EP0657014B1 - Air outlet for ventilation installations - Google Patents

Abstract

An air outlet ventilation installation, in particular for hall-like interiors, is arranged at the outlet of an air supply duct (1) and has at least a propelling nozzle (3) for a propelling air jet and a discharge field (4) provided with a plurality of discharge openings adjacent to the propelling nozzle (3) to draw trailing air out of the air supply duct. At least one shield (5) which laterally extends approximately in the direction of the air jet is associated to at least the propelling nozzle (3). The shield (5) at least partially covers the discharge area of the propelling nozzle (3) and protects it against the inflow of ambient air. Thanks to the shield (5), trailing air is drawn mainly out of the discharge field (4) by the kinetic energy of the air jets that leave the propelling nozzles.

Description

The invention relates to an air outlet for a ventilation system for ventilation of rooms, especially of hall-like rooms, each at the exit of a Air supply duct is arranged and with at least a propellant nozzle for a propellant jet and one of the Driving nozzle adjacent exit field for out of the air duct air to be extracted, which is a variety of outlet openings.

From NL-A-6610938 an air outlet is the above known type known, with the unpleasant drafts should be avoided. The disadvantage of this previously known However, the facility is that through the exit field, especially if the exit field at the same time is designed as a filter, only insufficient amounts of drag air be carried out. Another disadvantage of the previously known Setup is that about the propellant jets a significant space vortex is induced when in the case of large rooms, the fresh air to be supplied also should get into room areas that have a greater distance from the air outlet. To achieve this is it required the propellant air with a significant flow rate to blow into the room so that the Specification of a draft that is as free of draft as possible so-called source ventilation cannot be achieved here. A another disadvantage is that a relative high energy consumption for appropriately designed fans must be used.

From DE-A-28 51 046 is an air outlet device for Room air conditioning and ventilation systems known, at the air duct at the outlet points each with a perforated plate covering the outlet opening for Tow air is provided. The one with the perforated plate The exit area is encircled with a collar-shaped apron provided to allow access to room air in the immediate exit area. The This system uses a separate, provided propellant nozzle integrated in the perforated plate, via a separate pipe network using a additional pressure generator is made available. Such a two-channel system with an additional pressure generator causes a not inconsiderable additional effort both in the construction and operation of such a system.

The invention has for its object an air outlet of the kind described in the introduction to improve that the kinetic provided by the propellant nozzle Energy essentially only for acceleration and the transport of the tow air is available, without this causing a noticeable whirl of indoor air is induced.

This object is achieved according to the invention with the Labeling part of claim 1 specified means. By shielding the propellant nozzles, as a rule several propellant nozzles are assigned to each air outlet achieved that over the kinetic energy of the Air jets escaping air jets primarily Drag air is extracted from the exit field and practically all of it via the air supply duct Air provided far into the room to be ventilated Space is carried in. The arrangement is convenient so that about 10 to 30% of the over the amount of air to be supplied via the propellant nozzle and correspondingly 90 to 70% over the exit field is brought into the room. Since practically no induction is exerted on the still air, pro Unit of time up to twenty times the volume exclusively Circulate draft-free via the air outlet.

The fact that the free passage cross section of the propellant nozzle part of the exit field to be attributed greater than that is the driving nozzle, but a higher penetration resistance has, it is ensured that the air outlet be carried out without dividing the air supply duct can. The exit field is expediently marked by a Perforated plate formed. The backlog resistance of such Perforated plate is sufficient even with relatively large individual diameters the holes out to make the necessary differences in the passage resistance between the driving nozzle and the exit field to create. Another advantage is here in the fact that large-area exit fields can be created, in the corresponding propellant nozzles are used.

While it is basically possible, the shielding to effect by a baffle or the like is in one Embodiment of the invention provided that the shield at least in part through a channel-like extension of the air outlet is formed which is the outlet plane protrudes beyond the motive nozzle in the jet direction and at least has a part of the exit field for the drag air. This is particularly useful when arranging several Driving nozzles next to each other ensures that the from the Propellant jets emerging at least partially can expand and this due to the pressure conditions practical within the channel-like extension only drag air from the exit field of the Propellant air jets is taken. Only at a greater distance the exit field then has a slight impact Induction of indoor air. It is particularly useful it when the exit field is in the form of a channel-like Extension is formed and at least the driving nozzle partially encloses.

In an advantageous embodiment of the invention is also provided that the exit field at least partially essentially perpendicular to the jet axis of the driving nozzle is aligned.

In a further advantageous embodiment of the invention it is provided that at least part of the exit field aligned at an angle to the jet axis of the driving nozzle is, the outlet openings of the beam axis are turned. This arrangement is the mixing the drag air improved with the propellant air. Appropriately it is here when the exit plane of the exit openings of the exit field approximately parallel to the exit plane the nozzle are aligned.

In a useful further embodiment of the invention provided that the driving nozzle with respect to its jet axis is adjustable. With this arrangement the advantageous possibility given with standard components to meet different operational requirements. So one is supplied with cold air in the to be ventilated Place the propellant nozzle below the outlet field, then the jet axis of the propellant nozzle slightly upwards is deflected, the exit field expediently is arranged above the driving nozzle and thus from the driving jet the drag air is "carried" into the room. At the supply of warm air, the arrangement is convenient hit the other way around, so that with one above the Exit field arranged driving nozzle, the jet axis is slightly deflected down over the exit field supplied warm air "pressed" into the room becomes.

Fig. 1

eine Seitenansicht eines Luftaustritts, teilweise im Schnitt,

Fig. 2

eine Stirnansicht des Luftaustritts gem. Fig. 1 in einer Ausgestaltung mit mehreren Treibdüsen,

Fig. 3

eine andere Anordnung des Luftaustritts gem. Fig. 2,

Fig. 4

eine andere Ausgestaltung des Luftaustritts gem. Fig. 1,

Fig. 5

in einer Seitenansicht die Bauform des Luftaustritts gem. Fig. 1 mit nur einer Treibdüse, teilweise im Schnitt,

Fig. 6

eine Stirnansicht des Luftaustritts gem. Fig. 5,

Fig. 7

eine weitere Ausführungsform eines Luftaustritts, teilwesie im Schnitt,

Fig. 8

eine Stirnansicht des Luftaustritts gem. Fig. 7,

Fig. 9

im Schnitt eine Abwandlung des Luftaustritts gem. Fig. 7.

The invention is explained in more detail with reference to schematic drawings of exemplary embodiments. Show it:

Fig. 1

a side view of an air outlet, partially in section,

Fig. 2

a front view of the air outlet acc. 1 in an embodiment with several driving nozzles,

Fig. 3

another arrangement of the air outlet acc. Fig. 2,

Fig. 4

another embodiment of the air outlet acc. Fig. 1

Fig. 5

in a side view the design of the air outlet acc. 1 with only one driving nozzle, partly in section,

Fig. 6

a front view of the air outlet acc. Fig. 5,

Fig. 7

another embodiment of an air outlet, partly in section,

Fig. 8

a front view of the air outlet acc. Fig. 7,

Fig. 9

on average a modification of the air outlet acc. Fig. 7.

The one in Fig. 1 in a side view and in Fig. 2 in a Air outlet shown in front view is as a final component 1 formed for an outlet on an air supply duct 2. The air outlet is essentially made up of several Driving nozzles 3 for generating driving jets that can be pivoted can be stored so that the beam axis 7 of each generated driving jet adjustable in its angular position is. The driving nozzle 3 is an exit field 4 for drag air assigned, which is formed for example by a perforated plate is and that in the illustrated embodiment located above the level of the driving nozzles 3. In Fig. 2 is the perforated plate schematically through the cross hatching shown. The exit field is designed so that its surface is not only above the outlet nozzles 3 but also clearly on both sides in the Extends into it. If the air supply duct 2 supplied with supply air, part of this air enters through the driving nozzles 3 in the form of several driving jets in the room. The other part of the air is over that Exit field introduced into the room. The passage cross sections the driving nozzles on the one hand and the total cross-sectional area the exit field 4 on the other and the corresponding flow resistances of the driving nozzles 3 on the one hand and the exit field 4 on the other are coordinated so that the flow rate the driving jets in the area of the nozzle orifice is two to five times as high as that from the exit field 4 escaping drag air.

Such an air outlet is in the to be ventilated Space at an appropriate distance above the floor, for example in a workshop to be ventilated Introduced into the room at a height of over three meters. To prevent this from happening through the drive nozzles 3 exiting propellant jets create a room vortex is induced are at the air outlet acc. Fig. 1 the driving nozzles 3 from the room by a shield 5, covered in the form of a cover plate, for example that primarily that emerging from the exit field 4 Drag air carried into the room by the propulsion jets becomes. The driving jets can move upwards expand and take almost exclusively drag air from the exit field with, being by the drag air because of the relatively low flow rate only to a small extent indoor air in the so introduced Supply air is mixed in. The speeds can be set so that the arrangement acts like a source ventilation. At a flow rate the air in the propulsion jets for example 5 to 20 m / sec and a flow rate the air drag from 1 to 4 m / sec, respectively measured in the exit plane, isothermal Operation an average speed of Supply air at a distance of about 5 m from the relevant one Exit area of the air outlet of about 30-120 cm / sec. The drag air is here from the driving jets carried the room inside. When supplying cold air in the space can be useful, as indicated in Fig. 1, by pivoting the jet axis 7 of the driving nozzle 3 "carry" the drag air upwards into the room, in order to carry the cold air as far as possible into the room, so that the supply air ultimately has a large area towards the floor can sink.

As shown in Fig. 3, the air outlet can also be arranged in reverse, which is particularly the case with It is advisable to supply warm air to a high hall. In this case, the shield 5 is then arranged above the beam axis 7 pivoted downward, so that the the exit rock 4 exiting warm air into the room is "pressed down".

4 is a modification of the embodiment according to. Fig. 1 shown. In this embodiment, is next to an edge-like shield 5 of the driving nozzle 3 opposite a shielding of the propellant nozzle 3 towards the bottom of the room provided at the top in the form of a channel-like extension 6, whose end forms the exit field 4, so that the Exit level of the exit field 4 the exit level of the driving nozzle 3 in the beam direction.

5 and 6 is an embodiment with a single nozzle shown, which is narrow, the exit field 4th is only arranged above the driving nozzle 3. Here is next to the shield 5 covering the area of the propellant nozzle covers down, also on both sides a corresponding Cover 5.1 provided which also allows side access prevented by room air. The one shown in Figs. 5 and 6 Embodiment can also according to the arrangement. Fig. 3 to be built in.

7 and 8 is a further embodiment of the design acc. Fig. 4 in a vertical section (Fig. 7) and in one Front view (Fig. 8) shown. In this embodiment encompasses the exit field in the form of a channel-like one Extension of the driving nozzles 3 overall like a channel, whereby this embodiment is also based on a propellant nozzle can be trained.

9 is a modification of the embodiment according to. Fig. 7 shown. Here is the channel-like extension 6, which also forms the shield of the driving nozzle 3 designed in such a way that the exit plane of the exit field 4 aligned at an angle to the beam axis 7, wherein the exit openings of the exit field of the beam axis 7 are turned. It is again possible to use the exit field 4 to design in the form of a perforated plate, so that the outlet openings are directed against the beam axis are. But it is also possible, as shown here, that the outlet openings of the outlet field 4 in the form a variety of small scoops 8 is executed, the Exit planes approximately parallel to the exit plane of the Driving nozzle 3 are arranged. The embodiment acc. 9 can be used both as a single nozzle arrangement and as Multiple arrangement roughly in the design according to. Fig. 7 and 8 are executed. Due to the inclined arrangement of the exit field there is initially a good one Mixing of the air volumes supplied via the supply duct in the form of propellant air and drag air with the corresponding Slowdown in flow velocity, so that when you touch the outer edges, this slow "Supply air jet" only to a small extent a room air vortex is induced.

The term "perforated sheet" also includes other designs lattice-like structures. For ventilation of a hall there are air outlets on the air supply duct at appropriate intervals arranged as described above.

In a further modification of the invention, the shield 5, for example in the embodiments according to FIGS. 1 to 4 changeable in the orientation to the beam axis, in particular pivotally connected to the end component 1 be. This means that even after installation Influencing and adjusting the beam effect in the Space inside possible.

In a modification of the described and illustrated embodiments can the shield 5 instead of a full area Plate also through at least a part their surface formed with a perforated plate will. If the perforation is in the area of free end edge of the shield arranged here already interfering with air from the shielded Area.

Claims (10)

1. An air outlet for a ventilation installation for ventilating rooms, in particular hall-like rooms, which is arranged at the outlet of an air supply duct (2) in each case, and having at least one propelling nozzle (3) for a jet of propelling air and a discharge field (4) adjoining the propelling nozzle (3) for trailing air which has to be removed from the air supply duct (2), which field has a plurality of discharge openings, characterised in that at least one shield (5, 6) extending laterally approximately in the direction of the jet is associated with at least the propelling nozzle (3) likewise supplied with air from the air supply duct (2), which shield at least partially protects the discharge region of the propelling nozzle (3) from the ingress of ambient air, the free passage cross-section of the part of the discharge field (4) associated with the propelling nozzle (3) being greater than the free passage cross-section of the propelling nozzle (3), but having a higher passage resistance than the propelling nozzle (3).
2. An air outlet according to Claim 1, characterised in that the shield (5) is formed at least in part by a duct-like extension (6) of the air supply duct which projects beyond the discharge plane of the propelling nozzle (3) in the direction of the jet and which has at least part of the discharge field (4) for trailing air.
3. An air outlet according to Claim 1 or 2, characterised in that the discharge field (4) is in the form of a duct-like extension (6) which at least partially surrounds the propelling nozzle (3).
4. An air outlet according to one of Claims 1 to 3, characterised in that the discharge field (4) is oriented at least in part substantially at right-angles to the jet axis of the propelling nozzle.
5. An air outlet according to one of Claims 1 to 4, characterised in that at least part of the discharge field (4) is oriented at an angle to the jet axis (7) of the propelling nozzle (3), the discharge openings facing the jet axis (7).
6. An air outlet according to Claim 5, characterised in that the discharge plane (9) of the discharge openings of the discharge field (4) is oriented approximately parallel to the discharge plane of the propelling nozzle (3).
7. An air outlet according to one of Claims 1 to 6, characterised in that the propelling nozzle (3) is adjustably mounted relative to its jet axis (7).
8. An air outlet according to one of Claims 1 to 7, characterised in that the discharge field (4) is formed by a perforated plate.
9. An air outlet according to one of Claims 1 to 8, characterised in that the orientation of the shield (5) is arranged to be changeable relative to the direction of the jet, in particular pivotable.
10. An air outlet according to one of Claims 1 to 9, characterised in that the shield (5) is provided with perforations at least over part of its surface.

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