EP0619462A2 - Air outlet - Google Patents

Abstract

The invention relates to an air outlet having at least one air outlet opening which is assigned an air chamber continuously supplied with preferably treated supply air, and having a pressure-increasing device which produces in the air chamber preferably pulse-like, in particular periodic air pressure increases such that appropriate quantities of air are ejected in each case as vortices along a vortex path from the air outlet opening. Provision is made for the air chamber (2) to be assigned at least one pressure frequency source (30) for generating air pressure vibrations. <IMAGE>

Description

The invention relates to an air outlet with at least one air outlet opening, which is associated with an air chamber continuously supplied with preferably treated supply air, and with a pressure increasing device which preferably generates pulsed, in particular periodic, air pressure increases in the air chamber in such a way that corresponding amounts of air are each produced as vortices along a vortex street the air outlet opening.

Air outlets are known in many different designs. They are used, for example, to ventilate or air-condition a common room. The distance between the lounge area in the lounge and the individual air outlets is often relatively large.

For example, if the rooms to be ventilated are halls, there are installation heights of 6 to 8 m or installations on the side walls of the halls, whereby the halls can have a width of 20 to 30 m. The supply air temperature depends on the respective heating or cooling load. she can for example in the range between 16 ° and 30 ° C. The penetration depth of the supplied air into the room depends on the difference to the room temperature. Particularly when heating is required, a correspondingly high blowing-out speed of the supply air emerging from the air outlet is required in order to blow sufficiently deep into the room. If large distances have to be covered, for example in the halls mentioned above, conventional air outlets usually do not produce a satisfactory result. Induction effects are undesirable to a large extent, since pollutants that can accumulate above the area where the room is located are returned to this area by introducing the supply air through admixture.

In order to discharge the supply air, in particular over large distances, without causing a substantial mixture with the ambient air, it is provided that the air chamber is assigned a pressure-increasing device which, in the air chamber, preferably generates pulsed, in particular periodic, air pressure increases in such a way that corresponding amounts of air are in each case as vortices are expelled from the air outlet opening along a vortex street. The supply air flowing continuously into the air chamber is expelled from the air outlet opening due to the pressure-increasing device, which leads to eddy formation, so that eddy air flows along a desired direction, that is, along the vortex road mentioned, the stay zone are fed. Because of their swirl, these air vortices form relatively tightly holding together structures, so that there is only an insignificant interference of bypass air when these vortices are carried out along the vortex street. The pulse-like emergence of the air vortices leads to the fact that they can be directed specifically over large distances to the desired spatial zone.

With such an air outlet, it is thus possible to introduce the air into the desired zone of the room.

In order to increase the versatility of this air outlet according to the invention, it is provided that the air chamber is assigned at least one pressure frequency source for generating air pressure vibrations. In addition to the pressure increasing device, which serves to eject the air vortices from the air outlet opening, a further device, namely the pressure frequency source, is thus provided, with which air pressure vibrations are generated within the air chamber. These air pressure vibrations do not serve to eject the vertebrae, but influence the ejection of the vertebrae. Depending on the type and strength of the air pressure vibrations, the penetration depth of the vortices into the room to be ventilated can be influenced in particular. It is also possible to influence the direction of the ejected vortices, ie the direction of the vortex street. There is also the possibility of expanding the vertebrae, that is, enlarging the vertebrae in the course of the transverse Whirling movement. As a result of this influence, in the heating case, i.e. when heated air is blown into the room, the eddies can be introduced far into the lounge area of the room, so that, for example, sufficient heating is also achieved in the floor area so that people who are in the room feel subjectively comfortable. In cold cases, i.e. when cooled air is introduced into the room, the depth of penetration of the air vortices can be changed by adjusting the pressure frequency source in such a way that the vortices penetrate less far into the room than in the heating case, in order to avoid drafts that occur in this room zone people who are staying are perceived as unpleasant.

It is also advantageous if the pressure frequency source has an electromagnetic excitation device. Such an excitation device can be controlled very easily with signals of various types, as a result of which the desired influence on the ejected vertebrae can take place. The pressure frequency source can in particular be designed as or in the manner of a loudspeaker, that is to say it has an electromagnetic excitation device and a membrane excitable by it, which is located within the air chamber or forms a wall or part of a wall of the air chamber. This pressure frequency source is preferably connected to an electrical frequency generator which generates selectable drive voltages, so that the pressure frequency source can be excited in a corresponding manner. The Control voltage can be changed in its curve shape and / or in its frequency and / or in its amplitude and can be specified in the desired manner. For example, it is possible to supply various voltage forms, such as sine voltages, square-wave voltages, triangular voltages, etc., to the pressure frequency source, which reacts in a corresponding manner and generates associated air pressure vibrations. A frequency selection makes it possible, in particular, to generate a resonance state in the air chamber, as a result of which it is possible to influence the air vortices particularly strongly. The strength of the air pressure oscillations can be influenced by means of the adjustable amplitude of the control voltage, which likewise leads to effects on the vortices to be ejected.

It is preferably provided that the pressure frequency source is opposite the air outlet opening. For example, the air chamber can be designed as a cuboid or cuboid space. The pressure frequency source is then arranged on the wall of the air chamber, which is opposite the wall of the air chamber provided with an air outlet opening. However, in addition to this preferred variant mentioned above, other designs are also possible, that is to say the pressure frequency source can also be arranged on another wall of the air chamber. In the aforementioned preferred embodiment of the juxtaposition of the air outlet opening and the pressure frequency source, provision can furthermore be made for an air supply line to open into one of the walls of the air chamber, this wall being neither the Pressure increasing device still has the pressure frequency source. By means of the supply air line, the air chamber is continuously supplied with supply air, which is then blown out through the blow-out opening and whose flow shape is influenced by the pressure increasing device. According to other exemplary embodiments, however, the supply air line can also be assigned differently, that is to say it can also open into a wall which, for example, likewise has the pressure frequency source.

It is possible for the pressure increasing device to work according to the electromagnetic principle, that is to say it has a coil which moves a membrane by electromagnetic means, which means that pulsed air pressure increases can be generated in order to expel the vortices. This same electromagnetic device can also be excited by the electrical frequency generator, so that it simultaneously forms the pressure frequency source, the vibrations generated to bring about the air pressure vibrations being superimposed by corresponding pulses in order to eject the vortices.

Figur 1

einen Luftauslaß für den Austritt von Toruswirbeln,

Figur 2

eine Draufsicht auf den Luftauslaß gemäß Figur 1 und

Figur 3

einen Luftauslaß für den Austritt von Stabwirbeln.

The drawings illustrate the invention using exemplary embodiments and show:

Figure 1

an air outlet for the exit of torus vertebrae,

Figure 2

a plan view of the air outlet according to Figure 1 and

Figure 3

an air outlet for the exit of rod vortices.

Figure 1 shows an air outlet 1, which is shown only schematically. The air outlet 1 has an air chamber 2, which is cubic. It has a front wall 3, a rear wall 4, side walls 5 and 6 as well as a bottom wall 7 and a top wall 8.

In the front wall 3 there is an air outlet opening 9 which has a circular cross section. A supply air line 10 opens into the side wall 5, via which the interior of the air chamber 2 is continuously supplied with supply air 11 (primary air), in particular processed supply air. According to FIG. 2, the side wall 6 of the air chamber 2 is designed as an elastic wall, in particular as a rubber membrane 12, which is connected to an iron core 14 via an actuating rod 13. The iron core 14 is longitudinally displaceable within an electrical coil 15 which is connected to a frequency generator 16. Alternatively, it is of course also possible that the actuating rod 13 or a corresponding device is connected to the coil 15, which is movable in the magnetic field of a permanent magnet.

Corresponding to the excitation frequency, the excitation strength and the time course of the excitation of the coil 15 by means of the frequency generator 16, the iron core 14 is moved, which is via the actuating rod 13 deflects the rubber membrane 12. As a result, corresponding air pressure increases are generated in the interior of the air chamber 2, which lead to the ejection of air vortices from the air outlet opening 9 of the air outlet 1. Depending on the excitation and design of the air outlet opening 9, the shape of the individual air vortices 17 emerging from the air outlet opening 9 can be changed. For example, FIG. 1 shows a torus vertebra with a torus diameter d and a free diameter D of the torus ring. The individual vortices move along a vortex street, the direction of which is indicated by the arrow 18 in FIG.

According to FIG. 2, a pressure frequency source 30, which has an electromagnetic excitation device 31, is arranged on the rear wall 4 of the air chamber 2. The pressure frequency source 30 is preferably constructed as a loudspeaker or in the manner of a loudspeaker, that is to say it has a membrane which forms part of the wall of the air chamber 2 and which can be electromagnetically excited. The pressure frequency source 30 is connected to a frequency generator 33 via an electrical connection 32. The frequency generator 33 supplies drive voltages which can be selected in the curve shape, in the frequency and / or in the amplitude. Depending on the application, it is also possible for a specific control voltage to be supplied to the pressure frequency source 30 with a specific curve shape, a specific frequency and a specific amplitude. As a result, the pressure frequency source generates 2 air pressure vibrations in the interior of the air chamber, which have an effect on the penetration depth of the vortices ejected from the air outlet opening 9 by means of the pressure increasing device and / or on the direction of the vortices (direction of the vortex road (arrow 18)) and / or on the widening of the vortices due to the vortex movement. As can be seen in FIG. 2, the front wall 3 has the air outlet opening 9 and the rear wall 4 opposite the front wall 3 has the pressure frequency source 30. The side wall 5 standing at a 90 ° angle to the front wall 3 is provided with the supply air line 10 and the side wall 6 opposite the side wall 5 is provided with the pressure increasing device.

FIG. 3 shows a further exemplary embodiment of an air outlet 1, the air chamber 2 of which is cylindrical in shape with a circular cross section. In the jacket wall 19 of the air chamber 2, a rectangular air outlet opening 9 is provided, from which, due to a pressure-increasing device, which, for example, can also have a rubber membrane 12 with an excitation device, rod vortices 20 emerge along a vortex street 18. The pressure increasing device can be located, for example, on the circular end wall 21 of the air chamber 2 (not shown). The supply air line 10 is located at the opposite end of the end wall 21. Furthermore, the air chamber 2 of the exemplary embodiment in FIG. 3 is also provided with a pressure frequency source which is connected to a corresponding frequency generator. This is not shown in FIG. 3. For example it is possible to also accommodate the pressure frequency source 30 on the end wall 21 of the air chamber 2. As already mentioned, it is also possible to provide only one electromagnetic excitation device which both generates the pulsed air pressure increases for ejecting the vortices and also works simultaneously as a pressure frequency source.

Claims (11)

Air outlet with at least one air outlet opening, which is associated with an air chamber continuously supplied with preferably treated supply air, and with a pressure increasing device, which preferably generates pulsed, in particular periodic, air pressure increases in the air chamber such that corresponding amounts of air are expelled from the air outlet opening as vortices along a vortex street , characterized in that the air chamber (2) is assigned at least one pressure frequency source (30) for generating air pressure vibrations. Air outlet according to claim 1, characterized in that the pressure frequency source (30) has an electromagnetic excitation device (31). Air outlet according to one of the preceding claims, characterized in that the pressure frequency source (30) is designed as or in the manner of a loudspeaker. Air outlet according to one of the preceding claims, characterized in that the pressure frequency source is connected to an electrical frequency generator (33). Air outlet according to one of the preceding claims, characterized in that the frequency generator (33) supplies at least one selectable control voltage for the pressure frequency source (30), which control voltage has a selectable curve shape and / or a selectable frequency and / or a selectable amplitude. Air outlet according to one of the preceding claims, characterized in that the pressure frequency source (30) generates such air pressure vibrations that a resonance state is generated in the air chamber (2). Air outlet according to one of the preceding claims, characterized in that the pressure frequency source (30) generates air pressure vibrations such that the depth of penetration of the vortices (17, 20) ejected from the air outlet opening (9) by means of the pressure increasing device is influenced and / or that the direction of the vortex street (arrow 18) is influenced and / or that the widening of the vertebrae which occurs in the course of the vortex movement is influenced. Air outlet according to one of the preceding claims, characterized in that the pressure frequency source (30) is opposite the air outlet opening (9). Air outlet according to one of the preceding claims, characterized in that the pressure frequency source (30) is arranged on the wall (rear wall 4) of the air chamber (2) which lies opposite the wall (front wall 3) of the air chamber (2) provided with an air outlet opening (9) . Air outlet according to one of the preceding claims, characterized in that a supply air line (10) opens into a wall (side wall 5) and that neither the pressure increasing device nor the pressure frequency source (30) are associated with this wall (side wall 5). Air outlet according to one of the preceding claims, characterized in that the pressure increasing device simultaneously forms the pressure frequency source (30).

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