DE102022101578B3 - air treatment system - Google Patents

Abstract

The present invention relates to an air treatment system with an air treatment tower, wherein the air treatment tower has support columns, air inlet openings arranged between the support columns, an upper air outlet opening, a flow channel fluidly connecting the air inlet openings and the upper air outlet opening and tapering towards the air outlet opening, and a supported by the support columns, has the flow channel surrounding, rotationally hyperbolic jacket. In order to provide an air treatment system that improves the air quality and the climate in inner-city areas and that can also be advantageously integrated into a cityscape, an annular aperture is arranged according to the invention in the flow duct of the air treatment system, with which a circular flow cross-sectional area of the flow duct can be enlarged and can be reduced, wherein the aperture has a plurality of segments that can be moved at least radially and partially overlap each other, which can each be at least partially stowed in at least one pocket of the air treatment tower formed on an inner surface of the casing, wherein at a free end of one of the segments a parallel to an axis of rotation of the Air treatment tower aligned diffuser tube is arranged.

Description

The present invention relates to an air treatment system with an air treatment tower, wherein the air treatment tower has support columns, air inlet openings arranged between the support columns, an upper air outlet opening, a flow channel fluidly connecting the air inlet openings and the upper air outlet opening and tapering towards the air outlet opening, and a supported by the support columns, has the flow channel surrounding, rotationally hyperbolic jacket.

The starting point for the air treatment system according to the invention are cooling towers, such as are known from the prior art in a wide variety of designs. The intended purpose of cooling towers is to remove excess heat or heat that is no longer technically usable from power plant or industrial processes using a heat exchanger such as water or air.

In a natural draft cooling tower, as for example from the publication DE 20 2007 007 744 U1 is known, it is mostly shell structures made of concrete, which are built in the form of a rotational hyperboloid. The outer surface of the cooling tower stands on pillars or struts between which air can flow into the cooling tower from below. The air inside the cooling tower rises by convection and exits the cooling tower at an upper opening.

From the pamphlet WO 2008/031307 A1 a hyperbolic cooling tower is known with special air nozzles that produce an upward jet of air.

The pamphlet FR 2 275 744 A1 discloses a cooling tower in whose lower air inlet area a conical flow body is arranged, which deflects the air flowing past it in the direction of the inner surface of the cooling tower.

Also from the publication FR 2452 621 A1 a cooling tower is known in which the air flowing through is directed by air baffles and flow bodies.

Natural draft cooling towers are often very oppressive structures, up to 200 m high, whose integration into the landscape often meets with resistance from the population. To protect the landscape, more compact designs such as cell coolers, fan cooling towers or hybrid cooling towers are also being built. Another measure to integrate cooling towers more discreetly into the landscape consists in adapting the outer surface of the cooling tower to the surroundings by means of a color or even an artistic design.

The Supertrees in the Gardens of the Bay in Singapore provide an example of how cooling towers can be integrated very aesthetically and usefully in the middle of densely populated inner cities in order to ensure pleasant ventilation and improve air quality there. The plant-covered towers are integrated into a lush park landscape and attract millions of tourists every year. However, they are not purely decorative objects, but also serve a number of practical purposes, such as cultivating rare plants, generating electricity using photovoltaics and collecting rainwater. They also serve as cooling towers for the cooling systems of the surrounding greenhouses. The towers thus contribute to pleasant ventilation and sustainable climate management within the densely populated city-state with more than 5 million inhabitants.

Proceeding from this, it is the object of the present invention to provide an air treatment system which improves the air quality and the climate in inner-city areas and which at the same time can be advantageously integrated into a cityscape.

According to the invention, this object is achieved by an air treatment system with an air treatment tower, the air treatment tower supporting pillars, air inlet openings arranged between the supporting pillars, an upper air outlet opening, a flow channel fluidically connecting the air inlet openings and the upper air outlet opening and tapering towards the air outlet opening, and a flow channel carried by the supporting pillars , has a rotationally hyperbolic jacket surrounding the flow channel, wherein an annular aperture is arranged in the flow channel, with which a circular flow cross-sectional area of the flow channel can be enlarged and reduced, wherein the aperture has a plurality of segments that can be moved at least radially and partially overlap each other, each of which in at least one pocket formed on a jacket inner surface of the jacket of the air treatment tower can be at least partially stowed, wherein on a free At the end of one of the segments, a diffuser tube aligned parallel to a rotational axis of the air treatment tower is arranged.

The shell of the air treatment tower according to the invention has the shape of a rotational hyperboloid whose cross section is the Luftaust tapering towards the riding opening. The mantle is built on spaced buttresses. The air treatment tower has a plurality of air intake ports each formed between adjacent support columns. Thus, air can flow through the air inlet openings, that is, between the support pillars, from below into the flow channel of the air treatment tower. The air then rises within the flow channel, like in a chimney, to finally exit the flow channel again through the air outlet opening formed at the top of the air treatment tower.

Air masses close to the ground are thus transported upwards through the air treatment tower.

If the air treatment tower according to the invention is erected within a city in which the air masses close to the ground are polluted by exhaust gases and/or dust, it contributes there to an improvement in inner-city air quality by constantly discharging these polluted and/or dust-polluted air masses upwards.

According to the invention, the flow cross-sectional area of the flow channel of the air treatment tower can be reduced and enlarged by an adjustable aperture and the air flow through the flow channel can thus be controlled in terms of volume flow and the flow type of the air flow can be varied between a laminar and a turbulent flow.

The adjustable aperture has a number of segments that can be moved radially and partially overlap one another. The segments protrude from an inside of the shroud toward the center of the flow channel. The circular flow cross-sectional area of the flow channel can be reduced from the inside of the casing by the segments. To reduce the flow cross-sectional area, the segments are radially displaced toward the center of the flow channel, thereby reducing the diameter of the circular flow cross-sectional area.

A diffuser tube is arranged at a free end of one of the segments, which is aligned parallel to the axis of rotation of the air treatment tower.

The individual segments can be moved towards the center of the flow channel and the flow cross-sectional area can thus be reduced until a flow through the flow channel is only possible through the diffuser tube. In this case, air flows through the flow channel in a turbulent manner. This leads to a lively turbulence of the rising air masses above the aperture.

To increase the flow cross-sectional area, the segments are moved radially outwards, that is, away from the center of the flow channel. The segments each slide into at least one pocket formed on the inner surface of the casing. Those surface portions of the segments currently stowed in the at least one pocket do not contribute to the reduction in flow cross-sectional area. Thus, the flow cross-sectional area is at a maximum when the segments are fully stowed in the at least one pocket.

The segments overlap each other so that the flow cross-sectional area is always circular, regardless of the radial arrangement of the segments, and no gaps can form between adjacent segments.

When the aperture is open, the flow channel of the air treatment tower is flown through in a laminar manner, i.e. there is no turbulence of the rising air masses.

In order to increase the volume flow through the flow channel, it is advantageous if the inner surface of the casing is provided with a coating that smoothes it.

In order to promote the erection of the air treatment tower in a very busy location in the middle of a city, it is advantageous if the air treatment system has a ring-shaped windbreak that is arranged opposite the air inlet openings and runs around the air treatment tower on the ground.

This windbreak, which is formed in a ring around the air treatment tower, forms a wall in front of the air inlet openings of the air treatment tower and ensures that the air cannot flow directly into the air inlet openings, i.e. not directly above the ground, thereby damaging pedestrians who are next to the air treatment tower , would be exposed to an unpleasant draft. Instead, the air is drawn in through the windbreak and thus over the heads of passers-by. Furthermore, the wind protection can be interrupted at suitable points, for example adjacent to areas inaccessible to passers-by, so that an intake of air at these points also does not impair passers-by.

The air flow through the air treatment tower can be further improved if the air treatment system around the air outlet of the air-handling tower arranged around and curved towards the axis of rotation of the air-handling tower.

The wind deflection shields ensure that no turbulence forms within the flow channel, which would be caused by pressure fluctuations as a result of winds blowing transversely to the air outlet opening of the air treatment tower. The wind deflection shields divert currents running transversely to the air outlet opening upwards. At the air outlet opening in the lee of the wind deflector shields, there are stable pressure conditions that are independent of gusts of wind. A control and/or regulation of the volume flow through the air treatment tower is thus possible independently of changing wind influences.

Instead of individual air deflection shields, which are arranged around the air outlet opening of the air treatment tower, several air deflection shields arranged one above the other can also be arranged around the air outlet opening of the air treatment tower. For example, several, preferably pivotably mounted, air deflection shields can be attached one above the other, ie vertically spaced from one another, to a carrier, the carrier itself being attached to the jacket of the air treatment tower in the region of the air outlet opening. A plurality of vertically spaced and pivotable air deflection shields makes it possible to react even more sensitively to changing wind influences by varying the slipstream generated by the wind deflection shields.

By attaching additional wind deflection shields directly above the air outlet opening, the flow duct is lengthened to a certain extent by such a section that is completely in the lee of the wind deflection shields.

By varying the slipstream, that is, by pivoting the wind deflection shields, the flow path of the air through the air treatment tower can be lengthened and shortened.
In addition to merely improving the air exchange between the ground and the height by means of a vertical flow provided and controlled by the air treatment tower of the air treatment system according to the invention, the air treatment tower can also be used for air purification and/or treatment and can be equipped accordingly.

In a particularly advantageous embodiment of the air treatment system, the air treatment system has a wire mesh which is arranged in an air inlet area of the air treatment tower, has baffle plates and is connected to an electrical voltage source.

The air intake area is inside the air treatment tower and is formed between the air intake openings. The air flowing into the air treatment tower is forced to flow through the wire mesh arranged in the air inlet area. The wire mesh has baffles on which the air flowing through the wire mesh is deflected. When flowing through the wire mesh, dust particles contained in the air collide with the baffle plates. The wire mesh is connected to a voltage source. When electric current flows through the wire mesh, the dust particles become electrostatically charged when they collide with the baffle plates. The electrically charged dust particles are then deflected by a magnetic field surrounding the current-carrying wire mesh and separated from the air. The deflected, electrically charged dust particles can be separated, for example, by chemical binding and/or washing out and/or sucking off the dust particles.

The current-carrying wire mesh can also be used as an electrical heater. By heating the incoming air, the air flow through the flow channel is additionally driven by convection. The heating of the incoming air thus offers an additional possibility of controlling the volume flow through the flow channel.

If the air treatment system is used for air purification, it proves to be advantageous if the air treatment system has at least one air deflection body, which is arranged above the air outlet opening on the axis of rotation of the air treatment tower.

The vertically flowing air, which emerges from the flow channel above the air treatment tower, is deflected radially to the axis of rotation of the air treatment tower by the at least one air deflection body. As a result, the air treated and cleaned by the air treatment tower is evenly distributed around the air treatment tower. This advantageous distribution of the treated air allows fresh air to be provided evenly around the air treatment tower, for example within smog-ridden cities.
In a further advantageous embodiment of the air treatment system according to the invention, this has at least one condensate collection tank arranged between the supporting pillars of the air treatment tower. In this/n condensate Water that has condensed out within the flow channel and other condensable impurities, such as hydrocarbons, can be collected from the air in a collection basin.

In order to make the air treatment system accessible and thus usable as an observation tower, for example, it is advantageous if the air treatment tower has at least one platform attached to the casing of the air treatment tower, the platform being designed as a concrete bead running around the casing of the air treatment tower.

The at least one platform is preferably a concrete bead which is attached to the casing of the air treatment tower from the outside and runs around the casing and is reinforced by steel inserts. The platform encircling the jacket of the air treatment tower is preferably designed as a ring or a polygon.

In a further embodiment of the air treatment tower, several such platforms are fastened to the mantle of the air treatment tower one above the other like storeys.

A wide variety of facilities can be accommodated on the platforms, such as cafes, restaurants, offices or retail stores.

The function of the air treatment tower is in no way impaired by the building on the outer surface of the air treatment tower in different levels. In addition, this allows the space on which the air treatment tower is built to be used for other municipal facilities. Due to the extensive utilization of the floor space achieved in this way, the integration of such a building is also economically feasible in the center of a densely populated city with high property prices. In addition, by building on the outer surface of the air treatment tower, it can be achieved that it blends harmoniously into the surrounding cityscape or is even staged as a futuristic landmark of an up-and-coming city.

It proves to be extremely advantageous if the air treatment system has a gondola leading to the at least one platform.

The gondola is preferably an elevator, through which the at least one platform can be approached from the ground. If the air treatment tower has several platforms, then preferably all platforms, such as the individual floors in a high-rise building, can be reached through the gondola.

In this context, it is particularly advantageous if rails are arranged on an outer surface of the casing, along which the gondola can be moved to the at least one platform.

On the other hand, it is favorable if the air treatment system has a column set up next to the air treatment tower, along which the gondola can be moved to the at least one platform.

The column for the nacelle can be designed to be particularly filigree, i.e. with a particularly small diameter, if it is made of reinforced concrete, the steel reinforcement of which has a bundle of parallel, spaced steel struts, with spaced ring safety devices being arranged along the steel struts, in where the steel struts are arranged coaxially. For this purpose, the ring fuses are designed, for example, as cylindrical wire cages, in which the assigned steel strut is arranged coaxially. The ring locks are preferably either integrally connected to the steel struts, for example they are welded to them, or the ring locks are thermally shrunk onto the steel struts. The ring locks improve the concrete connection to the steel reinforcement insert. At the same time, lateral forces acting on the column are deflected by the ring locks in the longitudinal direction of the steel struts.

In a preferred embodiment of the invention, the pillars of the air treatment tower are anchored in the ground in an earthquake-proof manner. It is particularly advantageous here if the supporting pillars of the air treatment tower are each erected separately on plates that can be moved hydraulically in each case parallel and perpendicular to the ground. The moveable plates decouple the pillars from the ground so that deformations in the ground, e.g. due to slight earth tremors, are not transferred to them.

For sustainable operation of the air treatment system with optimal use of solar energy, it is particularly useful if the air treatment system has solar panels that are attached to a frame attached to the shell of the air treatment tower, the solar panels being movable and/or pivotable along the frame.

Preferably, fluid-cooled solar panels are placed in a ring around the air treatment tower. The solar panels are fastened, for example, to a steel and/or the light metal framework. The frame is preferably made of tubes to which the individual solar panels are fastened with resilient tensioning elements.

By using spring-loaded tensioning elements to fasten the solar panels to the tubes of the scaffolding, any concentricity errors that may exist in the tubes are compensated. This prevents the solar panels from bending as a result of any concentricity errors when pivoting or moving.

Since the solar panels can be moved along the circumference of the shell on the frame and at the same time can be pivoted around the frame that supports them, they can be aligned with the current position of the sun. This guarantees an optimal yield of solar energy at different times of the day and year. The solar panels contribute to a sustainable power supply of the air treatment system. In addition, the waste heat from the solar panels can be used for heating purposes. For example, neighboring buildings of the air treatment tower, as well as facilities built on the platform of the air treatment tower, can be heated with the waste heat from the solar panels.

The waste heat from the solar panels can also be fed into a district heating network or stored in a heat storage tank. If the air treatment system has at least one condensate collection tank arranged between the pillars of the air treatment tower, in which condensed water and other condensable contaminants are collected, the waste heat from the solar panels can be used advantageously for the treatment and clarification of this condensate.

• 1 schematisch eine Ausführungsform des erfindungsgemäßen Luftaufbereitungssystems in einer Vorderansicht zeigt;
• 2 schematisch eine Säule aus Stahlbeton für eine Gondel einer Ausführungsform des erfindungsgemäßen Luftaufbereitungssystems in einem Längsschnitt zeigt; und
• 3 schematisch eine erdbebensichere Verankerung von Stützpfeilern einer Ausführungsform des erfindungsgemäßen Luftaufbereitungssystems in einer Draufsicht zeigt.

Preferred embodiments of the present invention, their structure, function and advantages are explained in more detail below with reference to figures, where

• 1 schematically shows an embodiment of the air treatment system according to the invention in a front view;
• 2 schematically shows a column made of reinforced concrete for a nacelle of an embodiment of the air treatment system according to the invention in a longitudinal section; and
• 3 shows schematically an earthquake-proof anchoring of pillars of an embodiment of the air treatment system according to the invention in a plan view.

The illustrated embodiments are by the 1 until 3 not reproduced to scale. The schematic representations in the 1 until 3 are greatly simplified for the sake of clarity.

1 shows schematically an embodiment of the air treatment system according to the invention with an air treatment tower 1 in a front view, with hidden elements inside the air treatment tower 1 being shown in dashed lines.

The air treatment tower 1 has a plurality of support columns 2 spaced from each other in a circle.

Air inlet openings 3 of the air treatment tower 1 are formed between the pillars 2 . Air can flow into the air treatment tower 1 from below through these air inlet openings 3 . in the in 1 In the embodiment of the air treatment tower 1 shown, the air inlet openings 3 are each the free space between two adjacent support pillars 2.

At its upper end, the air treatment tower 1 has an air outlet opening 4 through which the air flowing into the air treatment tower 1 from below flows out again.

The air inlet openings 2 and the air outlet opening 4 are fluidically connected to one another by a flow channel 5 of the air treatment tower 1 . The flow channel 5 tapers towards the air outlet opening 4 .

The air treatment tower 1 has a rotationally hyperbolic jacket 6 which is designed to encircle the flow channel 5 . The mantle 6 is supported by the pillars 2 . The shell 6 of the air treatment tower 1 is at in 1 shown embodiment of the air treatment tower 1 as the jacket of a cooling tower made of reinforced concrete.

The amount of in the 1 shown air treatment tower 1 is about 65 m.

The flow channel 5 has an annular aperture 7 . A circular flow cross-sectional area of the flow channel 5 can be enlarged and reduced with the aperture 7 .

The aperture 7 has a plurality of segments 8 that can be moved at least radially and partially overlap one another. In the in the 1 shown embodiment of the air treatment tower 1 according to the invention, the segments 8 are designed as thin, curved sheets. Alternatively, the segments 8 can be made of curved plastic plates, preferably fiber-reinforced plastic plates, be trained. in the in 1 In the embodiment shown, adjacent ones of the segments 8 overlap one another, so that an air flow between adjacent ones of the segments 8 is not possible. The overlap of the segments 8 is in the in 1 shown embodiment comparable to the overlapping of the petals of a tulip.

Due to the overlapping of adjacent ones of the segments 8 , an air flow through the flow channel 5 is always only possible through a circular flow cross-sectional area in the center of the annular aperture 7 .

A diffuser tube 10 is arranged at a free end of one of the segments 8 . In the in the 1 In the embodiment shown, the diffuser tube 10 is a steel tube which is welded to the free end of one of the segments 8 . The diffuser tube 10 is always aligned parallel to a rotation axis A of the air treatment tower 1 . If the flow cross-sectional area of the flow channel 5 is reduced further and further by moving the individual segments 8 of the aperture 7 towards the center of the flow channel 5, the flow channel 5 is finally almost completely closed by the annular aperture 7. In this case, there is an air flow through the flow channel 5 of the air treatment tower 1 only possible through the diffuser tube 10 therethrough. When the air treatment tower 1 is operated with forced flow through the diffuser pipe 10 , the air masses rising in the flow duct 5 flow turbulently through the flow duct 5 . This leads to a lively turbulence of the air above the aperture 7.

The air treatment tower 1 has at least one pocket 9 formed on an inner surface of the shell 6 and/or attached thereto. At the in the 1 The embodiment of the air treatment tower 1 shown has a single pocket 9 which is open at the top and is ring-shaped so that it completely encircles the axis of rotation A of the air treatment tower 1 once. The pocket 9 is fixed to the jacket inner surface of the jacket 6 . When the flow cross section is increased, all segments 8 of the aperture 7 slide from above into a single pocket 9.

Instead of a single pocket 9, a plurality of pockets 9 can also be formed on the inner surface of the jacket 6. For example, each of the segments 8 can be assigned an individual pocket 9 for their stowage.

The pocket 9 is at the in 1 embodiment shown made of plastic. In an embodiment that is not shown, the pocket is formed from a plurality of metal sheets that are riveted or welded to one another.

The inner surface of the jacket of the flow channel 5 is provided with a coating that forms a smooth surface.

That in the 1 The air treatment system shown has a windbreak 11 which runs around the air treatment tower 1 on the ground and which is arranged in front of the air inlet openings 3 of the air treatment tower 1 . The windbreak 11 prevents passers-by in the vicinity of the air treatment tower 1 from being exposed to an unpleasant draft from the air flowing into the air treatment tower 1 . The inflow of air into the air inlet openings 3 takes place over the windbreak 11 and thus takes place at a sufficient height above the ground so as not to impair passers-by. At the in 1 In the embodiment of the air treatment tower 1 shown, the windbreak 11 is formed from individual, flat windbreak elements made of plexiglass, which are placed around the air treatment tower 1.

That in the 1 The air treatment system shown has wind deflection shields 12 which are arranged around the air outlet opening 4 of the air treatment tower 1 . The wind deflection shields 12 are curved towards the axis of rotation A of the air treatment tower 1 . Winds blowing transversely to the air outlet opening 4 are preferably deflected upwards by the wind deflection shields 12 .

The one in the 1 The illustrated embodiment of the air treatment system has a wire mesh 13 having baffles, which is connected to an electrical voltage source. The wire mesh 13 is arranged in an air inlet area of the air treatment tower 1 . The air inlet area is in turn formed at the base of the air treatment tower 1 between its air inlet openings 3 . The air flowing into the air treatment tower 1 flows through the in the 1 In the embodiment of the air treatment system shown, first the wire mesh 13. This leads to collisions between the dust particles contained in the inflowing air and the baffle plates of the wire mesh 13. If the wire mesh 13 is traversed by electricity, the dust particles are electrostatically charged when they collide with the baffle plates and through deflected around the current-carrying wire mesh 13 trained magnetic field. in the in 1 shown embodiment of the invention, the dust particles by the magnetic field to a suction, not shown geinrichtung down and separated by suction from the air. Further possibilities for separation consist of washing out or chemically binding the dust particles deflected by the magnetic field.

The one in the 1 The embodiment shown of the air treatment system according to the invention has an air deflection body 25 which is arranged above the air outlet opening 4 on the axis of rotation A of the air treatment tower 1 . The air that emerges from the flow channel 5 above the air treatment tower 1 is deflected radially to the axis of rotation A of the air treatment tower 1 by the air deflection body 25 and distributed evenly around the air treatment tower 1 . The air deflection body 25 is at the in 1 shown embodiment as a balloon adjustable in its dimensions, floating above the air outlet opening 4, which is attached to the bottom of the air treatment tower 1 with a rope 26. Instead, an air deflection body 25 designed as a balloon could also be fastened to the jacket 6 of the air treatment tower with several cables. However, the air deflection body 25 can also be rigid and arranged above the air outlet opening 4 by means of suitable holding elements.

In a non-illustrated embodiment of the air treatment system according to the invention, the air treatment system has at least one condensate collection tank, which is arranged between the supporting pillars 2 of the air treatment tower 1 .

If the air treatment tower 1 has a wire mesh 13, then it is advantageous if the at least one condensate collecting basin is arranged below the wire mesh 13.

In the at least one condensate collection tank, condensable components, such as water or hydrocarbons, can be collected from the air rising in the flow channel 5 of the air treatment tower 1 . The condensate from the condensate collection tank can then be clarified or treated in some other way.

the inside 1 The air treatment tower 1 shown has a platform 14 attached to the shell 6 of the air treatment tower 1 . The platform 14 is designed as a concrete bead surrounding the casing 6 of the air treatment tower 1 . The concrete bead is at the in 1 shown embodiment reinforced with steel inserts, which are firmly connected to the steel frame of the shell 6. The platform 14 offers space for the establishment of, for example, cafes, restaurants and/or business premises.

In an embodiment of the air treatment system that is not shown, the air treatment tower 1 has a plurality of platforms 14 which are arranged one above the other like the floors of a house.

This in 1 The air treatment system shown has a gondola 15 with which the platform 14 can be reached from the ground. The gondola 15 can be moved along a column 16 of the air treatment system. The column 16 is arranged next to the air treatment tower 1 and is aligned parallel to the axis of rotation A thereof.

In the 1 Column 16 shown consists mainly of reinforced concrete. A longitudinal section of the 1 Column 16 shown is in 2 shown. For the sake of better representation, in 2 only a part, namely a longitudinal section, of the column 16 is shown. The steel reinforcement of the column 16 has a bundle of steel struts 19 spaced apart from one another and aligned parallel to the axis of rotation A of the air treatment tower 1 . Ring fuses 20 spaced apart from one another are arranged along the steel struts 19 . The ring fuses 20 are in the 1 and 2 shown embodiment formed as a cylindrical wire cages in which the respectively associated steel strut 19 is arranged coaxially. The ring fuses 20 are in the in 1 and 2 shown embodiment of the air treatment system thermally shrunk onto the steel struts 19. The ring fuses 20 improve the concrete connection to the steel reinforcement insert. At the same time, transverse forces acting on the column 16 are deflected by the ring locks 20 in the longitudinal direction of the steel struts 19 . With this extremely advantageous reinforcement, Column 16, which is more than 50 meters high, can be designed in a very filigree manner.

In an embodiment that is not shown, the air treatment tower 1 has a gondola 15 that can be moved along the casing 6 of the air treatment tower 1 . The gondola 15 preferably moves on rails that are laid on an outer surface of the casing 6 .

The buttresses 2 of the in 1 illustrated embodiment of the air treatment tower 1 are earthquake-proof connected to the ground. This will, as in 3 shown, achieved in that the pillars 2 are intercepted individually. For this purpose, the pillars 2 are each erected on a separate, hydraulically movable plate 21 which can be moved parallel and perpendicular to the earth's surface within a compensation area 22 .

Deformations in the ground call for relative changes in position between the individual hydraulic electrically movable plates 21 out. These relative changes in position are 3 registered embodiment shown by a total of six lasers 23, which are each offset by 60 ° to each other along a circle K1. The total of six hydraulically movable plates 21 are also arranged offset by 60° from one another along a circle K2. Each of the plates 21 has a reflector 24 aligned with the common center point M of the circles K1, K2, on which reflector 24 the light emitted by a respectively associated laser 23 is reflected back to the center point M.

through the in 3 Schematically shown arrangement of the laser 23 and the respective associated reflectors 24 can be quickly and precisely detected changes in position between the erected on the plates 21 pillars 2 as a result of tremors and compensated by a corresponding counter-movement of the hydraulically movable plate 21.

the inside 1 The air treatment tower 1 shown has a plurality of solar panels 17 which are attached to a frame 18 which is attached to the jacket 6 of the air treatment tower 1 . The solar panels 17 can be moved and pivoted along the framework 18 .

At the in 1 shown embodiment of the invention are fluid-cooled solar panels 17 arranged around the air treatment tower 1 around. The solar panels 17 are attached to a framework 18 connected to the shell 6 of the air treatment tower 1 . The framework 18 is formed from tubes to which the individual solar panels 17 are each fastened with resilient tensioning elements. Fastening by means of resilient clamping elements prevents the solar panels 17 from bending when pivoting or moving as a result of any concentricity errors in the tubes of the frame 18 .

The frame 18 is preferably made of steel or light metal.

The solar panels 17 can be moved along the circumference of the shell 6 on the framework 18 . At the same time, they can be pivoted around the framework that supports them. This allows them to be aligned with the current position of the sun. This guarantees an optimal yield of solar energy at different times of the day and year. The solar panels 17 contribute to a sustainable power supply of the air treatment tower 1.

Claims (15)

Air treatment system with an air treatment tower (1), wherein the air treatment tower (1) has supporting pillars (2), air inlet openings (3) arranged between the supporting pillars (2), an upper air outlet opening (4), the air inlet openings (3) and the upper air outlet opening (4 ) fluidically connecting flow channel (5) that tapers towards the air outlet opening (4), and a rotationally hyperbolic jacket (6) which is carried by the supporting pillars (2) and surrounds the flow channel (5), characterized in that in the flow channel ( 5) an annular aperture (7) is arranged, with which a circular flow cross-sectional area of the flow channel (5) can be enlarged and reduced, the aperture (7) having a plurality of segments (8) which can be moved at least radially and partially overlap each other and which each have at least a pocket (9) of the air treatment tower (1) formed on an inner surface of the shell (6). are at least partially stowable, with a diffuser tube (10) aligned parallel to an axis of rotation (A) of the air treatment tower being arranged at a free end of one of the segments (8). air treatment system claim 1 , characterized in that the inner surface of the jacket (6) is provided with a smoothing coating. Air treatment system according to one of the preceding claims, characterized in that the air treatment system has an annular windshield (11) which is arranged opposite the air inlet openings (3) of the air treatment tower (1) and runs around the air treatment tower (1) on the ground. Air treatment system according to one of the preceding claims, characterized in that the air treatment system has wind deflection shields (12) arranged around the air outlet opening (4) of the air treatment tower (1) and curved towards the axis of rotation (A) of the air treatment tower (1). Air treatment system according to one of the preceding claims, characterized in that the air treatment system has a wire mesh (13) which is arranged in an air inlet area of the air treatment tower (1), has baffle plates and is connected to an electrical voltage source. Air treatment system according to one of the preceding claims, characterized in that the air treatment system at least a condensate collection tank arranged between the supporting pillars (2) of the air treatment tower (1). air treatment system claim 6 , characterized in that the air treatment system has at least one air deflection body (25) which is arranged above the air outlet opening (4) on the axis of rotation (A) of the air treatment tower (1). Air treatment system according to one of the preceding claims, characterized in that the air treatment tower (1) has at least one platform (14) attached to the jacket (6) of the air treatment tower (1), the platform (14) being a platform (14) surrounding the jacket (6). Concrete bead is formed. air treatment system claim 8 , characterized in that the air treatment system has a gondola (15) leading to the at least one platform (14). air treatment system claim 9 , characterized in that rails are arranged on an outer surface of the jacket (6), along which the gondola (15) to the at least one platform (14) can be moved. air treatment system claim 9 , characterized in that the air treatment system has a column (16) erected next to the air treatment tower (1), along which the gondola (15) can be moved to the at least one platform (14). air treatment system claim 11 , characterized in that the column (16) is made of reinforced concrete, the steel reinforcement of which has a bundle of parallel, spaced-apart steel struts (19), with spaced-apart annular locks (20) being arranged along the steel struts (19), in which the steel struts (19) are each arranged coaxially. Air treatment system according to one of the preceding claims, characterized in that the supporting pillars (2) of the air treatment tower (1) are each erected separately on plates (21) which can be moved hydraulically in each case parallel and perpendicular to the ground. Air treatment system according to one of the preceding claims, characterized in that the air treatment system comprises solar panels (17) which are attached to a framework (18) fixed to the shell (6) of the air treatment tower (1) and the solar panels (17) along the framework (18) can be moved and/or pivoted. air treatment system Claim 14 , characterized in that the frame (18) is formed from tubes to which the solar panels (17) are each attached with resilient clamping elements.

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