EP1399645A1 - Suction device comprising a fire protection system - Google Patents

Abstract

The invention relates to a suction device (1), preferably for a tunnel (2), especially for a tunnel for vehicles, comprising at least one vortex hood, (4, 5). In order to improve the suction properties of said suction device (1), to prevent it from being damaged, to a large extent, in the event of a fire, and to be able to act directly on the source of fire, at least one injection device (17) comprising at least one nozzle (18) is provided, said nozzle (18) being arranged on or in the vortex hood (4, 5) and being embodied in such a way that it produces a spray mist consisting of fine droplets (32).

Description

 Exhaust device and method for exhausting gases

The invention relates to a suction device, preferably for a tunnel, in particular for a car tunnel, with at least one swirl hood. Furthermore, the invention relates to a method for the suction of gases by means of at least one suction device of the aforementioned type.

Suction devices of the aforementioned type are already known from the prior art. Line-shaped detection elements in the form of so-called swirl hoods are an essential component of such suction devices. The principle of cyclones, which is known from nature, is used here, in which a sink current is superimposed with a potential vortex. At the core of the vortex, the vortex thread, there are large negative pressures of up to -5000 Pa. The rotation speed around the core is about ten times the suction speed. The advantages of this flow form lie in the good suction effect, with which particularly impulsive gas flows such as thermal convection flows can be detected particularly well. Systems of this type have hitherto been used preferably in the iron and steel industry for extracting pollutant-laden convection currents and for extracting smoke or harmful gases, for example in the event of a fire.

As is well known, a cyclone develops enormous pulling forces in its environment. This suction effect is achieved in a swirl hood by an artificially generated swirl, so that the smoke or harmful gases arising at the source of a fire are immediately extracted. These flows are 50-100 times as strong as conventional suction processes. The vertebra is so stable that it can be extended as desired. For this purpose, suction openings are installed at regular intervals, which "support" the vortex. In this way, a tunnel or underground car park can be equipped with a "swivel hood" along its entire length. In the event of a fire, the sections that are closest to the source of the fire are automatically activated. In this way it is possible to limit the spread of smoke and to keep the escape and rescue routes smoke-free. Suction devices of the aforementioned type, as stated, already have very good suction properties.

The object of the present invention is now to provide a suction device and a method of the type mentioned at the outset, the suction properties being further improved and, moreover, damage to the suction device in the event of fire being largely avoided and the fire source being influenced directly can.

To achieve the above object, it is provided in a suction device with the preamble features of claim 1 that at least one injector device having at least one nozzle is provided and the nozzle of the injector device is arranged on or in the swirl hood and is designed to generate a spray mist. According to the method, it is accordingly provided that a fluid in the manner of a spray is injected into the gas to be extracted and / or into the ambient air, in particular directly in front of the vortex hood and / or into the vortex hood.

In principle, it is possible according to the invention that the fluid is injected into the gas flow to be extracted or into the air surrounding the extraction device. If the fluid is injected into the gas flow to be extracted, which can be, for example, hot flue gases and / or gases with a high particle load, the gas flow through the suction device according to the invention or the method according to the invention is quickly and efficiently already in the vicinity of the suction device cooled. At the same time, particles in the gas stream are bound before they enter the suction device. If the fluid is injected into the ambient air, the physical-chemical parameters of the ambient air can be positively influenced. Damage to objects or people in the fire area is reduced or at least considerably delayed.

In order to increase the heat transfer rate or the speed of the gas cooling, the fluid is introduced into the gas stream as a spray with a large heat and mass transfer area. In this way, on the one hand, the suction device as such can be protected against the damaging influence of the sucked gases, especially from the high flue gas temperatures, are protected. On the other hand, due to the lower temperature load on the suction device, lower system costs are to be estimated.

When injecting from outside the swirl hood, it is best to inject against the intake flow directed into the swirl hood. It is also conceivable that the injection takes place transversely to the intake flow directed into the swirl hood. When spraying into the swirl hood, all variants of the alignment of the nozzle are also possible. In order to ensure a particularly strong swirling of the injected fluid, the nozzle of the injection device can be arranged on the outside of the swirl hood in the area of the suction opening. However, it is also conceivable to arrange the nozzle from the outside in the central region and / or in the region of the end faces of the swirl hood and / or by means of suitable spacers, counter to or transversely to the intake flow.

According to the invention it is further provided that the injected liquid or the spray mist is quickly braked by the intake flow, deflected and then carried along with almost no slip. Sudden evaporation of at least part of the injected fluid occurs, the heat transfer rate or the cooling rate of the hot flue gas increasing sharply. The main advantages of the suction device according to the invention thus result from an improved heat transfer between the sprayed spray and the extracted hot flue gas. The most efficient possible heat transfer can be achieved with strongly turbulent flows and high temperature differences. Ultimately, the suction device according to the invention and the method according to the invention ensure that the hot flue gases are cooled in a fraction of a second before entering the swirl hood. Overall, this also contributes to an increase in the performance of the smoke extraction system.

The air temperature and the particle loading of the air can be regulated by injecting a fluid in the manner of a spray into the ambient air in front of the vortex hood or into the vortex hood itself. Here too, the large heat and mass transfer areas of the spray mist immediately for rapid cooling or particle binding of the ambient air. Together with the particles, other noxious gas components can simultaneously be bound by the spray, it being possible, for example, to use an absorption agent as the fluid. The harmful gas components bound to the absorbent by absorption can be, for example, carbon monoxide, nitrogen oxides, sulfur or acidic gas components. Ultimately, the injection of a fluid into the ambient air helps to improve the overall air quality in the area of the suction device. People who are in the area of the suction device are no longer hindered in their orientation by thick clouds of smoke.

The fluid injected via the nozzle of the injection device should preferably have an average drop diameter of less than 100 μm, in particular less than 10 μm. A smaller drop diameter is also possible. The smaller the diameter of the injected fluid droplets, the faster the injected fluid droplets are braked by the intake flow, deflected and then carried along with virtually no slippage. At the same time, as the drop diameter drops, the heat transfer rate increases, which means that the flue gases are cooled more quickly. Ultimately, a smaller droplet diameter contributes to the swirling of the sprayed-in spray, which in turn has a positive effect on the heat transfer.

If the suction device is used in a tunnel, the swirl hood of the suction device can preferably be arranged below the tunnel ceiling, in particular in the longitudinal direction of the tunnel. In addition, a plurality of swirl hoods can be provided, the swirl hoods preferably being arranged opposite or next to one another in the longitudinal direction of the tunnel and the suction openings of the swirl hoods facing away from one another. This makes it possible, for example, to use one of the two swirl hoods arranged opposite one another for the supply of air, while the other of the two swirl hoods is used for extracting the flue gases or the harmful gases. This is particularly useful when the suction device is arranged in a tunnel that has several lanes, the suction device should have such a width, that it extends across several lanes transverse to the direction of travel. If there is a fire on one of the two lanes, one of the side-by-side swirl hoods can be provided for extraction or for supply air if necessary.

Of course, it is also conceivable according to the invention that the injection device with at least one nozzle is used to inject into the vortex hood with at least one further nozzle. As a result, the advantages of the suction device according to the invention can be combined with the advantages which result from the arrangement of the nozzle within the vortex hood and the injection of the fluid into the extracted gas stream after entry into the suction device.

In principle, it is possible that the injection of a fluid is only provided in the event of a fire or when highly particulate-laden exhaust gases are generated. In addition, it can be advantageous to already provide the injection of the fluid at regular intervals so that a fire does not even occur. It may also be necessary to inject the fluid after the fire, if there is reason to fear that the fire will rekindle.

Depending on the type and application, it is possible to design the suction device according to the invention in different ways. In principle, it is thus possible for the injection device to have only a single nozzle, through which the fluid is injected into the extracted gas or the ambient air. However, since devices of the generic type can generally have housings that reach a considerable length with a large number of flow sinks, it is structurally provided that the injection device has a plurality of nozzles, so that, according to the method, the fluid is injected at a plurality of points. It can be provided that a plurality of nozzles are arranged distributed over the length of the housing, and several nozzles can also be arranged at certain points over the cross section of the housing. Depending on the application, it need not be so that adjacent nozzles lie on the same longitudinal axis of the housing. A spiral or zigzag arrangement is also possible. Ultimately, the number and arrangement depends of the nozzles depending on the respective application requirements. The principle applies that the more nozzles or injection points are required, the higher the temperature of the exhaust gas stream and / or the ambient temperature or the higher the particle loading.

Since even when the fluid with a very small droplet diameter is injected, it cannot be avoided that a smaller part of the droplets may be deposited on the housing wall of the swirl hood, it is advisable to have at least one collecting and running on the housing in the longitudinal direction Drainage channel to be provided. This channel can be formed in one piece with the housing. In principle, however, it is also possible to retrofit this channel, for example using a corresponding sheet.

To improve the dispersion of the fluid during the injection, it is advisable to add a dispersion gas to the fluid, at least immediately before the injection. A control or regulating device must be provided for this purpose. This control or regulating device not only controls the addition of the dispersion gas, but also serves to add the fluid and / or dispersion gas as required. It is thus possible to inject only the fluid, only the dispersion gas or a fluid mixed with dispersion gas into the intake flow via the control or regulating device. The injection is controlled as required.

In this context, it is particularly advantageous that two-substance nozzles are used as nozzles, through which both the dispersion gas and the fluid are injected. When using two-component nozzles and through a continuous flow of the dispersion gas, contamination of the nozzle opening and thus closure of the opening can be prevented even when the injection of the fluid is switched off.

The supply of the fluid or the dispersion gas takes place via corresponding supply lines, which can in principle be integrated into the housing or attached to it. As is usual in the prior art, the housing of the swirl hoods has a plurality of housing sections which can be connected to one another in the longitudinal direction. According to the invention, the individual housing sections then have supply sections which are terminated with sealing connections are provided so that the individual lead sections can be connected to each other in a sealed manner. It goes without saying that it is fundamentally also possible to retrofit corresponding supply lines to the housing.

As has been explained above, the injection is carried out as required. In this context, it is particularly advantageous that the quantity and / or the admission pressure of the fluid is controlled or regulated in order to set the desired drop distribution, exhaust gas temperatures and / or hood temperatures and / or particle loads. A corresponding control or regulating device is provided for this purpose, which is preferably coupled to the nozzles, so that certain nozzle diameters can be set. Furthermore, it is provided in a preferred embodiment that each nozzle or groups of nozzles can be controlled via the control and regulating device. The amount of fluid and / or gas injected can also be controlled or regulated.

Appropriate sensors are provided for measuring the relevant values in connection with the control or regulation, which are used for measuring extinction, humidity and / or temperature.

The invention further relates to a method for extracting gases, in particular smoke gases from a tunnel in the event of a fire, with at least one extraction device, the extraction device preferably having at least two vortex hoods and the vortex hoods being arranged next to one another and extending in the longitudinal direction.

In order to act on the source of the fire and to further improve the protection of persons and objects in the fire area, the invention provides that the flue gas is extracted in the event of a fire through the swirl hood assigned to a source of fire, and that the swirl hood facing away from the source of the fire supplies or deactivates supply air and that a fluid is injected into the supply air flow or into the ambient air, in particular in the form of a spray, on the suction side of the vortex hood which supplies or is deactivated. First of all, the advantage of the method according to the invention is that the fire performance of a source of fire in the area of the suction device can be significantly reduced. Through the injection on the supply air side, the tunnel area around the source of the fire is completely nebulized with the finest water droplets. This atomized air is converted in the combustion reaction, with the water droplets significantly lowering the combustion temperatures at the source of the fire. As a result, the fire performance and the flue gas volume flow decrease. Preferably, the injection located on the supply air side continues to be operated, while the injection located on the suction side is not absolutely necessary. To support this, the injection of a fluid into the intake flow located on the suction side can of course continue to be operated. The intake flow on the exhaust air side of the tunnel, i.e. below the fire, and the supply air supply on the supply air side create a circulating flow that transports the fluid droplets injected on the supply air side or the spray mist directly to the source of the fire. The resulting lower flue gas temperatures and reduced fire performance allow the required smoke extraction performance of the extraction device to be reduced. The protection of the objects arranged in the fire area or of the people in the fire area, but also the protection of the suction device and the building as such, is significantly improved as a result. At this point it may be pointed out that a “spraying device” is also understood to mean a sprinkler system or the like.

Opposing swivel hood segments are preferably operated according to the previously described method only at the points where there is a source of fire. After the fire has ended or after the smoke gases have been extracted, the swirl hoods can be deactivated and / or supply air can be supplied. A further operating possibility is that after a fire, namely after the smoke gas has been extracted, a fluid is injected on both sides of the tunnel. At a later point in time, both swirl hoods can be used again in the suction operation. When a fluid is injected into the ambient air on both sides, the area below the suction device or the entire tunnel or the like is almost completely obscured. In addition, it is possible to limit the spread of smoke and fog to the source of the fire by forming a secondary flow directed towards the source of the fire. However, it must be ensured that the fire does not rekindle as a result of the secondary flow or is supplied with fire-demanding oxygen.

Exemplary embodiments of the invention are explained below with reference to the drawing. It shows

1 is a perspective cross-sectional view of an embodiment of a suction device according to the invention,

Fig. 2 is a schematic view of part of the invention

Suction device with fluid injection,

Fig. 3 is a schematic representation of the injection of a fluid in

Shape of a spray against the intake flow of a swirl hood,

4 shows a schematic representation of an embodiment of a suction device arranged in a tunnel with two opposite swirl hoods for smoke extraction on both sides in the event of a fire,

5 shows a schematic representation of the suction device from FIG. 4 for one-sided smoke extraction with fogging of the source of the fire in the event of a fire,

6 shows a schematic cross-sectional view of a further embodiment of a device according to the invention,

7 shows a cross-sectional view of a further embodiment of a device according to the invention and

8 shows a cross-sectional view of a further embodiment of a device according to the invention. 1 shows a suction device 1 for a tunnel 2, in particular for a car tunnel. It goes without saying that the term tunnel is to be understood very broadly, that is to say also includes corridors and similar tunnel-like structures. The suction device 1 has a channel 3 which is delimited by an upper limit and a lower limit. Furthermore, the suction device 1 has two swirl hoods 4, 5.

It is now provided that the swirl hoods 4, 5 are arranged between the upper limit and the lower limit and that the channel 3 is lent by a respective swirl hood 4, 5, d. H. is limited by the wall of the housing of the respective vortex hood 4, 5. In the illustrated embodiment, it is the case that the swirl hoods 4, 5 are arranged on the lower boundary. The lower boundary itself is designed as a lower, essentially flat channel plate 6 and in one piece with the swirl hoods 4, 5. The upper limit of the device 1 is formed by an upper channel plate 7, which is also formed in one piece with the swirl hoods 4, 5. The device 1 has a large number of such structural units, which are individual segments which can be lined up in a manner adapted to the length of the tunnel 2. The upper limit can also be formed by the tunnel ceiling.

Each of the vortex hoods 4, 5 has a plurality of suction tubes 8 which protrude directly into the channel 3 from the respective vortex hood 4, 5. If suction is carried out via the channel 3, vortices with a high circumferential speed form between adjacent exhaust pipes, which lead to a high dynamic and thus low static pressure in the area of the respective vortex hood 4, 5, so that exhaust gases can be extracted accordingly.

The channel 3 has a central partition 9 through which the channel 3 is divided into two sub-channels 10, 11. The subchannel 10 is assigned to the swirl hood 4, while the subchannel 11 is assigned to the swirl hood 5. The division of the duct 3 into the sub-ducts 10, 11 enables supply air to be supplied via one sub-duct and exhaust air to be discharged via the other sub-duct. In addition, a closure device 12 is provided for closing and opening the openings of the suction pipes 8 as required. The closure device 12 has closure elements not shown in detail in FIGS. 1 and 2, for example in the form of flaps, which are connected to one another in the present case via a connecting rod 13. The connecting rod 13 serves for the joint actuation of a plurality of closure elements.

2 shows a further embodiment of a device 1 according to the invention for detecting and extracting air or other gases. The suction device 1 also has two swirl hoods, each of which in turn has a housing 14 which at least partially encloses a vortex flow which forms within the housing 14 during operation of the device 1. The housing 14 has an elongated shape, the housing 14 having a suction opening 15 extending in the axial direction for gripping or suctioning. The housing 14 itself has a substantially cylindrical shape, the cross section narrowing on one side. Instead, the housing can also be spiral or in the form of a worm gear. A plurality of suction tubes 8 open into the housing 14 and project into the channel 3 on the other side. The individual suction pipes 8 are connected to a suction device 16 via the channel 3 or the partial channel 10.

According to the invention, the device 1 is associated with an injection device 17 for injecting a fluid on the outside of the housing 14, the fluid being injected into the extracted or supplied gas stream outside the vortex hood or into the ambient air. Although it is fundamentally possible for the injection device 17 to have only a single nozzle 18, a plurality of nozzles 18 are provided in all the exemplary embodiments shown. From Fig. 2 it follows that a plurality of nozzles 18 are provided distributed over the length of the housing 14. In principle, however, it is also possible to arrange the individual nozzles 18 elsewhere on the housing 14, for example in the region of the end faces 19, 20 of the housing 14 or else in the region of the suction pipes 8. In the embodiment shown in FIG. 2, a control or regulating device 21 is also provided, through which fluid or else a dispersion gas can be supplied if necessary. Via the device 21 it is therefore possible to inject either only fluid, only dispersion gas or else fluid dispersed with gas. For this purpose, the nozzles 18 are preferably designed as two-substance nozzles. These nozzles 18 are characterized in that the fluid and the gas are supplied separately and then mixed in the nozzle. The gas-dispersed fluid then exits through a common nozzle opening. For control or regulation, the device 21 is coupled to the conveying devices 22 for the fluid and 23 for the dispersion gas. In this way, the flow and thus the amount of fluid and / or dispersion gas injected can be controlled or regulated. Furthermore, the control or regulating device 21 is provided for controlling or regulating the desired drop distributions, the exhaust gas temperatures and / or the housing temperatures. Moreover, it goes without saying that the injection device 17 has, in addition to the conveying devices 22, 23 for the fluid or the dispersion gas, corresponding supply lines 24, 25, via which the fluid or the gas is fed to the nozzles 18. The feed lines 24, 25 can be integrated into the housing 14 or can also be retrofitted.

3 shows a schematic cross-sectional view of a detail from a suction device 1 according to the invention. According to FIG. 3, the suction device 1 has at least one swirl hood 4 and at least one injection device 17 having at least one nozzle 18. In the present case, the nozzle 18 of the injection device 17 is arranged on the outside 31 of the swirl hood 4 in the region of the suction opening 15. The outlet opening of the nozzle 18 is preferably directed counter to or transversely to the intake flow 33 provided with flow arrows in the swirl hood 4. The suction flow 33 is deflected inside the vortex hood 4 after passing through the cut-off opening 15, so that a vortex flow 34 is established. The vortex flow 34 is formed between two adjacent suction pipes 8 of the swirl hood 4, only one suction pipe 8 being shown in FIG. 3. 1, the suction device 1 is arranged, for example, under a tunnel ceiling 35, the swirl hood 4 being bounded at the bottom by a lower boundary 6. The fluid is injected outside the swirl hood 4 against the suction flow 33 or direction in the form of a spray. The injected liquid droplets are quickly decelerated by the intake flow 33, deflected and then carried along with almost no slip. Due to the injection of the liquid droplets opposite or transverse to the intake flow 33, a spray mist 32 with a turbulent flow profile is formed in the injection area. The turbulence contributes to the fact that the heat transfer between the intake flow 33, which can be hot flue gases or particle-laden flue gases, for example, and the spray mist 32 takes place very quickly, with a large part of the heat transferred to the spray mist 32 to evaporate the Fluid leads. The smoke gases sucked in by the intake flow 33 are suddenly cooled. At the same time, the particles contained in the flue gas are bound. The cooling of the flue gases leads to a reduction in the volume of the extracted gas flow, so that the power of the extraction device 1 required for extraction ultimately drops. This has a positive effect on the level of investment and operating costs of the suction device 1. In addition, the flue gases are cooled in the area below the suction device 1, whereby damage to the objects arranged below the suction device 1 or to the suction device 1 can be reduced or delayed. In addition, people who are in tunnel 2 are protected.

4 shows a possible operating state of the suction device 1 according to the invention. 4 has at least two swirl hoods 4, 5 in two channels 10, 11 which are separate from one another. Suction tubes 8 are provided at regular intervals, only one suction tube 8 of a swirl hood 4, 5 being shown in each case.

The two swirl hoods 4, 5 of the suction device 1 are assigned to two different tunnel areas. If there is a fire 36 below the swirl hoods 4 as a result of a fire, for example as a result of a burning motor vehicle 37, then preferably preferably both swirl hoods 4, 5 can be used to extract the released smoke gases. By injecting a fluid through the injection device 17, the flue gases are cooled in the manner described above.

5 shows an alternative mode of operation of the suction device 1 according to the invention when it is arranged in a tunnel 2. The configuration of the suction device 1 and the arrangement of the injection device 17 correspond to the configuration shown in FIG. 3. In a departure from the operating mode shown in FIG. 4, it is provided according to FIG. 5 that the smoke gases are only extracted on the side of the suction device 1 facing the fire source 36 by means of the swirl hood 5 assigned to this area. The swirl hood 4 facing away from the source of the fire 36 either leads supply air into the tunnel 1 or is completely deactivated. It is now provided that the injection of a fluid through the injection device 17 continues on the side of the suction device 1 facing away from the source of the fire 36. It is the case here that the nozzle 18 of the injection device 17 on the side of the suction device 1 facing away from the source of the fire 36 is directed in the direction of the air flow supplied to the tunnel 2. The fluid injected into the supply air flow leads to the formation of a region 38 with atomized air.

As a result of the different flow directions of the two vortex hoods 4, 5, a circulation flow is established in the tunnel 2, which is directed from the side of the suction device 1 facing away from the source of the fire 36 towards the side of the suction device 1 facing the source of the fire 36. As a result, the area 38 is transported with atomized air in the direction of the source of the fire 36, the source of the fire 36 being atomized with water droplets. The atomized air is partially consumed in the combustion reaction in the source of the fire 36, the water droplets reducing the temperatures in and around the source of the fire 36. This reduces the fire performance and thus the flue gas volume flow.

It is also not shown that the swirl hood segments 4, 5 of the suction device 1 are preferably activated only in the areas in which there is a source of fire 36. This can ensure that the area 38 with nebulized air does not spread over the entire tunnel 2, but only in the area of the source of the fire 36 it is possible that the method described above also applies to suction devices in which a different suction element is provided instead of a swirl hood 4, 5.

A further operating possibility, not shown in detail, of the suction device 1 according to the invention consists in that after the smoke gas has been extracted, the fluid is injected into the tunnel 2 on both sides of the suction device 1. As a result, a largely complete fogging of the tunnel 2 can be achieved. This is particularly useful when there is reason to fear that the source of the fire 36 will revive after it has gone out, or that further sources of fire may occur at other locations.

In the embodiments of FIGS. 6 to 8, an injection is shown in which the fluid is injected into the housing 40 of the swirl hood 4, 5.

In the embodiment shown in FIG. 6, only one nozzle 18 is provided in the cross-sectional plane shown, while in the embodiment shown in FIG. 7, three nozzles 18 are arranged in the cross-sectional plane. It goes without saying that even more than three nozzles 18 can be provided in the cross-sectional plane. For the rest, it is not fundamentally necessary for nozzles 18 arranged next to one another in the longitudinal direction of the housing 40 to lie on the same longitudinal axis of the housing. It is also possible that the nozzles 18 are arranged along the length of the housing 14, for example in a zigzag arrangement or in a spiral arrangement.

In the embodiment shown in FIGS. 6 and 7, the nozzles 18 are aligned with their nozzle axes transversely to the direction of the eddy current. The nozzles 18 are therefore directed towards the center 41 of the vortex. In contrast, two other possibilities are shown in FIG. The upper of the two illustrated nozzles 18 is oriented with its nozzle axis in the direction of the vortex flow, which is indicated by the arrows 42, while the lower nozzle 18 is oriented with its nozzle axis against the direction 42 of the vortex flow. In all of the illustrated embodiments, it is otherwise the case that a nozzle 18 with such a nozzle öffiiung has been chosen that there is a widely expanding spray cone 43. In the illustrated exemplary embodiments, the spray cones 43 each widen by more than 60 degrees.

In the embodiment shown in FIG. 1, the individual nozzles 18 are arranged exactly in the middle between two adjacent suction openings 15 or suction or sink pipes 8. In principle, however, it is also possible to arrange the individual nozzles 8 elsewhere on the housing 14, for example in the region of the end faces of the housing 14 or in the region of the suction pipes 8.

In the embodiment shown in FIG. 8, two collecting and drainage channels 44, 45 running in the longitudinal direction of the housing 2 are provided on the housing 14. In the exemplary embodiment shown, the grooves 44, 45 are formed in one piece with the housing 14. Both channels 44, 45 have a predetermined inclination in the longitudinal direction so that the collected fluid can run off. The collecting and drainage channel 44 is preceded by a curvature 46, so that the vortex flow, which flows along the inner wall of the housing 12 in the area of the aperture 47, does not break off at the channel 44. Correspondingly, the groove 45 is also formed, which is arranged in a recessed manner with respect to the adjacent inner wall of the housing 14, to be precise also with the outer edge. The suction with the swirl hood 4, 5 shown in FIGS. 6 to 8 takes place in such a way that within the swirl hood 4, 5 a vortex is generated with a high peripheral speed. This results in a high dynamic pressure and a correspondingly low static vacuum. In this way, the gas to be extracted, which is denoted by the arrows 48, is extracted via the suction opening 15.

Claims

claims:

1. Absaugvo direction (1), preferably for a tunnel (2), in particular for a car tunnel, with at least one swirl hood (4, 5), characterized in that at least one injection device (17) having at least one nozzle (18) is provided and that the nozzle (18) of the injection device (17) is arranged on or in the swirl hood (4, 5) and is designed to generate a spray (32).

2. Suction device according to claim 1, characterized in that the outlet opening of the nozzle (18) from dr vortex hood (4, 5) or into the vortex hood (4, 5) and that the outlet opening of the nozzle (18) opposite or transversely to the intake flow (33) directed into the swirl hood (4, 5).

3. Suction device according to claim 1 or 2, characterized in that the nozzle (18) is designed for the injection of fluid droplets and that, preferably, the average pot diameter is <100 microns, in particular <10 microns.

4. Suction device according to one of the preceding claims, characterized in that at least two in particular symmetrically arranged swirl hoods (4, 5) are provided, the swirl hoods (4, 5) preferably extending in the longitudinal direction of the tunnel (2) and being arranged next to one another and the suction openings (15) of the swirl hoods (4, 5) facing away from one another.

5. Suction device according to one of the preceding claims, characterized in that at least two swirl hoods (4, 5) in at least one preferably having an upper limit and a lower limit channel (3) are arranged between the upper and the lower limit and that the channel (3) is preferably delimited by a swirl hood (4, 5).

6. Suction device according to one of the preceding claims, characterized in that the injection device (17) has a plurality of nozzles (18) and / or that over the length of the swirl hood (4, 5) distributed from the outside a plurality of nozzles (18) are arranged and / or that a plurality of nozzles (18) are arranged distributed from the outside over the cross section of the swirl hood (4, 5) and or that at least one nozzle (18) is arranged from the outside in the central area and / or in the area of the end faces ( 19, 20) of the swirl hood (4, 5) and / or the suction openings (15) is provided.

7. Suction device according to one of the preceding claims, characterized in that on or in the housing (14) of the swirl hood (4, 5) at least one in the longitudinal direction of the housing (14) extending collecting and drainage channel is provided.

8. Suction device according to one of the preceding claims, characterized in that a control device (21) for supplying the fluid and / or a dispersion gas for the fluid is provided and / or that as nozzles (18) two-substance nozzles are provided for supplying the dispersion gas to the fluid are and / or that the mass flow of the fluid and / or the dispersion gas is adjustable.

9. Suction device according to one of the preceding claims, characterized in that a further control or regulating device for controlling or regulating desired drop distributions, exhaust gas temperatures and / or housing temperatures is provided and / or that the further control or regulating device is coupled to the nozzles (18) and that each nozzle (18) or groups of nozzles (18) can be controlled via the further control and regulating device and / or that the further control or regulating device is coupled to sensors for absorbance measurement, moisture measurement and / or temperature measurement.

10. A method for the extraction of gases by means of at least one suction device (1), preferably a suction device (1) according to one of the preceding claims, in particular for the extraction of flue gases from a tunnel (2), characterized in that in the gas to be extracted and / or into the ambient air, especially immediately before the swirl hood (4, 5) and / or a fluid in the manner of a spray (32) is injected into the swirl hood (4, 5).

11. The method according to claim 10, characterized in that the fluid is injected against or transversely to the direction of the intake flow (33) of the gas and / or that the fluid is injected only in the event of fire.

12. A method for extracting gases, in particular flue gases from a tunnel (2) in the event of a fire, with at least one suction device (1), preferably according to one of the preceding claims 1 to 11, the suction device (1) preferably having at least two swirl hoods (4, 5) and wherein the swirl hoods (4, 5) are arranged side by side and extend in the longitudinal direction, preferably according to one of the method claims 10 or 11, characterized in that the flue gas in the event of a fire through the swirl hood (4, 1) associated with a source of fire (36). 5) is suctioned off that the swirl hood (5, 4) facing away from the source of the fire (36) supplies or deactivates supply air and that during the extraction on the suction side of the supply air supply or deactivated swirl hood (5, 4) a fluid in the form of a spray mist into the Supply air flow and / or is injected into the ambient air and / or

13. The method according to claim 12, characterized in that in the event of fire, a fluid is injected from the suction swirl hood (4, 5) and / or that gas is sucked off in the event of a fire via both swirl hoods (4, 5).

14. The method according to any one of the preceding claims 12 to 13, characterized in that after the extraction of the flue gas both vortex hoods (4, 5) are deactivated and / or supply air and / or that in particular after deactivating the vortex hoods (4, 5) a fluid is injected on both suction sides.