EP2863129A1 - Extraction device, in particular steam extractor - Google Patents

Abstract

The invention relates to a suction device, in particular a vapor extraction device comprising a housing (2) with at least one suction opening (3) and a suction device accommodated in the housing (2) for generating a suction flow (AS) and with means for influencing the flow direction of the suction flow (AS). in which the means for influencing the flow direction of the suction flow (AS) are formed by a plurality of guide grooves (6) extending at least in sections along the outer surface sections (2a) of the housing (2) adjoining the suction opening (3) in the direction of Extend suction (3).

Description

The invention relates to a trigger device, in particular a vapor extraction device according to the preamble of claim 1.

Deduction devices, in particular extractor device for detecting and extracting fumes, vapors and other fluid or gaseous media in the kitchen or in the industrial sector are well known. Here, the suction of the media is carried out by generating a suction flow over at least one narrow suction port, for example, a surface or Schlitzabsaugung. Corresponding suction devices are for example in the DE 202011005698 U1 or the DE 20207549 U1 described. In such exhaust devices, however, the detection effect decreases sharply with the distance to the suction source, in particular the suction port.

Furthermore, in order to improve the detection effect, so-called "blow-suction processes" are known in which the detection effect is also made possible by fumes or vapors which are produced farther away from the suction opening or area by generating an additional blow flow oriented in the direction of the suction source , The guidance and orientation of the blast flow is effected by the adhesion effect on the smooth outer surfaces of the housing of the suction device and in hole vortex method additionally by guiding the blast flow in the exhaust openings. After blowing, the flow is discontinued. Preferably, a blast flow with a tangential flow component, i. blown out with a angular momentum component to a central suction port. By reducing the radial distance of this flow drawn to the suction opening, the tangential flow component, i. it forms a swirl flow. As a result, a tornado-like flow structure is to be generated, which enhances the detection effect of the extractor device. However, there is no disadvantageous active guidance of the generated blast flow.

Furthermore, from the WO 2012/062249 a method and an associated fan or suction device for influencing the flow behavior of turbomachines, in which the turbomachine has a flow leading surface having at least one structured surface portion, wherein at least in the Surface areas of the turbomachine, in which the flow is detached from the surface and / or turbulent flows occur, are generated by means of a structured surface portion longitudinal vortex, through which the flow is structured. Disadvantageously, due to the small depth of the structuring, no subdivision of the flow is possible, ie disadvantageously there is no active guidance and / or subdivision of the intake and / or blowing flow of a turbomachine.

From the DE 295 13 292 a vapor extraction element for arrangement above at least one vapor source is known, which has a radial fan with curved at least against the direction of rotation blades, in which the air to be withdrawn via a nozzle train is fed substantially centrally. For this purpose, the nozzle train has baffles which form a feed channel running along the axis of rotation of the radial fan.

Proceeding from this, the present invention seeks to provide a trigger device, in particular extractor device with improved detection effect, which allows influencing the intake flow. Based on the features of the preamble of claim 1, the object is achieved by its characterizing features.

The essential aspect of the extraction device according to the invention is to be seen in that the withdrawal device comprises means for influencing the flow direction of the intake flow, which are formed by a plurality of channel-like guides, at least in sections along the adjoining the suction port outer surface of the housing in the direction of the suction port extend. Due to the structuring according to the invention of the surface of the housing in the region of the suction opening, suction flow is particularly advantageously generated by the suction effect of the sink, which is conducted over a longer distance and influenced in such a way as to produce a so-called channel flow compared to the prior art. Due to the friction in the channel-like guides of the housing outer wall, a mixing of the generated gutter flow with the environment and thus an improvement of the detection effect in comparison to the wall currents of flat surfaces of conventional suction takes place. Another advantage over flat surfaces of conventional suction devices is the rugged structure of gutter jet surfaces. Due to these "roughness elements", eruptive vapor or density flows are slowed down more than over smooth surfaces. This in turn increases the detection effect. An extraction device equipped with the guide grooves according to the invention is significantly quieter than known devices and has a significant improvement in energy efficiency.

Due to the branched gutter structure, the gutters can also be branched into areas of the suction device in which in normal surface suction or conventional planar blow suction hardly a detection effect occurs. Since the method works with both active and passive gutter flows, it has the potential to be used in low-cost extraction devices, ie mass-produced products.

Further advantageously, a multiplicity of flows are generated by the guide grooves, which can also extend transversely to the "main flow direction" of the suction device and have the purpose of transporting fluids or pollutants to the suction opening in such a way that the suction effect or the volume flow of the suction device is considerably increased ,

Particularly advantageously, in each case one guide channel has at least two opposite open ends and a channel channel connecting them, wherein at least one end of a guide channel opens into the suction opening.

Further advantageously, the guide grooves are formed by the adjoining the suction or surrounding surface portions of the housing, and preferably by introduced into the surface portions of the housing recesses or depressions or a corresponding deformation of the outer wall of the housing.

Preferably, the suction opening are formed by a slot-like or planar opening in the housing, wherein the flat suction opening has a square, rectangular, polygonal, circular, kidney-shaped, cardioid-shaped, elliptical, superellipsoidal, superformula-shaped or spiralarmförmigen cross-section.

In an alternative embodiment variant of the invention, the suction device additionally has means for generating a blast flow and supplying the blast flow via the guide grooves to the intake opening. In this way, a blast flow can be generated, which is fed into the guide grooves and enhances the intake flow.

Further advantageously, the guide troughs have a part-circular, angular, round, V-shaped, inclined or T-shaped channel cross-section. Also, the guide grooves have a groove width and a gutter depth, but the gutter depth is preferably larger than the gutter width. The surface of the channel cross-section of the guide grooves increases in a preferred embodiment in the direction of the suction opening.

The channel-like guides can either be arranged on or formed by a curved surface section of the housing.

Advantageously, the guide grooves are formed by means of two adjacent guide plates, wherein a plurality of such guide plates are either arranged directly on the housing surface or part of a housing guide ring, in particular an attachment component.

Further advantageously, the guide grooves are designed as open guide grooves or at least partially closed guide grooves.

Furthermore, the subject of the invention is a Gebläseeinströmring for use in a suction device according to the invention, which has a plurality of guide grooves, which extend in the direction of the Gebläseeinströmring enclosed by the suction on the ring surface.

Further developments, advantages and applications of the invention will become apparent from the following description of exemplary embodiments and from the figures. In this case, all described and / or illustrated features alone or in any combination in principle subject of the invention, regardless of their Summary in the claims or their dependency. Also, the content of the claims is made an integral part of the description.

Fig. 1

eine schematische Schnittdarstellung durch eine erfindungsgemäße Abzugsvorrichtung in Form einer Dunstabzugshaube,

Fig. 2

eine schematische Schnittdarstellung durch eine erfindungsgemäße Abzugsvorrichtung in Form einer Dunstabzugshaube mit aktiver Blasströmung,

Fig. 3

eine perspektivische Ansicht des Ansaugbereiches der Dunstabzugshaube gemäß Figur 2 mit Führungsrinnen,

Fig. 4

eine perspektivische Ansicht des Ansaugbereiches der Dunstabzugshaube gemäß Figur 2 mit alternativ ausgeführten Führungsrinnen,

Fig. 5a-m

unterschiedliche Querschnittsformen der Führungsrinnen,

Fig. 6a-d

eine schematische Draufsicht auf den Ansaugbereich einer Dunstabzugshaube mit schlitzartigen Einlassöffnungen und einer kreisförmigen Einlassöffnung.

Fig. 7a-c

eine schematische Seitenansicht sowie perspektivische Ansichten einer alternativen Ausführungsform einer Dunstabzugshaube mit aktiver Blasströmung,

Fig. 8a,b

eine perspektivische Ansicht der Ansaugbereiche mit in Form von Ausnehmungen bzw. Vertiefungen in der Gehäuseoberfläche gebildeten Rinnenführungen,

Fig. 9a-f

perspektivische Ansichten eines Gebläseeinströmringes für einen Trommelläufer mit erfindungsgemäß ausgebildeten Führungsrinnen

Fig. 10

eine perspektivische Ansicht einer Ausführungsvariante eines Gebläseeinströmringes mit Führungslamellen für einen Trommelläufer mit erfindungsgemäß ausgebildeten Führungsrinnen,

Fig. 11

eine perspektivische Ansicht einer alternativen Ausführungsvariante eines Gebläseeinströmringes mit Führungslamellen für einen Trommelläufer mit erfindungsgemäß ausgebildeten Führungsrinnen,

Fig. 12a,b

eine perspektivische Ansicht eines als Aufsatzbauteil ausgebildeten Gebläseeinströmringes mit Führungslamellen für einen Trommelläufer ohne und mit einer zumindest abschnittsweisen Abdeckung,

Fig. 13a, b

eine perspektivische Ansicht sowie einer Seitenansicht einer alternativen Ausführungsvariante eines Gebläseeinströmringes mit Führungslamellen mit variabler Lamellenhöhe für einen Trommelläufer mit erfindungsgemäß ausgebildeten Führungsrinnen,

Fig. 14

eine schematische Draufsicht auf eine weitere alternative Ausführungsvariante eines Gebläseeinströmringes mit Führungslamellen für einen Trommelläufer mit erfindungsgemäß ausgebildeten Führungsrinnen und

Fig. 15

eine perspektivische Ansicht einer alternativen Ausführungsvariante eines Gebläseeinströmringes mit aus einem Grundkörper hergestellten Führungslamellen für einen Trommelläufer mit erfindungsgemäß ausgebildeten Führungsrinnen.

The invention will be explained in more detail below with reference to the figures of exemplary embodiments. Show it:

Fig. 1

FIG. 2 a schematic sectional view through an extraction device according to the invention in the form of an extractor hood, FIG.

Fig. 2

1 is a schematic sectional view through an extraction device according to the invention in the form of an extractor hood with active blast flow,

Fig. 3

a perspective view of the intake of the hood according to FIG. 2 with guide channels,

Fig. 4

a perspective view of the intake of the hood according to FIG. 2 with alternatively designed guide troughs,

Fig. 5a-m

different cross-sectional shapes of the guide channels,

Fig. 6a-d

a schematic plan view of the intake of an extractor hood with slot-like inlet openings and a circular inlet opening.

Fig. 7a-c

3 a schematic side view and perspective views of an alternative embodiment of an extractor hood with active blast flow,

Fig. 8a, b

a perspective view of the suction with formed in the form of recesses or depressions in the housing surface channel guides,

Fig. 9a-f

perspective views of a Gebläseeinströmringes for a drum rotor with inventively designed guide grooves

Fig. 10

a perspective view of a variant of a Gebläseeinströmringes with guide blades for a drum rotor with inventively designed guide grooves,

Fig. 11

a perspective view of an alternative embodiment of a Gebläseeinströmringes with guide blades for a drum rotor with inventively designed guide grooves,

Fig. 12a, b

3 a perspective view of a fan inlet ring formed as an attachment component with guide lamellae for a drum rotor without and with an at least partial cover;

Fig. 13a, b

a perspective view and a side view of an alternative embodiment of a Gebläseeinströmringes with guide blades with variable blade height for a drum rotor with inventively designed guide grooves,

Fig. 14

a schematic plan view of a further alternative embodiment of a Gebläseeinströmringes with guide blades for a drum rotor with inventively designed guide grooves and

Fig. 15

a perspective view of an alternative embodiment of a Gebläseeinströmringes made with a base body guide plates for a drum rotor with inventively designed guide grooves.

In the figures, 1 denotes in each case a take-off device, in particular a vapor extraction device, which in each case has at least one housing 2, in particular a hood-like housing body.

In a preferably provided on the underside of the housing 2 suction region 1 'of the trigger device 1, at least one suction port 3 is provided, which may have a different geometric configuration, in particular cross-sectional shape and surface depending on the embodiment. The suction opening 3 may be formed, for example in the form of a slot-like or planar opening, wherein the flat Opening, for example, a square, rectangular, polygonal, circular, kidney-shaped, cardioid-shaped, elliptical, superellipsenförmigen, superformula-shaped or spiralarmförmigen cross-section.

Such extraction devices or extractor devices 1 have a suction device, for example in the form of a drum rotor or the like suction devices such as a radial fan for generating a flow sink, which is designed to generate a suction flow AS via the suction port 3. A filter device 4 may also be provided in the housing 2 of the extraction device or extractor device 1 for filtering the swaths, vapors or the like of fluid or gaseous media sucked in by means of the intake flow AS.

FIG. 1 shows by way of example in a simplified sectional view a longitudinal section through a designed as an extractor hood extractor device 1, the housing 2 a hood-like housing body with a suction in the intake 1 'of the extractor device 1 arranged suction port 3, which has a circular cross-section in the present embodiment. Further, the hood-like housing body 2 on the suction region 1 'opposite side joins a chimney-like exhaust duct 5 at. In the housing 2, for example, a filter device 4 is provided. By means of a suction device, not shown, preferably accommodated in the housing 2, a flow depression is produced which causes an intake flow AS via the suction opening 3. The intake flow AS is preferably oriented along a vertical axis VA of the extractor device 1. When using a drum rotor as a suction, for example, the axis of rotation of the drum rotor and the vertical axis VA coincide.

The extractor device 1 according to the invention has means for influencing the flow direction of the intake flow AS, which are formed by a multiplicity of guide grooves 6 which extend at least in sections along the surface sections 2a of the housing 2 adjoining the intake opening 3 in the direction of the intake opening 3. Such a guide channel 6 has, for example, two opposite open ends 6 ', 6 ", wherein at least one end 6' of a guide channel 6 opens into the suction opening 3 and, for example, the The suction effect of the depression of the extractor device 1 generates a flow in the guide channels 6 which influences the intake flow AS, in particular the flow direction of the extractor device 1. This flow becomes also referred to below as the channel flow RS.

Between the open ends 6 ', 6 "of a guide channel 6, a channel channel 6"' forms. The guide channel 6 may be designed differently with regard to the channel cross-section RQ, the channel depth RT and / or the channel width RB. In a preferred embodiment variant, the area of the channel cross-section RQ increases in the direction of the intake opening 3 or is dimensioned such that both the intake ambient air and a generated channel flow RS can be guided therein.

Preferably, a plurality of guide grooves 6 are arranged side by side, which are each formed identical to each other, in terms of channel cross-section RQ, gutter depth RT and / or the channel width RB. The guide grooves 6 extend in each case in the direction of the suction opening 3, preferably with at least one radial and / or tangential directional component with respect to the center of the suction opening 3 or the vertical axis VA.

In the present embodiment according to Figure 1-3 The guide grooves 6 extend, for example, radially to the center or center of the circular intake opening 3 and have no tangential component. Preferably, the gutter depth RT is greater than the groove width RB to ensure the emergence of a sufficiently strong groove flow RS. The gutter depth RT is for example between 1 cm and 10 cm, wherein the gutter width RB can be between 0.5 cm and 15 cm. Here, the dimensions of the guide channel 6 are adapted to the dimensions of the suction device or the drum rotor. For example, when using a drum rotor 8 with an impeller diameter of about 150 mm, the gutter depth RT is between 2 cm and 5 cm and the gutter width RB between 0.5 cm and 7 cm. The channel length RL is also dependent on the diameter of the intake opening 3 and the impeller diameter of the drum rotor 8 and preferably corresponds to 10% to 60% of the respective diameter. At a Impeller diameter of about 150 mm, the guide grooves 6 so that, for example, a groove length RL between 15 mm and 90 mm.

The guide grooves 6 are formed by the adjoining the suction opening 3 or these surrounding surface portions 2a of the housing 2, and preferably by introduced into the surface portions 2a of the housing 2 recesses, depressions or a corresponding deformation of the outer wall of the housing 2. Thus form these are the outer wall of the housing 2 or are mounted on this. In one embodiment, the guide grooves 6 receiving or forming surface portions 2a of the housing 2 may be formed curved at least in sections.

In an alternative embodiment of the invention according to the FIGS. 7 and the Figures 10-15 the guide grooves 6 are formed by a plurality of guide blades 9, which are preferably arranged in the region of the adjoining the suction opening 3 or these surface portions 2a of the housing 2. In this case, two adjacent guide blades 9 each include a guide channel 6. The guide plates 9 are either connected directly to the housing 2 or formed integrally therewith.

Alternatively, the guide blades 9 may be part of an attachment component 10, which has, for example, an annular support plate 10.1 with a feed opening 3 adapted to the through opening 10.2, to which the guide blades 9 are fixed or formed integrally therewith. Such an attachment component 10 may be made of metal or plastic, for example. Advantageously, the attachment component 10 can also be retrofitted to existing extraction devices or extractor devices 1 in order to achieve the advantages of the "channel guide" according to the invention. The guide blades 9 have, for example, a wall thickness which is between 0.05 mm and 8 mm. The course of the wall thickness along the radial extent of the guide channel 6 or guide plate 9 is approximately uniform or decreases slightly in the direction of the vertical axis VA.

Furthermore, the guide grooves 6 may be formed such that they combine to form a larger guide trough and / or in two or more guide troughs split, wherein the guide grooves 6 preferably converge on a common center. In this case, secondary guide channels and main guide channels may be provided which have differently dimensioned cross-sectional areas, wherein the main guide channels preferably have a larger cross-sectional area than the secondary guide channels. The secondary guide channels preferably open at an acute angle in the main guide channels. This results in a tree-like or plant-like branching of the guide grooves 6.

Further, the guide grooves 6 taken by themselves may have a curvature and / or terminate the free end 6 'of the guide grooves 6 opening into the suction opening 3 with the edge of the suction opening 3, i. the guide grooves 6 extend obliquely to the edge of the suction opening 3, in particular in the case of a slot-like suction opening 3rd

Also, in an alternative embodiment of the invention, the suction device or extractor device 1 means for generating a Blasströmung BS and feed the Blasströmung BS via the guide grooves 6 to the intake port 3 have. For this purpose, a blower arrangement not shown in the figures is preferably provided, via which a blowing flow BS is generated, which is introduced via a suitable channel system and associated outlet nozzles in the region of the other end 6 "of the respective guide channel 6 in the channel channel 6" 'and by means of Guide grooves 6 is guided in the direction of the suction port 3, ie the intake flow AS supports.

In FIG. 2 is exemplary in FIG. 1 illustrated extractor hood shown, which, however, additionally comprises means for generating a blast flow BS. Via a feed channel 7, which extends in a section annularly around the exhaust air duct 5 and thus forms an annular feed space in cross-section, which is a via in the FIG. 2 blower assembly not shown generated Blasströmung BS to the free ends 6 "of the guide troughs 6 out, via nozzle-like openings of the annular feed space the laterally into the respective channel channel 6"'of the guide trough 6 open. By means of the blowing flow BS thus produced and guided via the guide channel 6 to the suction opening 3, a clear improvement in the detection effect of the extractor device 1 results.

In FIGS. 3 and 4 each is a perspective view of a fume extractor 1 according to FIG. 2 shown with active bubble flow. Here are in the embodiment according to FIG. 3 the guide grooves 6 radially oriented to the central axis of the circular suction port 3, while in the embodiment according to FIG. 4 are curved and extend tangentially to the central axis of the circular intake opening 3.

An extractor device 1 with guide grooves 6 according to the invention can thus be operated in an active embodiment variant with a blowing flow BS or in a passive embodiment variant with groove flow RS generated by means of suction flow.

In the FIGS. 5 (A) to (M) different channel cross sections RQ of the guide grooves 6 are shown by way of example; and a simple rectangular cross section in FIG. 5 (A) , a U-shaped cross section in FIG. 5 (B) , a semicircular cross-section in FIG. 5 (C) , a U-shaped cross-section with rounded upper edges in FIG. 5 (D) , a rectangular cross section with rounded corners in FIG. 5 (E) , a rectangular cross-section with rounded corners and a round central gutter floor in FIG. 5 (F) , a rectangular cross section with rounded corner areas and a round central gutter recess in FIG. 5 (G) , a rectangular cross-section with lateral bulge in FIG. 5 (H) , an inverted T-shaped cross section in FIG. 5 (I) , a cross-section having two rounded bulges in FIG FIG. 5 (J) , a dovetailed cross section in FIG. 5 (K) , a rectangular cross section with wavy wall in Figure 5 (L) and a triangular cross section in FIG. 5 (M) , In this case, a guide trough 6 can also have different cross-sectional shapes at the two opposite ends 6 ', 6 "which merge into one another. The guide trough 6 can also run obliquely to the vertical axis VA.

The guide grooves 6 are formed, for example, as open guide grooves, ie the guide grooves 6 are formed open on the side facing away from the trigger device or extractor device 1 side. Also, the guide grooves 6 may be formed at least partially tubular or in the form of closed guide grooves, ie the opening of the guide grooves 6 facing away from the extraction device or extractor device 1 can be designed to be closed.

In the FIGS. 6a, b is a schematic view of the intake 1 'of a fume extractor 1 shown with a slot-like suction port 3, in which the guide grooves 6 extend obliquely to the straight housing edge enclosing the suction port 3, in Fig. 6a a plurality of outer guide grooves 6a on the outwardly adjoining housing surface portions 2a and in Fig. 6b both a plurality of outer and inner guide grooves 6a, 6b in the outside and inside of the slot-like suction port 3 subsequent housing surface portions 2a, b. The lines of the guide grooves 6a, 6b, in particular the angle to the slot-like suction port 3 is arbitrary.

In FIG. 6c a fume extractor 1 is shown with an annular suction port 3 with outer guide grooves 6a. FIG. 6d shows a fume extractor 1 with a circular suction port 3 with also outer guide grooves 6a. By means of the guide grooves 6a, 6b, a passive channel flow RS is generated via the suction.

Figure 7a shows a cross section through a fume extraction device 1 with a curved housing surface 2a with guide grooves arranged thereon 6. The guide grooves 6 are hereby separated from each other by a respective guide blade 9, which is for example plate-shaped. The extractor device 1 has on the upper side outlets for a blast flow BS, via which the blast flow BS is guided or blown into the guide grooves 6. FIG. 7b shows a perspective view of the along the curved housing surface 2a extending guide grooves 6, which are preferably parallel to each other, in vertical planes. The suction opening 3 is formed in the present case by a lattice-like suction element 3 ', which has a plurality of small, matrix-like arranged suction openings. In FIG. 7c is a front view of the extractor device 1 is shown, on the open to the front guide grooves 6, which are separated in the present embodiment by partitions.

The FIGS. 8a, b show embodiments of a suction 1 'a fume extractor 1 with a circular suction port 3, in which the channel guides 6 are formed by introduced into the housing surface recesses or depressions. FIG. 8a shows, for example straight guide grooves 6 and Fig. 8b curved guide grooves 6 in a perspective view. The free ends 6 'of the guide grooves 6 open in each case directly into the suction port. 3

In the FIGS. 9a-f a Gebläseeinströmring 7 a blower arrangement is shown, which is provided with the guide grooves 6 according to the invention. The Gebläseeinströmring 7 may for example also be designed as an attachment component 10.

The Gebläseeinströmring 7 has a plurality of guide grooves 6, which extend in the direction of the suction port 3 on the ring surface. The guide grooves 6 are thus formed for supplying a flow into the circular suction opening 3 at an inflow angle a, which is enclosed by a tangent to the inner contour of the inflow opening 3 and the guide grooves 6. Depending on the blower type or application or circumferential position f, this inflow angle a can be chosen differently. Figure 9a-f show an arrangement of the guide grooves 6 using a constant inflow angle a over the entire circumference 0 <f <360 °. This results in a regular course of the guide grooves 6, ie arranged at a constant distance from each other and constant inflow angle a over the circumference.

The FIGS. 9c, d show here in addition to Gebläseeinströmring 7, the impeller of a drum rotor 8 a fan assembly which rotates clockwise about vertical axis VA. By an appropriate choice of the orientation of the blower arranged on the Gebläseeinströmring 7 guide troughs 6 either a flow in the clockwise direction, ie in the direction of rotation of the drum rotor 8 or a flow counterclockwise, ie against the direction of rotation of the drum rotor 8 are generated. This is a special application of passive channel flows RS. With an orientation of the guide grooves 6 in the direction of rotation of the drum rotor 8 results in a reduction of the noise of the drum rotor 8 and a volume flow increase.

FIGS. 10 and 11 For example, each show a perspective plan view of a Gebläseeinströmring 7 whose guide grooves 6 and guide plates 9 are curved, which have different gutter depths RT. The guide grooves 6 have a rectangular channel cross section RQ. In the FIGS. 10 and 11 Guide grooves 6 and guide plates 9 are oriented in the direction of rotation of the drum rotor 8 about its axis of rotation or the vertical axis VA. Alternatively, the guide grooves 6 and guide plates 9 can be oriented counter to the direction of rotation of the drum rotor 8 about its axis of rotation or the vertical axis VA. The Gebläseeinströmring 7 thus forms a "gutter ring" with guide grooves 6 increased gutter depth RT. As a result, an impeller of a fan similar structure is generated.

The FIGS. 12a . b show a trained as an attachment component 10 Gebläseeinströmring with guide blades 9, which have a low wall thickness, preferably a wall thickness less than 1 mm. The guide blades 9 are preferably elastically deformable and / or spring-like, ie are deformed by the flowing past at least slightly elastic. The guide blades 9 may be made for example of plastic or a similar elastically deformable material. Advantageously, the guide blades 9 of the attachment component 10 may be provided with a cover 11, so that at least partially closed guide grooves 6 are formed. In FIG. 12b For example, a cover 11 with two sections 11.1, 11.2 indicated different radial width, which preferably extends over all the guide blades 9 and thus forms an annular cover 11.

In the FIGS. 13a, b By way of example, an embodiment variant of a fan inflow ring 7 is shown, in which the gutter depth RT or the height of the guide blades 9 increases in the direction of the axis of rotation of the drum rotor 8 or the vertical axis VA or in the radial direction and decreases again after exceeding a peak value at the level of the intake 3 ends. The guide blades 9 are in turn curved.

FIG. 14 shows an alternative embodiment of an integrated into the housing 2 Gebläseteinströmringes 7 in a schematic plan view. The gutter length RL takes in this case along the circumference of the intake opening 3, so that a helical arrangement of the guide grooves 6 is formed.

The FIG. 15 shows an arrangement of a drum rotor 8 and a Gebläseeinströmring 7, which is made for example of a one-piece body 12.

Existing suction devices with drummers 8 can easily be retrofitted with a blower inlet ring 7 or attachment component 10 designed according to the invention, i. It is possible without a high technical and financial effort to improve the suction power. It is understood that the invention is not limited to drum rotor 8, but any can be provided to the Gebläseeinströmring 7 subsequent fan units.

The invention has been described above by means of exemplary embodiments. It is understood that numerous changes and modifications are possible, without thereby departing from the invention underlying the idea of the invention.

LIST OF REFERENCE NUMBERS

1

Discharge device or extractor device

1'

suction

2

casing

3

suction

4

filter means

5

exhaust duct

6

guide troughs

6a

outer guide channels

6b

inner guide channels

6 ', 6 "

The End

6 " '

duct channel

7

Gebläseeinströmring

8th

drum runners

9

Arrangers

10

essay component

10.1

annular support plate

10.2

Through opening

11

cover

11.1, 11.2

sections

a

Inflow

AS

intake flow

BS

blast flow

RS

gutter flow

RB

Channel width

RT

channel depth

RQ

Channel cross-section

RL

drain length

VA

vertical axis

Claims (13)

Suction device, in particular extractor device, comprising a housing (2) with at least one suction opening (3) and a suction device accommodated in the housing (2) for generating a suction flow (AS) and with means for influencing the flow direction of the suction flow (AS),
characterized,
in that the means for influencing the flow direction of the intake flow (AS) are formed by a multiplicity of guide grooves (6) extending at least in sections along the outer surface sections (2a) of the housing (2) following the intake opening (3) in the direction of the intake opening (3) extend. Suction device according to claim 1, characterized in that in each case one guide channel (6) has at least two opposite open ends (6 ', 6 ") and a channel channel (6"') connecting them, wherein at least one end (6 ') of a guide channel (6) opens into the suction opening (3). Suction device according to Claim 1 or 2, characterized in that the guide grooves (6) are formed by the surface sections (2a) of the housing (2) adjoining or surrounding the suction opening (3), preferably through into the surface sections (2a ) of the housing recesses or recesses or a corresponding deformation of the outer wall of the housing (2). Suction device according to one of claims 1 to 3, characterized in that the suction opening (3) is formed by a slot-like or planar opening in the housing (2). Suction device according to one of claims 4, characterized in that the flat suction opening (2) has a square, rectangular, polygonal, circular, kidney-shaped, cardioid-shaped, elliptical, has superellipsenförmigen, superformula-shaped or spiralarmförmigen cross-section. Suction device according to one of claims 1 to 5, characterized in that the suction device (2) comprises means for generating a blast flow (BS) and supplying the blast flow (BS) via the guide grooves (6) to the suction port (3). Suction device according to one of claims 1 to 6, characterized in that the guide grooves (6) have a part-circular, angular, round, V-shaped, inclined or T-shaped channel cross-section. Suction device according to one of claims 1 to 7, characterized in that the guide grooves (6) have a groove width (RB) and a gutter depth (RT), wherein the gutter depth (RT) is greater than the groove width (RB). Suction device according to claim 8, characterized in that the surface of the channel cross-section (RQ) of the guide grooves (6) increases in the direction of the suction opening (3). Suction device according to one of claims 1 to 9, characterized in that the guide grooves (6) on a curved surface portions (2a) of the housing (2) are arranged or formed by this. Suction device according to one of claims 1 to 10, characterized in that the guide grooves (6) by means of two adjacent guide blades (9) are formed. Suction device according to one of claims 1 to 11, characterized in that the guide grooves (6) are designed as open guide grooves or at least partially closed guide grooves. Blower inlet ring for use in a suction device (1) according to any one of the preceding claims, characterized in that the Blower inlet (7) has a plurality of guide grooves (6) extending in the direction of the suction opening (3) on the ring surface.

Images