DE10026601C1 - Suction device - Google Patents

Abstract

The invention relates to a suction device (1) for suctioning gases, in particular air and / or smoke, with a swirl chamber (3) having at least one inflow opening (4) in a housing (2), with at least two opening into the swirl chamber (3) Suction openings (5, 6) and with a suction system having at least one suction chamber (7, 8) as part of the housing (2), the swirl chamber (3) being connected to the suction chamber (7, 8) via the suction openings (5, 6) A stabilized swirl flow is formed between the suction openings (5, 6) during the suction operation in the swirl chamber (3) and the outside (9, 10) of the suction chamber (7, 8) leading into the inflow opening (4) is at least partially is designed as a flow guide surface. In order to provide a suction device of the type mentioned at the outset, which is optimized in terms of flow technology, the invention provides that the housing (2) in the area of the suction chamber (7, 8) and the swirl chamber (3) has an S-shaped cross section is.

Description

The invention relates to a suction device for suction of gases, in particular their air and / or smoke, with at least one inflow opening Vortex chamber in one housing, with at least two opening into the vortex chamber the suction openings and with at least one suction chamber as part of the Extraction system with housing, the swirl chamber via the suction openings is connected to the suction chamber, whereby during the suction drives a stabilized swirl flow between the suction opening in the swirl chamber trained and wherein the leading into the inflow opening of the Ab Suction chamber is at least partially designed as a flow control surface.

A suction device of the type mentioned, which can also be used as a swirl hood is already known from EP 0 998 986 A2. In the case of an execution Game of the known suction device are the suction chamber and the vortex mer part of a common housing. Air is sucked in itself known manner via the inflow opening, the air supplied on the one hand the rounded outside of the housing in the area of the swirl chamber and others partly on the beveled outside of the suction leading into the inflow opening chamber is led. The aforementioned flow guide surface ends at that of the vortex opposite side of the chamber on an angled end wall dung, which can also serve to attach the suction device. Overall the suction chamber due to the aforementioned training with the beveled Flow guide surface and the bevelled end wall about the shape of a right triangle.

For various applications in the extraction of gases, the well-known Ab However, suction device is not particularly suitable. In some installation situations it can happen in the suction operation that the sucked air on the rear Front wall of the suction duct bounces and on the sharp edge between the End wall and the flow guide surface which leads into the inflow opening, tears off. This stall and the deflection of the air sucked in not only the suction effect in the area of the inflow opening and thus the Extraction power, this also leads to the gas to be extracted first of all Inflow opening is led away. From a fluidic point of view, this is Ab Suction device therefore disadvantageous.

The object of the present invention is to provide a suction device at the outset to provide named type, which is optimized from a fluidic point of view is.

This object is essentially achieved in that the housing cross-sectionally S-shaped in the area of the suction chamber and the swirl chamber forms is. The S shape of the housing in the area of the suction chamber and the vortex chamber causes the air to be extracted from both sides of the inflow opening ago the vortex chamber is supplied from the side of the suction chamber via the S-shape of the housing, which serves as an inflow surface just like the rounded one Outside of the vortex chamber. Unwanted stalls and diversions of the air flow at the swirl hood in the area of the suction channel does not occur. The sucked in air is optimally on the outside of the housing in the area of the Ab suction chamber directed into the inlet opening. This is particularly important if the suction device is used for smoke extraction, i.e. in the event of a fire. At the invention, it is namely possible from an immediate and quickly effective to carry out the suction of the smoke, while in the prior art it comes to it men that the smoke to be extracted on the end wall of the suction chamber what is on fire is first directed back into the room to be extracted case can be devastating.

In connection with the S-shaped design of the housing in the area of the suction It is particularly advisable for the outer chamber to be distant from the swirl chamber the outside of the suction chamber is tapered to the mounting surface, preferred wise at an angle of less than 80 ° to the mounting surface. In this way, the serves This outer area also as an inflow or guide surface.

Furthermore, it is advantageous for fluidic reasons that the the area adjoining the outer area of the outside of the suction chamber is bellied and merges into the inflow opening. In this way there is one Completely edge-free inflow surface, on the undesirable distractions from the Zu flow opening can not occur. At this point, however, it is allowed be pointed out that it is also possible in principle on the outside of the  Suction chamber to provide at least one edge. So while maintaining the flow-bearing S-shape the housing in the area of the suction chamber and also the swirl chamber can also be polygonal.

For the rest, as has already been mentioned, the inflows Opening leading outside of the swirl chamber as a rounded and / or beveled te flow control surface to be formed to the bilateral suction, so from Be range, which are located on both sides of the suction device.

In an alternative, also flow-optimized embodiment, the vortices are chamber and the suction chamber arranged so that the in nere area of the vortex chamber represents a wall of the suction chamber and that the housing in the area of the outside of the suction chamber and in the suction beak adjacent inner region of the vertebral chamber in cross section is shaped. In this embodiment, too, the outer region is Outside of the suction chamber bevelled to the mounting surface or to the outside bent, preferably at an angle of less than 80 °. In this embodiment the outside of the suction chamber goes directly into the inflow opening, where at the outer area adjoins the outer edge of the inflow opening at the end. The outer area thus represents only an arch section or an incline represents that goes directly into the inflow opening.

Depending on the application, the area opposite the suction chamber can of the housing also be beak-shaped, in the previously be written way, but in the opposite direction to the suction mer. The swirl chamber is then between this area and the suction chamber educated. This configuration enables suction on both sides in the same way supply, i.e. from the side of the suction chamber as well as from the side of the swirl chamber forth without undesired deflections of the medium to be extracted occur.

In another embodiment, which is particularly suitable to be arranged in the region of angled transitions, the ge the suction chamber opposite boundary of the vortex chamber is approximately at right angles to the fastening supply surface. This embodiment corresponds in principle to the embodiment of EP 0 998 986 A2 ( FIGS. 10 and 11) mentioned at the outset, but has the advantage that the curved or bevelled outside of the suction channel results in a favorable flow guide surface and the hood is very small overall , which is particularly important when there is only a little room or ceiling height available.

With regard to a flow-optimized suction with low ceiling heights it is also appropriate that the suction device is designed as a whole, that the vortex chamber and the suction chamber next to each other when installed which are arranged. Especially in cases of this kind, the invention makes this possible Double-sided suction to carry in a variety of building arrangements offers particular advantages. A particularly preferred area of application for the Extraction device according to the invention are underground garages. It concerns underground garages are usually very large open spaces with a low ceiling height. in the In the event of a fire, it must be ensured that there is sufficient fire or Smoke protection results. To the space available for an underground car park to be able to make optimal use of it without having to pull in the walls closed fire compartments are necessary, the use of the erfin Suction device according to the invention, because, as has been explained above, by the use of a single suction device two, namely the two of the Ab suction device adjacent areas can be suctioned off and so an efficient and safe smoke evacuation results without the realization of Smoke sections through retracted walls is required. Otherwise results by using the suction device according to the invention, a Chen cost-effective extraction, since only one for two areas to be extracted Suction device is required.

With regard to the juxtaposition of the vortex chamber and the suction chamber in the installed state, it is favorable that the inflow opening in the suction space and preferably at least essentially downward is. In this way there is sufficient suction of the suction device adjacent areas of the building concerned.  

In principle, it is possible for the suction device according to the invention to be ge in itself to form a closed or closed housing, the suction channel is then connected to a suction device for generating negative pressure. It is however, it is also possible that a part of the housing by a wall and / or Ceiling area of a building is formed. In this case, the housing is in Area of the mounting surface at least partially open. The housing can then easily be made in several parts. The same applies to the previous ones described training with beak-shaped housing, the housing also in Area of the boundary can be at least partially open. It goes without saying that the housing parts attached to the wall or on the ceiling accordingly are sealed.

Basically, it is possible that since the suction channel and the swirl channel each other are immediately adjacent as simple openings between suction openings the swirl channel and the suction channel are provided. Make these breakthroughs in suction mode represent flow sinks, between which there are stabilized swirl flows training. However, it is preferred for the suction openings in the vortexes nal protruding sink openings. Over into the spinal canal protruding sink tubes can arrange the center of the swirl flow in can be better controlled within the spinal canal.

In a particularly preferred embodiment of the present invention Two suction channels are provided, the suction device then advantageously a control device is assigned to the suction channels separately or together to be able to operate. The use of two suction channels between which the spinal canal can offer a number of advantages. To get there To be able to ensure adequate suction, correspondingly large suction cross sections or volumes are made available. This sets a large training of the suction chamber ahead. Usually this is the case strong suction only in special cases, for example in the event of a fire such. Otherwise, the room air extraction or ventilation of the concerned Room with smaller suction cross sections. Just when two Suction channels with different suction cross sections can be provided at Lower suction power required with the smaller suction channel, with higher  Extraction capacity with the extraction duct with the larger extraction cross-section be tested. In the event of a fire, when the maximum suction power is required both suction channels operated. In this case it is favorable that the suction opening gene of one suction channel offset to the suction openings of the other suction channel are arranged. Then there are vertebral sinks alternating on ge opposite sides of the vertebral canal, each producing a swirl flow between a suction opening of a suction channel and a contiguous one Beard suction opening of the other suction channel.

Preferred embodiments of the present invention result from the following description of exemplary embodiments with reference to the drawing.

It shows

Fig. 1 is a schematic representation of a first embodiment of a suction device OF INVENTION to the invention in case of fire,

Fig. 2 is a schematic representation of a second embodiment of he inventive suction device in case of fire,

Fig. 3 is a schematic representation of a third embodiment of he inventive suction device in case of fire,

Fig. 4 is a bottom view of the suction device of FIG. 3,

Fig. 5 is a schematic cross-sectional view of another embodiment of a suction device according to the invention and

Fig. 6 is a schematic cross-sectional view of yet another embodiment of a suction device according to the invention.

In the figures, a suction device 1 is shown, which is provided for suction of gases, namely in particular air and / or smoke. "Air" also means more or less heavily contaminated air. The suction device 1 has a housing 2 in which a swirl chamber 3 is formed. The Wirbelkam mer 3 is open to the outside via an inflow opening 4 .

As can be seen in particular from FIG. 4, a plurality of suction openings 5 , 6 open into the swirl chamber 3 . The individual suction openings 5 and 6 are each equally spaced from each other. Furthermore, a suction device, not shown, is provided, with which the suction openings 5 , 6 are each connected via a suction chamber 7 , 8 . During the suction operation, the suction device generates a vacuum, so that the suction openings 5 , 6 in the vortex chamber 3 each represent vacuum sinks. A stabilized swirl flow is formed in the swirl chamber 3 between the lower negative pressure. The swirl flow results in a high dynamic pressure in the Wirbelkam mer 3 , which results in a correspondingly low static pressure and thus a negative pressure, so that air is sucked in via the inflow opening 4 .

In the illustrated embodiment, a plurality of suction openings 5 , 6 are provided. About the variety of suction openings 5 , 6 , the length of the suction device 1 can be extended as desired. Otherwise, the suction chambers 7 , 8 , of which at least one is fundamentally required, are also part of the housing 2 . The leading into the inflow opening 4 outside 9 , 10 of the respective suction chamber 7 , 8 is designed as a flow guide surface.

It is essential and this applies to the embodiments according to FIGS. 1 to 4 that the housing 2 in the area of the suction chamber 7 and the swirl chamber 3 is S-shaped in cross section. The embodiments of FIGS. 1 and 2 differ with regard to the design of the outer region 11, which is distant from the swirl chamber 3, of the outside 9 of the suction chamber 7 . In the embodiment according to FIG. 1, this area 11 is arranged approximately at right angles to the fastening surface 12 , while the area 11 in the embodiment according to FIG. 2 is at an angle of less than 45 ° to the fastening surface 12 . The area 13 adjoining the area 11 of the outside 9 of the suction chamber 7 is bulged in relation to the mounting surface 12 and then merges into the inflow opening 4 . The S-shape mentioned above is essentially the result of the shape of the swirl chamber 3 and the subsequent bulging loading area 13th

In FIGS. 5 and 6 are two other, also flow-optimized Ausführungsfor of the suction device 1 shown men. As in the embodiments described at the outset, the swirl chamber 3 and the suction chamber 8 are directly adjacent to one another, in the present case, however, such that the inner region 14 of the we chamber 3 represents a wall of the suction chamber 8 , the housing 2 in the region of the outside 10 of the Suction chamber 8 and in the cross-section of the inner region 14 of the swirl chamber 3 bordering on the suction chamber 8 . What is meant by "beak-shaped" results from FIGS. 5 and 6. In addition, it should be noted in this connection that the loading area 14 does not have to be the wall of the suction chamber 8 . What is meant is only the immediately adjacent arrangement of the inner region 14 and the wall of the suction chamber 8 . The arrangement of the suction chamber 8 next to the vortex chamber 3 , as shown in FIGS. 5 and 6, results in an optimal use of space while avoiding dead spaces on the outside of the vortex chamber 3 with optimized flow guidance.

As can be seen from FIGS. 5 and 6, the outer region of the outside 10 of the suction chamber 8 is bent outwards toward the fastening surface, in a hyperbolic manner. The hyperbolic outer area merges directly into the flow opening 4 .

In the illustrated in Fig. 5 embodiment of the suction chamber is also formed beak-shaped opposing portion 15 of the housing 2, 8, depending on but in the opposite direction to the suction chamber 8. The outside 16 of the area 15 is also hyperbolic or has an arcuate section. In principle, a beveling of the area 15 is also possible in order to achieve a flow guiding surface. The same applies to the outside 10 of the suction chamber 8 , which can be chamfered and / or curved instead of the hyperbolic design.

In Fig. 6 shows an embodiment which is suitable for arrangement in the region of a wall / ceiling transfer or in the region of a fall. The boundary 17 of the swirl chamber 3 opposite the suction chamber 8 is arranged approximately at right angles to the fastening surface 12 .

All of the other embodiments are essentially designed in such a way that the outside of the respective suction chamber 7 , 8 is free of flow separation edges from a fluidic point of view and at least essentially free of dead space.

In all embodiments, it is also the case that the swirl chamber 3 and the respective suction chamber 7 , 8 are arranged side by side in the installed state. By juxtaposition of the swirl chamber 3 and the respective From suction chamber 7 , 8 , the suction device 1 according to the invention can also be used in rooms with a low ceiling height. In this case, in order to be able to aim for a good suction, the inflow opening 4 should be directed into the space to be extracted, preferably essentially downwards.

It is not shown that parts of the housing can also be formed from a wall or ceiling section. In these areas, the housing 2 is then excluded accordingly.

As can also be seen from the individual figures, sink tubes are provided for the suction openings 5 , 6 , which protrude into the swirl chamber 3 . It is understood that, instead of the sink tubes, simple openings between the swirl chamber 3 and the respective suction chamber 7 , 8 can be provided.

In the embodiment shown in FIG. 3, two suction chambers 7 , 8 are provided within the housing 2 , between which the swirl chamber 3 is arranged. This embodiment also has the significant advantage that the overall height of the suction device 1 is very low, which makes the suction device 1 according to the invention particularly suitable for rooms with low room heights. In this case, a control device (not shown) is provided in order to be able to operate the suction chambers 7 , 8 separately or together. In the illustrated embodiment, the suction chambers 7 , 8 each have different suction cross sections. The suction device 1 can thus be operated in a simple manner with three stages. Is sucked through both suction chambers 7, 8, is formed between the respective suction ports 5 from the one suction chamber 7 and the adjacent suction holes 6 of the other suction chamber 8 are each a stabilized swirl flow. The individual suction openings are staggered and always at the same distance.

Moreover, it goes without saying that in the embodiment shown in FIG. 5 it is also possible to implement a second suction chamber in area 15 .

Finally, FIGS. 1 to 3 illustrate that when using the suction device 1 according to the invention, extraction of air or smoke from two adjacent areas or smoke sections, for example in an underground car park with optimized flow control, is possible.

Claims (20)

1. Suction device ( 1 ) for extracting gases, in particular air and / or smoke, with a swirl chamber ( 3 ) having at least one inflow opening ( 4 ) in a housing ( 2 ), with at least two suction openings ( 3 ) opening into the swirl chamber ( 3 ) 5 , 6 ) and with a suction system having at least one suction chamber ( 7 , 8 ) as part of the housing ( 2 ), the swirl chamber ( 3 ) being connected to the suction chamber ( 7 , 8 ) via the suction openings ( 5 , 6 ), wherein during the suction operation in the swirl chamber ( 3 ) a stabilized swirl flow between the suction openings ( 5 , 6 ) is formed and the opening ( 4 ) leading into the inlet opening ( 4 ) outside ( 9 , 10 ) of the suction chamber ( 7 , 8 ) at least partially is designed as a flow guide surface, characterized in that the housing ( 2 ) in the area of the suction chamber ( 7 , 8 ) and the swirl chamber ( 3 ) is S-shaped in cross section. 2. Suction device according to claim 1, characterized in that the outer, the swirl chamber ( 3 ) distant region of the outside ( 9 ) of the suction chamber ( 7 ) for BEFE stigungsfläche ( 12 ) is chamfered, preferably at an angle less than 80 °. 3. Suction device according to claim 1 or 2, characterized in that the area ( 13 ) adjoining the outer region ( 11 ) of the outside ( 9 ) of the suction chamber ( 7 ) is bulged and merges into the inflow opening ( 4 ). 4. Suction device according to one of the preceding claims, characterized in that the outside ( 10 ) leading into the inflow opening ( 4 ) of the vortex chamber ( 3 ) is designed as a rounded and / or beveled flow guide surface. 5. Suction device ( 1 ) for extracting gases, in particular air and / or smoke, with a swirl chamber ( 3 ) having at least one inflow opening ( 4 ) in a housing ( 2 ), with at least two suction openings ( 3 ) opening into the swirl chamber ( 3 ) 5 , 6 ) and with a suction system having at least one suction chamber ( 7 , 8 ) as part of the housing ( 2 ), the swirl chamber ( 3 ) being connected to the suction chamber ( 7 , 8 ) via the suction openings ( 5 , 6 ), wherein during the suction operation in the swirl chamber ( 3 ) a stabilized swirl flow between the suction openings ( 5 , 6 ) is formed and the opening ( 4 ) leading into the inlet opening ( 4 ) outside ( 9 , 10 ) of the suction chamber ( 7 , 8 ) at least partially is designed as a flow guide surface, characterized in that the vortex chamber ( 3 ) and the suction chamber ( 9 ) are adjacent to one another such that the inner region ( 14 ) of the vortex chamber ( 3 ) has a wall of the Suction chamber ( 8 ) and that the housing ( 2 ) in the area of the outside ( 10 ) of the suction chamber ( 8 ) and in the inner region ( 14 ) of the swirl chamber ( 3 ) adjoining the suction chamber ( 8 ) is formed in cross section. 6. Suction device according to claim 5, characterized in that the outer loading area of the outside ( 10 ) of the suction chamber ( 8 ) to the fastening surface ( 12 ) is beveled and / or bent outwards, preferably at an angle of less than 80 °. 7. Suction device according to claim 5 or 6, characterized in that the outer region of the outside ( 10 ) merges into the inflow opening ( 4 ). 8. The suction device of one of claims 5 to 7, characterized in that the the suction chamber (8) opposite the area (15) of the housing (2) also formed beak-shaped, but in the opposite direction to the suction chamber (8). 9. Suction device according to one of claims 5 to 7, characterized in that the suction chamber ( 8 ) opposite boundary ( 17 ) of the Wirbelkam mer ( 3 ) is formed approximately at right angles to the mounting surface ( 12 ). 10. Suction device according to one of the preceding claims, characterized in that the outside ( 9 , 10 ) of the housing ( 2 ) is at least substantially free of dead space and / or free of flow separation edges in fluidic terms. 11. Suction device according to one of the preceding claims, characterized in that the swirl chamber ( 3 ) and the suction chamber ( 7 , 8 ) are arranged side by side in the built-in state. 12. Suction device according to one of the preceding claims, characterized in that the inflow opening ( 4 ) in the installed state is directed into the space to be suctioned, preferably at least essentially downwards. 13. Suction device according to one of the preceding claims, characterized in that the housing ( 2 ) in the region of the fastening surface ( 12 ) is at least partially open, so that the part of the fastening surface ( 12 ) facing the we belkammer ( 3 ) and / or the suction chamber ( 7 , 8 ) is at least partially formed by a wall or ceiling section. 14. Suction device according to one of the preceding claims, characterized in that the housing ( 2 ) in the region of the boundary ( 17 ) is at least partially open, so that the boundary ( 17 ) is at least partially formed by a wall or ceiling section. 15. Suction device according to one of the preceding claims, characterized in that for the suction openings ( 5 , 6 ) in the swirl chamber ( 3 ) inra ing pipes are provided. 16. Suction device according to one of the preceding claims, characterized in that at least two suction chambers ( 7 , 8 ) are provided. 17. Suction device according to one of the preceding claims, characterized in that the swirl chamber ( 3 ) between the suction chambers ( 7 , 8 ) is arranged. 18. Suction device according to one of the preceding claims, characterized in that a control device is provided to operate the suction chambers ( 7 , 8 ) separately or together. 19. Suction device according to one of the preceding claims, characterized in that the suction chambers ( 7 , 8 ) have different suction cross sections. 20. Suction device according to one of the preceding claims, characterized in that the suction openings ( 5 ) of one suction chamber ( 7 ) are arranged offset to the suction openings ( 6 ) of the other suction chamber ( 8 ), so that there is in each case a swirl flow between a suction opening the one suction chamber and an adjacent suction opening of the other suction chamber.