DE4417715C1 - Air outlet - Google Patents

Description

The invention relates to an air outlet with a perforated, preferably cylindrical housing, after the preamble of claim 1.

Generic air outlets are from the DE 93 03 152 U1 known.

Air outlets are also known, the two at a distance Perforated air outlet shells arranged concentrically one inside the other to further equalize the Air outlet speeds with displacement air diffusers have, see DE 40 37 287 A1.

Such air outlets are generally known as displacement and spring air outlets known.

Spring air outlets of the generic type, predominantly placed on the floor have the disadvantage that the supply air over the entire perforated housing at very low speeds and almost without Induction, i.e. without admixing room air, through flows around the lounge area and thereby for heat dissipation only with a small under temperature of mostly Max. 4 K can be blown in, otherwise the vertical Temperature gradients in the occupied zone for the feeling of comfort becomes too great. The vertical Temperature gradients should range from foot to Head area should not exceed 2 K. Another disadvantage is that the cold supply air escaping through the higher density sinks to the floor, it turns thereby reducing the intake air layer height increasing distance from the air outlet and the indoor air flow rates  in the lounge area are larger than directly near the outlet. The layer height is usually so flat that the people not the supply air from the so-called cold air lake, but the indoor air contaminated by recirculation above the Kaltluftsee's with contamination levels of have to breathe in over 1. To be sufficient Producing layer heights is an enormous amount of supply air with smaller sub-temperatures required that are irresponsible cause high air production costs.

Another fundamental disadvantage is that with Swell outlets due to the lower air outlet speeds no heating operation is possible because the warm supply air to the ceiling immediately after it has swelled out rises.

The invention has for its object the generic To design the air outlet so that dosed Induction at higher air outlet speeds a much lower supply air volume flow with be blown much larger under temperature can, the room air speeds with increasing Distance from air outlet does not get bigger, but decrease, the supply air layer height slightly above head height grows and the air outlet becomes much smaller.

This task is in the generic air passage solved by the features of claim 1. Beneficial Embodiments of the invention are the subclaims refer to.

The metered induction is adjusted in the cooling case so that the supply air flowing through the lounge area is at least slightly colder than the room air temperatures and the degree of contamination of the air we breathe is well below 1. The dimensionless degree of contamination 1 states that the pollutants are in the air 100% evenly distributed.  

In heating mode according to the invention are in the air outlet Means adjusted, causing the air outlet direction stepless, slightly sloping to the floor is and the air outlet speeds increased be achieved in this way that the warm supply air flows through the lounge area and not directly climbs to the ceiling. The source air outlets of the generic type Kinds are usually set up on the floor and have no adjustment means for air jet steering. If these source air diffusers were brought in Height above head would be used in the cooling case waterfall ventilation with high indoor air velocities set in the lounge area. When heating the warm supply air would rise to the ceiling immediately.

It is a low-turbulence displacement air outlet known from DE 41 36 946 A1, for heating operation but not for placement on the floor suitable is. The supply air is considered low turbulence Displacement flow from a height of approx. 3 to 4 m above the Blown out floor. The air jet steering is through a higher adjustable conical baffle made below an inner housing in the Outer housing is arranged.

Another known air outlet from EP 401 481 is also preferred in industrial halls with larger room heights and can be used for incoming flow the supply air from above is usually above head height or at Inflow from below arranged directly above the floor become. An inflow of the supply air into the air outlet from below through the floor, however, is mostly and especially not feasible in industrial halls.  

At the air outlet EP 401 481 the air jet steering by means of height-adjustable or rotatable aperture rings made and in heating mode with large Openings become excessively hot in the bottom of the air outlet when the flow is from above Approved.

There are also displacement air outlets from EP 401 481 and DE 41 36 936 A1, which are generally known from be supplied with supply air above and above head height to be ordered.

EP 401 481 describes that the air outlet can be set up directly on the floor if there is an inflow from below is. An inflow from below through the However, flooring is mostly and especially in industrial halls not feasible. At the air outlet of EP 401 481 is the air jet steering according to the Load cases heating and cooling by means of height adjustable or rotatable aperture rings and in heating mode with large excess temperatures are additional Openings in the bottom of the air outlet are released to to blow the warm air down to the floor. In the air passage of DE 41 36 946 A1, the air jet steering through a height-adjustable conical Impact body made below one Inner housing is arranged in the outer housing.

The air outlet according to the invention with metered induction at higher air outlet speeds Spring air outlets can be equivalent to head height and be placed on the floor. Through its dosed larger exit velocities induced this air outlet after cooling at radially oblique blow-out direction on the top and additionally reinforced for installation on the floor  sufficient radial air in the lower side of the radial jets, a waterfall ventilation, i.e. the falling of the cold supply air with the consequence of high indoor air velocities to avoid. In the case of heating, the Means in the air outlet adjusted so that the supply air is blown out obliquely to steeply and the Flow area.

When placed on the floor, the air outlet placed on feet or a short distance above mounted on the floor, the housing except for the Floor can be extended. Air jet controls can by opening and closing the bottom or / and due to cross-sectional changes in the housing be, z. B. by means of the bottom of the air outlet Motor and control circuit for the heating process automatically and guaranteed to be opened and an additional one individual intervention via changes in cross-section is possible in the housing and vice versa.

Embodiments of the invention are in the drawing shown and are explained in more detail below.

It shows:

Fig. 1 shows a vertical section of the air outlet

Fig. 2 shows a vertical section - only the lower part - of a second variant

Fig. 3 shows a vertical section of a third variant

Fig. 4 is a vertical section - only the lower part - of a fourth variant

Fig. 5 is a vertical section of a fifth variant

FIG. 5.1 is a horizontal section AA according to FIG. 5

Fig. 6 is a vertical section of a sixth variant

Fig. 6.1 shows a horizontal section B-B of FIG. 6.

The air outlet consists of a perforated cylindrical housing 1 with an air inlet nozzle 3 and this opposite a bottom 5 that can be opened, an orifice plate 6 and a cutting disc 4 in the perforated housing 1 , in which an inner tube 2 is arranged concentrically.

In Fig. 1, a flap 7 for opening the perforated bottom 5 is pivotally mounted about an axis 8 . When the bottom 5 is closed, the air exits the perforated housing 1 at an upward radial angle. When the base 5 is open, the supply air flows out of the housing 1 and out of the openings in the base 5 downwards. The flap 7 can be adjusted manually or by a motor 10 via a lever (not shown) connected to the axis 8 .

In Fig. 2 only the lower area of the outlet is shown. In contrast to FIG. 1, the housing 1 is extended around the perforated housing 1.1 to be placed on the floor 13 here. The perforation in the lower housing 1.1 can be carried out differently than in the upper housing 1 . The bottom 5 has a central opening 5.1 , which can be closed by the flap 7 .

In Fig. 3, the flap 7 has been replaced by a height-adjustable plate 9 for opening and closing the bottom 5 . The cutting disc 4 is not perforated in this embodiment. The plate 9 can be adjusted by a motor 10 or by hand.

In Fig. 4 only the lower area of the outlet is shown. In contrast to FIG. 2, the air outlet is here with feet 12 on the floor 13 . Unlike in FIG. 3, the plate 9 lies here within the housing 1 .

In the exemplary embodiment according to FIG. 5, the base 5 is designed with a round disk 5.2 rotating and sliding horizontally on it. Congruent openings 5.3, 5.4 are provided in the bottom 5 , as in the disk 5.2 , which can be closed or opened by rotating the disk 5.2 .

In the variant according to Fig. 6 and Fig. 6.1 bottom is executed in the same manner as in FIG. 5 and FIG. 5 5.1. In the illustration of FIG. 6 and FIG. 6.1 of the bottom is, however, 5 is closed. In addition, the inner tube 2 has a bottom 14 with openings at the bottom. Under the floor 14 there is a horizontally rotatable disk 14.1 with congruent openings. The disk 14.1 and the disk 5.2 can be rigidly connected to one another in a rotatable manner. In the position shown in FIG. 6, air flows through the base 14 and the disk 14.1 , the air flows out of the housing 1 radially upwards at an angle. By rotating the disc 14.1 in conjunction with disc 5.2 , the base 14 is closed and the base 5 is opened. The air flows downwards out of the air outlet 1 - heating.

The discs 14.1 and 5.2 can also be designed so that they can be rotated separately.

As shown in FIGS. 1 and 4, the cutting disc 4 can be closed or perforated, it has an influence on the direction of the radially emerging air jets.

In an example that is not shown, the cutting disc 4 can also be made variable in the perforation by placing a disc that can be rotated horizontally around the inner tube 2 on the cutting disc 4 and both discs have perforations that close or open the disc lying on the cutting disc 4 by twisting can be.

In a further exemplary embodiment, not shown, the inner tube 2 can be designed with flow-influencing means for changing the flow cross section, such as a perforated plate, an orifice plate, a pivotable orifice plate or flap, an iris diaphragm or perforated disks which can be rotated horizontally relative to one another.

Claims (15)

1. Air passage with a perforated, preferably cylindrical housing ( 1 ) with an air inlet socket ( 3 ) and with a bottom opposite this ( 5 ), wherein in the perforated housing ( 1 ) at least one orifice plate ( 6 ) is arranged, characterized in that concentric An inner tube ( 2 ) with a cutting disc ( 4 ) is arranged in the perforated housing ( 1 ) and the bottom ( 5 ) can be opened continuously for air jet steering. 2. Air outlet according to claim 1, characterized in that the bottom ( 5 ) is perforated and can be opened by a pivotable flap ( 7 ) about an axis ( 8 ). 3. Air outlet according to claim 1 and 2, characterized in that the bottom ( 5 ) and the pivotable flap ( 7 ) have perforations that are not congruent. 4. Air outlet according to claim 1, characterized in that a pivotable flap ( 7 ) or iris diaphragm is arranged in an opening ( 5.1 ) in the bottom ( 5 ). 5. Air outlet according to claim 1, characterized in that the bottom ( 5 ) air passage openings ( 5.4 ) and about it about an axis ( 8.1 ) rotatable and with the air passage openings ( 5.4 ) congruent openings ( 5.3 ) provided disc ( 5.2 ) for opening and closing the bottom ( 5 ). 6. Air outlet according to claim 1, characterized in that the opening (s) ( 5.1 ) in the bottom ( 5 ) by an up and down movable plate ( 9 ) can be opened and closed (and) and the plate ( 9 ) above or can be arranged below the bottom ( 5 ) and can also be moved through the bottom ( 5 ). 7. Air outlet according to claim 1 to 6, characterized in that the flow cross section in the housing ( 1 ) and in the inner tube ( 2 ) can be changed to influence the air jet. 8. Air outlet according to claim 1 to 7, characterized in that the flow cross-section of the inner tube ( 2 ) by means of an iris diaphragm ( 11 ), a pivoting diaphragm, pivotable flap or a pair of disks rotatable relative to one another (bottom 14 , disk 14.1 ) with congruent openings is changeable. 9. Air outlet according to claim 1 to 8, characterized in that the cutting disc ( 4 ) is perforated. 10. Air outlet according to claim 1 to 8, characterized in that the cutting disc ( 4 ) is closed. 11. Air outlet according to claim 1 to 9, characterized in that two cutting discs ( 4 ) directly one above the other with congruent openings, one fixed and one radially rotatable, are present and thereby the flow cross-section in the housing ( 1 ) is continuously variable. 12. Air outlet according to claim 1, 7 to 11, characterized in that the rotatable disc ( 14.1 ) for closing the inner tube ( 2 ) and the rotatable disc provided with openings ( 5.2 ) are rotatable together and that when the bottom ( 5 ) is open Inner tube ( 2 ) is closed. 13. Air outlet according to claim 1 to 12, characterized in that the housing ( 1 ) below the bottom ( 5 ) by a perforated housing ( 1.1 ) can be placed directly on the floor ( 13 ). 14. Air outlet according to claim 1 to 12, characterized in that the housing ( 1 ) by means of feet ( 12 ) on the floor ( 13 ) can be set up. 15. Air outlet according to claim 1 to 14, characterized in that the air jet steering by means of motor Control loop or independently influenced manually is.