EP0381192A1 - Ventilation device for roofs - Google Patents

Abstract

A ventilation device for roofs is described, which possesses a plurality of individual ducts (4) in the form of elongated holes and lying in a row, in front of which ducts are arranged flaps (16) which are preferably pivotably mounted and which can pivot, when subjected to an incident flow from outside, into a position which changes the free flow cross-section. <IMAGE>

Description

The invention relates to a device for rear ventilation of roofs, or a ridge or ridge vent cap for a roof ventilation system with a plurality of air passage openings distributed over the cap surface.

Inadequate roof ventilation can lead to considerable damage to the roof structure over time. These undesirable effects are counteracted by means of so-called fan caps, which are arranged in the ridge or ridge area.

The object of the present invention is to design devices of the type specified in such a way that largely independent of the respective inflow direction and in particular also with a low inflow, a very pronounced vacuum formation is achieved and thus a particularly effective roof ventilation is achieved.

Furthermore, this device should be suitable for a particularly economical production and, above all, be easily adaptable to different dimensions, while at the same time the desired vacuum formation is always guaranteed and thus there is no dependence of the vacuum formation on different ridge tiles.

This object is achieved according to the invention essentially in that the air passage openings consist of chimney-like elongated holes arranged in the central region of the cap and running parallel to the longitudinal direction of the cap and aligned with one another in the longitudinal direction.

A particularly advantageous embodiment of the invention is characterized in that at least some of the air passage openings are preceded by a pivotally mounted flap which can be pivoted when the flow flows from the outside into a position which changes the free flow cross section for the incoming air.

Due to this design, flow and pressure conditions always arise with inflows from the most varied directions, which particularly effectively promote the desired air circulation from the inside to the outside.

The flaps are pivoted when the air flows in, this constant pivoting also ensuring mobility in the long term. The flaps can preferably be reset by their own weight.

The flaps can be pivoted about horizontal axes or about vertical axes. In the case of a pivotable mounting about vertical axes, for example vertical axes, several, preferably two partial flaps can also be provided for each air passage opening.

According to an expedient embodiment variant, it is provided that the free air flow cross-section resulting between the cap outer surface and the ridge tiles overlapping it is reduced by the flaps pivoted in the direction of their end position.

The flaps upstream of the air passage openings are preferably immediately adjacent to the air passage openings.

It is advantageous to use transverse to the outer surface of the cap, in particular to support the ridge tile Provide webs and to arrange the air passage openings and the associated flaps between two such webs. The webs running in the transverse direction promote the lifting of the flaps and always ensure clear flow guidance.

The ridge or ridge fan cap is advantageously of central symmetry, at least when viewed in the longitudinal direction. If the cap flows from one side, the flaps on this side are raised, while the flaps on the other, opposite, outflow side remain in their starting position.

Further advantageous embodiment variants of the invention are specified in the subclaims.

The invention is illustrated below with reference to the drawing using preferred exemplary embodiments, wherein particularly advantageous features of a generally valid type are also explained.

• Fig. 1 eine schematische Querschnittsdarstellung einer Lüfterkappe nach der Erfindung, und
• Fig. 2 eine Draufsicht auf eine Lüfterkappe von der in Fig. 1 gezeigten Querschnittsform und
• Fig. 3 eine perspektivische Teilbereichsansicht einer weiteren Ausführungsform der Erfin­dung.

The drawing shows:

• Fig. 1 is a schematic cross-sectional view of a fan cap according to the invention, and
• Fig. 2 is a plan view of a fan cap of the cross-sectional shape shown in Fig. 1 and
• 3 shows a perspective partial area view of a further embodiment of the invention.

1 shows a fan cap with a fastening area 1, a middle area 2 and an edge area 3, the individual areas merging into one another via kinks. By separating this cap centrally, cap halves are created which can be used in the same way as the overall cap.

The fastening area 1 is provided on the edge with a gradation 13, for example, about 1 mm, the width of which is selected so that the non-stepped middle area is about 30 mm and the entire middle area is about 50 mm, so that adapted supports for different beam widths arise. However, these dimensions are only examples.

The central region 2 of the fan cap, which is made of plastic material, is particularly important for the desired cap suction function, and this suction function is achieved in a surprisingly effective manner by elongated hole openings 4 which are designed like chimneys and are in the form of an elongated row of holes with a small mutual distance between them Extend cap length.

The mouth plane 5 of these elongated hole openings 4 runs essentially parallel to the plane of the central region 2, and the longitudinal walls 7, 8 of the individual elongated hole 4 have different inclinations with respect to the plane of the central region 2 in such a way that a predefinable flow in the direction of the inside-out flow Cross section reduction sets.

The longitudinal wall 7 of the channel-like slot opening 4 located on the outer edge is more inclined than the opposite wall 8.

The outer edge region 3 can be free of support bumps, but can also be provided with support bumps 10 which are formed from the material of the edge region by appropriate deformation. These support bumps 10 can have different heights depending on the respective application, but it is preferably sufficient to provide two support bumps, for example support bumps with a first height of 6 mm or support bumps with a second height of 12 mm.

These support humps 10 preferably have a more inclined wall on the inflow side than on the side facing the central region 2, where the support hump boundary wall can run perpendicular to the plane of the edge region 3.

The outer edge of the edge region 2 is preferably angled at an obtuse angle, so that an edge strip 12, for example approximately 3 mm wide, is formed. In the illustrated embodiment, a spoiler strip 11 is provided in the region of the transition between this edge strip 12 and the edge region 3, which extends over the length of the fan cap. The height of this spoiler strip 11 is less than the height of the chimney walls 7, 8 of the elongated holes 4 and is preferably about 3 mm. With regard to the plane of the edge area 3, this spoiler strip 11 is expediently inward by approximately 15 °, i.e. inclined towards the slot openings 4.

The fastening region 1 and the central region 2 together form an angle of approximately 150 °, and the edge region expediently forms an angle of approximately 45 ° with a horizontal line.

It is essential for the invention that the elongated hole openings 4 always refer to the different ridge tiles used in practice at the same outer point lie and thus the desired and required vacuum is guaranteed for each type of ridge tile.

This is achieved in that the width dimension V of the central region 2 is changed in accordance with the respective requirements, but the distance K between the outer edge of the cap and the elongated hole openings 4 is always kept constant. For example, the dimension V can be 40/50/60/70 mm, but the dimension K remains unchanged.

The top view according to FIG. 2 shows the arrangement of the elongated hole openings 4 which run along a longitudinal line and which can be provided in the region of their center with a connecting or stiffening web 14 which is located in the region of the mouth plane of these chimney-like openings.

The support bumps 10, if present, are each located in the area between two successive slot openings 4 and in the central area of the respective slot opening.

The fastening area 1 is provided with a plurality of openings 15 which are at the same mutual distance. The stepped area 13 has the function of a water barrier.

The effective elongated hole width is preferably 12 mm and the elongated hole length is 125 mm, the arrangement being such that there is a fan cross-sectional area of 105 cm 2 on one side of the cap, this dimensioning yielding particularly good values, even when there is a pronounced acute-angle flow the slot openings are made in practice.

The mutual spacing of the elongated hole openings 4 which follow one another in a line is expediently approximately 15 mm, while at the end regions of the respective cap an open region of slightly more than 30 mm, which can be used for overlapping, is provided.

Fig. 3 shows a portion of a ridge or ridge fan cap of a roof ventilation system, which comprises ridge tiles that cross the cap.

The ridge or ridge fan cap is of central symmetry when viewed in the longitudinal direction and comprises, on each half of the cap, areas 26, 28 which merge into one another via a kink in which the elements relevant for achieving the desired roof ventilation are arranged. The area 28 extends outwards in the vicinity of the roof covering. A common central area 30, which in turn merges into area 26 via kinks, is used for fastening purposes.

The ridge or burr fan cap shown is a one-piece cap. Basically, however, multi-part caps, in particular cap halves, are also conceivable.

In the area 26 (only one shown) of the ridge or ridge fan cap, a series of air passage openings 4 are provided, which are designed as elongated holes and are arranged one behind the other in the longitudinal direction of the cap. For the sake of simplicity, only two such air passage openings 4 are shown in the figure. However, each ridge or ridge fan cap comprises a plurality of such openings on each side. In principle, several rows of openings lying one above the other can also be provided.

Each air passage opening 4 is pivotally mounted Flap 16 upstream. When there is an inflow from the outside, these flaps 16 can be pivoted into a position that changes the free flow cross section for the inflowing air. In this case, the free air flow cross section which results between the outer cap surface and the ridge tiles (not shown) which overlap it is preferably reduced by the flaps 16 pivoted in the direction of their end position (their starting position is shown).

The flaps 16 are each pivotally mounted about a horizontal axis 18. The pivot axes are adjacent to the air passage openings 4, which are designed as elongated holes and extend in the longitudinal direction of the cap. Furthermore, the flaps 16 are aligned parallel to the elongated air passage openings 4.

Transverse webs 20 are provided on the outer surface of the cap. These webs 20 extend approximately from the upper middle region 30 to approximately the lower edge of the respective region 28.

The air passage openings 4 and the associated flaps 16 are each arranged between two such webs 20. The webs 20 are preferably also designed to support the ridge tiles (not shown).

In the exemplary embodiment shown, the air passage openings 4 have a chimney-like shape. The walls 24 delimiting the chimney-like air passage openings 4 have a lower height than the associated flaps 16.

On the outer cap surface projections 22 are provided to limit the pivoting movement of the flaps 16. The flaps 16 are somewhat longer than those designed as elongated holes Air passage openings 4. The projections 22 are each arranged on the two sides of the air passage openings.

The height of the projections 22 corresponds at least substantially to the height of the flaps 16, but is less than the height of the webs 20, which preferably support the ridge tiles.

The pivot axes 18 of the flaps 16 directly adjacent to the air passage openings 4 are mounted in the webs 20. For this purpose, 20 recesses are provided in the webs, the cross section of which is substantially larger than that of the relevant pivot axis 18.

In the exemplary embodiment shown, the height of the flaps 16 corresponds at least essentially to the width of the air passage openings 4 measured in the transverse flap direction.

The flaps 16 are shown in their starting position in the figure. In this starting position, the flaps 16 are still a slight distance from the outer surface of the cap in order to form a gap, so that the air flow can act on the flaps from below and lift them up.

Because of the central symmetrical design seen in the longitudinal direction, the flaps 16 are accordingly raised on the wind inflow side, while they remain in their starting position on the wind downstream side. The flaps 16 are reset by their own weight. In principle, however, it is also conceivable to ensure the necessary resetting by means of spring elements or the like.

While in the present exemplary embodiment a separate flap 16 is assigned to each air passage opening 4 is, in principle, also conceivable to assign a common flap to several air passage openings.

The pivot axes 18 are expediently made of plastic. The cap itself can also be made of plastic.

Claims (16)

1. Device for rear ventilation of roofs with ventilation elements arranged in the ridge or ridge area in the form of fan caps with a fastening area, a central area having air passage openings and an adjoining edge area,
characterized by
that the air passage openings consist of chimney-like elongated hole openings (4) arranged in the central region (2) and running parallel to the longitudinal direction of the cap, which are aligned with one another in the longitudinal direction, the mouth planes (5) of the elongated hole openings (4) preferably running at least substantially parallel to the central region plane. 2. Device according to claim 1,
characterized by
that in each central region (2) there is a continuous row of chimney-like elongated openings (4) lying in a line, the mutual spacing of which is substantially equal to or slightly larger than the elongated width, and that the elongated length is in particular approximately ten times greater than the elongated width . 3. Device according to claim 1 or 2,
characterized by
that the longitudinal walls (7, 8) of the chimney-like elongated hole openings (4) have different inclinations with respect to the central region plane, leading to a chimney narrowing in the flow direction, the longitudinal wall (7) of the chimney-like elongated hole openings (4), which is located on the outer edge, preferably being more towards the fastening region (with respect to the central region plane) 1) is inclined towards the slot wall (8) located on the side of the fastening area (1). 4. Device according to one of the preceding claims,
characterized by
that the chimney height is slightly smaller or substantially equal to the slot width. 5. Device according to one of the preceding claims,
characterized by
that the central region (2) forms an obtuse angle with the outer region (3) and the distance between the series of Elongated holes (4) from the kink (9) formed are the same regardless of the respective cap width measured between the outer edge and the fastening area and the distance between the elongated holes (4) with respect to the outer edge of the cap is constant, in particular regardless of the respective width of the central region (2). 6. Device according to one of the preceding claims,
characterized by
that in the edge region (3) formed by protrusion bumps (10) are arranged in relation to the elongated hole openings (4) provided in the central region (2) in each case in the region between two successive elongated hole openings (4) and in the region of the center of an elongated hole opening (4). 7. Device according to one of the preceding claims,
characterized by
that a spoiler strip (11) extending over the length of the cap is provided on the outer edge of the cap and the outer edge region (3) preferably has an angled edge strip (12). 8. The device according to one or more of the preceding claims,
characterized by
that at least part of the air passage openings (4) is preceded by a pivotally mounted flap (16) which can be pivoted in the event of an inflow from the outside into a position which changes the free flow cross section for the incoming air and can be reset in particular by its own weight. 9. Device according to one of the preceding claims,
characterized by
that the flaps (16) are each pivotably mounted about a horizontal axis (18) and aligned parallel to the elongated air passage openings (12). 10. Device according to one of the preceding claims,
characterized by
that transverse webs (20) are provided on the outer surface of the cap, in particular to support the ridge tiles, and that the air passage openings (12) and the associated flaps (16) are arranged between two such webs. 11. The device according to claim 10,
characterized by
that the chimney-like air passage openings (12) bounding walls (24) have a lower height than the associated flaps (16). 12. Device according to one of the preceding claims,
characterized by
that projections (22) for limiting the pivoting movements of the flaps (16) are preferably arranged on the two outer sides of the air passage openings (12) on the cap outer surface and
that the height of the projections (22) corresponds at least substantially to the height of the flaps (16). 13. Device according to one of the preceding claims,
characterized by
that the free flow cross section resulting between the cap outer surface and the ridge tiles overlapping it is reduced by the flaps (16) pivoted into their end position. 14. Device according to one of the preceding claims,
characterized by
that the pivot axes (18) assigned to the flaps (16) are preferably mounted in recesses in the webs (20), the cross-section of which is substantially larger than that of the pivot axes. 15. Device according to one of the preceding claims,
characterized by
that the height of the flaps (16) corresponds at least substantially to the width of the air passage openings (12) measured in the transverse direction of the cap. 16. Device according to one of the preceding claims,
characterized by
that the flaps (16) which assume their starting position are at a distance from the outer surface of the cap to form an intermediate space.

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