SK284299B6 - Roof ridge sealing strip - Google Patents

Abstract

The invention relates to a roof ridge sealing strip (1) with a central bonded fabrics region (8) permitting air to pass through and two edge regions (8) which can be adapted to the wave shape of the roofing plates (6) and have an elastic stabilisation insert (S); to obtain a particularly easy to lay strip it is proposed that the stabilisation insert (S) take the form of sinusoidal wires (13) or strips (11) running parallel to the edge (10').

Description

Technical field

BACKGROUND OF THE INVENTION The present invention relates to a ridge insulating strip having a central, air-permeable zone having a web-like structure and two longitudinally extending wavy edge strips which are adapted to the wavy shape of the laid roofing tiles by means of a tensile (stretchable) stabilizing insert. the strips are in a pair of connecting zones connected to each other by a connecting strip with a web structure with a gap between the inner edges of the edge strips.

BACKGROUND OF THE INVENTION

The ridge insulating strips of this kind are covered by a roof ridge closure or a ridge forming a ridge and serve to seal the interior space of the roof against rain and flying snow, while the ridge insulating strips adhere to the roofing tiles. A ridge insulating strip of this kind is known from EP-0 341 343, according to which the central ridge insulating strip fits an air-permeable, waterproof and airborne snow-resistant fleece and the outer parts are made of a soft, stretchable foil strip. These foil strips are embedded with expanded metal grids. Furthermore, the edge strips are provided with a self-adhesive layer on the side of the film strip facing the roofing tiles. The production of such a ridge insulating strip proves to be very expensive. Also, ventilation or air diffusion is not optimal in this case.

FR-2 333 913 discloses a deformable strip of elastic synthetic material, intended primarily for sealing the roof at the location of various roof superstructures, for example skylights or windows. It is only marginally related to FIG. 14 also describes a ridge sealing strip of completely different construction, since this strip is divided in the longitudinal axis and thus consists in fact of a pair of strips which are overlapped to the upper side of the roof ridge.

DE-A1-4001766 discloses a ridge vent strip of air-permeable material which adheres along its longitudinal axis to a ridge batt and whose side portions are wavy in shape so that they are twice as long as the central part thereof and can thus be glued to the corrugated roof templates.

US-5,054,254 discloses a corrugated roof ventilation element for ridge roofs. The element has a very complex and thus expensive honeycomb structure.

The closest prior art is a ridge insulating strip as described in EP-PS 117 391. This ridge insulating strip is provided with a pair of longitudinally extending edge strips having a corrugated shape so that the ridge insulating strip can adapt to the corrugated shape of the roof covering. boards. In the central zone of the ridge insulating strip, a connecting region is formed which is not itself corrugated. In the area close to the ridge beam, air passage holes are provided in the connecting area to vent the space of the ridge beam. Said apertures are designed such that moisture coming out of the ridge beam wood can diffuse through them. The contact surface of the connecting area overlaps the ridge beam so that no vapors can be released from this space.

The object of the present invention is to provide a ridge insulating strip which is simpler and more cost-effective to manufacture. It is a further object of the invention to provide a ridge insulating strip construction that allows the ridge beam to be reduced in order to prevent insects and fungi, in particular, from being attacked.

SUMMARY OF THE INVENTION

This problem is solved and the drawbacks of similar ridge insulating strips are largely eliminated by a ridge insulating stripe with a medium, air-permeable zone having a web structure and two longitudinally extending corrugated edge strips which, due to the tensile or stabilizing material of the metal The edge strips are connected to one another in a pair of joint zones by a joint web with a web structure with a gap between the inner edges of the edge strips, according to the invention, characterized in that in the connection zones where the edge strips overlap with the joint strips , the air passageways extending in the width direction are formed.

Due to this embodiment, the ridge beam is permanently ventilated. The moisture contained in the ridge beam no longer diffuses through the holes. Rather, it is air that passes through the air passageways across the longitudinal direction of the ridge beam and can draw moisture directly from the ridge beam surface and take it away by convection. The solution according to the invention is fundamentally different from the moisture transport mechanism described in the prior art, since there the moisture is to come out of the ridge beam, to collect in the intermediate space and then to escape through the apertures through the diffusion path. The moisture removal according to the invention is based on a completely different principle. Air passage ducts are used to allow air to pass through the connecting zone. The air passing through these channels ensures optimum moisture removal, thus preventing insect and fungal attack.

A particularly advantageous simple solution is that the air passageways are formed by the spaces between the longitudinally extending waveguide edge strips and the straight-running connecting strips, so that no special precautions are needed to form said air passageways.

For practical reasons, and also to ventilate the space immediately around the ridge batten, it is preferred that the width of the joint strip substantially corresponds to the width of the ridge batten.

The connecting strip is preferably provided with an adhesive layer on its underside, which facilitates its attachment to the ridge latch.

In this case, the connecting strip abuts against the outer sides of the edge strips, thereby avoiding rain water overflow.

Due to the mechanical strength of the ridge insulating strip, it is further preferred that meander corrugated wires or strips run at the outer edge of its web as a stabilizing insert, which are supported on the web surface with the possibility of changing their meandering pattern. In this connection, it is furthermore advantageous if stabilizing inserts are attached to the edge strips by adhesive beads, which are elastic due to the meandering behavior of the wire.

The actual tensile stabilizing pad may be formed parallel to the web of the meander corrugated wire or perpendicular to the web of the meander corrugated strip, the meander course of the wire having the same meaning as the wavy course of the edge strip.

It is furthermore advantageous, for example, for transport, if the meandering corrugated wire is folded over in the adhesive beads.

From the point of view of the attachment of the ridge insulating strip, it is furthermore advantageous if the connecting strip is provided on its underside along the longitudinal centerline with ridges of compressible material forming fastening points on the ridge lattice. Said bumps are of sticky material and are covered with a cover foil on their surface.

In addition, it is advantageous if the outer sides of the individual edge strips are provided with an elastic protective layer which extends substantially from the outer edge of the edge stripe to the middle of the edge strip.

The assembly of the ridge insulating strip is facilitated and its detachment from the roofing tiles is avoided by providing longitudinal fold lines in the individual edge strips at a distance from the longitudinal centerline of the ridge insulating strip, in which the ridge insulating strip can more easily bend over the ridge insulating strip. Said longitudinal bending lines are preferably formed in the undulating regions of the edge strips and may be formed by forcing the wine depressions to the level of the wine tops.

Further, from a waterproofing point of view, it is preferred that the web is impregnated to achieve water impermeability while at the same time air permeable. Said impregnation may be carried out, for example, with an acrylic resin. Further, the edge webs of the web may be stitched to increase their strength, and the web is undulated in the longitudinal direction in the webs.

Accordingly, the present invention provides a ridge insulating strip which is simpler and more cost-effective to manufacture, wherein the ridge insulating strip, having a width of at least in the edge strips of a longitudinally extensible web, is provided as a stabilizing insert parallel to the edges extending therethrough. or strips which are attached to the nonwoven surface so that it is possible to vary their meandering pattern. This ensures optimal adaptation of the ridge insulating strip to the corrugated shape of the roofing tiles. Due to the simple construction and the low weight of the ridge insulating strip, the ridge insulating strip can be supplied in coils and, unlike the prior art, there is no need to provide the ridge insulating strip in the edge strips with a protective layer which is peeled off before laying. In order to lay such a ridge insulating strip, the ridge insulating strip merely unfolds over the ridge beam and is fastened there with nails or the like. A self-adhesive layer, which is provided with a protective film on delivery, may serve to attach the stabilizing pad. This self-adhesive layer thus fulfills the dual function of fastening for the stabilizing insert and after removing the protective film as an additional seal after laying and pressing the ridge insulating strip on the upper side of the roofing tiles. Such a self-adhesive layer made of rubber or plastic permits the meandering course of the stabilizing pad to be altered and thereby shaped. In a preferred further embodiment, it is envisaged that the attachment takes place by means of a glue which relates only to the region of the meandering ripple. This can be done by means of self-adhesive points which are provided with a continuous protective film when the ridge insulating strip is supplied. This point attachment of the stabilizing insert ensures optimum extensibility of the edge strips. A metal wire meandering in parallel to the web of the web is preferred as a forming stabilizer pad. Such a metal wire is easy to manufacture and is preferably spot-mounted by gluing to the edge strips. The meandering corrugated metal wire is thus considerably deformable and allows optimal adaptation of the ridge insulating strip to the corrugated shape of the laid roofing tiles. As an alternative to the one disclosed herein, the overload stabilizing insert may be formed meandering perpendicular to the nonwoven surface of the corrugated metal strip. It can also be fixed to the edge strips of the ridge insulating strip as described above by gluing. Both when using a meandering corrugated metal wire and using a meandering corrugated metal strip, the ripple amplitude is in the range of 1 to 3 cm.

A preferred further embodiment is that certain areas of the web are impregnated, for example with an acrylic resin, in order to achieve water resistance with simultaneous air permeability. This will allow ventilation of the roof space while sealing against rain and flying snow. According to a further preferred embodiment, the webs are stitched. Finally, the adaptation of the ridge insulating strip to the corrugated shape of the laid roofing tiles is optimized by the longitudinal corrugation of the web edges. Due to this embodiment, the non-woven fabric has increased extensibility in its edge strips.

The central bonding web is formed as 30 to 50 mm, preferably 40 mm wide and 150 to 250 g / m ^2, preferably 190 g / m ² dense fleece. The overhanging zone in the region of the connection between the joint web and the edge web has a width of 10 to 20 mm, preferably 15 mm. The laying of the ridge insulating strip so formed is simply achieved by fixing the ridge insulating strip in the region of its central joint strip to the ridge beam, for example by means of nails, and after removing the protective film from the self-adhesive layer is formed and glued to the roofing tiles. In one of the basic embodiments, it is envisaged that the overlapping connecting strip comprises air passageways extending in the width direction. These are due to the multi-part ridge insulating strip and ensure constant ventilation of the ridge beam. In contrast to the previously known ridge insulating strips, which, without ventilation, cover the upper longitudinal surfaces of the ridge beam over its entire surface, thus creating a high likelihood of attack by insects and fungi due to the high moisture content of the ridge beam, air passage guaranteed moisture content of ridge beam less than 20%. Insect and fungal infestation is thus successfully prevented. The air passageways may be formed by direct contact of the wine ridges in the longitudinal direction of the undulating edge strip to the flat connecting strip. In particular, this can be done in such a way that the flat central connecting strip is spot-glued on the underside to the tops of the wines in the longitudinal direction of the undulating edge strips. In the region of the wine depressions, passage channels are thus created for venting the ridge beam. The width of the joint strip corresponds approximately to the width of the ridge beam, thus achieving optimum ventilation thereof. Furthermore, the advantage is achieved that the ridge fixed on the upper side of the ridge insulating strip in the corner regions of the ridge beam on this ridge beam is compliantly supported by both a corrugated edge strip and a middle connecting strip having approximately the width of the ridge beam. An advantageous further embodiment consists in that the connecting strip is provided with an adhesive layer on its underside. As a result, the ridge insulating strip can be pre-fixed to the ridge by simply hammering. Thus, the staples or nails will only be used in this area after the ridge insulating strip has been completely laid or are not used at all, since the required additional fastening of the ridge insulating strip to the combs is achieved by the fastening means, e.g. Furthermore, the adhesive layer has the advantage with respect to the handling and laying of the ridge insulating strip that in order to eventually align the ridge insulating strip, the ridge insulating strip can be easily lifted again from the ridge beam and its position can be changed. It is further preferred that the joint strip abuts on the upper sides of the edge strips and that the edge strips are provided on the underside near the outer longitudinal edges to be attached to the roofing tiles with adhesive beads. Such a self-adhesive layer made of plastic, for example, allows optimal fixing of the outer longitudinal edges of the ridge insulating strip to the roofing tiles. Adhesive feet may be provided with a continuous protective film when the ridge insulating strip is delivered. This ensures optimal sealing of the roof interior against rain and flying snow. In order to improve the adaptation of the ridge insulating strip to the roofing tiles, meandering metal wire stabilizing inserts are advantageously fixed to the edge strips by means of adhesive beads such that the adhesive beads are fully embedded in the wire, their width being from 10 to 20 mm, preferably 15 mm. Thus, the adhesive beads have a dual function, both as an attachment to the stabilizing insert and, on the other hand, after the protective film has been removed, as an additional seal after laying and pressing the ridge insulating strip onto the top of the roofing tiles. The meandering course of the metal wire may have the same orientation as the wavy course of the edge strip. This provides the possibility of producing both the web and the stabilizing metal wire with a meandering course in one operation, which can be followed immediately by another operation for applying adhesive beads. This technology-optimized solution also provides the advantage that, due to the uniformly oriented wavy course of the metal wire with the edge strips, the undulations of the edge strips are not returned to their original shape during shrinking.

The crimping of the edge strip is stabilized by fixing it in the region of the central strip with a metal wire embedded in the adhesive foot, which provides an optimal possibility of winding the ridge insulating strip. In order for the stabilizing insert to be sufficiently deformable when adapting to the roofing tiles, it is provided that the metal wire is cast over the adhesive feet. When pressed onto the roofing tiles, the metal wire with a meandering profile corresponding to the wavy course of the edge strip is swiveled inside the adhesive foot to a position parallel to the surface of the edge strip. The meandering corrugated metal wire is thus considerably deformable and allows optimal adaptation of the ridge insulating strip to the corrugated shape of the laid roofing tiles. The connecting strip can be provided at its underside on the median longitudinal axis as ridge fastening points with compressible material bumps. These bumps may be formed of an adhesive material and may be provided with a cover film on their upper side. As a result, the ridge insulating strip is at least pre-fixed to the ridge by means of equally spaced ridges in the region of its connecting strip. This is achieved by applying a thumb pressure in the area of the ridge, whereby the compressible material is pushed from underneath the cover foil and connects the ridge insulating strip to the ridge beam. Now, after alignment of the entire ridge insulating strip has been achieved, nails or similar fasteners can be used in the region of the compressible bumps. In the case of the strongly adhesive material of the ridges, the bumps alone are sufficient to fix the ridge insulating strip to the ridge beam.

The sealing of the roof interior against rain or flying snow is optimized by providing the upper side of the edge strip with an elastic protective layer extending from the outer edge of the edge strip approximately in the middle of the edge strip. Thanks to this embodiment, the interior space of the roof is protected against moisture rising and rising away from the roofing tiles. This elastic protective layer may have a color that corresponds to the color of the roofing tiles and ridges, in order to also achieve an optically favorable action of the ridge area. It is also conceivable to provide the ridge insulating strip at a distance from the longitudinal central axis with longitudinal fold lines. The distance from the longitudinal centerline is here about 25 to 35 mm, preferably 30 mm. This prevents the ridge insulating strip from returning to its original position after being adhered to the roofing tiles when, for example, they are soiled. The bending lines also have the advantage that, after laying the ridge insulating strip on the ridge beam, the ridge insulating strip abuts almost automatically on the roofing tiles. This embodiment is also conceivable in ridge insulating strips which are provided with areas of potted wire mesh. The bending lines are preferably located in the ripple region. By means of this measure, the usual rigidity of the ridge insulating strip is achieved in this area as well, and the bending is limited to the desired locations. The longitudinal bending lines may be formed by embossing the wine depressions up to the height of the wine tops. Thus, the web of the ridge insulating strip is formed in a straight line in this region in the longitudinal direction of the ridge insulating strip. It is particularly advantageous that the already wound ridge insulating strip is provided with such bending lines.

BRIEF DESCRIPTION OF THE DRAWINGS

Further advantages and details of the invention are further elucidated on the basis of exemplary embodiments thereof, which are described with reference to the accompanying drawings, which show in FIG. 1 shows a section in the area of a ridge beam to show the arrangement of the ridge, the ridge insulating strip and the roofing tiles; FIG. 2 is a top view of a section of a ridge insulating strip according to a first embodiment of the invention; FIG. 3 shows a section along line III-III in FIG. 2 an edge strip of a ridge insulating strip; FIG. 4 is a section on the line IV - IV of FIG. 2 shows the middle section of the ridge insulating strip; FIG. 5 shows a section along the line V-V in FIG. 2 to a larger scale in the region of the strip serving as a stabilizing insert; FIG. 6 is an enlarged sectional view of FIG. 3 according to the scale of FIG. 5; FIG. 7 is an enlarged view of FIG. 2 in partial cross section in the region of the stabilizing pad; FIG. 8 shows a section along line VIII-VIII in FIG. 7; FIG. 9 shows a representation corresponding to FIG. 7, but relating to the second embodiment; FIG. 10 is a section on the X-X plane of FIG. 9; FIG. 11 is a view corresponding to FIG. 5, but relating to the second embodiment; FIG. 12 is a view corresponding to FIG. 7 relating to the third embodiment; FIG. 13 is a section along the line XIII - XIII of FIG. 12; FIG. 14 is a view corresponding to FIG. 5 according to the embodiment of FIG. 12; FIG. 15 is a cross-sectional view of the ridge area to illustrate the arrangement of the ridge, the ridge insulating strip and the roofing tiles; FIG. 16 is a plan view of a section of a ridge insulating strip according to the invention relating to a fourth embodiment; FIG. 17 is an enlarged view of FIG. 16 in the region of the stabilizing pad but with a view of the underside of the ridge insulating strip; FIG. 18 is a section on the line XVIII-XVIII of FIG. 17 shows an extreme portion of the ridge insulating strip to show a stabilizing pad embedded in the adhesive foot; FIG. 19 is an enlarged view of the view of FIG. 15 in the area of the ridge beam; FIG. 20 is a view corresponding to FIG. 16, but relating to the underside of the fifth embodiment; FIG. 21 is a section on the line XXI - XXI in FIG. 20 is an enlargement of the attachment point of the ridge beam; FIG. 22 is a section along line XXII - XXII of FIG. 20 with the extreme part of the ridge insulating strip; FIG. 23 is a view corresponding to FIG. 21, but after fixing the ridge insulating strip to the ridge beam; FIG. 24 is a section corresponding to FIG. 22, but after adapting and pressing the edge strip of the ridge insulating strip to the roofing tile; FIG. 25 is an enlarged top view of the ridge insulating strip after pressing the ridge insulating strip onto the roofing tile; FIG. 26 is a view corresponding to FIG. 20, but relating to another embodiment; FIG. 27 is a section along line XXVII - XXVII of FIG. 26; FIG. 28 is a section along line XXVIII - XXVIII of FIG. 26 and FIG. 29 is a view corresponding to FIG. 23, but relating to the embodiment of FIG. 26th

DETAILED DESCRIPTION OF THE INVENTION

As shown in FIG. 1, the ridge insulating strip 1 according to the invention serves to seal the interior space 2 of the roof against rain and flying snow, while the construction of the ridge insulating strip 1 is chosen to simultaneously ventilate the interior space 2 of the roof. The ridge insulating strip 1, supplied, for example, in the form of a coil, is unfolded on a ridge beam 4 attached to the rafter 3 and fastened there, for example by nails. The edge strips 9 of the ridge insulating strip 1 are adapted to the corrugated shape of the roofing tiles 6 attached to the roof battens 5 fixed to the rafter 3. After forming the ridge insulating strip 1 to the roofing tiles 6, a ridge 7 is formed which forms the ridge closure.

The ridge insulating strip 1 consists of a central web 8 with a web of air permeable structure and two stitched edge strips 9. The ridge insulating strip 1 is impregnated, for example with an acrylic resin, to achieve water-tightness with simultaneous air permeability.

The ridge insulating strip 1 shown in the first embodiment of FIG. 2 to 8 and in the second embodiment of FIG. 9 to 11, it is undulated at its edge strips 9, i.e. the web 10 is undulated perpendicular to its surface, as shown in FIG. 3 and 6. Thus, the ridge insulating strip 1 is stretchable in its edge strips 9.

In the edge strips 9, the web 10 is provided with an elongate stabilizing insert S running parallel to the outer edge 10 'of the web 10, which is formed by a meandering corrugated strip 11 of metal, the meandering shape of this strip 11 corresponding to the corrugated edge strip 9 of the nonwoven. 11 of metal is arranged on the offset side of the web 10, i.e. on the side facing the roofing tiles 6, as can be seen in FIG. 5. To reinforce the meandering corrugated strip 11 of metal, uniformly spaced adhesive points 12 are applied on the support side of the web 10 at the same time, which partially enclose the meandering corrugated strip 11 and thereby fix the meandering corrugated strip 11 to the web 10. It consists of a self-adhesive rubber or plastic which is provided on the underside with a removable protective film (not shown in the drawings) on the roof tile 6.

Different from this embodiment, in the second embodiment of FIG. 9 and 11, an elongate stabilizer insert S constructed as a meandering corrugated wire 13 of metal. The meandering corrugation is parallel to the web of the web 10. This meandering corrugated wire 13 has a plan view in FIG. 9 an amplitude Z of about 1 cm. In addition to the corrugated meander ripple running parallel to the web of the web 10, the meander corrugated wire 13 is also adapted to the wavy course of the edge web 9 of the web 10, as shown in FIG. The tension stabilizing insert S thus formed is also fixed to the web 10 by means of adhesive points 12 on the offset side of the ridge insulating strip 1. Due to this construction, the ridge insulating strip 1 in its edge strips 9 is optimally adapted to the corrugated shape of the laid roofing tiles 6.

In the third embodiment shown in FIG. 12 to 14, the web 10 is provided with flat edge strips 9. Also here, the web 10 is provided on its edge strips 9 on the underside, i.e. on the abutment side, parallel to the web surface running through the meandering corrugated wire 13 of metal. already mentioned, it is fixed by means of adhesive dots 12, as is also evident from FIG. 14th

In all exemplary embodiments, by partially casting the overload stabilizer pad S, made either parallel to the web of the web 10, a meandering corrugated metal wire 13, or perpendicular to the web of the web 10, is a meandering corrugated metal web 11 by means of adhesive points 12 in conjunction with the edge strips 9 of the web 10 ensure optimal adaptation of the ridge insulating strip 1 to the corrugated shape of the laid roofing tiles 6.

The ridge insulating strip 1 is fastened to the upper side of the ridge beam 4 in the region of its central joint strip 8, for example by means of nails. After removal of the protective film overlapping the adhesive points 12, the edge strips 9, provided with an elastic stabilizing insert S intended to be laid on the roofing tiles 6, adapted to the wavy course of the roofing tiles 6. The adhesive points 12 serving to attach the stabilizing inserts S to the web 10 are As already mentioned, it is designed as a self-adhesive layer and now also serves to fix the edge strips 9 to the roofing tiles 6.

The passage ventilation of the roof interior space 2 while attaining the watertightness is made possible by the gap remaining between the ridge 7 and the edge portion 9 of the ridge insulating strip 1, as shown by the arrow x.

The ridge insulating strip 1 shown in FIG. 15-29, it is also unfolded onto a ridge batt 40 attached to the rafters 30 and fixed there. The edge strips 90 of the ridge insulating strip 1 are adapted to the corrugated shape of the roofing tiles 60 attached to the roof battens 50 attached to the rafter 30. After forming the ridge insulating strip 1 onto the roofing tiles 60, the ridge 70 forming the ridge closure is mounted.

The ridge insulating strip 1 consists of two edge strips 90 connected to each other by a central web formed by a bonding strip 80. The edge strips 90, which allow air passage, are formed with a web structure and impregnated with acrylic resin to achieve water tightness while permeability in air . In order to protect the interior roof space 20 against the moisture rising in FIG. 15 against the arrow x, the outer sides 100 of the edge strips 90 are provided with an elastic protective layer 110 extending from the outer edge edges 120 of the edge strips 90 to about the middle of the edge strips 90. The edge region A thus formed is shown in FIG. 16-20. The optically favorable effect of the ridge region is achieved in that said protective layer 110 is colored in color to correspond to the roofing tiles 60 and the ridges 70.

The edge strips 90 are connected to each other by means of the connecting strips 80 such that the inner edges 130 of the edge strips 90 are opposed to one another forming a vent area B of the ridge batten 40. The connecting strips 80 have a width of 40 to 60 mm, preferably 45 mm. the width of the ridge batten 40, as a result of which the bonding zone C between the bonding band 80 and the edge band 90 is about 10 mm. The air-permeable zone D extends in the central part of the ridge insulation strip 1 between the two edge regions A.

The bonding strip 80 comprises air passageways 140 extending therethrough at its extending bonding zone C in the width direction. These arise from the direct application of the corrugated wave tops 90 of the edge strips 90 formed perpendicularly to the surface of the edge strips 90 to the underside of the flat connecting strip 80, as shown in FIG. 18 and 22.

The edge strips 90 are provided on their underside, i.e. after laying the ridge insulating strip 1 on the side facing the roofing tiles 60 and thus on the side facing away from the connecting strip 80, near the outer edges 120 with adhesive beads 150 for adhering to the roofing tiles 60 These adhesive beads 150 may be in the form of a self-adhesive rubber mass or plastic which is covered on its underside with a removable protective film (not shown in the drawings) on the roofing tiles 60.

The adhesive stabilizer inserts S, which in the embodiment shown in FIG. 15 to 19 formed parallel to the surface of the edge strip 90 by a meandering corrugated wire 160 of metal. Due to this modification, an optimum adaptation of the ridge insulating strip 1 in the region of its outer edges 120 to the corrugated shape of the laid roofing tiles 60 is achieved.

In the embodiment shown in FIG. 20 to 25, the meandering waveform of the metal wire 160 when delivering the ridge insulating strip 1 has the same direction as the wavy course of the edge strip 90. This embodiment has the advantage that both the edge strips 90 and the metal wires 160 can be rolled simultaneously in one a working operation to which a further working operation for applying glue beads 150 can be immediately followed. Only after pressing the edge strip 90 onto the roofing tile 60, does the metal wire 160 embedded in the adhesive bead 150 turn into a position parallel to the surface of the edge strip 90, as shown in FIG. 24th

The width of the bonding strip 80 is selected to approximately match the width of the ridge batten 40, as shown in FIG. 19. The underside of the bonding strip 80 of the first embodiment is continuously provided with an adhesive layer, not shown, which serves both to bond between the bonding strip 80 and the two edge strips 90 in bonding zone C and provides pre-fixing when laying the ridge insulating strip 1 on With this adhesive layer, the ridge insulating strip 1 can be simply fixed to the ridge late 40 by a hammer strike, so that it is not necessary to use staples or nails. The ridge insulating strip 1 can therefore be easily lifted again from the ridge batten 40 and re-fixed in a new position, if necessary, if necessary. Fixation of the ridge insulating strip 1 to the ridge lattice 40 by means of an adhesive layer occurs in the vent area B of the ridge beam 40, and the individual fastening points 180 of the ridge batten 40 are spaced apart at a certain distance to guarantee the desired venting of the ridge batten.

An alternative method of fixing the ridge insulating strip 1 to the ridge late 40 is shown in another embodiment. The connecting strip 80 on its underside in the central longitudinal axis is provided as a fastening point 180 on the ridge late 40 by a ridge 190 formed of a compressible material, as shown in FIG. These bumps 190 are formed of an adhesive material and have a top sheet 200 on their upper side. The ridge insulating strip 1 is only compressed in the region of the ridge 190 by the thumb against the ridge late 40 for fixation, so that the compressible ridge 190 is pushed out underneath the cover film 200 and adhering to the ridge late 40, as shown in FIG. 23. Depending on the adhesive strength, this measure may serve as a pre-fixation or also as a self-locking of the ridge insulating strip 1.

By providing a ridge insulating strip 1 with a central flat joining strip 80, which in the region of the two joining zones C is connected to the edge strips 90 to form air passageways 140, the ridge insulating strip 1 serves not only to insulate the interior space 20 of the roof against rain and flying the snow while venting the roof interior space 20, but also for the constant ventilation of the top side 170 of the ridge battens 40, thereby ensuring a moisture content in the ridge late 40 of less than 20%. This is particularly important against insect and fungal infestation. The air flow for venting the ridge batten 40 is shown in FIG. 19 marked with an arrow y. For optimum ventilation of the ridge battens 40, the ridge insulating band 1 is fixed only on the ridge lattice 40 in the region of its joint band 80, either by applying glue on the underside in the form of connecting strips or in the form of ridges 190, or staples or the like.

Due to the multi-part construction of the ridge insulating strip 1, the ridge insulating strip 1 is easily laid after fixing to the ridge lattice 40 without external interference on the roofing tiles 60, thereby forming and adhering to these roofing tiles 60 without prestressing. After removal of the protective film overlapping the adhesive beads 150, the edge strips 90 to be laid on the roofing tiles 60 are provided with an extensible and in one embodiment foldable stabilizing insert S adapted to the wavy course of the roofing tiles 60. The adhesive beads 150 serve to attach As already mentioned, the stabilizing inserts S to the edge strips 90 are designed as a self-adhesive layer and now also serve to fix the edge strips 90 to the roofing tiles 60.

The passage ventilation of the roof interior space 20 while attaining waterproofness is made possible by the gaps between the ridge 70 and the edge strips 90 of the ridge insulating strip 1 in the region of the hollows of the roofing tiles 60, as indicated by the arrow x in FIG. 15th

The exemplary embodiment shown in FIG. 26 to 29 has longitudinal fold lines 210 on both sides of the longitudinal centerline of the ridge insulating strip 1. These are arranged in the crimping region of the edge strip 90 at a distance of about 20 mm from the outer edge of the connecting strip 80. peaks of 230 wines. As can be seen in particular from FIG. 29, the self-folding of the edge strips 90 in the direction of the roofing tiles 60 is thus achieved. The longitudinal bending lines 210 are the locations where a break is required, which also have the advantage that after the edge strips 90 have been glued to the roofing tiles 60 against returning these edge strips 90 to their original position, which may occur in particular with dirty roofing tiles 60 on which the adhesive is less well held.

Claims (21)

PATENT CLAIMS A ridge insulating strip having a central, air-permeable zone having a web structure and two longitudinally extending wavy edge strips, which are adapted to the wavy shape of the laid roofing tiles by means of a stretchable stabilizing insert of metal or similar material, the edge strips the bonding zones connected to each other by a bonding web with a web structure with a gap between the inner edges of the edge strips, characterized in that in the bonding zones (C) where the edge strips (90) overlap with the bonding web (80), width of the ridge insulating strip (1) of the running air passageways (140). Ridge insulating strip according to claim 1, characterized in that the air passageways (140) are formed by spaces between the longitudinally extending edge strips (90) and the straight running strip (80). Ridge insulating strip according to any one of the preceding claims, characterized in that the width of the joint strip (80) substantially corresponds to the width of the ridge batten (40). Ridge insulating strip according to one of the preceding claims, characterized in that the connecting strip (80) is provided with an adhesive layer on its underside. Ridge insulating strip according to any one of the preceding claims, characterized in that the connecting strip (80) abuts the outer sides (100) of the edge strips (90). Ridge insulating strip according to one of the preceding claims, characterized in that meandering corrugated wires (13) or strips (11) are provided as a stabilizing insert (S) at the outer edge (10 ') of its web (10). the nonwoven surface (10) deposited with the possibility of changing its meandering pattern. Ridge insulating strip according to one of claims 1, 2, 5 and 6, characterized in that stabilizing inserts (S) are attached to the edge strips (90) by adhesive beads (150), which are due to the meandering course of the wire (160, 160). ') overloading. Ridge insulating strip according to one of claims 6 or 7, characterized in that the elongate stabilizing insert (S) is formed parallel to the web of the web (10) by a meandering corrugated wire (13). Ridge insulating strip according to one of claims 6 or 7, characterized in that the elongate stabilizing insert (S) is formed perpendicularly to the nonwoven surface (10) by a meandering corrugated strip (11). Ridge insulating strip according to one of Claims 6 to 9, characterized in that the meandering course of the wire (13, 160 ') has the same meaning as the wavy course of the edge strip (90). Ridge insulating strip according to one of Claims 5 to 10, characterized in that the meandering corrugated wire (13, 160 ') is pivoted in the adhesive beads (150). Ridge insulating strip according to one of the preceding claims, characterized in that the connecting strip (80 ') is provided on its underside along the longitudinal centerline with compressible material ridges (190) forming fastening points (180) on the ridge latch (180). 40). Ridge insulating strip according to claim 12, characterized in that the bumps (190) are made of an adhesive material and are covered on their surface with a cover foil (200). Ridge insulating strip according to one of the preceding claims, characterized in that the outer sides (100) of the individual edge strips (90) are provided with an elastic protective layer (110) which extends from the outer edge (120) of the edge strips (90). substantially in the middle of this edge strip (90). Ridge insulating strip according to one of the preceding claims, characterized in that longitudinal fold lines (210) are formed on the individual edge strips (90) at a distance from the longitudinal central axis of the ridge insulating strip (1). Ridge insulating strip according to claim 15, characterized in that the longitudinal fold lines (210) are formed in the undulating regions of the edge strips (90). Ridge insulating strip according to either of claims 15 or 16, characterized in that the longitudinal fold lines (210) are formed by pushing the wine depressions (220) down to the level of the wine tops (230). Ridge insulating strip according to any one of the preceding claims, characterized in that the web (10) is impregnated to achieve water impermeability with simultaneous air permeability. Ridge insulating strip according to claim 18, characterized in that the web (10) is impregnated with an acrylic resin. Ridge insulating strip according to either of claims 18 or 19, characterized in that the edge strips (9) of the web (10) are stitched. Ridge insulating strip according to one of the preceding claims, characterized in that the web (10) is undulated in the longitudinal direction in the edge strips (9).