HU223180B1 - Ridge or hip ventilation element - Google Patents

Abstract

A ridge vent member having a central portion that can be secured to a ridge, and having a central edge on either side of its limiting side portions, which can be placed on roof coverings with their outer edge region, and are air-permeable between their edge regions and the center portion. In the air-permeable regions and / or outer edges of the side portions, longitudinally extending ribs are provided in the longitudinal direction of the spine vent member, forming a storage region so that the spine vent member can be laterally extended. ŕ

Description

The scope of the description is 8 pages (including 2 tabs)

EN 223 180 Bl

The present invention relates to a spinal ventilation element, the middle portion of which can be fixed on a ridge and the lateral portions of the middle part of which are bounded by their outer edge surface on the roof covering, and which is perpendicular to the wind surfaces and the middle portion.

Such a spinal ventilation element is known from G 94 16 291.3.

Spine ventilation elements are used on the roof to cover the gap between the ridge and the roof. This part between the ridge and the roof covering is in the longitudinal direction of the roof ridge on the right or left side of the ridge. It is possible to prevent rainwater, snow, worms or dirt from entering the spinal ventilation element. At the same time, the spinal ventilation element must also allow sufficient ventilation of the roof interior to protect the roof from decay.

The known backbone ventilation element is made of one piece, a soft, open-cell foam. The predetermined geometrical dimensions of this need to bridge the gap between the ridge and the roof. The roof tiles on the spinal ventilation element are arranged such that the spinal ventilation elements are insulated in the roof covering. Problems arise when the spinal ventilation element cannot cover the gap between the spine and the roof cover. In this case, insulation problems occur in the wind areas between the roof covering and the tile. But ventilation can also come from improper fixing of the spinal ventilation elements, since the breathable range of the wind portions will in some circumstances be placed on the ridge or even on the roof covering. The breathable range therefore no longer fulfills the function of ventilating the attic.

However, when creating a roof chair, it is always the case that the spacing between the ridge and the roof (or roof covering) is different. Even in the case of inaccurate construction of the roof racks, the distance between the ridge and the roof covering may not be the same for the same roof.

A possible solution to these problems could be that the craftsman uses spinal ventilation elements of different sizes. However, performing this is demanding and will increase the cost of insulation between the roof covering and the tile.

DE 40 01 766 C2 also discloses a spinal ventilation element which can be secured in the spinal region as described above. The side portions of this spinal ventilation element are made of wool or fabric, the shape and dimensions of which give the shape and dimensions of the spinal ventilation element. As a result, this backbone ventilation element is not suitable for covering different distances between the spine and the roof covering.

In the insulating strip described in German Model 295 01 242.0, a middle strip passes between two longitudinally extending ribs with defined length sections into a side strip. According to this design, the insulating strip has predetermined bending edges that can be used at any time for different ridge edges.

Simple or multiple strokes, which are designed according to the ventilation arrangement according to the teachings of DE 38 25 348 A1, allow flow edges.

The longitudinal korea of the spinal ventilation element known from GB 21 55 516 A forms the edges of a supporting groove into which other components of the spinal ventilation element can be inserted.

It is an object of the present invention to provide a backbone ventilation element by means of which free spaces of different sizes can be covered between the ridge and the roof covering in order to maintain air circulation between the ridge and the roof covering and to allow easy isolation of the spacing between the ridge tiles and the roof covering.

According to the invention, this technical problem has been solved by the fact that the breathable regions and / or outer regions of the side portions are provided with longitudinal ribs extending in the longitudinal direction of the spinal ventilation element, forming a storage area such that the lateral ventilation member is extensible in the lateral length.

By forming the longitudinal ridges of the spinal ventilation element according to the invention, the spinal ventilation element can react at different distances between the spine and the roof covering. The ribs in the longitudinal direction of the spinal ventilation element ensure that the lateral outlet of the spinal ventilation element can be appropriately fitted and that the portion of the side section needed for ventilation is still provided. In the case of a smaller distance between the lateral length of the spinal ventilation element and the ridge and the roof covering, new ribs may be formed in the spinal ventilator to shorten the spinal ventilation element accordingly. For this reason, the wind range always lies on the islands in the roof covering, while the breathable area of the side portion of the spinal ventilation element is optimally secured between the ridge slats.

Thus, the tolerance fluctuations of the different ridge beams and the fixation of the ridge portions affect the targeted application of the spinal ventilation element.

According to the invention, the longitudinal ribs can be formed so that the corresponding sections of the side portions of the spinal ventilation elements are arranged on top of the spinal columns or adjacent to each other, so that the ribs point towards the spinal columns. The individual ribs do not have to be curved, they can be rounded. It is important, however, that the surface of the side-shaped side-piece can be folded or folded out like a harmonic. Therefore, according to the invention, the formation of the longitudinal ribs also means that certain regions of the side portions of the spinal ventilation element form waves or waves. The advantage of this wavy design is that the spinal ventilation element can be adapted crosswise in the longitudinal direction. When pulled out, the adjacent ribs are widened2

EN 223 180 Bl mok, and this section of the spinal cord is extended without any material tension.

In a particularly preferred embodiment of the spinal ventilation element according to the invention, the outer edge regions have a longitudinal rib that can be set relative to the flow edge away from the roof covering. With the possibility that the spinal ventilation element can be disassembled as required, such a flow wind can be formed at any position between the roof covering and the tile. The flow wind may be slightly uplifted to the spinal column, but may lie on the spinal column. The flow wind prevents the inflow of air, water, or dirt. Therefore, the air-permeable region of the spinal ventilation element is always dry and breathable so that the air can circulate in the breathable range.

In a further embodiment, the breathable region of the side portions consists of mesh fabrics that are interconnected with a moldable grid or fabric. By using each mesh fabric, a region of the spinal ventilation element is created on which air can flow through high efficiency. The air can flow out of the interior of the roof even when the partial regions of the side portions are folded onto one another with a grid structure. In contrast to the prior art, it is possible to provide airflow with the above-described latches.

In connection with the manufacture of the spinal ventilation element according to the invention, it is advantageous to have the outer edge regions of the side portions formed by the stiffening of the grid area, so that the entire spinal ventilation element is made up of a mesh or grid in addition to the middle portion. For insulation between the roof covering and the spine tiles, it is advantageous if the outer wind ranges consist of a moldable grid. This allows the edge ranges to be matched to the contour of the roof covering and to provide better insulation. By stiffening the grid ranges, it is possible to insulate the openings between the mesh fabrics, but retain the grid formability.

In an improved design of this embodiment, the wind ranges were reinforced by coating and / or covering the grid regions with a thin layer of film. The thin-layer foil, on the one hand, performs the task of blocking the grid openings of the grid regions and, on the other hand, increasing the stability of the wind ranges. In this way, the wind ranges fit well into different roof contours and fulfill the function of insulation.

In the first implementation of this improved design, the film can be made of light metal. For example, it is possible to cover the grid fabric with aluminum foil both on the upper side and on the lower side. The two aluminum foils can be glued together so that the moldable grid or fabric is embedded in an aluminum jacket. In the meantime, however, the formability of the grid structure is maintained despite the application of aluminum foil. Of course, other metal alloy films may also be used.

In a further embodiment of the lattice structure, the film is made of plastic. The advantage of using plastic is that the spinal ventilation element is made of a durable material in addition to its costly production.

Preferably, the grid area of the spinal ventilation element is formed by a flexible plastic or metal fiber. Such fibers (mesh fabrics) can further shape the side portion of a spinal ventilation element with the longitudinal ribs according to the invention to form a three-dimensional structure that is well suited to the roof area. The mesh fabrics can also be formed after fixing the spinal ventilation element. Like pulling a tennis racket, the mesh fabrics can also be shifted toward each other to correct for the loss of air permeability.

In a further preferred embodiment, the spinal ventilation element can be wound up. The advantage of this is that the spinal ventilation element can be wound into larger rolls, which can be stored very easily and cheaply, transported and fixed in the attic. Coils of length that are sufficient for an average roof can be created. By unwinding the spinal ventilation element, the craftsman can fix the spine ventilation element on the ridge and the roof covering without any problems.

As an alternative to the reelable design, the spinal ventilation element according to the invention can also be assembled into an endless backbone by means of ribs arranged transversely to its longitudinal direction. The ready-to-transport spinal ventilation element is thus no longer in a cylindrical roll, but is rectangular. This way you can store it better. The spinal ventilation element can be stored in a rectangular "spenderbox" and cut into strips of appropriate size as required.

The fixing of the spinal ventilation element is particularly easy if the lower part of the middle part and / or the outer edge portion of the side section is provided with an activated adhesive layer. By removing the protective film of the adhesive layer, the spine ventilation element can be attached. In this way, a permanent sealing of the gap between the spine and the sloping roof can be easily accomplished. Any adhesive technique and adhesive are suitable for gluing the spinal ventilation element, including glue. The glue binds insolublely to the plastic of the spinal ventilation element, so that, despite the high temperatures in the attic, the shape seal is secured.

Other features and advantages of the invention will be apparent from the following description of the embodiment of the invention, the drawing showing the essential details of the invention and the claims. Each feature can be implemented individually or in any combination.

The

Figure 1 is a perspective view of a roof ridge with a spinal ventilation element according to the invention;

Fig. 2 shows a coil for coiling the spinal ventilation element of FIG.

Figure 3 shows a front view of a further spinal ventilation element according to the invention.

EN 223 180 Bl

The invention is schematically illustrated by the figures so that the essential features of the invention can be recognized. The representations do not necessarily have to be scaled.

Figure 1 shows a spinal ventilation element 10, as exemplified in the spine region of a roof chair.

The spinal ventilation element 10 has a central portion 11 and a side portion 12 defining it. In the fixed state of the spinal ventilator 10, the lower part 13 of the central part is lying on the upper side 14 of a ridge 15. On the underside of the lower part 13, there is an adhesive surface, so that the central part 15 on the ridge 15 is fastened securely and securely.

The middle portion of the All is bounded by the breathable regions 16 of the side portion 12. The breathable regions 16 have two longitudinal ribs 18 and 19 running in the longitudinal direction 17 of the spinal fan element 10. According to the design of the longitudinal ribs 18 and 19, the region 16 can be folded out transversely to the longitudinal direction 17. The longitudinally transverse crystallization of the spinal fan element 10 can thus be altered. With further 18 and 19 longitudinal ribs, this function can be further enhanced. Different distances between the ridge 15 and the roof cover 20 can be overcome.

The roof cover 20 is formed by some roofing plates which lie on the roof rails 21 and 22. Roofs 21 and 22 are fixed on rafters 23 and 24. The ridge 15 is arranged above the rafters 23 and 24 by means of a rack holder 25.

The central portion 11 of the spinal ventilation element 10 passes through the breathable zone 16, which is also delimited by a non-breathable wind region 26. The side portion 12 comprises a breathable region 16 and a non-breathable winding region 26. The wind region 26 may also be folded so that its length 27 may also be varied in the direction of the arrow. In addition, cross ribs are formed in the edge region 26 having rib edges 27 in the direction of the arrow. The edge region 26 is thus well suited for wave-shaped roof contours.

The figure shows the longitudinal ribs 28-30 of the edge region 26. In the same way as in the lower range, there are further 28 longitudinal ribs in this wind region. In this case, both the range 16 and the wind region 26 can be folded in harmonic. The ranges formed by the ribs 28-30 may be folded in such a manner that the edge region 26 is preferably spread out parallel to the roof cover 20, or that the edge region 26 is formed with a flow edge 32 leading to a tile 31. The flow winder 32 prevents snow or rain from penetrating the roof tile 20 from the roof tile 20 to the breathable area 16.

The breathable region 16 comprises a plurality of mesh fabrics connected to a grid. The mesh fabrics consist of elastic fibers of a plastic, so that the lower region can also be shaped so that it can be adapted to the area between the ridge 15 and the roof cover 20.

A free space 33 between the spine tiles 31 and the spine ventilation element 10 forms a flow zone or a take-off zone for the air from the attic and the airflow flowing transversely to the roof ridge. In this free space 33, exiting air from the attic is gathered through the ranges 16.

Part of the air flow to the top of the roof flows into the free space 33 under a tile 34. Under a tile area 35, the airflow can escape from the free space 33 and take away the exhaust air in the free space 33. Other parts of the air stream are diverted by the tile 31 and create a vacuum on the windy side of the tile 35. As a result, the air in the free space 33 is drained in the tile area 35, thus ensuring good ventilation of the attic.

For ventilation of the attic, it is preferred that the air flow in the free space 33 flows in the direction of the arrow 27.

Figure 2 shows how the spinal ventilation element can be transported before installation.

The spinal ventilation element 10 consists of a central portion and a side portion 12. The spinal ventilation element 10 is symmetrically arranged to be secured to the central part (see Figure 1) of a spine. However, according to the invention, spinal ventilation elements are also conceivable, which are constructed asymmetrically, and are only used for insulation and ventilation of a single roof curve.

The middle part 12 is delimited by the side portions 12 on two sides. Each side portion 12 comprises a breathable region 16 and a non-breathable region 26. The breathable region 16 comprises a plurality of mesh fabrics connected to a mesh or grid. The grid is only indicated in Figure 2.

The side portions 12 of the spinal ventilation element 10 have longitudinal ribs 18, 19 and 28-30 so that the side portions 12 can be compressed as smoothly as possible. In the fixed state of the spinal fan element 10, the side portions 12 can be pulled out to bridge the different distances and spaces between the ridge and the roof covering. In the figure, the sections of the side portions 12 are compressed flat to coil the spinal fan element 10. The spinal ventilation element 10 is made of flexible plastic. Therefore, the side portions 12 can be easily folded, folded and optionally folded again. The longitudinal ribs 18,19 and 28-30 may also be formed in the manufactured state of the spinal fan element 10, but may be formed by the craftsman in the material at the other location of the side portion because of the material's formability. By forming longitudinal ribs 28-30, a flow wind of a different size (see Figure 1) can be formed in the edge region 26, the height of which can be determined by the free space under the spinal column.

The spinal ventilation element 40 of FIG. 3 consists of a central portion 41 and side portions 42 which define it. The central part 41 is flat and the material is different from the material of the side portions 42. The side portions 42 are made of two separate components, a breathable member 43

It consists of a block and a non-breathable wind area 44. The range 42 and the edge region 44 are made of different materials and are glued together. Therefore, the range 42 is good breathable, while the edge region 44 is well insulated.

The region 42 is bundled in harmonic manner with protruding longitudinal ribs so that the span 40 of the spine 40 can be varied in an arrow direction. The edge region 44 has transverse ribs 46 to accommodate the wave-shaped roof covering (see FIG

Figure 1). A flow wind 47 can prevent the penetration of snow or rain.

A spinal fan element 10 has a central portion 11 on which a spine 15 can be fastened and has a side portion 12. The central portion of each of the sides is delimited by side portions 12, which can be placed on tops 20 with their outer edge regions 26 and are air-permeable between their central regions 26 and the central portion 11. The side portions 12 are provided with longitudinal ribs 18, 19, 28-30 in their perpendicular regions 16 and / or their outer edge regions 26 in the longitudinal direction of the spine ventilation member 17. By using the ridge ventilation element 10, free spaces of different sizes can be covered between the ridge and the roof covering in such a way that air circulation is maintained between the ridge and the roof covering and the spacing between the tile and the roof covering can be easily insulated.

Claims (10)

PATENT CLAIMS A ridge vent member (10; 40) having a central portion (11; 41) secured to a ridge (15) and having flanking side portions (12; 42) defining the central portion (11; 41) on both sides with their outer edge region (26; 44). can be placed on roof coverings (20) and are air-permeable between their wind regions (26; 44) and the middle portion (11; 41), characterized in that the side portions (12; 42) are provided with photo longitudinal ribs (18, 19, 28-30) in their air permeable regions (16; 43) and / or outer wind regions (26; 44) in the longitudinal direction (17) of the spine vent member (10; 40), forming a storage region. such that the spine vent member (10; 40) is extendable laterally. A ridge vent member according to claim 1, characterized in that the outer wind regions (26; 44) have a longitudinal rib (28, 29, 30) adjustable relative to the flow edge (32; 47) away from the roof panel (20). up. Spine vent member according to claim 1 or 2, characterized in that the air-permeable regions (16; 43) of the side portions (12; 42) consist of individual webs interconnected to form a lattice or fabric. The spine ventilation element according to any one of the preceding claims, characterized in that the outer edge regions (26; 44) of the side portions (12; 42) are constituted by the stiffening regions. A ridge vent member according to claim 4, characterized in that the stiffening of the edge regions (26; 44) consists of layering and / or covering the lattice regions with a thin-walled film. 6. The spin vent according to claim 5, characterized in that the film is made of light metal. 7. The spin vent according to claim 5, characterized in that the film is made of plastic. The spine ventilation element according to any one of the preceding claims, characterized in that the fibers of the mesh fabric are made of flexible plastic or metal. Spine vent member according to any one of the preceding claims, characterized in that the spine vent member (10; 40) can be wound. A ridge vent member according to any one of the preceding claims, characterized in that the lower side of the outer edge region (26; 44) of the middle portion (11; 41) and / or the side portion (12; 42) is provided with an activable adhesive surface.