NL8004591A - AIR EXHAUST FROM CLIMATIZATION PLANTS. - Google Patents

Description

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Air outlet Tan air-conditioning systems

The invention relates to an air outlet from air-conditioning installations, in particular for large production halls, exhibition or exhibition halls, transport halls and the like.

In such large spaces, a constant airflow is necessary, which can be adapted to the different load conditions in all seasons by changing the air outlet direction and by the degree of turbulence. These air outlets, due to the use of the roof of the hall, for example for overhead traveling cranes, or because such a roof does not allow the load from the aeration installation 10, and finally also because such halls are partly open, as is the case with sports halls, in the area between the roof and the wall. The installation is either mounted in this corner range or also portal-like on the walls ♦

In a well-known installation (H. Brockmeyer "Die Strahlluftung 15 der Olyrnpia-Sporthalle" in the magazine "Gesundheits-Ingenieur" 1972, pages 161-1TO), the aeration section is mounted on the upper gallery behind and above the last spectator row. The supplied air is blown in via free-jet nozzles, the warm supplied air, in the case of heating, in the direction towards the bottom, isothermal air approximately horizontal, and cold supplied air, in the case of cooling, blown upwards at an angle. The control of the swiveling nozzle pot is technically laborious and the turbulence of the exiting jet cannot be controlled.

The object of the invention is now to improve and perfect an air outlet of the above-mentioned type in such a way that, with simple construction, it has the same effect and also enables the degree of turbulence and thereby the depth of penetration of the air flow to be varied.

An air outlet for air-conditioning installations, in particular for jet aeration of large halls, which is arranged on the side walls in the upper region thereof and in which the air flow emerges from two separate outlets with different effect, one outlet being arranged pivotally in the other for this purpose, according to the invention, further characterized in that at least one nozzle with the same jet direction is arranged in a cylindrical outlet 800 4 5 91 -2-.

In further elaboration of the invention, a nozzle can be pivoted centrally in a cylindrical outlet acting in the direction of the cylinder shaft and bearing a closing member, around which the annular turbulence-generating means are arranged.

Further characteristic features for the invention are set out in claims 3-8 following the figure description below.

In the drawing, by way of example only for the invention, three embodiments according to the invention are schematically shown. Referring to this, the invention will now be further elucidated.

Fig. 1 shows a cylindrical air outlet with built-in pivoting nozzle and a twist-triggering blades; FIG. 2 shows a number of air outlets with their twist-triggering members of FIG. 1 in a box-shaped outlet side by side applied; Fig. 3 shows a tubular air outlet, in the longitudinal opening of which segment-shaped fins and, in between, nozzles 20 are arranged in the jacket; Figures 5 and 6 are sectional views of the air outlet of Figure 3 in three different positions of the nozzles; Fig. 7 shows a tubular air outlet, in the longitudinal opening of which fins are arranged in the casing, and in which a second tube is also mounted concentrically in rotation with a longitudinal opening in the casing; Figures 8, 9 and 10 are sectional views of the air outlet of Figure 7 through three different positions of the second tube; Fig. 11 schematically shows an arrangement of air outlets in a portal; Figures 12 and 13 show, respectively. schematic view and cross-section of the placement of the air outlets in an aeration head carried by a column.

Centrally located in the cylindrical outlet 1 is a mouthpiece 2 pivotally mounted in the spherical half-shell 3. Between the shell 3 and inner wall k of the outlet, pivoting, a "twist" motion-causing blades 5 are arranged radially. Instead of such vanes, for example, perforated plates can also be used as means for generating turbulence. An adjustable closing member, which is indicated as disc 6, is mounted in front of the air inlet opening in the mouthpiece.

In the case of heating, the nozzle 2 is directed to the bottom. Concerning isothermal aeration and when cooling is required, the nozzle is closed with the disc 6, so that the supply air only exits from the ring around the nozzle. The airflow exiting from the nozzle upon heating has a high velocity and should flow down to the room where one is to be held, while the airflow exiting around the blades through said blades creates a turbulence. degree of adjustable strength and therefore has a rapid loss of speed.

The outlet according to fig. 1 can be mounted at random distances distributed on the upper wall part of a hall and each nozzle can be directed according to the circumstances in the room.

FIG. 2 shows that in a common box-shaped outlet a number of nozzles according to FIG. 1 can be arranged side by side with their turbulence-generating members.

In Figs. 3-6, in the tubular outlet 11, segment-shaped slats 13 carried by the tube segment 12 are arranged in the free sections 20 of the tubes 12 and between the slats and thereafter, in the circular arc, the nozzles 1 and 15. Behind the series of slats is a grille 16 as a turbulence-generating device. The lamellae 13 can be pivoted individually or in groups by hand or mechanically, in a manner not specified in the drawing.

The openings of the adjacent nozzles - which are shown rectangular in the present case but may also be round - should increase in arrow direction, ie in the direction of the blown air, in order to ensure that the pressure remains the same over the full length.

If it is the case that cooling is to be carried out, i.e. preferably in the summer, the tube segment 13 is rotated in the position according to fig., So that the cool air is blown upwards through the nozzles 15. The depth of penetration of the air flow is influenced by the degree of turbulence of the air exiting between the slats 13, which is disturbed by the grille 16.

In the isothermal case (Fig. 5) both nozzle series Ik and 15 are switched off by corresponding rotation of the tube segment 13. all air exits between the slats 13.

When heated (fig. 6), the nozzle series 1U is hoisted. Here, too, the penetration depth of the warm air is controlled by the turbulence of the air exiting between the slats.

In the example according to Figs. 7-10, a vertical axis can be pivoted 23 cm in the longitudinal opening of the tubular air outlet 21, the pivoting can take place individually or also in groups. The tube 2k with its slot-shaped outlet 25 is rotatably mounted concentrically with respect to the outlet 21. The direction of the incoming air is indicated by an arrow.

This slot also widens with the blow-in direction.

In the case of cooling (Fig. 8), the tube 2b with its outlet 25 is turned down. The cool air emerging from the trench strikes the inner wall of the outlet 21 and is reversed in the direction towards the ceiling between the slats 23, thereby undergoing a certain degree of turbulence.

In the isothermal case (fig. 9) the outlet 25 is behind the slats 23 s so that the air exits directly.

When heated (Fig. 10), the warm airflow exiting the outlet 25 is reflected on the upper inner wall of the outlet 21 and exits downwards between the slats 23.

The air outlets can be arranged, as schematically shown in Fig. 11, as a cross connection 31 of a gantry 33 formed together with the vertical air supply pipes 32 (indicated by air screws).

According to Figures 12 and 13, the invented air outlet is housed in an aeration head k2 carried by the supply air tube 1 + 1.

The supplied air flows out of three separate nozzles 1 + 1 + in three directions, separated for example by flexible shafts 1 + 3 for simultaneous pivoting.

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Claims (7)

1. Air outlet for air-conditioning installations, in particular for jet ventilation of large halls, which outlet is arranged on the side walls, in the upper region thereof, and in which the air flow emerges from two separate outlets of different effect, 5 of which one outlet has swivel hair in the others are provided, characterized in that in a cylindrical outlet (1; 21) at least one nozzle with the same jet direction (2; 1U, 15; 2ky 25) is arranged. Air outlet according to claim 1, characterized in that in a cylindrical outlet (1) acting in the direction of the cylinder axis, a nozzle (2) is pivoted centrally, and provided with a closing member (6), around which, annular turbulence generating means (5) are provided * Air outlet as claimed in claim 2, characterized in that a swirling blades (5) which cause twisting (5) are arranged as turbulence-causing means. b. Air outlet according to claim 2, characterized in that rods arranged as turbulence are arranged radially. Air outlet according to at least one of claims 2, 3 or k, characterized in that a number of nozzles (2) with their means (5) causing turbulence are arranged side by side in a common, elongated outlet. Air outlet according to claim 1, characterized in that in a cylindrical outlet (11) provided with a longitudinal opening in the jacket, a tube segment (12) is rotatably mounted concentrically, which segment corresponds to a longitudinal opening of the outlet. longitudinal opening in a number of cross-sectional planes carries segment-like slats (13), while nozzles (1b) are arranged between these slats and subsequently at the ends thereof. Air outlet according to claim 6, characterized in that grids (16) are arranged between the 30 slats (13). Air outlet according to claim 1, characterized in that in a number of cross-sectional planes of a cylindrical air outlet (21) provided with a longitudinal opening (22) in the jacket, rectangular blades (23) are pivotally mounted about vertical axes, while concentrically is rotatably mounted with respect to and cylinder (2U) provided in the air outlet (25). 800 45 91