RU2552219C2 - Perforated air-release panel - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates primarily to the technique of ventilation and air conditioning. Character of the invention consists in the provision of perforated air-release panel, comprising a thin-walled perforated sheet perforated by the additional sheet, forming the double perforated panel, disposed at a distance, not exceeding the magnitude of 2 hydraulic diameters of the holes of the first sheet in the direction of the air flow. At that, the relative mutual location of centres of holes on both perforated sheets or their areas is subject to certain laws, and perforated sheets or their portions can be installed with possibility of relative displacement.

EFFECT: invention enabled to obtain the technical result, namely: possibility to change the initial air velocities (by magnitude and direction) in the air outlet openings of the panel, increase the level of turbulence and reduce the maximum speeds in the supply air flow, as well as to change the value of local resistance of the device or its local zones.

Description

The invention relates primarily to the technique of ventilation and air conditioning.

Known perforated panel containing one perforated sheet placed in a metal frame. Such air distributors - perforated panels under the brand name SPP, SKP are serially produced at Arktos LLC in St. Petersburg. These panels are supplied with static pressure chambers, which are recommended to be mounted behind a false ceiling to arrange air supply from top to bottom in rooms with a height of 2.5 ÷ 5.0 m.

The described panels have the following drawback: the range of the air flow at a standardized comfortable speed of 0.2 m / s is for all standard sizes (when the air flow generating acoustic vibrations with a power of 45 dBA is the norm for offices) a value exceeding 3 m. Such a range of air flow, due to the insufficient supply flow turbulence level (living section panel when coefficient K _xc = 0.3), does not allow to recommend similar articles for supplying air directly to the working area of public placed d.

It is also known the use of perforated panel panels, occupying a significant (more than 50%) area of the ceilings in the premises (perforated ceilings).

(The description and calculations of the methods of supplying air through perforated thin-sheet surfaces are described in many works of M.I. Grimitlin, for example, Distribution of air in rooms. St. Petersburg. Publishing House Avok North-West, third ed. And corrected, 2004. - 320 p.)

The disadvantage of this method of supplying air to the room is the demolition of the air flow in the lateral air supply, organized behind the false ceiling. To counteract the drift of the supply air flow, it is necessary to use perforated panel-plates of increased thickness or to give a hem-wedge-shaped shape.

The closest to the claimed solution for the technical nature and the technical result achieved by the air exhaust device is the so-called low-speed air distributor. Such an air distributor contains a perforated air outlet sheet of a cylindrical (or flat) shape and usually installed in front of it at a distance (with a gap) of 30–50 mm, an equal or close-in perforated additional sheet for preliminary passive alignment (stabilization) of the injected air flow. In this design (USSR AS No. 1564478, IPC F24F 13/06, published May 15, 1990), both perforated sheets are made in the form of two coaxially arranged cylindrical ducts. The air outlet sheet is the front of the air distributor body forming the static pressure chamber. The air supply to the device is carried out through the nozzle of the static pressure chamber on the side with respect to the perforated sheets. This device design is additionally equipped with a special central insert.

Perforated low-speed air distributors are widely used in public buildings, as they allow for low air velocities in the served area with high air exchange rates.

Low-speed devices are used in “displacement ventilation” type air distribution circuits, the use of which ensures a comfortable microclimate in the working area of the air-conditioned room while saving energy resources for maintaining it in comparison with competing air distribution schemes. (X. Skidstad (editor), E. Mundt, P. Nielsen, C. Hagstrom, I. Railio. Displacing ventilation in non-production buildings / Transl. From English - 2nd ed., Rev., - M .: ABOK -PRESS, 2006. - 104 p.)

The described device is taken as a prototype of the invention.

The disadvantages of the prototype:

- large specific dimensions of the air distributor (the ratio of the volume of the air distributor to the flow rate of the exhaust air flow), which are determined by the small living section of the perforated air _outlet panel (K _ws ≈0.12);

- unevenness in the area of the air outlet panel of the field of initial air velocities (in magnitude and direction of vectors) entering through the perforated holes into the room, due to inefficient - passive - uncontrolled interaction of the passing air flow with perforated panels, which determines the low quality of alignment of the parameters of the released air stream;

- the chaotic relative mutual arrangement of the centers of the holes of both perforated sheets does not provide the possibility of controlled - active alignment by changing the aerodynamic drag and giving the desired direction to the exhaust air flow.

An object of the invention is to change the initial air velocities (in magnitude and direction) in the air outlets of the panel, increase the level of turbulence and decrease the maximum speeds in the supply air stream, as well as change the aerodynamic drag of the device.

The problem is solved as follows, on one side of the perforated sheet of the air outlet panel, a perforated additional sheet is installed at a distance not exceeding 2 hydraulic diameters of the holes of the first perforated panel sheet along the air. Moreover, the relative mutual placement of the centers of the holes on both (double) perforated sheets or their sections obeys a certain pattern.

The elimination of the chaotic relative relative location of the centers of the holes on both perforated sheets allows you to effectively use the plot of the formation of individual air jets formed during the passage of the holes of the first along the air perforated sheet of the panel and do not have time to merge into a single air stream, before contact with the surface of the second - directly air release sheet (In ventilation technology, the use of the features of the formation section of the jet air flow usually does not find practical application).

Separate air jets, having local increased speeds, when reaching the surface of the blind areas located between the holes of the second perforated air outlet plate of the panel, actively interact with them, forming turbulent vortices that reduce maximum speeds at the outlet of the air outlet panel and equalize local speeds in area this panel. And the relative mutual arrangement of the centers of the holes of both perforated sheets, obeying a certain regularity, allows you to set (adjust) the desired direction (deviation) of the air outlet flow, which has a high level of turbulence. At the same time, the traditionally passive function of the perforated sheets installed in the air exhaust devices becomes active - generating new qualitative changes in the produced air flow.

The adjustable distance (gap) between the double perforated sheets or their sections allows you to change the aerodynamic drag of the device or its local zones, in order to control the flow rate of the exhaust air.

For example, only when the distance (gap) between the double perforated panels is close to zero, two opposite results can be achieved:

- when combining the centers of the holes of both perforated sheets, the air outlet panel will function almost like a single perforated panel (maximum air flow);

- with a staggered arrangement of the centers of the holes of both perforated sheets in the case of the length of the blind sections of the air outlet sheet equal to or greater than the size of the holes of the first sheet of air along the air, the flow of exhaust air will be minimal - close to zero.

When two perforated sheets are located at a distance not exceeding the size of 2 hydraulic diameters of the holes of the first sheet of air along the air, and the centers of the holes are mutually displaced within their step size, the described effects are realized that are observed in the discharged air stream (the displacement of the holes is considered when they are projected onto air discharge plane).

The results of a physical experiment showed that at distances between two perforated sheets exceeding the size of the 2 hydraulic diameters of the holes of the first sheet of air along the air, individual streams of air formed during the passage of the holes of this perforated sheet quickly lose their individuality - merge into the general air flow and the novelty effect disappears.

A physical experiment was carried out with equal diameters (5 mm) of the holes of both equal-sized perforated sheets ( _Ks = 0.3 and 0.4), installed parallel to each other. Moreover, the projection of the centers of the openings of the first perforated sheet along the air onto the surface of the second — the air outlet sheet coincided with the centers of its blind sections separating the air outlet openings — the staggered relative arrangement of the holes when they were virtually “aligned” in one plane.

A decrease in the maximum speed of the released air flow was _{recorded by 1.5–3.0} times (K _zhs = 0.3) and by 1.25–1.5 times (K _zhs = 0.4) at distances of 1–2 m from the air outlet panels. The results are shown in relation to the same maximum speeds measured at the same points in the room at equal flow rates of uniformly injected air, which was released from the test panel after dismantling the perforated additional sheet. In this experiment, the optimal distances between the perforated sheets were 4–8 mm. Excessive air pressure in front of the air exhaust panel was maintained at a level corresponding to that in competing versions of perforated air distributors.

The results of mathematical modeling of the process under study for the panel used in the physical experiment, using the STAR-CD software package, confirmed the possibility of controlling the air flow leaving the air outlet panel when changing the relative relative position of the centers of the openings of both sheets of the panel. For example, with the relative position of two perforated panel sheets at an angle within the specified distance between them ≤10 mm. Therefore, the perforated additional sheet or parts thereof with the aim of regulating the exhaust air flow can be installed with the possibility of movement. Moreover, the maximum range of relative movement of the perforated sheets along their surface is equal to the pitch of the holes.

The technical result of the proposed device is to change the initial air velocities (in magnitude and direction) in the openings of the air outlet panel, increase the level of turbulence and reduce the maximum speeds in the supply air stream, as well as change the aerodynamic drag of the device or its local zones, in order to control the discharge air flow .

Increasing the level of turbulence of the produced air flow additionally allows you to create and effectively use the advantages of the zonal small-scale "dynamic microclimate" at distances of 0.5 ÷ 1.0 m from the panel surface. This is especially effective when applying personal (individual) air conditioning at workplaces, for example, office workers.

The invention allows for its implementation and achievement of new characteristics in the known design of the prototype (while maintaining the number and function of the elements) to change only two factors:

- arrange the relative relative position of the centers of the holes of both perforated sheets of the panel,

- arrange the relative relative position of the two perforated panel sheets at a distance not exceeding the value of 2 hydraulic diameters of the holes of the first sheet along the air.

With the chosen structural dimensions of the perforation of the sheets of the air outlet panel, changing the values, the distance (gap) between the double perforated sheets, the relative displacement of the centers of the holes of both sheets and (or) the slope between their surfaces allows you to adjust the parameters (speed, turbulence, range, directivity, flow rate) of the exhaust air flow and aerodynamic drag of the device.

In the practical implementation of the invention, a competitive air outlet panel can be made of perforated sheets made with holes of increased diameter and with an increased value of the coefficient of its live section. This allows you to reduce the aerodynamic drag of the product or to reduce its overall dimensions.

Claims (1)

Perforated air outlet panel including a thin-walled perforated sheet, characterized in that it is provided with an additional perforated sheet installed with a counter total deviation from geometrically parallel relative positioning of the sheet surfaces, not exceeding the maximum clearance between them, equal to 2 hydraulic diameters of the holes of the first sheet in the air moreover, the mutual displacement of the centers of the holes of both sheets is set in the range from zero to the step size of the perforation of the holes d second along the air sheet.