DE20303918U1 - Ridge or hip ventilation tile between outward bent edges and water channel side has air deflecting surface terminating flush with upper edge of channel strip of tile and rises steadily from between center region to foot region of tile - Google Patents

Abstract

The deep grooved ridge or hip ventilation tile (1) between its outward bent edges and its water channel side is provided with an air deflecting surface (4) which terminates flush with the upper edge of the channel strip of the tile and rises steadily from between the center region to the foot region of the tile. The aligning upper edges of ribs for the seating of the tiles end clearly below the upper edge of the tile's channel strip. The air-deflecting surface consists of one plane or as part of a gently rising parabola or hyperbola.

Description

Patent Attorney Dipl.-Ing. Lambert Eichelbaum

D-45659 Recklinghausen Krüppeleichen 6

Telephone: (02361) 21091-2 · Fax: (02361) 22949 · Email: pa@eichpatent.de

07.03.2003 fle 2943a/03

Applicant:

Oscar Fleck

Industriestr. 12, D - 45711 Datteln

"Ridge or hip ventilation tiles"

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Description:

The invention relates to a ridge or hip ventilation tile with a ridge-side head edge strip and a channel strip spaced therefrom and a channel arranged between these strips for ventilation and drainage, in which webs for placing the lower edge of a ridge tile are integrally connected to the channel bottom.

A ridge vent tile of this type is known from DE 33 20 850 C2. It is a vent tile with a semi-circular cover rim, from the bottom of which a flat central surface extends to the water rebate side. The channel strip is correctly referred to there as a dam strip because the frontal resistance of this dam strip opposes a considerable flow resistance to an air flow running perpendicular to the ridge, with the result that the air accumulates on this strip. In addition, this leads to turbulence and air separation near the upper edge of this dam strip, which in turn is associated with a reduced suction effect of the Venturi effect. In deeply interlocked tiles, this dam strip has an even more disadvantageous effect because it has an even greater overall height in the deep central section and therefore an even greater flow resistance.

In addition, the head edge is lower than the dam edge, which prevents precipitation in the form of rain,

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Snow and sleet represent an easily overcome obstacle when air currents run parallel to the ridge.

In addition, there are numerous ridge tiles that are adapted to the contour of the ridge using an adapter and therefore an additional part, in order to ensure ventilation on the one hand and to ensure that rainwater does not penetrate on the other. Instead of many, a plain ridge connection ventilation plate according to DE 38 10 206 Al and a ridge plug for a flat tile according to DE 40 11 070 Al are mentioned here as additional parts.

Further additional sealing or ventilation elements are known from GB 2 159 851 A and GB 2 186 606 A. These devices have the disadvantage of an even greater frontal resistance and the further disadvantage of an additional component, in this case an adapter, which must be adapted to both the roof covering panels adjacent to the ridge and the ridge tile sitting on top.

In contrast, the inventor of the subject matter of the non-generic DE 44 27 066 Cl takes a completely different approach to creating a longitudinally and transversely folded roof covering panel for ventilating a roof space below, whereby the ventilation and sealing zone is arranged between the water fold side and the cover rim side of the adjacent tile. For this purpose, this roof covering panel is similar in size and peripheral contour to a conventional roof covering panel without ventilation and is

can be laid either together with other roof covering panels with ventilation or with conventional roof covering panels with the same peripheral contour, so that with the same longitudinal section shape of the roof covering panels, in the roof covering panel with ventilation on its cover fold side, several spaced-apart cams are formed as projections to form the air passage area on its underside at the location of a cover fold rib of a conventional roof covering panel, which rest on a support surface on the water fold side of the adjacent roof covering panel, leaving air passage channels between the longitudinally adjacent roof covering panels.

Based on this closest prior art, the invention is based on the object of creating a ridge or hip ventilation tile of the type mentioned at the beginning, which is characterized by a low frontal resistance, particularly in the case of air flows running perpendicular to the ridge, and thus also by an increased ventilation effect of the interior of the roof even in the case of deeply interlocked tiles, and at the same time reliably prevents the penetration of rainwater.

This object is achieved according to the invention in connection with the generic term mentioned at the outset in that the deeply interlocked ventilation tile is provided between its cover rim and its water rebate side with an air guide surface which ends flush with the upper edge of the channel strip and rises continuously from between the middle area and the foot area of the ventilation tile, and that the upper edges of the webs which are in a flush line end significantly below the upper edge of the channel strip.

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Through the air guide surface from approximately the middle of the tile, an air flow running perpendicular to the longitudinal axis of the ridge is guided without any frontal resistance and therefore at an increased speed to the top of the ridge tile sitting on top, so that it can flow around the ridge tile at the same high speed and reach the opposite side of the roof with little loss.

According to the Bernoulli equation, this leads to an increase in the negative pressure in the channel, resulting in improved roof ventilation. This is also due to the fact that the upper edges of the webs, which are in a straight line, end well below the channel strip. As a result, the ridge tile, which rests with its lower edge on these upper edges of the webs, continuously follows the air guide surface with its outer contour, because its rounded shape means that it does not offer any significant frontal resistance to the incoming air, and the gap between the lower edge of the ridge tile and the channel floor is bridged, resulting in a flow barrier from the surrounding outside air against the precipitation trying to penetrate this gap.

According to an advantageous development of the invention, the air guide surface consists of one plane. This is associated with an accumulation of material in the deeply folded central area, but this also contributes to increased stability.

According to a further advantageous design, the air guide surface is designed as part of a gently rising parabola or hyperbola. Since this part of the parabola or hyperbola also lies between the middle of the length area and the foot area of the

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Since the ventilation brick increases continuously up to the channel strip, an idealized air guide surface for the respective air flow can be created with reduced material.

Despite this excellent ventilation, the ridge or hip vent tile according to the invention should nevertheless reliably prevent the ingress of precipitation water in the form of rain, snow and sleet. For this purpose, according to a first alternative, the webs are advantageously integrated in zigzag or sinusoidal waves that run transversely to the longitudinal axis, but with their apex lines parallel to the longitudinal axis of the tile. These waves create a flow grid below the bottom edge of the hip tile, which not only prevents precipitation from penetrating the roof space due to its front surfaces and the adjoining head edge strip, but also because of the air flowing out of the roof space due to an increased Venturi effect. The latter sucks or entrains any precipitation that may penetrate between the channel strip and the edge of the hip tile. This is because the idealized air guide surface guides the air over the hip tile with little resistance and at the appropriate speed, so that as the air speed increases, the suction effect from the inside of the roof to the outside inevitably increases. Rainwater can only enter the channel if there is little or no air flow, where it is prevented from entering the roof space by the head edge strip.

According to a third embodiment, the webs are formed by equally spaced ribs running parallel to the longitudinal axis of the brick with rounded end areas. Both

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These designs have the advantage that the lower edge of the hip tile is securely supported and the flow resistance for the air flowing out of the roof space due to the Venturi effect encounters only low flow resistance.

According to a fourth embodiment, the webs run transversely to the longitudinal axis of the ventilation tile, have concave front surfaces towards the eaves and are arranged in several rows, with the gaps between two webs overlapped by another web in the following row. This arrangement creates a significant flow resistance to the penetrating precipitation, but also to the air sucked in from the roof space. However, the flow resistance of the air sucked in from the roof space is reduced by the convex shape of the webs in their flow direction, while the flow resistance to precipitation attempting to penetrate is increased by the concave shape.

According to a fifth embodiment, the webs are provided with a known zigzag contour running transversely to the longitudinal axis of the ventilation brick. This embodiment is basically known from DE 33 20 850 C2 (see Fig. 4b).

According to a particularly advantageous development of the invention, the channel strip is provided with a height above the channel floor which overlaps the gap between the lower edge of the ridge tile and the channel floor in terms of flow, regardless of the respective roof pitch. This overlap creates a flow barrier which, on the one hand, leads to an increased

This leads to air intake from the roof space and on the other hand significantly reduces, if not completely prevents, the possibility of precipitation penetrating the gap described above. The rule here is that the higher the flow speed, the more this flow barrier prevents precipitation penetrating the gap described above and, when there is no wind or the flow speed is low, only a small amount of precipitation can penetrate into the channel, from where it is discharged via the water fold and through openings to the air guide surface.

For this purpose, the channel strip is advantageously provided with openings leading to the air guide surface for draining water from the channel. This creates additional flow paths for draining water in addition to the water folds. These openings are arranged in such a way that they meet a front surface of the webs on the ridge side, which together with this end area form a baffle for the precipitation penetrating into the channel.

In order to always be able to safely overlap the gap between the lower edge of the ridge tile resting on the ridge batten and/or on the upper edges of the webs and the duct floor with the duct strip and thus create the flow barrier described above, it is advantageous to design the angle β between the duct floor and the adjacent air guide surface to be approximately between 100° and 150°.

Since the roof batten adjacent to the ridge batten can have a different distance from it, but the lower edge of the ridge tile sitting on it must always find a secure support, the clear width of the channel between

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The headboard and the channel strip should be dimensioned between 80 mm and 100 mm so that different distances can be easily compensated.

The ridge or hip ventilation tile according to the invention can be made of ceramic materials as well as plastic and its surface can be colored in any RAL color.

Several embodiments of the invention are shown in the drawings.

Fig. 1 shows a partial perspective view of the ridge with several ridge and hip ventilation tiles according to the invention as well as the ridge tiles sitting on top,

Fig. 2 is a plan view of a first embodiment of the ventilation brick with zigzag-shaped waves running parallel to its longitudinal axis as webs,
20

Fig. 3 the view in the direction of arrow III onto the head edge strip of the ridge tile of Fig. 2,

Fig. 4 the view in the direction of arrow IV onto the foot area of the ridge vent tile of Fig. 2,

Fig. 5 is a side view in the direction of arrow V of Fig. 2,

Fig. 6 the side view in the direction of arrow VI of

Fig.7,

Fig. 7 the bottom view of the ridge vent tile from Fig. 2, 5

Fig. 8 the sectional view along the line VIII-VIII of the ridge vent tile of Fig. 2 with a flat air guide surface,

Fig. 9 a section along the line VIII-VIII of Fig. 2 through a ridge ventilation tile with a gently rising air guiding surface in the form of a partial parabola or partial hyperbola,

Fig. 10 the top view of the head area of a second embodiment of a ridge ventilation tile with sinusoidal waves running parallel to the longitudinal axis of the tile as webs,

Fig. 11 is a plan view of the head of a third embodiment of a ridge ventilation tile with equally spaced ribs running parallel to the longitudinal axis of the tile as webs with rounded end areas,

Fig. 12 is a plan view of the head area of a fourth embodiment of a ridge ventilation tile with webs running in a zigzag shape to the longitudinal axis of the tile,

25

Fig. 13 is a plan view of the head area of a fifth embodiment of a ridge ventilation tile with webs running transversely to its longitudinal axis and concavely deformed towards the eaves,

30

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Fig. 14 a section along the line VIII-VIII of Fig. 2 through a ventilation tile with an air guide surface rising gently from the foot area and a channel strip clearly overlapping the gap between the channel bottom and the lower edge of the ridge tile,

Fig. 15 the cross-sectional view through a ridge area with a roof pitch of 60° and

Fig. 16 the cross-sectional view through a ridge area with a roof pitch of 45°.

The ridge or hip ventilation tile 1 according to Figures 2 to 7 has a cover rebate side 2, a water rebate side 3 and a middle part 3 with an air guide surface 4 located between them. At the head area 5, the ridge ventilation tile 1 is provided with a ridge-side head edge strip 6 and a channel strip 7 spaced apart from it with a channel 8 arranged between these strips 6, 7 for ventilation and drainage. In the representation in Figure 2, webs 9 are arranged in the channel 8, which run parallel to the longitudinal axis 10 of the tile 1. These webs 9 are integrated in zigzag-shaped waves 11 running transversely to the longitudinal axis 10.

In the embodiment of Fig. 10, these waves 11 have a sinusoidal course. These webs 9 are closed at their end faces 9a, so that air and water can only flow out or run off through the channels 12 located between the webs 9. These zigzag or sinusoidal waves 11 and thus the webs 9 are firmly connected to the channel floor 8a.

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As can be clearly seen from Figures 4 to 6, the upper edges 9b of the webs 9 lie in a line of alignment 13 (see Fig. 4) and end slightly below the upper edge 7a of the channel strip 7. The apex lines 9c of the webs 9 always run parallel to the longitudinal axis 10 of the ventilation brick 1.

As can be seen from Fig. 8 in conjunction with Figures 5 and 6, the air guide surface 4 in this embodiment is designed as a plane which rises continuously from a region 14 approximately in the middle region 15 of the brick 1 in the form of a straight line to the upper edge 7a of the channel strip 7 and ends there.

In Fig. 9, the air guide surface 4 is designed as part of a gently rising parabola or hyperbola. Otherwise, parts that correspond to Fig. 8 are designated with the same reference numbers.

As can also be seen from Figures 2 and 10 to 12, the channel strip 7 is provided with openings 16, 17 leading to the air guide surface 4 for draining water from the channel 8. The clear width W of the channel 8 between the head edge strip 6 and the channel strip 7 is advantageously dimensioned between 80 mm and 100 mm.

These openings 16, 17 are advantageously arranged such that they meet on the ridge side an end face 9a of the webs 9, which together with this end region form an impact edge for the precipitation penetrating into the channel 8 via these openings 16, 17.

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In Fig. 11, the webs 9 are provided with the same distance a from each other, run parallel to the longitudinal axis 10 of the ventilation brick 1 and are formed by ribs 9 with rounded end regions 18, 19.

Fig. 12 shows a further embodiment of the webs 9. In this embodiment, the webs 9 are provided with a zigzag contour 20 running along the longitudinal axis 10 of the ventilation brick 1.

Fig. 13 shows an embodiment of the webs 9 which run transversely to the longitudinal axis 10 and have a concave front surface 9a towards the eaves and a convex surface 9d towards the ridge side. The webs 9 are arranged in several rows one behind the other, with the gaps - which may also be of different widths - between two webs 9 being overlapped by another web 9 in the following row. Otherwise, parts identical to the embodiments described above are designated with the same reference numbers. In addition, this embodiment is also provided with two side strips 35, 36, of which the strip 36 on the water fold side 3 has several openings 37 for water drainage. These webs 35, 36 serve primarily to improve the support of the lower edge 24b of the ridge tile 24 sitting on top.

In Fig. 14, the height H of the channel strip 7 is designed in such a way that the gap S between the lower edge 24b of the ridge tile 24 and the channel bottom 8a is overlapped in terms of flow, regardless of the respective roof pitch α. For this reason, the upper edge 7a of the channel strip 7 ends significantly above the lower edge 24b of the ridge tile 24. This ensures an extremely effective

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A flow barrier 38 is created against attempts by precipitation to penetrate in the direction of arrow 29, the size of which naturally depends on the speed of the outside air. In addition, this ridge tile 1 is thinner than the embodiments in Figures 8 and 9. Otherwise, parts that correspond to Figures 8 and 9 are designated with the same reference numbers.

In Fig. 15 a roof pitch α of 60° is shown and in Fig. 16 a roof pitch α of 45° is shown. The ridge tile 24 sits on the one hand on the ridge batten 39 and with its lower edges 24b on the webs 9. As these figures show, depending on the roof pitch, the position of the upper edge 7a of the channel strip 7 shifts in relation to the gap S for one and the same ridge or hip vent tile 1. In order to ensure that the gap S always overlaps securely with the channel strip 7 even with different roof pitches α, the angle β according to Fig. 14 between the channel base 8a and the adjacent air guide surface 4 is dimensioned between 100° and 150°.

As can be seen from Figures 15 and 16, one and the same ridge or hip ventilation tile 1 is used in both embodiments. The roof rafters 40 and roof battens 41 used correspond to the known embodiments.

The function of the vent brick 1 is explained below using Figures 1, 8, 9 and 14:

Assuming an air flow of the outside air in the direction of the flow arrows 21 approximately perpendicular to the ridge batten 22, this air flow is directed over the lower area 23 of the

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Ventilation tile 1 is guided to the air guide surface 4, which guides the air flow 21 along a continuous path to the upper edge 7a of the channel strip 7, where it flows around the surface 24a of the ridge tile 24 at increased speed and reaches the other side of the roof. Since the lower edge 24b of the ridge tile 24 rests on the upper edges 9b of the webs 9, which in turn end significantly below the upper edge 7a of the channel strip 7, the air guide surface forms an almost continuous air guide surface 25 with the upper side 24a of the ridge tile 24 (see Fig. 8, 9 and 14), whereby the speed of the air flow 21 is not slowed down, but on the contrary even accelerated, because a braking front wall as in the prior art is missing. According to the Bernoulli equation, this creates a negative pressure in the area 26, which, due to the associated Venturi effect, causes a vent flow 27 from the roof interior 28. This means that if precipitation falls at the same time, for example in the most unfavourable direction of incidence according to arrow 29 in Fig. 8 and 14, the falling precipitation is carried along by the vent flow 27 and the outside air flow 21 and prevented from penetrating the gutters 12 because the outside air flow 21 forms a flow barrier 38.

But even under the most unfavourable conditions, for example when there is no air flow and when precipitation is pouring down from above, the air can only penetrate into the channel 8 as far as the head edge strip 6 and is guided from there via the openings 16, 17 and 37 shown in Figures 2 and 10 to 13 out of the channel 8 either to the water fold side 3 or into the area between the cover fold side and the water fold side 3 to the outside onto the air guide surface 4.

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According to Fig. 7, the ridge or hip ventilation tile 1 is held on its underside la by one or two suspension lugs 30 on the roof batten 31 closest to the ridge batten 22 in a manner known per se. The rebate ribs 32 with the water-conducting channels 33 in between are also known prior art and, like the design of the cover rebate side 2, are not the subject of the present invention.

&iacgr;&ogr; It is understood that to improve the aerodynamics of the

The air guide surface 4 of the ventilation brick 1 can extend down to its base region 23, which according to the embodiment of Fig. 14 does not necessarily have to involve an increased expenditure of material. Initial tests have shown that the desired aerodynamic effect can be achieved by extending the air guide surface 4 down to the central region 15 or just below.

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List of reference symbols

Ridge or hip ventilation tiles 1 5

Bottom of the ridge or
Ridge ventilation brick 1 la

Top of the ridge

or ridge vent brick 1 Ib

Cover fold page 2

Water fold side 3

Air guide surface 4

Head area 5

Header border 6

Channel bar 7

Upper edge of channel strip 7 7a 25

Channel 8

Channel floor 8a

Bridges 9

Front surfaces of the webs 9 9a

Upper edges of the webs 9 9b 35

Vertex lines of the bridges 9 9c

convex surface of the webs 9 9d

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Longitudinal axis of the brick 1 10 zigzag waves 11 Gutters 12 Vanishing line 13 Area of the ridge of the
Air guide surface 4 14 Middle area of brick 1 15 Breakthroughs 16, 17 End areas of the
rib-shaped webs 9 18, 19 Zigzag contour of the webs 9 20 Flow arrow 21 Ridge batten 22 Foot area of
Vent brick 1 23 Ridge tiles 24 Surface of the ridge tile 24 24a Bottom edge of the ridge tile 24 24b Air guide surface 25 Area of air inflow
of the vent flow 26 Vent flow 27

.· 07:03:2004.

Roof interior

Arrow of the incoming precipitation 5 Hanging nose Roof batten Folded ribs Water guiding channels

25

Gap between the webs Side rails Openings Flow barrier Ridge batten Rafters Roof battens Clear width of the channel Distance between the webs Gap Angle

35

35.36

α, β

Claims (13)

1. Ridge or hip ventilation tile with a ridge-side head edge strip and a channel strip spaced therefrom and a channel arranged between these strips for ventilation and drainage, in which webs for placing the lower edge of a ridge tile are integrally connected to the channel floor, characterized in that the deeply interlocked ventilation tile ( 1 ) is provided between its cover rim ( 2 ) and its water rebate side ( 3 ) with an air guide surface ( 4 ) which ends flush with the upper edge ( 7 a) of the channel strip ( 7 ) and rises continuously from between the middle region ( 15 ) and the foot region ( 23 ) of the ventilation tile ( 1 ), and that the upper edges ( 9 a) of the webs ( 9 ) lying in a line of alignment ( 13 ) end significantly below the upper edge ( 7 a) of the channel strip ( 7 ). 2. Ridge or hip ventilation tile according to claim 1, characterized in that the air guiding surface ( 4 ) consists of one plane. 3. Ridge or hip ventilation tile according to claim 1 , characterized in that the air guiding surface ( 4 ) is formed as part of a gently rising parabola or hyperbola. 4. Ridge or hip ventilation tile according to one of claims 1 to 3, characterized in that the webs ( 9 ) are integrated in zigzag or sinusoidal waves running transversely to the longitudinal axis ( 10 ), but with their apex lines ( 9b ) parallel to the longitudinal axis ( 10 ) of the ventilation tile ( 1 ). 5. Ridge or hip ventilation tile according to one of claims 1 to 3, characterized in that the webs ( 9 ) are formed by equally spaced ribs running parallel to the longitudinal axis ( 10 ) of the ventilation tile ( 1 ) with rounded end regions ( 18 , 19 ). 6. Ridge or hip ventilation tile according to one of claims 1 to 3, characterized in that the webs ( 9 ) run transversely to the longitudinal axis ( 10 ) of the ventilation tile ( 1 ), have concave end faces ( 9a ) towards the eaves and are arranged in several rows and the gaps ( 34 ) between two webs ( 9 ) are overlapped by a further web ( 9 ) of the following row. 7. Ridge or hip ventilation tile according to one of claims 1 to 3, characterized in that the webs ( 9 ) are provided with a known zigzag contour running transversely to the longitudinal axis ( 10 ) of the ventilation tile ( 1 ). 8. Ridge or hip ventilation tile according to one of claims 1 to 7, characterized in that the channel strip ( 7 ) is provided with a height (H) above the channel bottom ( 8a ) which fluidically overlaps the gap ( 5 ) between the lower edge ( 24b ) of the ridge tile ( 24 ) and the channel bottom ( 8a ) independently of the respective roof pitch (α). 9. Ridge or hip ventilation tile according to one or more of claims 1 to 8, characterized in that the channel strip ( 7 ) is provided with openings ( 16 , 17 ) leading to the air guiding surface ( 4 ) for draining water from the channel ( 8 ). 10. Ridge or hip ventilation tile according to one of claims 1 to 8, characterized in that the angle (β) between the channel bottom ( 8a ) and that of the adjacent air guide surface ( 4 ) is between 100° and 150°. 11. Ridge or hip ventilation tile according to one or more of claims 1 to 10, characterized in that the clear width (W) of the channel ( 8 ) between the head strip ( 6 ) and the channel strip ( 7 ) is between 80 mm and 100 mm. 12. Ridge or hip ventilation tile according to one or more of claims 1 to 11, characterized in that it ( 1 ) is made of ceramic materials or of plastic. 13. Ridge or hip ventilation tile according to one or more of claims 1 to 12, characterized in that its surface ( 1b ) can be colored in any RAL color.