EP0802378B1 - Venting device - Google Patents

Abstract

The venting attachment (E) comprises an upwardly oriented riser pipe (7) whose upper mouth end (8) under interposition covers a skirt of a hood (9). The skirt is developed concentric to the mouth end's arranged air line-ring (L), where the ring split (10) is separated between a mouth end's edge (12) and the hood's lower edge (13). There are two connected pipe sections (a,b) through a truncated cone jacket area from which one pipe section (b), in overlap to the mouth end, projects below via the hood's lower edge. The inner diameter (d) of the cross-section's smaller truncated cone jacket section's set pipe section (a) may be larger than the outer diameter (d') of the riser-pipe's mouth end.

Description

The invention relates to a ventilation attachment, especially at the top end of roof penetration pipes, with an upward rising pipe, the upper end of the mouth with the interposition of a Apron from a hood with peripherally curved downward Hood ring wall section overlaid which apron as an air guide ring arranged concentrically to the end of the mouth is designed, the annular gap between the edge of the mouth and hood lower edge in a first annular gap mouth and divides another annular gap mouth, further two pipe parts connected by a truncated cone surface has, of which on the larger cross-sectional frustum section attached pipe part in overlap at the end of the mouth down over the hood edge protrudes.

A venting attachment of this kind is provided by the GB-A 1 204 571 known. The one there in the annular gap between Muzzle end edge and hood lower edge inserted, flow dividing air guide ring is related to its cross-sectionally larger pipe part significantly in the direction the roof skin extended. The overlap to the one there The riser pipe corresponds approximately to 7 times that Height of the end of the mouth measured width. The results in a longer dwell time of the flow with the Consequence of increased condensation. Furthermore the edge of the hood is aligned with the pipe section mentioned. There the one lying between the connected pipe parts Truncated cone surface, realized as rotationally symmetrical arched shoulder, clearly below the bonnet rim driving rain can fall under itself relatively flat hood.

Then there is a vent attachment through the DE-OS 21 28 035 known. 2 and 3 a pipe section in a collar-like sheet falling off to the outside about. A distance also extends over this apron arranged all around. Again with vertical A hood extends over this distance. This one, from Non-round roof skin, practically designed like a pagoda roof Breather attachment is essentially under rain Aspects.

The object of the invention is a generic Venting attachment in a technically simple way Way in terms of ventilation performance and rain entry security to optimize.

This task is solved by the in the claims specified invention.

As a result of such a design, it is a highly effective venting attachment with surprisingly homogeneous flow behavior achieved. The vent attachment can be used for the strand ventilation can be used as well mobile spaces. It is rainproof, low resistance and condensation free. The solution is simple and expedient. In detail, the procedure is such that the Width measured in a plane of the edge of the mouth of the shortened annular gap mouth roughly the size of the Overlap corresponds to that of the peripheral step higher, other annular gap mouth also one has radial width corresponding to the overlap, the hood ring wall portion outwardly one further lateral overhang forms. The concentric Assignment of the air guide ring to the end of the mouth brings a directional independence from that Ventilation attachment rinsing / crossing air flow. Along with the essentially practical S-shaped Cross section of the air guide ring become detachments the flow paths and vortex formation are significantly reduced. Remaining separation effects, which pressure loss and a not inconsiderable reduction in throughput bring with them, do not fall Weight.

In an advantageous further development suggested that the inside diameter of the smaller in cross section Applying the truncated cone section Pipe part is larger than the outer diameter of the Riser mouth end. This leads to a reduction in Flow velocities within the fan and thus to a pressure recovery that is favorable in terms of flow technology. Furthermore, the invention proposes that the pipe parts have a funnel-shaped wall profile have an extension to the respective free pipe part end there. That brings with respect to the hood-side tube part one cross-sectional expansion and the other, after a slight enlargement at the bottom of the pipe section of the annular gap mouth. There is also an advantageous one Feature of the invention in that the annular gap is such is formed that the lower edge of the hood essentially lies on the level of the edge of the mouth. In another After all, flow optimization is still cheap, that the hood the top of the pipe part there arched overlapping and in a slightly flared Hood ring wall section merges. Between the Hood ceiling and the peripheral hood ring wall section there is a larger angle circumferentially symmetrically than 90 °. It is also proposed that the center of the arch at the level of the central area of the truncated cone and approximately aligned above the End of the mouth lies. That yields equivalent Flow conditions on the outside of the ring gap dividing air guide ring. There is also a advantageous feature of the invention in that the Lower edge of the hood is corrugated. This leads in the circumferential direction to spaced shields, each drawn lower, just formed by the wave crests. That increases on the one hand the protection against rain entry and leaves in Area of the higher parts, the wave valleys so, airflow bays. It is an advantage that the lower edge of the air guide ring is also corrugated, so that comparable conditions also arise there. Moreover The invention proposes that both the Underside of hood and underside of air guide ring corrugated run in such a way that both wave crests and wave troughs each lie in a common radial plane. It is favorable if the common radial plane passes through Locking means is defined. This is achieved with simple Averaged by clipping between the hood and Air guide ring by means of it down from the ceiling outgoing finger. They can also be used as Radial webs act. The clipping not only brings a simple, superfluous traditional fastener Allocation of the hood, but allows anytime later retrofitting of the ventilation attachment. Concrete the clipping is achieved in that the Fingers with a snap-on mouth and on hers Attack ends are forked, using their forks take the pipe part like a rider between them. Such an attack end unites via the snap mouth the function of the support and that of Bondage. The hood is simply plugged in assigned. Afterwards she is stuck. The air flow can stick to the very small fingers divide. It is also proposed that the Each snap-in finger prongs turn to Form the free end of the insertion opening. Through this measure, a self-centering, the plug-in can be felt practically Effect. It is also an advantage that the insertion opening in a Z-shaped course in one to to the root of the fork tines, as Flat part of the designed finger continues. That yields high resilience, respectively restoring effect and at the same time great stability because of the avoidance direction lies in the plane of the flat parts. To avoid a Notch effect is the base of the space rounded convex. The finger contour is then continued so that the top of the horizontal Z-web is supported on the upper edge of the pipe part, the lower edge of the Z-bar runs out into a clamping surface, which is adapted to one sloping counter surface of the truncated cone surface of the air guide ring. The due to a corresponding Prestress to be achieved from the restoring force The clamping action of the clamping surface has a practical effect a permanent readjustment, but in any case a bracing the hood at the top of the Pipe part. In this context it is also favorable that the level of the fingers transverse to the lateral surface of the air guide ring. A solution from even more independent Meaning then is that the finger connecting together with an air guide ring and riser pipe Radial web that defines the radial plane Form stop position. In this way it becomes an already necessary / existing one Element used. It is further education then favorable that the stop position a locking groove is upstream. The hood with the fingers is aligned so that the fingers against the same angle distributed radial webs. It takes time only the one in the pipe extension direction Plug-in assignment engaging in the locking groove. A alternative solution is achieved through a common Radial plane defining rotation between a deliberately negotiable locking lug of the air guide ring and a radial web connecting this to the riser pipe. This leads to a double lock or cross lock, first oriented axially, then in the direction of rotation going. The inner forks function consistently of the snap-in finger as a rotary finger. This is given a particularly stable use training through a T-shaped cross section of the rotary index finger. Finally, it is fluidically advantageous that the hood has a slightly arched ceiling.

Fig. 1

mehr übersichtsmäßig den erfindungsgemäß ausgebildeten Entlüftungsaufsatz an einem Dachentlüfter, und zwar in Seitenansicht,

Fig. 2

den Entlüftungsaufsatz mit Steigrohr im Vertikalschnitt, in bevorzugter Ausgestaltung,

Fig. 3

den Entlüftungsaufsatz mit Steigrohr im Vertikalschnitt gemäß Fig. 2, jedoch in bezüglich Haube und Luftleitring abgewandelter Ausbildung,

Fig. 4

die Unteransicht hierzu,

Fig. 5

einen Vertikalschnitt durch die Haube, eine Wellung des Haubenunterrandes sowie Finger als Rastmittel verdeutlichend,

Fig. 6

die Unteransicht hierzu,

Fig. 7

die Rastverbindung zwischen Haube und Luftleitring in Vergrößerung,

Fig. 8

den Schnitt gemäß Linie VIII-VIII in Fig. 7,

Fig. 9

das entsprechende Rastmittel in abgewandelter Ausgestaltung, ebenfalls vergrößert,

Fig. 10

den Schnitt gemäß Linie X-X in Fig. 9,

Fig. 11

eine der Fig. 9 entsprechende Darstellung eines weiter abgewandelten Fingers und

Fig. 12

den Schnitt gemäß Linie XII-XII in Fig. 11.

The subject matter of the invention is explained in more detail below on the basis of an illustrative embodiment. It shows

Fig. 1

more clearly the ventilation attachment designed according to the invention on a roof vent, in a side view,

Fig. 2

the ventilation attachment with riser pipe in vertical section, in a preferred embodiment,

Fig. 3

2, but in a design modified with respect to the hood and air guide ring,

Fig. 4

the bottom view of this,

Fig. 5

a vertical section through the hood, showing a corrugation of the lower edge of the hood and fingers as locking means,

Fig. 6

the bottom view of this,

Fig. 7

the locking connection between hood and air guide ring in enlargement,

Fig. 8

the section along line VIII-VIII in Fig. 7,

Fig. 9

the corresponding locking means in a modified configuration, also enlarged,

Fig. 10

the section along line XX in Fig. 9,

Fig. 11

9 shows a representation of a further modified finger and

Fig. 12

the section along line XII-XII in Fig. 11th

The vent attachment E according to the invention is a Roof ventilators assigned to realized roof duct D. Part of this is a vertically alignable Roof penetration pipe 1. That stands over a so-called Flex hose 2, for example, with the not shown Canal strand of a building in connection.

The roof duct D is on a covering plate 3 realized. This forms a bulging towards the top of the roof Cathedral 4 from. The one in the direction of inclination Roof 4 has a circular arch-shaped arch is covered by a cap 5. It is based on 4 led off.

The cap 5 sits in an upward direction Neck 6 continued. On the continuation is a vertical subsequent riser pipe 7 connected, which in the vent attachment E mentioned above expires.

The said curvature is at the top of the dome 4 centered on a radius point P. The latter lies First parallel, not far from the lower edge the roofing sheet 3. Shapes in this area the dome 4 does not have one on both sides of the tube passage Storage bag shown in more detail. In the storage pockets a suitable hinge pin intervenes. The is also in paired assignment on section of the roof penetration pipe on the roof chamber side 1. The latter can be brought about by one vertical alignment of the roof duct 1 um the radius point P relative to the roof covering plate 3 tilt adjustment. Further details are given from EP-OS 0 276 389. The upper mouth end 8 of the riser 7 is from overlay a hood 9. The latter is circular Floor plan on. Regarding the riser pipe 7 is also a circular cross section.

The roof of the mouth end 8 through the hood 9 is such that an annular gap 10 between the two parts remains. It has the same cross-section everywhere and is there the ventilation flow to the outside air rising in 1 from.

In the annular gap 10 is a rotationally symmetrical, d. H. annular apron inserted. It partially sticks out in the interior of the hood 9 and ends with a clear Distance to the inside of a slightly cone-shaped according to FIG. 2, otherwise just designed ceiling 11 of the hood 9. The corresponding cone tip lies in the center Z of the Hood 9. The center Z lies in the longitudinal central axis x-x of the riser pipe 7. However, there is also a slightly curved one Blanket 11 conceivable.

The intermediate apron is as concentric air guide ring L arranged at the mouth end 8, the annular gap 10 between the end edge of the mouth 12 and hood lower edge 13 divides. It is, in cross section seen, essentially S-shaped shape (cf. Fig. 2). 3 has one more bell-shaped cross-section on, but also under Maintaining the S-typical, opposite redirection the free ends.

In the following, the S-shaped cross-sectional shape is to begin with 2 are described in more detail. There the S is composed of two pipe parts a and b. The stand over a truncated cone surface c in connection with each other. It is a one-piece ring body.

The helix angle of the truncated cone surface c closes an angle of approx. 30 ° to a vertical Line, for example the longitudinal central axis x-x.

As can further be seen in FIG. 2, the tube parts a and b not cylindrical, they take you weak funnel-shaped course of the wall. That of the hood 9 facing, ie upper tube part a goes in on the hood side a widening over.

The one pointing in the direction of the roof skin or dome 4 lower pipe part b widens to the end there there. Below is a wall exhibition of approx. 3 ° underlying, while above the funnel-shaped wall course an acute angle of about 6 ° to the longitudinal central axis includes x-x.

As shown in FIG. 2, this leads upwards a clear widening of the upper air ring mouth 14. Below is a slight widening of the one there annular gap mouth 15 near the riser pipe.

The inner diameter d of the smaller in cross section Is the truncated cone section of the tubular part a recognizable larger than the outer diameter d 'of the riser mouth end 8th.

The one with the larger cross-section of the truncated cone attached pipe part b is in the axial or vertical overlap Ü to the mouth 8 of the riser 7. Said pipe part b also goes down towards the cathedral, over the lower edge of the hood 13 addition. The latter jumps towards the end of the mouth 8 of the riser pipe by the amount of overlap Ü back.

As can be seen from the drawing, the annular gap 10 designed so that the hood lower edge 13 essentially on the plane y-y of the mouth end edge 12 lies. The plane y-y is horizontal, that is perpendicular to the longitudinal central axis x-x of the ventilation attachment E. In this way lies a practically tiered outside start of the annular gap 10 in front. The in the Plane y-y measured radial width of the curved annular gap mouth 15 corresponds approximately to the degree of overlap Ü. The peripherally higher, others Annular gap mouth 15 'also has a radial width according to the overlap Ü.

Another design feature of the cross-sectional geometry arises with regard to the interior of the annular gap 10, so inside the hood space by there the hood 9 the upper edge 16 of the tubular part there a arched overlap. This largely results swirl-free deflection zone for the ventilation flow. Affected by the corresponding cross curvature, respectively formation of a rotationally symmetrical revolving Bogens 17, is slightly more than the top half the hood 9. The height of the hood corresponds approximately to that half the radius of the hood or the radius of the mouth end 8 of the riser pipe 7 according to FIG. 2.

The edge of the hood 9 is not purely cylindrical, but easily issued, so that the other annular gap mouth 15 'slightly widened. The opening angle is approx. 3 ° to the longitudinal central axis x-x. The hood ring wall section exhibited bears the reference symbol 18th

The arc 17 runs along a circular arc line. The Center 19 of the arc 17 or its radius lies on the horizontal plane z-z of the central region of the truncated cone surface c of the air guide ring L and also aligned above the end of the mouth 12. The relevant Escape line is a vertical one.

The flow-separating air guide ring L leaves between the said mouth end edge 12 and the smaller cross-section Truncated cone section of the upper tube part a a flow connection gap 20 of about double the height of the pipe part a to the central ventilation flow in the riser 7.

Which is in the funnel-shaped expansion, respectively cross-sectional larger zone of the upper tube part a resulting Flow is overflowing the top 16 gently into the periphery through the arch 17 of the hood 9 limited and inside by the outside of the Truncated cone surface c limited, slightly larger than the entrances and exits of this annular chamber 21 then passed to the cap sweeping and underpowered electricity to be delivered cheaply.

The newly developed venting attachment E was created the basis of various fluidic criteria, supported by appropriate flow tests. This resulted in those from the illustrated and described Drawing emerging geometries. Especially the fact that the smallest cross section of the Air guide ring L is larger than that of the upper pipe end, leads to a clear favor of the current within the vent attachment E and thus too a fluid pressure favorable recovery. A rotationally symmetrical structure ensures one same effect regardless of direction. The ceiling area the hood 9 avoids condensation.

The air guide ring L can with respect to Pipe part a, the pipe part b and the truncated cone surface c have softer curvature transitions, as already indicated, in a more bell-shaped cross-sectional shape.

The bracket of the air guide ring L and the hood 9 on Riser pipe 7 happens over narrow, continuously with 25 designated radial webs. There are three for each level Radial webs 25 offset at the same angle are realized.

There is then a thread at the foot of the riser pipe 7 26, which with the matching mating thread of the nozzle 6 interacts. An inside or outside Wall overhang 27 ensures a waterproof, stop-limited Connection to the subsequent element the roof duct D.

3 to 12 are further education below Details of the vent attachment E described explained. The reference numbers are where to understand required, applied analogously, partly without text Repetitions. The pipe parts a, b are no longer funneled in opposite directions, but rather cylindrical, at least that Outsides.

A modification of the hood 9 is that its Cover 11 runs slightly arched. The bulge is in terms of area to the cross-sectional area of the riser pipe 7 limited to then continuously in the Transverse curvature, formed by the rotationally symmetrical encircling arc 17. The center Z is here the Zenith of the spherically vaulted ceiling 11. Here, how shown, a injection point. The camber elevation corresponds approximately to that through the blunt cone 2 cant achieved compared to the ceiling side Approach of the arch 17. The ceiling vault lies in both cases still in the drag area of the flow. The wall thickness of the hood 9 is essentially consistently the same.

Next modification: the lower hood edge 13 is corrugated. It is an even curl, forming eight wave crests with troughs in between. It is a concave and convex uniform Curl. The troughs of the lower edge of the hood 13 lie clearly below the plane y-y of the mouth edge 12 of the riser pipe 7 (see FIG. 3). The wave crests exceed this level by a significant amount, so that evenly distributed in the circumferential direction, there are vertically aligned shields. The in-between troughs leave current bays.

The same structure is also with regard to one Bottom edge 28 of the guide ring L realized. The lower Pipe part b of the same is here also in gap-forming vertical overlap Ü to said plane y-y of Muzzle edge 12, being over the registered overlap Ü, the tops of the wave valleys, Wave crests like shields as an extension downwards extend.

Hood 9 and air guide ring L, both in turn rotationally symmetrical are assigned to each other so that the crests and valleys of the hood 9 in one common radial plane lie to the wave crests and Wave valleys of the air guide ring L. The corrugations are equal in character and orientation.

The common radial plane is defined by locking means, and simply by oriented clipping between hood 9 and air guide ring L by means of the inside of the ceiling 11 of the hood 9 directed downwards outgoing finger F. There are three such an evenly distributed finger F im Free-standing hood space molded onto the ceiling 11. You meet the function of the support and that of the bondage the hood 9.

The finger contribution of the bondage is that at their free end with one down and outwardly open snap jaw S equipped fingers F are bifurcated at the end of their attack there (cf. e.g. B. Fig. 9). The partially split fingers F sit on the upper edge 16 of the tubular part a, wherein she with her fork tines 29, 30 the upper edge 16 record practically like a rider between them. The the Forks 29, 30 shape-defining on the inside Slot is designated 31 in its entirety. He opens downwards and, according to FIG. 7, also sideways aligned.

At the lower end of the slot 31 are the fork tines 29, 30 of the snap-finger F designed so that you Snap mouth S one for free, d. H. lower, sideways insertion opening widening towards the end 32 forms (see FIG. 9). You can use this achieve a welcome centering, even if it is missing Line of sight. Accordingly, a correct one occurs Feel or insert the pipe part a in the Slot 31 or latching overflow of the fork tines.

As can be seen from the drawings, the slot 31 is stepped. That means he changes his vertically Direction by jumping, so that the slot 31, starting from its insertion opening 32, by Z-shaped Course, that is, forming a crossing, into one to to the root 33 of the fork tines 29, 30 sufficient space 34 continues. The one falling on the free space 34 vertical length of the slot 31 is almost as large as the vertical to the insertion opening 32 Length of the slot 31. "Vertical" refers to the drawn illustration. If the Venting attachment E can of course also mean this "perpendicular to the inclination plane" of a roofing slab.

The bottom of the free space 34 is rounded convex, this to rule out a notch effect. The curve bears reference number 35.

The transverse to the vertical portions of the slot 31 lying Z-web 36 forms the actual support restraining element des Schnappmaules S. The structure is there continue so that the upper edge 36 'of the substantially horizontally extending Z-web 36 on the him facing end edge, ie upper edge 16 of the tubular part a, supports, whereas the lower edge 36 '' of the Z-leg runs out into a clamping surface 37. The latter extends obliquely, at an angle, which is that of the truncated cone surface c of the air guide ring L essentially corresponds. The rake face 37 thus acts with an inclined, together with 38 designated counter surface. The real one Interlocking occurs over a horizontal shoulder 16 'as a counter-catch for that from the free end of the fork tine 29 formed locking head 39.

The locking flank of the locking head 39 is the lower one Edge 36 '' of the Z-web 36.

The clamping surface 37 is fixed, i. H. if necessary with a certain preload on the counter surface 38.

The corresponding one, from the opening-side end of the riser pipe 7 opposite fork tines 29 realized clamping surface 37 practices on the intermediate air guide ring L a self-adjusting clamp stop. He is but can be overcome by willpower, so that the hood 9 is reversibly assignable.

The horizontal locking shoulder 16 'results from injection molding advantageous by the slope of the truncated cone surface c not pointed out there; it is already emerging practically through the core division of the injection mold there, d. H. due to the release, and with enough Jump.

As can be seen from the relevant figures, the fork tines 29, apart from its slightly thicker locking head 39, such a slim or narrow shaft that he is resilient. The other fork tine 30 is against it significantly wider. The evasive Suspension lies in the radial direction of extension the finger F designed as flat parts

The locking head 39 of the fork tine 29 tapers slightly towards the free end to cross in a funnel-shaped insertion opening 32 determining To pass over the oblique flank. The other, the funnel-shaped The flank that defines the insertion opening is opposite realized and slightly in the direction of the slot base transferred. This flank extends over that facing away from the locking head 39 Side of the truncated cone surface c of the air guide ring L.

In the variant according to FIG. 7, however, this is not the case the case according to significantly shorter design of the with 30 designated forks.

One or the fingers F can perform an additional function with regard to the alignment of the troughs and Wave crests in a common radial plane. For this, the procedure is such that the finger F is together connecting with an air guide ring L and riser 7 Radial web 25 the stop position defining the radial plane forms by the finger F on such Radialsteg 25 is leaning to the side, which position in Is matched accordingly with regard to the corrugation. This position can be held frictionally, for example become.

On the other hand, it is envisaged that this lean-on stop position secure by a locking groove 40. Educated this locking groove 40 is one of the thickness of the finger F corresponding angular zone between a broadside 25 'of the radial web 25 and one spaced apart overlying, overflow latching nose 41 of the air guide ring L. The somewhere in between between the angularly spaced radial webs 25 on the shoulder 16 ' plug-in hood 9 is easy according to the embodiment twisted clockwise, eventually the fork tines 29 with its locking head 39 at an angle rising back 42 of the detent 41 overflows finally, stepping behind their blocking edge 43, in to catch the mentioned locking groove 40. The inner one Forks 29 of snap-action finger F thus function as a locking finger.

Although the restoring force of this rotary index finger by Bending in the plane of greater width can happen the resilience or restoring force increased be by the fork tines 29 a T-shaped cross section receives (see Fig. 12). The two T-legs have an overall width that that of the radial lying T-leg essentially corresponds. The locking groove 40 is matched to these conditions. The one lying in the circumferential direction of the guide ring L. free end of one T-leg kicks against Broadside 25 ', that of the other T-leg against the Barrier edge 43.

The upper tube part a tapers slightly on its Inside (see e.g. Fig. 9) continuously in Towards its upper edge 16.

Claims (23)

1. Venting attachment (E), especially at the upper end of roof duct pipes (1), having an upwardly-oriented riser pipe (7), the upper mouth end (8) of which is covered by a hood (9) with interposition of a skirt, the hood (9) having a peripherally downwardly curved hood annular wall portion (18), the skirt being configured to be concentric with the air guide annulus (L) which is located at the mouth end (8), the annulus (L) dividing the annular gap (10) between mouth end edge (12) and hood lower edge (13) into a first annular gap opening (15) and a second annular gap opening (15'), the skirt further having tubular portions (a, h) connected by a frustoconical sleeve surface (c), the tubular portion (b) of these tubular portions which is attached to the frustoconical sleeve section of greater cross-section projecting downwardly beyond the hood lower edge (13) in overlapping relationship (Ü) with the mouth end (8), characterised in that the width of the skirted annular ring opening (15) measured in a plane (y-y) of the mouth end edge (12) corresponds approximately to the dimension of the overlap (Ü), that the second annular gap opening (15'), which is located at a higher level in a peripherally step-shaped manner, likewise has a radial width corresponding to the overlap (Ü), the hood annular wall portion (18) forming in the outward direction a further extending lateral overhang.
2. Venting attachment according to Claim 1, characterised in that the inner diameter (d) of the tubular portion (a) which is attached to the frustoconical sleeve section of lesser cross-section is greater than the outer diameter (d') of the riser pipe mouth end (8).
3. Venting attachment according to one or more of the preceding claims, characterised in that the tubular portions (a, b) have wall extending in a funnel-shaped manner with widening towards the respective free tubular portion end.
4. Venting attachment according to Claim 1, characterised in that the annular gap (10) is formed in such a way that the hood lower edge (13) is located substantially at the plane (y-y) of the mouth end edge (12).
5. Venting attachment according to one or more of the preceding claims, characterised in that the hood (9) covers the upper edge of the tubular portion (a) in an arched manner and changes into a slightly outwardly-located hood annular wall portion (18).
6. Venting attachment according to Claims 1 and 5, characterised in that the centre (19) of the arch (17) of the curved hood annular wall portion (18) is located at the plane (z-z) of the central region of the frustoconical sleeve (c) and approximately aligned above the mouth end edge (12).
7. Venting attachment according to one or more of the preceding claims, characterised in that the hood lower edge (13) is wavy.
8. Venting attachment according to one or more of the preceding claims, characterised in that the lower edge (28) of the air guide annulus is wavy.
9. Venting attachment according to Claims 7 and 8, characterised in that the both the hood lower edge (13) and also the lower edge (28) of the air guide annulus extend in a wavy manner such that both wave peaks and also wave valleys are each located in a common radial plane.
10. Venting attachment according to Claim 9, characterised in that the common radial plane is defined by stop means.
11. Venting attachment according to Claim 10, characterised by a clipping arrangement between hood (9) and air guide annulus (L) by means of fingers (F) extending from the top (11) of the hood in a downwardly directed manner.
12. Venting attachment according to Claim 11, characterised in that the fingers (F) are equipped with a snap jaw (S) and are forked at their engaging end, the forked prongs (29, 30) of the fingers receiving the tubular portion (a) between them in straddling manner.
13. Venting attachment according to Claim 12, characterised in that the forked prongs (29, 30) of cach snap jaw finger (F) form an insertion opening (32) which widens towards the free end.
14. Venting attachment according to Claim 13, characterised in that the insertion opening (32) continues in a Z-shaped manner into a free space (34) of each finger, which is configured as a flat portion, the free space (34) extending up to the root of the fork prongs (29, 30).
15. Venting attachment according to Claim 14, characterised in that the base of the free space (34) is rounded in a convex manner.
16. Venting attachment according to Claim 14, characterised in that the upper edge (36') of a Z-land (36) extending substantially horizontally is supported on the upper edge (16) of the tubular portion (a), the edge (36") of the Z-land (36) which is by contrast located at a lower level ending in a holding surface (37) which engages against a matching slopingly-oriented counter-surface (38) of the frustoconical sleeve surface (c) of the air guide annulus (L).
17. Venting attachment according to Claim 11, characterised in that the plane of the fingers (F) is oriented transverse to the sleeve surface of the air guide annulus (L).
18. Venting attachment according to Claim 17, characterised in that the finger (F) together with a radial web (25) connecting air guide annulus (L) and riser pipe (7) form the stop position defining the radial plane.
19. Venting attachment according to Claim 19, characterised in that a latching groove extends in front of the stop position.
20. Venting attachment according to Claims 10, 18 and 19, characterised by a rotational latch between a latching nose (41) of the air guide annulus (L), which nose can be overcome by deliberate action, and a radial web (25) connecting the annulus (L) to the riser pipe (7), the rotational latch determining the common radial plane.
21. Venting attachment according to Claim 12, characterised in that the inner fork prong (29) of the snap-jaw finger (F) functions as a rotational latch finger.
22. Venting attachment according to Claim 21, characterised by a T-shaped cross-section of the rotational latch finger.
23. Venting attachment according to Claim 1, characterised in that the hood (9) has a gently curved top (11).

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