HUT60810A - Ridge-ventilating device - Google Patents

Abstract

A roof ventilation arrangement with a roof ventilation valve (1) fitted beneath the ridge tile (4) has a gap (7) in the longitudinal edges in which are fitted inserts which cause the air flowing into the gap to eddy or divert it. The roof ventilation valve (1) may have devices by means of which the gap (7) can be completely closed so that there is a gap on the leeward side only. The suction effect thus achieved can be used to take off exhaust air from the inner roof space through the ventilation gaps to the outside on the leeward side.

Description

The present invention relates to a roof ridge ventilation device. The device consists of a roof ridge vent under the spine tiles. The roof ridge vent hood has unique passages extending in a row in the longitudinal direction of the roof, with their frontal mouth openings extending to the opposite inclined roof portions, intersecting the cavity below the ridge ends. The channels are open to air flow zones. The roof ridge vent cap has openings in flow-favorable locations.

Such a roof ridge ventilation device is described in DE-PS

No. 23,083 description.

The importance of roof ridge ventilation on sloping roofs has steadily increased in recent years, as the structure of roofs has changed significantly as a result of the use of new materials and the utilization of the roof area, such as living space. Many of the previously proven rules for roof construction have been overshadowed by new materials, improved production of materials, and greater requirements for insulation. In the past, for example, poor tiling between tiles provided good roof ventilation and thus prevented dewatering. However, the current high level of roofing prevents largely uncontrolled air exchange between the lower and upper airflows. What's more, in the past, the large volume of air in the attic below the slanted roofs, which was not used for residential purposes, was able to absorb the moisture generated without any problems. For new roof structures, the volume of air available to absorb moisture is limited to the volume of air in the aeration section between the heat insulation and the underlying layer - lower tension barrier or rainproof interior roof. In addition, on warm summer days, good and fast heat dissipation must always be ensured. This increases the risk of local condensation and resulting roof damage. Therefore, it is always necessary to ensure that the moisture in the aeration area under the roof tile is safely drained. This can only be achieved by providing aeration with a strong airflow. This is in accordance with DIN-4108. standard.

With the known roof ridge venting device, the air under the ridge tile can flow to a large extent from the windward side and may flow out again on the windshielded side. The air can escape from the interior and from the aeration area under the roofing panels towards the roof ridge and can be led out into the open air along with the air flowing in the roof ridge portion perpendicular to the ridge.

If the air flow is routed across a sloping roof, the ridge tile acts as a cutting edge for the air flow. On the windward side, a suction zone is formed, where air flows from the aeration slots, interior space and roof ridge section, if the openings leading to the suction zone have large enough cross sections. This solution creates a good air circulation in the roof aeration slots, which ensures good ventilation of the sloping roofs.

DE-A-22 62 924 discloses a roof ridge arrangement having air reflective walls between the roofing panels and the roof ridge. The reflective walls have openings that open into the space below the roof ridge cap. The reflective walls are designed to prevent water and debris from entering the attic. The openings formed by the reflective walls allow air to escape from the roof's interior.

DE-B-1 295 788; Also known from the specification is a roof ridge venting device which is used together with planes or molded sheets. This roof ridge venting device consists of two roof ridge connection plates on both sides of the roof ridge, the roof ridge side edges of which are bent and an aeration gap is left between these edges. The curved edges of the roof ridge joining panels are covered by an overlay which is spaced over the edges. The cover is held by a substantially inverted U-shaped clip on the underside. The two branches of the clamp projecting into the aeration gap between the roof ridge connecting plates can be clamped by a spreading device to the bent edges of the roof ridge connecting plates and the ends of the staples are snug against these flanges. With these solutions, the formed aeration gap can be almost completely free of air disturbance fittings. The width of the device can be easily adapted to the particular circumstances.

It is an object of the present invention to further develop a roof ridge venting device of the type described above, so that the air currents in the roof ridge portion can be further directed and used for more efficient ventilation of inclined roofs.

• · «· ·

According to the present invention, this object is accomplished by distributing elements in the roof ridge vent cap directed toward the ridge tiles which provide greater resistance to the inflow of air from the outside than to the flow of air from the interior to the roof ridge. .

The great advantage of the roof ridge ventilation device according to the invention is that it provides greater resistance to the air inflowing from the wind than to the air coming from the windward direction. The roof ridge vent cap acts as an aerodynamic throttle system over a wide range and takes advantage of the known flow advantages. The air inflowing from the wind direction not only becomes turbulent in the gap between the ridge tile and the roof ridge vent, but also changes its direction. Thus, conventional, such as

DE-PS 30 23 093; Compared to the known roof ridge ventilation systems, a greater percentage of the air flowing under the ridge tiles flows through the ridge tiles. With this solution, the suction under the spine tile is permanently stabilized and, at the same time, it is effectively prevented from entering the roof ridge from the outside into the aeration slit, downwind, towards the gutter. In summary, the flow conditions are more defined than in known roof ridge ventilation systems.

In a preferred embodiment of the invention, the elements in the cap are aerodynamically positioned in the individual channel.

- 6 interfering bodies.

This has the advantage that the flow resistance to the incoming air can be high within a single roof ridge vent. The interfering bodies can complement and improve the operation of the longitudinal windscreens on the longitudinal flange of the roof ridge vent.

Advantageously, bumps may also be used which define the individual channels from the side. Incoming air encounters large obstacles, especially concave surfaces and edges. This will intensely disturb the intake air. The air flowing out of the roof ridge fits over the contours of the bumps and flows much more evenly.

Through the openings above the roof ridge vent, airflow from the aeration vents and from the interior can be prevented from entering the roof ridge through the roof ridge vent as far as possible, and from there, can flow to the suction zone.

In another preferred embodiment of the invention, there are sealing strips on the rim portion of the roof ridge vent cap in the direction of the roofing panels. The advantage of this is that the roof ridge vents are snug against the roof panels and over and over the roof ridge vents.

When placing a triangular cross-member on the roof ridge vent cap, the inlet, air • ···

- 7 currents can cause the flow to be cut off and thus the first effective reversal of the wind.

The roof ridge ventilation device according to the invention thus fulfills all the extended requirements for roof ventilation. The roof ridge ventilation device of the present invention takes full advantage of the prior art roof ridge ventilation systems and improves them through increased forced ventilation.

Further advantages will be apparent from the description and accompanying drawings. The above-mentioned features and those to be described later may be used alone or in combination with each other. These embodiments are merely exemplary and not intended to be exhaustive.

Our invention by way of example! DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS With reference to the drawings, in which:

Figure 1 is a perspective view of a roof ridge ventilation device according to the invention, with a roof ridge vent cap covering the clearance between the ridge member and the roofing panels;

Fig. 2 is a perspective view of an embodiment of a roof ridge venting device according to the invention, with a short section of the roof ridge venting cap.

- 8 sleds showing repetitive structural projections,

Figure 3 is a top plan view of a further embodiment of a roof ridge vent cap, located on both sides of a ridge member,

Figure 4 is a perspective view of a further embodiment of a roof ridge vent bottle.

In each of the figures, the device according to the invention is shown in part in very schematic and not in scale. In some figures, the objects are enlarged to give a better view of their structure.

Figure 1 shows a short section of a roof ridge ventilation device with a roof ridge vent 1. The roof ridge vent 1 rests on one side and is fixed to the ridge member 2 as shown in the figure, and on the other side, with its longitudinal flange 3, rests on the surface of the roofing sheets. The roof ridge vent cap covers the clearance between ridge 2 and the roofing panels. There is such a free space on each side of the spine 2. However, Fig. 1 shows only a short section on one side of an inclined roof.

The roof ridge vent cap 1 is covered by ridge tiles 4 secured by ridge clips 5 on the ridge member 2.

• · • ·· ···

- 9 The ridge tiles are seated with a nose 6 on the roof ridge vent cap 1 and pressed against the roof panels. Below the longitudinal flange 3, a sealing strip may be applied to the roof ridge vent cap 1, which fills in the remaining spaces between the longitudinal flange 3 and the roofing sheets. The ridge tiles 4 are always positioned relative to the roof ridge vent 1 so that there is a gap 7 at their longitudinal flanges between the roof ridge vent 1 and the ridge tiles 4. The ridge tile 4 is always at a certain distance from the roof ridge vent 1 and only rests above the nose 6 directly on the roof ridge vent 1.

The central part of the roof ridge vent 1 has protrusions 11 with openings 12 in the walls.

The protrusions 11 are spaced longitudinally from each other to form recesses therebetween. From the base of the projections 11, the roof ridge vent cap slightly rises towards one of the edges 13. A sharply sloping surface portion 14 is connected to the edge 13. The surface section 14 is preferably concave. At the end of the surface section 14 there is formed a strip 15 of triangular cross-section. The end of the surface section 14 corresponds to the longitudinal flange 3 in this embodiment.

The protrusions 11 spaced apart from each other on the roof ridge vent 1 form individual channels 16, which may have interfering bodies 17 at the bottom.

The interfering bodies 17 are disposed on the roof ridge vent cap 1 so that they pass through the surface of the roof ridge vent cap 1 in a direction with a constant contour towards the ridge element without forming a stair. On the side facing the longitudinal flange 3 of the roof ridge vent 1, the interfering bodies 17 are formed as leaping surfaces. These surfaces exhibit greater resistance to the air flowing to them than the surfaces of the interfering bodies 17 towards the spine member 2.

In the external context, we refer to the external atmosphere of an inclined roof.

If air flows from the outside into the roof ridge, air may flow into the gap 7, and some parts of the flow will change direction according to the arrow 22. This part of the air flow passes through the ridge tiles 4 in the wind direction. Other portions of the flow undergo a change of direction in the arrow 23 depicted in the result line. This reversed flow contributes to the addition of portions of the air still flowing in the direction of the arrow 21 in the direction of the arrow 22. In addition, the large surface area 14, which acts as an aerodynamically shaped baffle plate, has a flow resistance which is also suitable for changing the direction of the flow.

The roof ridge vent 1 cap design is structured with the cap cooperating 4 ridge tiles and the so-called ························································· ··

The lattice 15, which is designed as a spoiler and also contributes to disrupting flow from the arrow 21, forms a roof ridge ventilation system that directs windward flow primarily over the roof and greatly prevents air from outside the roof ridge vent 1 flow unhindered through the gap 7 between the inside of the ridge tiles 4 to form a very stable suction zone on the edge 24 of the ridge. This suction zone is a suction that sucks through the apertures 12 in the arrow direction 25 from the interior of the outgoing aeration and the aeration slots and drains it out of the roof ridge on the windshield side.

Figure 2 shows a further embodiment of the roof ridge vent cap 30. This embodiment is particularly suitable for changing the direction of the air flowing into the roof ridge from the wind direction, disturbing this air and exhibiting high resistance to it. Figure 2 is a perspective view of again only a short section of the roof ridge vent 30. This section shows the essential structural solutions of the roof ridge vent 30 cap. The arrangements are repeated and are mirror-shaped on the other side of the web 31. The gasket 32 of the roof ridge vent 30 rests through a sealing strip 33 on the surface of the roofing sheets. The inclined face 32 'in the path of the flow of air acts as a wind deflector. The sealing strip 33 may be a foamed plastic or a highly deformable ultraviolet resistant material such as rock wool. For section 32 there is a central section 34

Λ · ·

- 12 joints on which 35 projections are formed. The protrusions are designed to strongly interfere with the inflow of air from the outside and, on the other hand, to cause almost no airflow from the interior. The side surfaces are inclined with respect to the surface 36 facing the arrow flow. The side surfaces have an angle of 10 ° to 15 ° with the vertical side surface. In the figure, the score line indicates the arrow direction 36, which exemplifies how the air from the outside is redirected or disturbed. Through the openings 38 surrounded by the raised rim 38 ', air can flow from the interior of the roof or from the aeration slots under the roof panels to the roof ridge below the roof tiles. This air flows over section 39 as the air flows into the roof 36 in the arrow direction and then exits the roof ridge on the windward side. Through section 39, the roof ridge vent cap 30 is secured to the ridge member 31. Next to the openings 38, there are supports 38 '' which effectively prevent the ridge tiles from resting on the section 39.

Figure 3 shows a further embodiment of a roof ridge vent 60. The figure shows how the roof ridge vent cap 60 is located along two sides of a ridge member 61. A portion 62 of the roof ridge vent cap 60 rests on the ridge member 61 and is secured to the ridge member 61 through this portion. Section 62 is joined on two long sides by sections 63 and 64, which are a section 65, which is a section 65.

- 13 the roof ridge vent 60 are closed in width.

Air currents can flow to the roof ridge vent cap 60 from the direction of arrow 66 and arrow.

The roof ridge vent cap 60 lies in sections 65 on the roof panels of the respective inclined roof section. Between the projections 68 located in sections 63 and 64, there are 69 obstructions. The interfering bodies 69 may, for example, be triangular bodies with their tapering, tapering side surfaces facing the spine element 61 and having a substantially vertical, steeply inclined surface facing the section 65. In the section 63 there are also openings 70 in the roof interior space or in the aeration slots through which the air can flow through the roof ridge vent cap 60 into the individual spaces 71 into the outer space.

The apertures 70 have a flange 70 'extending towards the underside of the tile. The openings 70 are joined by supports 70 '' on the side facing the spine element 61 to ensure that the underside of the spine tile is always at a certain distance from the section 62.

Figure 4 shows a further exemplary section of a roof ridge vent 75 having protrusions 76. The protrusions 76 are located substantially in the center of the roof ridge vent cap 5 and are saw-tooth-shaped on their side surfaces such that they exhibit a broad surface resistance in the direction of air flowing from the outer space 77 facing only surfaces

- There are 14 with a constant skew. The surface 79, formed as an aerodynamic interfering surface, forms a resistance to the air flowing in the direction of the arrow 77, which is part of the body 80. The body 80 deflects, disrupts, enforces, and directs the air from the arrow direction 77 far above the spine tiles. Between the protrusions 76 there are openings 81 which connect the interior of the roof or the aeration portion with the space between the roof ridge vent cap 75 and the underside of the tile. Below the body 80 is a sealing strip 82 through which the roof ridge vent cap 75 rests on the roofing panels. The aerodynamic interfering surface is formed by the face of the body 80 and the sealing strip 82.

The projections 76 have a triangular cross-section and support 83 on the spine.

Claims (5)

PATENT CLAIMS A roof ridge ventilation device with a roof ridge ventilation cap (1; located below the ridge tiles (4); 30; 60; 75;), having individual ducts (16; 71) intersecting the space beneath the spine tiles (4;) and arranged in the longitudinal direction of the roof, with their mouth openings facing opposite inclined roof portions and facing the air flow zones (16; 71). open; the roof ridge vent (1; 30; 60; 75) at flow-favorable locations of openings (12; 38; 70) characterized in that elements distributed in the roof ridge vent cap (1; 30; 60; 75), directed towards the ridge tiles (4), have a higher resistance to the flow of air from the outside than from the inside. and for the air flowing out of the roof ridge to the outside. Roof ridge ventilation device according to claim 1, characterized in that the elements are interfering bodies (17; 69) located at the individual channels (16; 71). Roof ridge venting device according to claim 1 or 2, characterized in that the elements are protrusions (35; 68; 71) delimiting the individual channels (16; 71) from the side. «« · Ν · • · »· · · · · · · · · · · · · · · · · 4. Roof ridge vent roof device according to one of Claims 1 to 3, characterized in that sealing strips (33; 82) are provided on the edge of the roof ridge vent cap (1; 30; 60; 75) on the side facing the roofing panels. 5. Roof ridge ventilation device according to one of Claims 1 to 3, characterized in that the roof ridge ventilation cap (1) comprises a strip (15) of triangular cross-section.