EP1462731B1 - Air curtain having a double air stream for a door opening - Google Patents

Abstract

The air wall device for the separating of two areas (5,6) lying on both sides of door opening (8) in a building has a first and second air outlet through which a first and second compressed airflow each in the form of an air wall (4a,4b) emerges at an angle of 0 to 60 degrees to the plane of the door opening. The second air outlet similar to the first is located in the closing region of the door (9) and is entrained by the door. The air outlets entrained by the door are connected by at least one flexible pipe to a corresponding air fan.

Description

The present invention relates to an air-wall device for separating two areas of space adjoining one another at a door opening which can be closed by a door, with an airflow compressed into an airwall according to the preamble of claim 1.

Airwall equipment is well known per se (see, for example, DE-20205864-U). They serve to separate the climate or atmosphere and to prevent or at least reduce heat losses at building openings, in particular at open door openings, where due to frequent passage of people and / or vehicles mechanical separation devices can not or only insufficiently used.

For this purpose, in air-wall systems, relatively small amounts of air flow at very high pressure in a laminar or at least approximately laminar, planar core-jet flow at the building opening to be shielded, which causes a wall-shaped partitioning of the building opening against transverse air masses over the entire opening area. The building openings or door openings can be arranged both inside the building and on an outer wall of the building. Although usually ambient air is used to generate the air walls, basically any gas compositions can be used for this purpose Furthermore, so-called air curtain systems are known in which blown relatively large amounts of air to be shielded building opening and usually previously heated to hold incoming cold air as possible, but at least so far to warm that the climate or temperature inside the building or the respective Space are changed as little as possible. The amount of air blown out does not flow laminarly in a core air level, but comparatively turbulently.

In contrast, cold air masses are not conditioned or heated in air-wall systems, which pass through the building opening, but the passage of cold air masses is greatly reduced depending on the design of the airwall system or even almost completely prevented. In this way, a highly effective separation of the indoor and outdoor air or the climate can be achieved on both sides of the building opening. The lower amounts of air to be bled and the ability to eliminate the need to heat the air flow allow a structurally simpler design of air wall systems and make their operation in relation to air curtain systems extremely effective and relatively inexpensive. Separation in the sense of this application is to be understood as maintaining an already existing separation.

In known air wall devices are usually stationary systems, which are usually mounted stationary above the building opening. So that in this case a sufficiently strong air flow is ensured even at the opposite end of the door opening of the air wall device and the best possible screening result is achieved, these systems must be consistently operated with high performance, which is associated with correspondingly high operating costs. For large opening areas, for example in large gateways in the industrial sector, this is particularly disadvantageous, especially if the building opening for the inlet or outlet of people or smaller vehicles is often only partially opened and this still the full power of the airflow system is needed.

In order to avoid these disadvantages, DE 100 56 596 A1 has proposed an air curtain system of the type mentioned above which provides a customized air curtain as a function of the opening height of the door and the distance still to be bridged. The arrangement of the air curtain on the closing edge associated with the closing area of the door can be achieved in each closed position of the door optimum position of the air curtain relative to each free opening area of the door opening and the efficiency of the air curtain can be increased accordingly with a simultaneous reduction in operating costs.

A disadvantage of this proposed solution, however, is that the entire air curtain device is arranged as a compact complete installation on the closing area of the door. The very high weight of such a complete installation can burden average sized gates in their static design in unacceptably high levels, so that the airflow system either not or can be used only with elaborate reinforcement constructions of existing gates. In addition, the very high weight of the complete installation, in particular, the motors for opening and closing the door in terms of their drive performance clearly overburden, which can lead to damage and failure of the door drive and thus to significant adverse effects on operations and associated additional costs. To avoid such damage reinforcements of the gates and stronger door drives are therefore required, which is associated with additional material and installation costs and in particular with additional costs.

Apart from these disadvantages, although an improved shielding result can be achieved at lower power and thus at correspondingly lower operating costs, the separation or shielding effect achieved in certain applications, in particular in the case of atmospheres contaminated by odor and / or particles, is still insufficient ,

It would therefore be desirable to provide an airwall device which, while maintaining the comparatively low operating costs, no longer has the aforementioned disadvantages and moreover satisfies even stronger shielding requirements.

In order to further improve the shielding effect of an airwall, for example, US Pat. No. 3,211,078 proposed the use of two parallel air walls which shield a building opening in the form of a parallel air layer composite. Furthermore, an air-wall device with two parallel air walls is also known from EP 0 645 588 B1, in which case even a third air wall runs parallel between the two outer air walls.

Both devices assume that two or more parallel juxtaposed air streams difficult to mix with each other. From this they deduce a good separation of the two gas atmospheres to be separated on both sides of the building opening.

However, since air streams that are guided in parallel in this way also impinge parallel and in particular perpendicularly on the opposite end region of the building opening, they each divide in half and flow away on both sides. Thus, in each case half of the respective volume flow penetrates into the space located between the two parallel air walls from both sides, which mix turbulently there. The air forced into this space from both sides must then escape from the gap to avoid a local increase in pressure. Since this is an equality of the atmosphere is sought, the air escapes to the side of the building opening to which it has the greater temperature difference. This escape leads to further turbulent mixing with the affected airwall.

If, for example, a freezer compartment of approx. -28 ° C is sealed off from a room area with a room temperature of approx. + 20 ° C, then escapes the resulting in the interspace turbulent mixed air in the frozen area, which must then be cooled again energy-intensive. This effect occurs all the more pronounced in the solution known from EP 0 645 588 B1 due to the additionally introduced and preferably heated air flow into the intermediate space.

According to these known proposals for solutions, the foreclosure of the building opening in particular at deep-freezing areas is therefore possible only under strong heating and conveying costs of the airwall system and under intensive cooling with a separate cooling system, which in turn causes in addition to the design cost higher production costs also significantly higher operating costs.

Moreover, it is disadvantageous that persons who have to move through such an airwall system, the turbulent turbulence in the space and on at least one of the two air walls perceive as very disturbing.

Object of the present invention is therefore to provide a structurally simple, inexpensive to manufacture and easy to handle airwall device of the type mentioned, which offers improved shielding with low energy consumption, especially against odors and / or particles loaded atmospheres, and a permanently safe Guaranteed use at gates and no additional reinforcing measures regarding the carrying capacity of a conventional door or to increase the performance of the door drive requires.

This object is achieved by an airwall device according to claim 1. Advantageous embodiments and modifications of the invention will become apparent from the dependent claims.

Essential in the inventive arrangement of the airwall device is that the airwall device has a second air outlet, through which a second compressed air flow in the form of a second air wall at an angle of 0 ° to 60 ° to the door opening, wherein the second air outlet also at is arranged in the closing region of the door and carried by the door, that the two air outlets are arranged such that the core planes of the two air walls emerge obliquely from the air outlets, whereby the distance between the two air walls increases with increasing distance from the air outlets, and wherein between the exit directions of the two air walls an angle between 1 ° and 120 ° that the air blower or the air wall device is fixed to the building, preferably in an edge region of the door opening, is arranged, and that entrained by the gate Air outlets over m at least one flexible line with the stationary air blower (s) are connected.

The solution according to the invention is characterized by two significant advantages. The first significant advantage is that not the complete airwall device must be arranged as a complete installation on the gate and carried along with the gate. According to the present invention, it is sufficient to attach only part of the airwall device to the closing area of the door and to move with the goal, while an essential component is arranged with the vast majority by weight not on the gate, but fixed to the building and does not have to be carried along with the goal. Therefore, the weight loads on the door are significantly reduced to about 10%, and damage to the door or the door drive caused thereby can be avoided without requiring special reinforcements to the statics of the door or the drive power of the door drive.

In this constructively simple manner, a highly effective air wall device is created at low operating costs, in particular also subsequently can be retrofitted to existing gates. The gates can be designed in particular as a sliding, lifting, rolling or sectional doors.

The second major advantage of the solution according to the invention is that the advantages of a double Luftwandabschottung can be used without the disadvantages of turbulent air mixing in the space and the leakage of turbulent mixed air through an air wall through to the extent of the previously known air wall devices with parallel air walls occur. Mixing the two air walls can even be completely avoided at sufficiently large angles.

The different climatic zones adjacent to one another at the building opening and to be separated or separated therefore remain reliably in their respective spatial surroundings due to the two low-turbulence flat core air wall beams.

Since the two Flachwandkernluftstrahlen with increasing distance from the respective air outlets from each other, flow on impact on objects, for example, on the building opening passing body or on the air outlets opposite boundaries or floors, only much smaller parts of the respective volume flow back in the direction of Building opening or back into the gap. The sharper the angle at which the airwall impinges on the ground or an object, the less air portions flow back inward into the space between the two airwalls and the less there can be turbulent air turbulence there.

The air flow device according to the invention is inexpensive to manufacture and easy to handle with a simple construction. It ensures an improved shielding of the two space areas at a building opening, not only with respect to different temperatures, with a low energy consumption. but especially if in the room area on one side of the building wall there is an atmosphere contaminated by odor and / or by particles, for example by dust or bacteria. In the food sector, too, this may be of great advantage from a hygienic point of view. According to the invention, the efficiency of the air wall can be increased while reducing the operating costs.

It is particularly advantageous if the flexible line comprises flexible and / or variable-length hoses and / or pipe connections. As a result, the flexible connection of the air blower with the moving air outlet can be achieved in a particularly simple manner.

Depending on the type of flexible lines, it may also be advantageous if a device for guiding the flexible lines is provided at the door opening. Such a guide device may in particular be formed by link chains or by receiving matrices, wherein the receiving matrices may preferably be subdivided into lamellae or may include a sectionally cut open rubber profile.

The air wall device according to the invention comprises means for sucking in outside air and / or inside air and means for compressing the sucked air, which then emerges as a laminar air flow in the form of an air wall from the respective air outlet. The second air outlet of the device is advantageously arranged at least approximately parallel to the first air outlet. It is preferably proposed that the second air outlet is arranged at a distance of 1 to 80 cm, preferably 5 to 20 cm, adjacent to the first air outlet.

It is particularly advantageous if an angle of between 5 ° and 60 °, preferably between 10 ° and 30 °, lies between the exit directions of the two air walls. As a result, turbulent mixing of the two air walls can be prevented particularly reliably.

In this case, the first or the second air flow emerge parallel to the plane of the door opening from the respective air outlet. According to the invention, however, at least one air wall is directed so that it extends at an angle to the plane of the door opening.

A particularly low-turbulence and at least approximately laminar air flow in the form of a flat core air jet wall can be achieved in that the first and the second air outlet respectively comprises at least one core air jet nozzle with an air guide, through which the respective air wall emerges. The louver is advantageously integrated as laminar rectifier for the air flow in the Kernluftstrahldüse and upstream of the outlet slots. The length of the louver in the flow direction is a multiple, in particular 2.5 to 6 times the nozzle gap width.

According to a particularly preferred and easy to mount embodiment of the invention, the first air outlet and the second air outlet in a common housing, in particular in a common Doppelkernluftstrahldüse be arranged with two nozzle chambers.

It is also particularly advantageous if the first and / or second air outlet, in particular the Kernluftstrahldüse (s) and / or the louver (s), is adjustable, in particular pivotable, that the outlet direction of the exiting air wall is variable. As a result, the angle of the air wall to the door opening can be adapted particularly flexible to different applications.

In order to achieve a particularly good effectiveness of the foreclosure of the door opening for each door position, it is also particularly advantageous if the exit direction of an air wall or both air walls by means of a control or automatic control unit automatically, preferably as a function of the opening degree of the door and / or in dependence of the desired and / or currently present climatic conditions, is controllable or controllable or are.

According to a first, particularly inexpensive embodiment of the invention, it is proposed to connect the first and the second air outlet with a common air blower and then divide the sucked and compressed air into two partial air streams.

According to an alternative, particularly variable embodiment of the invention, however, each air outlet can be connected to a separate air blower, wherein preferably each sucked air can be compressed to different pressures and / or heated to different temperatures, and in particular different volume flows can be sucked. In this case, a particularly effective shielding can furthermore be achieved by providing a regulation or control unit by means of which the two air blowers and / or the optionally provided heating device (s) can be controlled or regulated independently of one another, the pressure and / or the volumetric flow and / or the temperature of the first and the second airwall are independently controllable or controllable. The mentioned parameters can be adapted automatically to the prevailing environmental conditions.

In order to achieve a particularly good effectiveness of the airwall device, it is furthermore particularly advantageous if sealing means, in particular sealing walls, are provided on the lateral edges of the door opening, against which the lateral end regions of the air walls rest or flow.

According to a particularly preferred embodiment of the invention it is proposed that at least one control air outlet is arranged in the edge region of the door opening, which is flown by the two air walls, in particular in the lower edge region of the door opening, through which a control air flow at an angle to the outflow direction of the first and / or the second air wall, preferably perpendicular to the door opening, can flow out, that the first or second air wall can be deflected in the flow direction of the control air flow. This will be a particularly favorable flow in the bottom area opposite the two air outlets, in which the affected air wall flows away in the desired direction only to one side, in particular away from the respective other air wall.

In this way, an unwanted mixing of the air or gas compositions to be separated from each other of the two space regions can be avoided, which in known air wall systems by the outflow of a portion of the volume flow of an air wall, usually one of the two separated and differently air-conditioned and / or different with particles and / or odors polluted room areas is taken, may occur. Such unwanted mixing can therefore lead to additional costs for the cooling of the affected space area or make the application in hygienically sensitive areas difficult or even impossible.

The inventive development of the airwall device, these problems are avoided. If, for example, a deep-freeze area of approximately -28 ° C. is to be sealed off from a room area with a room temperature of approximately + 20 ° C. by an air wall and the air for the air wall is sucked out of the deep-freeze area, then the cooled air can become the air wall be completely deflected back into the freezer at the bottom, so that it comes neither to a reduction of the room temperature of the room area by inflowing cold air nor to a heating of the freezer compartment by incoming room air. If the air for the airwall is taken from the room area with + 20 ° C or if the air of the air wall over its flow path would be too much heated, so the air of the air wall can be completely deflected back to the warmer space area, so that In this case too, there is no heating of the deep-freeze area due to incoming warm air, so that energy-intensive additional cooling measures are not required.

It is preferably proposed to provide at the bottom in the middle between the impact areas of the two air walls a double control air jet nozzle or two control air jet nozzles directed in opposite directions away from each other and at least approximately parallel to the ground for each control air flow following the air wall impinging there on both sides deflected outside and let flow out.

Preferably, the two control air jet nozzles or the double control air jet nozzle each extend continuously at least over the width of an air wall. In this case, the air of each air wall can advantageously be sucked out of the area of space at which the respective air wall is applied, so that the air conditions of both areas are not changed or only extremely small.

According to a particularly inexpensive embodiment, it is proposed to connect the control air outlet on the one hand and the two air outlets for the two air walls on the other hand with a common air blower and then divide the sucked and compressed air into two partial air streams. According to an alternative, particularly variable embodiment of the invention, however, the control air outlet may be connected to a separate air blower, in which case advantageously the air sucked compressed to another pressure and / or can be conditioned differently than the air for the air walls. In particular, different volume flows can also be sucked in here.

In order to protect the control air outlet from damage by external mechanical loads, it is furthermore particularly advantageous if the control air outlet is at least partially covered by a covering element provided with air passage openings. In particular, when the control air outlet is arranged at the bottom, damage to the occurrence of persons or when driving over vehicles can be avoided by an appropriately arranged fender.

It is also particularly advantageous if a device for the climatic and / or physical and / or mechanical and / or biological treatment of the sucked air is provided for the first and / or for the second air wall and / or for the at least one control air flow. For example, a heating device or a cooling device for cooling and, alternatively or additionally, a filter, in particular an electrostatic precipitator or a UV filter, and / or a dehumidifier for one or both air streams can be arranged. In this way, even the sucked air can be cleaned of any existing germs and impurities, so that the resulting germ-free and purified air wall can also be used in hygienically sensitive areas, especially in the food and food sectors. Due to the obliquely divergent flow course of the two air walls and the associated deflection of the air streams impinging on the floor to the outside on the side facing away from the gap and the other airwall side, the suitability of the air wall system according to the invention in these hygiene areas is further enhanced

Even with differently tempered and against each other to be partitioned room areas special advantages can be achieved by different conditioning of the two air flow streams. In the intermediate space between the two outlet slots of the air walls, a mixed climate zone is formed, which produces a lock effect in terms of flow. In the mixed climate zone, a temperature occurs which lies between the temperatures of the two climate zones or gas atmospheres to be separated or sealed off, and which in particular also lies above the dew point. The temperature of the mixed climate zone depends on the one hand on the two temperatures of the space regions to be shielded and on the other hand on the exit angles of the core air jets, on their mass flow rates and on their conditionings.

Also, in this embodiment of the invention, the physical effect of the dew point shift can be used, which prevents fogging and icing of the located in the vicinity of the opening functional elements. For this purpose, the low-temperature air is sucked in by a fan and heated before its re-emergence on the low-temperature side of the building opening to above the dew point, so that is bound by the heated core air jet, the contained air humidity flowing to the other side of the building opening climate zone / gas atmosphere in the mixed climate zone. The design of the heat exchanger or the heating unit is dependent on the partial pressure of water vapor and the temperature of the warmer ambient air.

It is also particularly advantageous if a control or control unit is provided, through which the air flow and / or the optional existing physical installation components, in particular the desired heating or cooling capacity of the air walls and / or the optionally present at least one control air flow and / or humidification - Or dehumidifiers and / or filters and / or biological treatment equipment, such as degermination, preferably depending on the degree of opening of the door and / or automatically controlled or controlled depending on the desired and / or currently present climatic conditions.

In this way, depending on the opening height of the door and the associated still to be bridged route always provided a customized airwall and in each closed position of the door optimally adjusted airwall device can be achieved. The efficiency of the airwall device can thereby be increased while reducing the operating costs.

Further advantages and features of the invention will become apparent from the following description and the embodiments illustrated in the drawings.

Figur 1:

Querschnitt durch eine erste Ausführungsvariante einer erfindungsgemäßen Luftwandvorrichtung,

Figur 2:

vergrößerte Darstellung des Teilbereichs E aus Figur 1,

Figur 3:

Seitenansicht der Luftwandvorrichtung aus Figur 1

Figur 4:

Schnittansicht der Doppelkernluftstrahldüse aus Richtung A in Figur 3, und

Figur 5:

Querschnitt durch eine zweite Ausführungsvariante einer erfindungsgemäßen Luftwandvorrichtung.

Figur 6:

Seitenansicht einer weiteren Ausführungsvariante einer erfindungsgemäßen Luftwandvorrichtung

Show it:

FIG. 1:

Cross section through a first embodiment of an airwall device according to the invention,

FIG. 2:

enlarged view of the portion E of Figure 1,

FIG. 3:

Side view of the airwall device of Figure 1

FIG. 4:

Section view of the Doppelkernluftstrahldüse from direction A in Figure 3, and

FIG. 5:

Cross section through a second embodiment of an airwall device according to the invention.

FIG. 6:

Side view of another embodiment of an airwall device according to the invention

The arrangements of air-wall devices 1 according to the invention shown in the figures each have a Doppelkernluftstrahldüse 2, in which a first air outlet 3a for a first air wall 4a and a second air outlet 3b for a second air wall 4b are provided. The air wall device 1 is used to separate the prevailing in the two spatial regions 5 and 6 on the two sides of a building wall 7 climate on a introduced in the building wall 7 door opening 8. The door opening 8 can be closed by a vertically closing sectional door 9 or partially or completely become. To open the door opening 8, the door 9 is moved upward and deflected horizontally above the door opening 8.

The lower end of the door 9 forms the closing area 29, which is guided in the vertical plane of the door opening 8 up and down and rests with the door 4 closed at the bottom 6, in particular via a sealing lip. In the case of horizontally closing gates, the closing area 29 can also rest against the closing area of a second gate in the closed state.

At this closing portion 29 of the gate 9, the Doppelkernluftstrahldüse 2 is fixed so that it is carried vertically when opening or closing of the gate 9. The air blower 10 or 10a and 10b of the airwall device 1 necessary for the production of the air walls 4a and 4b are, according to the invention, not fixed to the door 9 but fixedly attached to the building and respectively arranged on the door 9 via a flexible conduit 11 Double core air jet 2 connected. The air blower 10 or 10a and 10b are thus not moved when opening or closing the gate 9. As a result, a considerable saving of the weight to be carried by the door 9 and to be moved is achieved. Thus, for example, under constant boundary conditions, the weight to be borne by the door 9 of a complete installation according to the known prior art can be reduced from approximately 300 kg to approximately 24 kg in the embodiment according to the invention. The clearly predominant proportion by weight of the air wall device 1 is thus arranged stationary on the building and exerts no burden on the gate 9. Reinforcements on the statics of the gate 9 or on the drive power of the functioning as a door drive motor 27 are therefore not required.

In the embodiment variant shown in FIG. 3, two separate air blowers 10a and 10b are provided for the two air outlets 3a and 3b, wherein the respectively sucked ambient air 12 is compressed to different pressures by a respective compressor 13a, 13b. The air 12 sucked in by the air blower 10a is also heated by an air heater 14.

The Doppelkernluftstrahldüse 2 has in a single nozzle housing two at a small distance adjacent and through a partition 15th separate nozzle chambers 16 a and 16 b, each extending over the entire width of the gate 9. From each nozzle chamber 16a, 16b exits a separate air wall 4a, 4b, which is guided on each serving as a baffle guide plate 17a, 17b with a rectifier profile 18 such that the foreclosure of the building opening 8 exiting air wall 4a, 4b low turbulence and laminar in exits a so-called nuclear air jet plane.

According to the invention, the air outlets 3a and 3b and the baffles 17a and 17b are arranged so that the Kernluftstrahlebenen the two air walls 4a and 4b at an angle γ, which is here about 12 °, diagonally apart. The two air walls 4a, 4b flow in such a way that their distance from one another increases with increasing distance from the air outlets 3a, 3b. As a result, a turbulent air mixing in the space 19 between the two air walls 4a, 4b in the area of the bottom 20 or optionally through the gate opening 8 passing obstacle is largely avoided and the escape of turbulent mixed air through one or both air walls 4a, 4b does not occur on.

In the embodiment shown in Figures 1 and 2, located closer to the door 9 air wall 4a is directed at an angle α of about 10 ° through the door opening 8 into the space area 5 to the outside, while the other air wall 4b with a very small Angle β of about 2 ° in the opposite direction is directed inward in the space area 6.

In addition, a plurality of proximity sensors 21 are arranged on one side of the door opening 8 on the building, which are connected to a controller 22, through which the air flow rate of the air blower 10 a and 10 b, for example, depending on the opening degree of the door 9 can be automatically controlled.

In the exemplary embodiment shown in FIG. 5, two further air outlets are provided on the bottom 20 as control air outlets 23a and 23b, through which in each case a further compressed air flow as control airflow 24a, 24b is perpendicular to the building opening 8 or parallel to the bottom 20 in the direction of the space area 5 and 6 exits to the side. As a result, a particularly favorable flow profile is achieved in the bottom region 28, in which the air flow streams 4 a and 4 b impinging here flow away in the opposite direction from the respective other air wall 4 b or 4 a together with the respective control air flow 24 a, 24 b. An uncontrolled outflow of the air walls 4a, 4b on both sides of the space regions 5 and 6 is thus reliably prevented.

Here, the two control air outlets 23a and 23b are provided in the middle between the impingement lines of the two air walls 4a, 4b in the form of a double nozzle 25, which diverts the air wall 4a, 4b impinging there on both sides through the control air streams 24a, 24b to the outside and flow off leaves. A mixing of the two air walls 4a and 4b is also excluded in the bottom area 28.

Top of the double nozzle 25 is covered by an apron 26 and protected from mechanical stress. In the guard plate 26 side openings are introduced, through which the control air streams 24a, 24b can escape to the outside.

In the embodiment shown in Figure 6, only a common air blower 10 is provided for the two air outlets 3a and 3b. The sucked ambient air 12 is heated by an air heater 14 and compressed by a compressor 13 to the required for a secure foreclosure of the door opening 8 high air pressure. The air blower 10 is here connected via a flexible line 11 with the Doppelkernluftstrahldüse 2, in which the compressed air flow is divided into two partial air streams for the two air walls 4a and 4b. The flexible conduit 11 is in this case formed by a variable in length hose, wherein the length of the hose 11 adapts to the respective opening degree of the gate 9.

In the embodiment shown in Figure 2, the flexible lines 11a and 11b, in contrast, each formed by a flexible hose line whose bending or course changes depending on the opening degree of the gate 9.

Claims (11)

1. Air curtain installation (1) for separation of two spaces (5, 6) located on both sides of a door opening (8) located in or on a building that can be closed by a door (9) that performs a motion largely in the plane or parallel to the plane of the door opening (8) at least within the closing area (29),
   whereby the air curtain installation (1) has at least one air blower (10, 10a, 10b) and a first air exhaust through which a first compressed air stream is discharged in the form of a first air curtain (4a) at an angle from 0° to 60° to the plane of the door opening (8) and that is situated in the closing area (29) of the door (9) and is moved along with the door (9),
   characterised by the fact
   that the air curtain installation (1) has a second air exhaust (3b) through which a second compressed air stream is discharged in the form of a second air curtain (4b) at an angle from 0° to 60° to the plane of the door opening (8), whereby the second air exhaust (3b) is also situated in the closing area (29) of the door (9) and is moved along with the door (9),
   that the two air exhausts (3a, 3b) are positioned in such a way that the core planes of the two air curtains (4a, 4b) leave the air exhausts (3a, 3b) diagonally to each other, whereby the distance between the two air curtains (4a, 4b) increases with increasing distance from the air exhausts and whereby the angle between the exhaust mechanisms of the two air curtains (γ) is between 1° and 120°,
   that the air blower or air blowers (10, 10a, 10b) of the air curtain installation (1) is or are located in fixed positions on the building, preferably in an edge area of the door opening (8),
   and that the air exhausts (3a, 3b) moved along with the door (9) are connected to the fixed air blower(s) (10, 10a, 10b) by at least one flexible duct (11, 11a, 11b).
2. Air curtain installation according to Claim 1 characterised by the fact that the first (3a) and the second (3b) air exhaust each encompass at least one core air jet nozzle with an air guiding mechanism (17a, 17b) through which the respective air curtain (4a, 4b) is discharged in the low-turbulence and at least approximately laminar form of a wall.
3. Air curtain installation according to Claim 1 or 2 characterised by the fact that the first air exhaust (3a) and the second air exhaust (3b) are situated in a shared housing (2), in particular in a shared double core air jet nozzle (2) with two nozzle chambers (16a, 16b).
4. Air curtain installation according to the previous Claims characterised by the fact that the first (3a) and/or second air exhaust (3b), in particular the core air jet nozzle(s) (2) and/or the air guiding mechanism(s) (17a, 17b) are adjustable in such a way, in particular pivoting, that the discharge direction of the exiting air curtain (4a, 4b) is variable.
5. Air curtain installation according to Claim 4 characterised by the fact that a regulation or control unit is provided with which the discharge direction of at least one air curtain (4a, 4b) can be automatically controlled, preferably in dependence on the extent to which the door (9) is opened and/or in dependence on the desired and/or current climate conditions.
6. Air curtain installation according to the previous Claims characterised by the fact that each air exhaust (3a, 3b) is connected to a separate air blower (10a, 10b), whereby the respective air (12) drawn in can preferably be compressed to different pressures and/or heated to different temperatures and whereby, in particular, different volume flows can be drawn in,
   and that preferably a regulation or control unit is provided with which the two air blowers (10a, 10b) and/or any heating unit(s) (14) provided can be controlled or regulated independently of each other, whereby the pressure and/or the volume flow and/or the temperature of the first (4a) and the second (4b) air curtain can be controlled or regulated independently of each other.
7. Air curtain installation according to the previous Claims characterised by the fact that seal elements, in particular seal walls, are provided on the side edges of the door opening (8) along which the side end areas of the air curtains (4a, 4b) flow.
8. Air curtain installation according to the previous Claims characterised by the fact that in a second, preferably lower edge area (20) of the door opening (8), at least one control air exhaust (23a, 23b) is positioned through which a control air stream (24a, 24b) can flow out at an angle to the discharge direction of the first and/or second air curtain (4a, 4b), preferably perpendicular to the door opening (8), in such a way that the first or second air curtain (4a, 4b) can be redirected in the direction of the control air stream.
9. Air curtain installation according to Claim 8 characterised by the fact that two control air jet nozzles (23a, 23b) for one control air stream (24a, 24b) each are positioned on the floor (20) between the areas where the air curtains (4a, 4b) meet the floor (20) facing away from each other in opposite directions and at least approximately parallel to the floor (20).
10. Air curtain installation according to the previous Claims characterised by the fact that a mechanism (14) for climatic and/or physical and/or mechanical and/or biological treatment of the air (12) drawn in is provided for the first (4a) and/or for the second (4b) air curtain and/or for the at least one control air stream (24a, 24b), in particular a heating unit (14) or a cooling unit and/or a filter unit and/or a dehumidification unit.
11. Air curtain installation according to the previous Claims characterised by the fact that a regulation or control unit is provided with which the air throughput and/or any existing installation components for control of climate or physical parameters, in particular the desired heating or cooling of the air curtains (4a, 4b) and/or of the at least one control air stream (24a, 24b), can be or are automatically regulated or controlled, preferably in dependence on the extent to which the door (9) is open and/or in dependence on the desired and/or current climate conditions.

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