrical air duct with a circular cross-section , and a pair of opposite end outlet openings, in the wall of which a pair of through holes is made coaxially to each other, while the ducts are coaxially connected to each other at the ends to form a rectilinear duct with a pair of opposite end inlet openings and a pair of coaxially oriented circular guide bores for the air duct, located in the opposite walls of the duct, and the air duct is installed in the guide through holes in such a way that the through holes of the air duct are located inside the air duct and communicate with the inlet holes, while the length of the air duct is made with an internal screw thread for swirling air flows or from the ends of the air duct 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 air duct with the formation of reflective screens with concave, from the side of the air flow , surface, and oriented at an angle to the axis of the air duct. 16. Air distributor according to claim 15, characterized in that the air duct has the ability to axially move transversely to the duct with cutting off the air flows through the through holes of the air duct. 17. An air distributor according to claim 16, characterized in that the air duct is located horizontally or installed in the guide holes of the air duct with the possibility of fixing the position. 18. Air distributor according to one of paragraphs. 15-17, characterized in that the air duct is cylindrical with a circular cross-section, and along the length of the air duct, an internal screw thread is made for swirling air flows in opposite directions. 19. An air distributor containing two rectilinear supply ducts, in the wall of one of which there is a passage opening, a shielding element, a passage window with the possibility of being placed in the wall, and the possibility of ensuring parallelism, and placing a pair of opposed outlet openings covered by the shielding element, characterized in that that the ducts are coaxially connected to each other at the ends to form an air duct with a pair of opposite end inlet openings and a horizontally oriented flat wall with a passage hole located in the latter, and the shielding element is made in the form of a rectilinear air duct with a pair of opposite end outlet openings and a pair of oriented horizontally opposed parallel walls with a passage window made in one of the last, the axis of which crosses the opposite wall at right angles to form a reflective screen, while the air duct is installed parallel to the duct, and horizontally The wall walls with the through-hole and through the through-hole are longitudinally adjacent to each other to ensure communication of the through-hole with the through-hole. 20. Air distributor according to claim 19, characterized in that the air duct is installed above the air duct. 21. Air distributor according to one of paragraphs. 19, 20, characterized in that longitudinal cuts are made from the ends of the air duct and along the perimeter of the latter with the formation of depressions and projections alternating with depressions, and the projections are bent towards the longitudinal axis of the air duct with the formation of reflective screens oriented at an angle to the longitudinal axis of the air duct. 22. Air distributor according to one of paragraphs. 19-21, characterized in that the air duct has the ability to move longitudinally relative to the duct with overlapping the passage opening and cutting off the air flow in the air duct. 23. An air distributor comprising a supply air duct with a passageway located in the wall and a shielding element with the possibility of placement, covered by a shielding element, a pair of opposed outlet openings, characterized in that a passageway is additionally made in the wall of the supply air duct to form a pair of coaxially located opposite passage openings, and the element is made in the form of an elastic nozzle enclosing the air duct around the perimeter with the possibility of elastically deformable contact with the latter and installed with overlapping a pair of opposed passage holes communicated with the nozzle along the perimeter of the chute, open from the side of the duct wall, while the passage holes are located opposite to the shielding wall troughs, and on the outside of the nozzle there is a pair of coaxial outlet openings communicated with the trough, the axes of which are located perpendicular to the axes of the opposed passage openings. 24. An air distributor according to claim 23, characterized in that the outlet openings are made of diffuser and / or the outlet openings are made of the same shape and size, and the passage openings are of the same shape and size. 25. Air distributor according to one of paragraphs. 23, 24, characterized in that on the wall of the air duct, on the side of contact with the nozzle, intersecting grooves or grooves are made with the formation of mesh corrugation, and / or the air duct is oriented horizontally. 26. An air distributor containing a rectilinear supply air duct with a passage opening in the wall, a shielding element with a cylindrical surface and the possibility of placing, covered by a shielding element, a pair of opposed outlet openings, characterized in that the supply air duct is cylindrical with a circular cross-section, and in the wall of the air duct is additionally made a through hole with the formation of a pair of coaxially located in the wall of opposed through holes, and the element is made in the form of an elastic cylindrical nozzle with a circular cross section, covering the air duct around the perimeter with the possibility of elastically deformable contact with the latter and installed with overlapping a pair of opposite through holes, and along the perimeter of the nozzle is made of an internal annular channel with a pair of coaxial inlet openings communicated with the latter, open from the side of the air duct wall and communicated with the through holes of the air duct, while The chimney holes are located opposite to the shielding wall of the channel, and on the outer side of the nozzle there is a pair of coaxial outlet holes communicated with the channel, the axes of which are located perpendicular to the axes of the inlet holes, while the nozzle is rotatable relative to the air duct with overlapping of the passage and inlet holes. 27. An air distributor according to claim 26, characterized in that the outlet openings are made of diffuser and / or the outlet openings are made of the same shape and size, the passage openings are of the same shape and size, and the inlet openings are of the same shape and size. 28. Air distributor according to one of paragraphs. 26, 27, characterized in that the air duct is oriented horizontally or the nozzles are mounted on the air duct with the possibility of fixing the position. 29. An air distributor containing a covering outlet openings, a shielding element, and the possibility of placing a supply air duct with a through hole, characterized in that the element is made in the form

-shaped crosspiece, including a supply pipe with an end inlet, and three outlet pipes with end outlets connected to the supply pipe, and longitudinal cuts are made from the ends of the outlet pipes and along the perimeter of the latter, with the formation of depressions and protrusions alternating with depressions, and the protrusions are bent towards the longitudinal axis of the corresponding outlet pipe with the formation of reflective screens oriented at an angle to the axis of the outlet pipe. 30. An air distributor according to claim 29, characterized in that the cross is detachable, the inlet and outlet pipes are made with rectangular cross-sections, and the axes of the said pipes are located in the same plane, and a hollow perforated insert is installed inside the cross, like an air flow divider in the form prisms with a cross-section bounded by the astroid, with the possibility of mechanical contact of the concave faces with the ribs formed by the intersection of the nozzles and / or each of the outlet nozzles is made with a channel having variable length, flow section and wall thickness to form a diffuser channel. 31. An air distributor containing a shielding element with a cylindrical surface and the possibility of placing a rectilinear supply air duct with a through hole, a straight air duct with a through hole located in the wall, covered by the shielding element, a pair of outlet holes, and a gap associated with the element, characterized in that the element is made as

-shaped tee, including a straight air duct with a channel of circular cross-section, a pair of end-end opposite outlets and a round through-hole located in the wall, and a cylindrical supply pipe of circular cross-section connected to the air duct with opposite end inlet and outlet openings, and the pipe is installed in a round the through hole of the air duct with the possibility of communication of the latter with the outlet of the branch pipe and the formation of a gap between the outlet and the opposed wall of the air duct, while the longitudinal axis of the branch pipe is oriented perpendicular to the longitudinal axis of the air duct with the formation of a concave shielding section of the wall of the air duct located opposite to the outlet opening of the branch pipe, and the branch pipe is made with variable along the length of the flow section and wall thickness with the formation of a conical diffuser channel. 32. An air distributor according to claim 31, characterized in that longitudinal cuts are made from the ends of the air duct and along the perimeter of the latter with the formation of depressions and protrusions alternating with depressions, and the protrusions are bent towards the longitudinal axis of the air duct with the formation of reflective screens with concave, from the flow side air, surfaces, and oriented at an angle to the longitudinal axis of the air duct. 33. An air distributor according to claim 31, characterized in that an internal screw thread is made along the length of the air duct for swirling air flows.

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