SK34197A3 - Roof structure - Google Patents

Abstract

The construction has a truss with several rafters (2) which have sheathing (4) on them. This sheathing supports a moisture shielding sheet (6). On the sheathing and sheet, directly over and parallel to the rafters are elongated support lamellae (8) of highly compressed mineral wool which run in the fall line of the roof and connected to the rafters. These lamellae accommodate a roof load on the roof parts (10,12) located over them. Insulating material is lain on the damp barrier between the lamellae, It has a concealment on the side facing the roof covering support (10,12) which is open to diffusion, weather resistant and/or waterproof. The concealment is directly and/or indirectly connected with the lamellae.

Description

Technical field

The invention relates to a roof structure for pitched roofs covered with roofing tiles or the like.

BACKGROUND OF THE INVENTION

DE-OS 28 39 767 discloses a roof structure comprising an insulating system which, as an insulating layer, has rollable thermal insulation strips loosely laid on the visor in parallel with the eaves, and at certain intervals are held in position by supporting planks, also parallel to the eaves. On the basis of supporting planks consisting of wood, which are spaced approximately 2 m apart, several interruptions of the thermal insulation layer laid on the visor sheath follow, so that cold or thermal bridges are always formed in the area of the support planks. Also, if the supporting planks were removed, the satisfactory insulating effect of the laid thermal insulation strips would not be given, since then the roof load consisting of its own weight, the snow and wind loads would compress the thermal insulation strips.

DE-OS 34 35 648 discloses a roof construction with a roof thermal insulation system which removes the disadvantage of the cold or thermal bridges caused by the supporting wood planks described in connection with the above-mentioned publication. In this case, it is proposed to lay the strips of insulating material running parallel to the ridge or eaves on the visible shoring, located on the rafters, and supporting strips, for example known from DE-OS 28 39 767, pass between the strips of insulating material. then additional supporting planks extending vertically to the eaves or ridge are nailed and between these further supporting planks are again laid strips or strips of insulating material which extend 90 degrees to the first strips or strips. A lath on the roof covering is then placed on the supporting planks of the second layer of insulating material running vertically relative to the eaves. The transient thermal or cold bridges caused by the support planes are reduced in the subject-matter of DE-OS 34 35 648 to essentially point locations where the supporting planes of the first and second insulating layers cross each other vertically, so that the insulating properties of this The roof construction is considerably improved over the aforementioned file, yet this roof construction has not insignificant disadvantages. The construction of the insulation system is very time-consuming and therefore cost-intensive because of the large number of supporting boards and strips of insulating material, since it is indeed desirable for the roof to double the thermal insulation, namely one insulating layer of the first layer and then. an insulating layer of the second layer extending vertically thereto. Furthermore, this two-layer construction with a large number of required supporting planks results in an undesirable increase in roof weight. Also, from the point of view of the fire protection technique, the consideration of supplementary support plates is disadvantageous.

The problems mentioned in the above-mentioned state of the art in roof construction do not arise according to DE-OS 36 15 109. In this roof structure, the support planes extending between the individual strips of insulating material, which serve as a supporting structure for later loading of the roof, are dispensed with. Instead, on the visor of the rafters placed on the rafters, individual sheets of insulating material, which are provided with diffusion-open but water-impermeable spreading on their upper side, are placed on the visible sheet so that at each longitudinal and transverse edge overlapping or protruding In the sub-region for diffusion of the open lamination, the adjacent boards of the insulating material overlap, so that there is a scaling, water-impermeable, but non-diffusion-open lamination of the entire insulation layer. Directly to this tile, the supporting battens that are running vertically to the ridge and eaves are then laid, which then attach transverse laths for laying the roofing tiles. The fixing of the support plates is carried out by overcharging, through the material of the insulating plates and through the visible shoring to the underlying rafters. This roof construction allows for a full-surface insulation layer without thermal or cold bridges, but insulating boards, because they absorb the total roof load, must have a static resistance of at least 50 KN / m ² and consequently a relatively high density, resulting in not insignificant price increases. roof construction. The required high density of the insulation boards in turn has a negative effect on the possibilities of thermal insulation. In order to achieve a good insulating effect, the thermal insulation boards must be of adequate thickness. However, as the thickness of the thermal insulation boards increases, the total roof load increases. Further, the higher the shear load acting in the direction of the eaves, the thicker the thermal insulation boards are, which results in higher bending moments on the insulation elements of the insulation boards. Finally, such thick boards are also poorly worked, cut, laid.

G 94 17 906.9 discloses a roof construction of roofs covered with roofing tiles such as rafter roofs, roof purlins of roofs, solid roof structures of concrete or similar structures with a supporting sheet attached to rafters with foil insulation against moisture, laid on a carrier sheet, an insulating layer which is laid on the insulation against moisture, and a water-repellent and diffusion-open foil which is separately laid on the covering layer and covers it. The roof structure is characterized in that the insulating layer is constructed of at least two kinds, alternatively individually and parallel to the ridge without the gaps of the laid strips, one type of strips serving to absorb the roof load of the roof elements lying over the insulating layer introduced through the base battens; the tile lath lying thereon, and compared to the second type of strip, which is not loaded and used only for insulating purposes, has a significantly higher pressure resistance and is made several times narrower than the described second type of strip. After the formation of an insulating layer consisting of the above-mentioned two kinds of insulating layer strips which are not yet weather-protected, the above-mentioned water-repellent diffusion-open foil is considered, and the individual base lath strips are pre-drilled in the area of the load strip. through the insulating layer covered with the underlying crossing points of the rafters with carpentry nails. Subsequently, the tile lath is installed transversely to the base lath, and the roofing tiles are placed on them.

However, this roof construction has various disadvantages. Thus, for example, two types of insulating layer strips laid parallel to the ridge are not protected from the effects of weathering during laying or after laying, but must only be additionally covered with a water-repellent, open-diffusion-resistant foil. Since these roofing work requires some time, the insulation layer may be damaged by rain or the like in the meantime. On the basis of the above-mentioned work steps, a longer favorable weather period must also be planned for the construction of the roof structure, which may lead to a not insignificant time delay, depending on the circumstances. Furthermore, both the above-described insulating layer construction as well as the subsequently placed protective foil, which is substantially fixed in position only by the base lath mounted subsequently on the foil, are very susceptible to wind damage, which again makes the construction progress depending on the weather and, in addition, increases the risk of accidents during construction work. The base battens can be recharged at their crossing points with the load-bearing strips, with them and with the underlying rafter crossing points, whereby not only the load concentration at these points results in a load concentration at a small number of highly loaded fixation points , but also a high pressure load on the load strip. Finally, condensation water may accumulate in front of the strips, or water penetrating into the insulating layer, especially due to the running roof strips running parallel to the roof edge, or possibly damaging the roof structure into the insulating layer, which may damage the insulating layer.

It is therefore an object of the invention to provide. a simple and efficient roof structure which far removed the drawbacks associated with the prior art roof structures.

SUMMARY OF THE INVENTION

This object is solved by a roof structure according to the invention with the features of claim 1.

Accordingly, the roof structure according to the invention for pitched roofs or the like, covered with roofing slabs, consists essentially of a truss, comprising a plurality of rafters, a chassis arranged on the rafters, a foil insulation against the support, and a chassis and a foil moisture insulation, directly above the rafters, substantially parallel to them, and in the slope of the roof running and connected to the rafters, longitudinally extending lamellas of highly compacted mineral wool, which absorb the roof load of the roof panels lying above the load-bearing lamellas introduced by the support a roof covering as well as an insulating material laid between the moisture-insulating support slats, with diffusion-open, weather-resistant and / or waterproof laminating, located on the side facing the roofing support arrangement, which is directly or indirectly connected to the carrier plates. For the purposes of the invention, the term roof covering support is to be understood, for example, as a batten for tiles and / or a basic batten which carries the roof tiles or roof tiles. According to the invention, the carrier plate may be composed of a plurality of substantially shorter carrier plate segments, which are aligned in the same manner and which form an individual carrier plate extending substantially over the entire length of the rafter. Shorter carrier plate segments are easier to handle and transport.

The roof structure according to the invention allows the preparation of an uninterrupted layer without local thermal or cold bridges, since with the load-bearing load-bearing lamellas of highly compacted mineral wool and an insulating material laid between the load-bearing lamellas, it is feasible to combine material and components having substantially uniform insulating properties. Due to the load-bearing load-bearing lamellas, the insulating material located between the load-bearing lamellas of the roof structure, with the structure above the insulation layer, is not mechanically loaded, in particular not loaded under pressure, such as simple, soft and relatively thin felt which they can be produced inexpensively and thus contribute considerably to the cost reduction of the overall roof structure. Since the load-bearing strips are arranged directly above and parallel to the roof rafters, the load-bearing strips not only provide a structurally advantageous direct introduction of roof loads into the rafters, but the load-bearing strips extending over the entire length of the rafters are easy, efficient and versatile to the rafters. method, and allow large-scale load dissipation while far-reaching avoidance of local load concentrations. Thanks to this arrangement according to the invention, in addition, the carrier plates themselves can be made of lightweight materials and already. The above-described positive insulating properties, thus reducing the weight of these components, and handling the load-bearing lamellas in the construction of the roof is simplified. As a result of load-bearing strips running parallel to the rafters and along the roof slope, any condensed water accumulated or, due to damage to the insulation layer into the insulation layer, penetrated water or water which has reached the support layer cannot accumulate on the components, but it can easily run down the roof slope. The roof structure according to the invention also has the advantage that even after the insulation elements have been laid between the load-bearing lamellas, a closed, weather-resistant, temporary roof surface is formed. Finally, the roof construction according to the invention, both in the construction of the insulating layer and the finished provisional roof surface, due to the direct or indirect connection of the load-bearing lamellas to the laminating of the insulating material, is very stable under wind action. weather and, moreover, it contributes to increasing occupational safety.

According to an advantageous feature of the embodiment of the invention, the supporting lamella of the roof structure has a substantially vertical standing arrangement of fibers. This arrangement of the fibers favorably affects the high compressive strength of the load-bearing lamellas for picking up or transferring roof loads to the underlying load-bearing rafter, and furthermore permits the fastening element corresponding to the rafter to be pushed through them without appreciably affecting the strength properties of the load-bearing lamella.

For the practical embodiment of the carrier lamellas made of highly densified mineral wool, it has proved to be particularly favorable that the mineral wool material of the carrier lamella has a density of about 25 to 100 kg / m ² .

Another embodiment according to the invention provides that the carrier plate comprises one or more vertically arranged lamellar plates. This has the advantage, in particular, if the carrier plate is made up of several thin lamellar plates for manufacturing reasons. The individual lamella boards may be joined together by suitable joining means, such as tooth joining, gluing, local welding of mineral wool material, mechanical joining means and the like.

According to a further advantageous feature of the embodiment of the invention, it is contemplated that the support strip has at least one extending stiffening beam extending substantially over the entire height of the support strip. The reinforcing partition may be of any suitable material, for example of high density mineral wool, in particular of a higher density than the other mineral wool of the carrier lamella, of wood, in particular plywood or particle board, of expanded or non-foamed plastic, paper, cardboard, gypsum , metal or the like, as well as combinations thereof, and is used to increase the compressive strength and rigidity of the carrier lamella. In particular, however, the reinforcing partition for preventing cold or thermal bridges should have substantially the same insulating properties as the highly compacted mineral wool material of the carrier lamella. The stiffening beam may have relief holes or something similar.

It has proven to be particularly advantageous that the support lamella on its side facing the roof structure, i.e., the roofing structure, i.e. the roofing structure. on the windward side, it has at least one laminated weatherproof and / or waterproof reinforcing strips. This reinforcing strip allows favorable large-area introduction of forces acting on the load-bearing lamella due to roof loads or additional components. In particular, components running through the support lamella crosswise, such as directly on the reinforcing strip of tiled or roofing materials resulting from high local stresses, can be introduced into the carrier lamella through the reinforcing strip without affecting the mechanically more sensitive glass wool material. Furthermore, the reinforcing strip can be used as a connecting means for individual lamella boards.

A further positive embodiment of the invention assumes that the reinforcing strip is formed wider than the carrier strip and projects beyond this lateral overlap. Accordingly, the carrier lamella has a cross-sectional shape which is equal to the T-shaped beam. This not only increases the resistive moment of the carrier lamella, but also allows an insulating material laid between the carrier lamellas for moisture insulation which is usually reversibly deformed due to its consistency. press with their lateral edges below the lateral overhang of the reinforcing strip, thereby fixing it in its position in the simplest manner by a clamping effect. Even when using a substantially rigid insulating material, such as a cured foam or the like, the insulating material can be fixed in this manner. In this case, however, this generally proceeds in such a way that the board-shaped insulating material of a suitable thickness and width is either inserted from the ridge side between two carrier slats and under the overlap of the reinforcing strips, or the supporting lamella is placed first. laterally below the overlap of this support strip, and thereafter, a support strip adjacent to the first support strip and the insulating material plate is mounted above the next rafter, and so the insulating material plate is also fixed under the overhangs of the reinforcing strips of adjacent supporting plates. However, for the sake of simplicity, the above-described insulating material felt is generally the most widely used, since these can be made particularly easy to process.

It has also proved to be advantageous for the reinforcing strip to have fasteners on its end faces facing the longitudinal dimension of the carrier plate. If the carrier plate, as explained above, is composed of a plurality of face-to-face segments of the carrier plates, these connecting elements facilitate the interconnection and the exact positioning of the individual components. For example, groove and / or tongue, claws and the like can be used as connecting elements. Comparable connecting elements can be additionally or alternatively considered at the front ends of the mineral wool material of the carrier lamella. As a connecting element, the abovementioned reinforcement bar is also possible, but extends outwardly through the front side of the carrier lamella, which engaging in a corresponding recess of the carrier lamella segment of the same design can serve to position the aligned segments.

In particular, the reinforcing strip of the carrier lamella is made of wood, in particular a particle board. This material is not very cheap, but can also be well bonded with the mineral wool material of the carrier lamella, or laminated on the mineral wool. In general, however, any other suitable material or appropriate material combination is also contemplated.

For reasons of fire protection technology, it is particularly preferred that the reinforcing strip is made of a fire resistant material. For example, a Pyroex (R) board, which is classified in fire protection class B1, may be used as the reinforcing strip material. Of course, other fire resistant materials are also applicable, even with greater fire resistance and a higher class of fire protection.

A further advantageous feature of the embodiment of the invention provides that the reinforcing strip of the carrier lamella is provided with a foil or fleece weatherproof and / or waterproof lining which comprises hinged overlapping seals with adhesive tape, the contact areas extending substantially parallel to the longitudinal direction of the reinforcing strip. along its free side edges, and the adhesive tapes are connectable with an insulating material laid between side adjacent and parallel running slats for insulation against moisture. Foil or fleece weatherproofing lining not only serves to weathering the reinforcing strip itself, but also, due to its contact overlaps, equipped with adhesive tapes, makes it easy to make a lamination of the insulating material, the contact overlap overlaps the side edges of the insulating material for laminating. Thus, already in the construction of the insulating layer of the roof structure, a rigid and wind-proof connection is made between the load-bearing lamellas and the insulating material, and the finished insulating layer provides a temporary resistant and / or weather protection during the construction phase. Suitably, the overlap adhesive tape material is also weatherproof and / or waterproof. In order to ensure easy packing of the carrier plates for the manufacture of economically transportable packaging units and to avoid damaging the overlap, the workshop overlap is folded onto the reinforcing strip or the sides of the carrier plates so that they do not protrude laterally in this position.

In addition, it has been found to be advantageous that, according to another embodiment of the invention, a further overlap is provided at at least one front end of the reinforcing strip of the carrier lamella, and serves to produce an overlap with the same formed carrier lamellae. This variant is particularly recommended in the method of placing the foil or fleece weatherproof and / or waterproof linings mentioned in the previous paragraph, which can then be formed in one piece. The term "carrier plate", which has such a feature, is also to be understood as a single segment of the carrier plate. A further contact interference is arranged in particular at the lower end, i.e. at the end of the eaves side, of the strengthening strip of the carrier lamella, so that in a plurality of superimposed segments of the carrier lamellas this additional contact interference can be arranged more closely, i.e. closer to the ridge of the carrier lamella. the scaled ridge end of the lower arrangement, i.e. closer to the eaves of the support strip, and thus a more favorable outflow of water is achievable by combining the contact overlap with the foil or fleece lining of the support strip. Furthermore, the further contact overlap can serve as positioning aid and as a provisional fastening means for mounting the carrier lamella segment, for example the contact lap of the already assembled carrier lamella segment, glued to the carrier lamella segment, is intended to be fixed. The fitter now has a free hand to align the last segment of the load-bearing lamella and fasten it according to regulations. Since the load-bearing slats of the roof structure according to the invention, as described above, can be formed with a low weight, a further contact overlap can completely absorb the total weight of the load-bearing slat segment.

An additional advantageous feature of the embodiment of the invention provides that a foil or fleece lining is provided between the carrier plate and the reinforcing strip. This ensures easy and durable fixing of the lining. If the thickness of the insulating material laid between the laterally adjacent and parallel slats is chosen so that it corresponds essentially to the height of the support strip from its bearing surface on the supporting sheeting or the foil insulation to the lower edge of the reinforcing strip, i.e. the upper side The insulating material lies at the same height with the lining, can. not only an effective and durable connection between the insulating layer and the carrier lamella, but also a uniform plane of the insulating layer, which is only overlapped by the reinforcing strips, can be created by means of contact overlaps of the lining provided with adhesive tape. This, in turn, allows the reinforcing strips to be used as a direct bearing surface for roof tile lathing and to dispense with the usually desired basic lathing. This results in low complexity and low cost in the construction of the roof structure according to the invention. Due to the reinforcing strips lying above the plane of the insulating layer, the back ventilation of the roof covering is also good in the above construction method.

Furthermore, it has been found to be advantageous that the foil or fleece lining is arranged on the side facing the support structure of the roof covering, that is to say on the windward side of the reinforcing strip, and this is substantially overlapped. In this case, the lining takes on a dual function, on the one hand, providing a simple and effective weather protection for the reinforcing strip and, on the other hand, providing a weatherproof connection between the carrier plate and the insulating material by means of contact overlaps equipped with adhesive tapes. With a corresponding choice of the thickness of the insulating material laid between the carrier lamellas, this variant can also be used to form a flat insulating layer, the upper side of the reinforcing strip being substantially flush with the upper side of the insulating material. This version is essential at a suitable length of the overlap of the lining, but also applicable in connection with insulating materials of a smaller thickness.

According to a further variant of the invention, the reinforcing strip of the carrier lamella on its side facing the roof tile support arrangement comprises a base batten running substantially parallel to the longitudinal dimension of the carrier lamella. This base batten is preferably formed as an integral part of the reinforcing strip, but can also be placed separately on the reinforcing strip, for example by means of glue, nails, clips or the like. With the support strips having the above-described embodiment, the time-consuming and hence the cost of making the roof can be further reduced according to the invention, since the usually necessary work step of placing the base lath is eliminated. If the carrier plates are comprised of the above-described carrier plate segments, the handling of these components, as opposed to conventional base strips, which normally extend in one piece over the entire path from the ridge edge to the eaves edge, is thus considerably cumbersome, significantly simplified. Also with regard to occupational safety, this should be assessed positively.

An additional feature of the embodiment of the invention provides that the reinforcing strip is provided with a predetermined hole pattern on its side facing the roof support structure to simplify the positioning and positioning of the fastening means of the support slats. This hole pattern, which is preferably considered as shop floor, can give the installer advance fixing points intended to be favorable to the construction of the slats, thus contributing to the high quality of the roof construction, the reproducibility of the roof structure, and the simplification and acceleration of assembly work.

If one or more of the holes of the raster holes are located at a predetermined angle with respect to the plane of the thickened strip in the thickened strip of the load-bearing strip, and / or are at their side facing the roofing support arrangement, recessed with a predetermined cone angle extending substantially up to to the underside of the strip, this facilitates the placement of the fastening means of the load-bearing lamellas on the inclined roof plane in a structurally favorable arrangement. This also has a positive effect on the achieved quality, strength and reproducibility of the roof structure. The predetermined angle or cone angle of the holes can always be matched to the slope of the roof for which the load-bearing strips are to be used.

The load-bearing lamellas are primarily connected to the rafters by means of mechanical fastening elements, whereby the fastening elements absorb the roof load of the roof elements lying above the insulating layer introduced through the load-bearing arrangement. Such mechanical fasteners may be, for example, nails and / or bolts, or combinations thereof, and similar components, which have proved to be particularly suitable, easy to handle and inexpensive fasteners for this purpose. The mechanical fastening elements serve both for fixing the load-bearing strips in the roof structure, as well as for catching and draining or introducing roof loads into the underlying roof rafters. They therefore perform a dual function. The invention is not limited to these mechanical fasteners; on the contrary, any suitable fastener may be used for the intended purpose.

Another advantageous embodiment of the invention provides that the nails and / or bolts are, when viewed from the side of the rafters in the truss pattern, overlaid or screwed over the rafters with the rafters, this overcharging or unscrewing serves to fasten the carrier plates and absorb the roof load the elements lying above the insulating layer introduced through the support arrangement. This embodiment, which can also absorb shear forces, allows a very stable and load-bearing roof structure in a simple and efficient manner. Other equivalent fastening means may be used in place of the nails and / or screws mentioned above.

With respect to the technical aspects of fire protection of the roof structure, it has been found to be advantageous that the supporting structure of the roof structure according to the invention is of fire-resistant material and / or at least on the side facing the space formed by the roof structure has a fireproof layer. Pyroex (R) boards, for example, can be used as a fireproof material.

In this regard, according to a further preferred embodiment of the invention, it has been shown to be advantageous that the support sheeting is essentially made of a particle board whose binder comprises fire-resistant particles.

According to another embodiment of the invention, the insulating material, in each case between the moisture-insulating support lamellas, is made of a strip of insulating material, which is available in the form of a mineral wool felt package with diffusion open lamination covering the mineral wool felt, the insulating material strip only has a laterally protruding edge extending in the longitudinal direction of the strip and a folding contact overlap with the adhesive tape on the insulating material strip. This insulating strip, in conjunction with the roof construction described above, allows an extremely simple and efficient installation of the insulating material between the supporting slats. In order to fill the area between two adjacent and parallel slats with an insulating material, the strip of insulating material is, by means of a suitable separating mechanism, for example a knife, across the longitudinal direction of the strip at a desired width, i.e. a width which substantially corresponds the distance between two adjacent carrier plates, cut off and laid between the carrier plates. The joint overlap of the separated stripe is directed to the roof gutter side so that the edge from the ridge side of the next, lower stripe therefrom can be scaled over this joint overlap, and can be connected to a previously laid stripe by means of an adhesive tape. The procedure is carried out analogously for other strips of insulating material until the area between the two adjacent carrier plates is completely filled with the insulating material. The number of total insulating material strips required for the roof insulation depends, in addition to the size of the roof area, on the width of the insulating material strip used.

It is advantageous to provide the lamination and / or felt of mineral wool across and / or vertically to the longitudinal direction of the strip by means of strip marking. This simplifies the accurate cutting of the insulating material strip section. Marking lines can be made intermittently or at irregular intervals from each other. The lane marking is particularly effective optically. In principle, however, notches on the strip of insulating material can also be used as markings, thus facilitating cutting.

Finally, according to a further feature of the invention, it is contemplated that, in connection with the insulating material strip described above, the insulating layer laid between the moisture-insulating support lamellas is formed from one or more strips separated transversely to the longitudinal direction of the strip overlapping the insulation strip. By means of a clamping effect based on the overlap and consistency of the insulating material, the materials are self-retained between the carrier plates. In this way, the strips can be laid and fastened very easily and quickly between the carrier plates. For conventional insulating material materials such as glass wool or the like, an overlap for clamping effect of, for example, 10 mm is required.

BRIEF DESCRIPTION OF THE DRAWINGS

Advantageous features of the invention are the embodiments as well as the other and advantages of the roof structure according to the following described and explained on the basis of the accompanying drawings which show in FIG. 1 is a schematic cross-sectional side view of a roof structure according to the invention with a first embodiment of a load-bearing strip, FIG. 2 is an enlarged view of section A-A of FIG. 1, FIG. 3 is a schematic enlargement of the detail X of FIG. 1 in the region of the front contact point of the two support plates, FIG. 4 is a schematic perspective view of an insulating material strip used for the roof structure according to the invention; FIG. 5 is a schematic cross-sectional view of a second embodiment of a roof rail according to the invention; FIG. 6 is a schematic cross-sectional view of a third embodiment of a roof rail according to the invention; FIG. 7 is a schematic cross-sectional view of a fourth embodiment of a roof rail according to the invention; Fig. 8 is a schematic cross-sectional view of a fifth embodiment of a roof rail according to the invention; FIG. 9 is a schematic perspective view of a sixth embodiment of a roof rail according to the invention, and FIG. 10 shows a schematic cross-section B-B of FIG. 9th

DETAILED DESCRIPTION OF THE INVENTION

In the following description and figures, the same components are referred to with the same reference numerals to prevent repetition, unless further differentiation is required.

Fig. 1 shows a schematic cross-sectional side view of a roof structure according to the invention for a rafter pitched roof covered with roofing tiles, i.e. roof tiles. This roof structure covering the attic of the house comprises essentially a roof truss with a plurality of parallel and spaced roof rafters 2, with a truss 4 arranged on the rafters 2, with a foil insulation 6 against the trusses. 4, and on the supporting sheet 6 and the moisture-proof foil insulation 6, directly above the rafters 2 arranged substantially parallel thereto and in the slope of the roof extending and connected to the rafters 2, extending longitudinally extending support lamellae 8 of highly compacted mineral wool. The carrier plate 8y associated with each individual rafter 2 is composed of a plurality of 1212 mm long segmented carrier plates 8 arranged in front of one another for ease of assembly handling. For the sake of simplicity, these carrier plate segments are referred to as carrier plates 13 in the following description. The load-bearing slats E3 serve to absorb the roof load of the roof elements lying under the load-bearing slats 8y introduced through the load-bearing arrangement of the roof covering. The roofing support arrangement is to be understood here as the base strips 10, arranged on the load-bearing strips and substantially parallel thereto, and attached to them the strips 12 extending substantially parallel to the ridge of the roof and across the base strips 10 and the load-bearing strips on which roof tiles are laid, that is, roof tiles. The tiles contributing to the roof load are not due to the better overview in FIG. 1.

As shown in FIG. 1, the carrier plates 43 are connected by means of nails 14 to the rafters 2, the nails 14 being overlapped in the lattice pattern through the base strips 10 and the carrier plates 8 to the rafters 2. Instead of nails, screws or special screws that exactly anchor basic lath on the insulating material layer in the rafter. The corresponding slope of the nails or screws is chosen depending on the slope of the roof and the strength properties obtainable by the overrun.

In the interspace between the two adjacent and parallel supporting lamellas 8y, the interspace essentially corresponding to the interspace between two adjacent rafters 2, insulating material strips 16 are laid on the insulation 6. These insulating material strips 16, which have a weather-resistant and weatherproof laminate on the windshield side, i.e. the side facing the roof tiles, are directly or indirectly connected to the carrier lamellae 8a. This will be discussed in more detail later. The insulating layer formed from the insulating material strips 16 and the carrier strips 8y overlaps the overall attic space 18 to be insulated. The roof overhang, for which no insulation is required, is fed from the eaves side to the insulating layer by means of the shutters 20 and the closing eaves board 22.

FIG. 2, which shows an enlarged section AA of FIG. 1, further details of the roof structure according to the invention are apparent. The carrier lamella 8 has a substantially vertical standing arrangement of E fibers as indicated by the thin vertical lines in the drawing. The support strip 8 of FIG. 2 is in this case composed of two vertically arranged and joined together laminated plates 8A, 8B connected by gluing 24. Correspondingly cut URSA (R) insulating material sheets of high density glass wool with a density of approximately 25 to 100 kg / m ³ are used as lamella boards 8A, 8B. Of course, the carrier plate may also consist of only one plate. When using two or more lamella boards, these do not necessarily have the same physical properties.

As shown in FIG. 2 further shown, the load-bearing slats 43 have a weather-resistant and waterproof reinforcing strip 8.2 having the same width as the support strip 8 on the side facing the roof tiles 26, which in the exemplary embodiment is made of a fireproof chipboard. Pyroex (R) (fire protection class BI, fire resistance F30). In general, however, any other suitable material is also applicable. The support strip 43 shown in FIG. 1 and FIG. 2 has a width b1 of about 100 mm and, including the reinforcing strip 8.2, an overall height h1 of about 120 mm.

The reinforcing strip 8.2 of the carrier lamella 8 is on its upper side, that is to say the side facing the base lath 10, already in the workshop equipped with a foil or fleece weatherproof and weatherproof lining 8.4 which covers the reinforcing strip 8.2 over its entire surface. In the following description, this lining is designated as sheet film 8.4. According to FIG. 2, the sheet film 8.4 comprises two overlapping protrusions 8.6 protruding laterally over the lateral edges of the reinforcing strip 8.2 of the carrier plate and extending substantially parallel to the longitudinal dimension of the reinforcing strip 8.2 along its always free lateral edge, which are always provided with adhesive tape on their side facing the rafter. . The adhesive tape is expediently protected from its use by a stripping film or the like.

The insulating material 16, which is laid between two laterally adjacent and parallel supporting lamellas 8 on the insulation 6 against moisture, has one side open for diffusion and basically lathed 10, i.e. facing the winding side 16.2. The thickness of the insulating material 16 in the present case is 120 mm selected so that it corresponds to the height h1 of the support strip 8y including its reinforcing strip 8.2, so that the upper side of the insulating material 16 closely fits with the upper side of the reinforcing strip 8.2 of the support strip 8. the foils 84 are glued to the laminating 16.2 of the insulating material 16 with their adhesive strips, thus connecting the insulating material 16 to the carrier lamella 8y

As shown in FIG. 2, the base batten 10, which in turn carries tile battens 12, is placed separately on the carrier lamella 8y. By means of the above-described lattice overlay 14 over the base batten 10 and the carrier lamella 8, the connection to the rafter 2 is established. 2 noticeable. The load-bearing sheath 4, made of particle board or plank, of the roof structure according to the invention, in the present case for fire protection purposes, is provided with a fire-resistant layer 4.2 on its side facing the attic space 18 formed by the roof structure. Instead of this layer, it is also possible to use a Pyroex® fire-resistant board or a particle board whose binder contains fire-resistant components.

Fig. 3 shows a schematic enlargement of the detail X of FIG. 1 in the region of the front contact point of the two support plates 13. As shown in the drawing, the reinforcing strips 8.2 of the supporting lamellae 8y are arranged side by side without intermediate space, always on their face facing the longitudinal dimension of the carrier lamellae 8y with corresponding connecting elements 28y 30, which allow the carrier lamellas to be connected precisely. In a given embodiment, a tongue-and-groove joint is used.

As shown in FIG. 3 further shown, the sheet film 8.4 of the respective lamella 8; formed by extending over the end of the carrier lamella from the eaves side and forming a further joint overlap 8.8 which flakyly overlaps the sheet film 8.4 of the underlying carrier lamella 8y attaching to this carrier lamina 8. The further joint overlap 8.8 is by its adhesive tape The stripping film, intended to protect the adhesive tape of the further contact overlap 8.8, is expediently designed such that it is removable independently of the strips of the lateral overlap 8.6 of the strip sheet 8.4 of the carrier strip 8.

Fig. 4 shows a schematic perspective view of a mineral wool felt insulation strip R applied to a roof structure according to the invention, from which insulating material strips 16 are formed between two laterally adjacent and parallel running slats 8y placed on top of each other. insulation 6 against moisture. This insulating material strip R, which is available in the form of a bale in the present case, has a one-sided, diffusion-open laminating 16.2 which, in the rolled-up state, points towards the inside of the bale. The insulating material web R furthermore has optically easily recognizable stripe marking 16.4 located on the laminating 16.2 and extending vertically and across the longitudinal direction of the web. The individual marking lines 16.4 of the strip marking, of which for the sake of clarity in FIG. 4, only one is arranged at a distance of 50 mm from one another. In general, any other line spacing, naturally along and / or across, is naturally selectable, but in practice a 50 mm split has proven to be practical. The positioning of the strip marking 16.4 on the laminating 16.2 is advantageous in the above-described laminating arrangement 16.2 within the coiled insulating material strip R, since the marking 16.4 then immediately lies in a position suitable for processing by the user when the insulating material strip R is unfolded. Tagging location

16.4 on mineral wool felt is also conceivable.

The insulating material strip R has, at its lateral edge only, laterally extending longitudinally extending in the longitudinal direction of the strip, and overlapping the overlapping seams 16.6 with the adhesive tape onto the insulating material strip R. Also, this adhesive tape is expediently protected from its use by a release film or the like.

In order to fill the area located between two adjacent and parallel supporting lamellas with insulating material, the insulating material strip 16 is separated transversely to the longitudinal direction of the strip by a suitable separating device, for example a knife 32, the separated width b2 corresponding to the distance between two adjacent by supporting lamellas Q, for example by an overhang of approximately 10 mm. Due to this overlap and the consistency of the insulating material, the insulating material strip 16 can be subsequently fixed in a simple clamping manner by self-retaining between the carrier lamellae. The length of the separated insulating material strip 16 results from the width Rb of the insulating material strip. Laying of the strip of insulating material 16 is preferably carried out from the roof ridge to the gutter. The overlap 16.6 of the separated insulating material strip 16 is directed towards the gutter side of the roof, so that the edge from the ridge side of the next, lower lying strip 16 can be covered in scale with this overlap 16.6 and bonded to the previously laid insulating material strip. The procedure is analogously carried out for further strips of insulating material until the area between two adjacent slats 38 is completely filled with the insulating material. For the remaining sections of the roof, the procedure is analogous.

Fig. 5 shows a schematic cross-sectional view of a second embodiment of a roof rail 13 according to the invention. This variant is essentially identical to that of FIG. 1 and FIG. In contrast thereto, the carrier plate 83 is formed from a single plate. Further, the reinforcing strip 8.2 is wider than the support strip 8 and overlaps it with a lateral overhang U, so that the support strip 83 has a cross-sectional shape that approaches the T-shaped beam. This not only increases the resistive moment of the support strip 83, but The insulating material 16, which is always positioned between adjacent supporting lamellae 3 on the moisture insulation 6, which is usually reversibly deformable by virtue of its consistency, is pushed by its side edges below the lateral overhang U of the reinforcing strip, thereby easing it in its position by the inverse clamping effect. This method of attachment of the insulating material 16 is shown in FIG. 5th

In FIG. 6 shows a schematic cross-sectional view of a third embodiment of a roof structure load-bearing lamella according to the invention. The peculiarity of this embodiment variant, which basically corresponds to the combination of the embodiments according to FIG. 2 and FIG. 5 is that the sheet film 8.4 is disposed between the carrier web 8 and its reinforcing strip 8.2.

Fig. 7 shows a schematic cross-sectional view of a fourth embodiment of a roof rail 8 according to the invention. In this version, the carrier web strip 8.2 includes on its side to the roof tile support arrangement substantially parallel to the longitudinal dimension of the carrier web a running base batten 10. This base batten 10 is in this case itself an integral part of the reinforcing ribbon 8.2. Thus, the placement of a separate base batten may be omitted.

Fig. 8 shows a schematic cross-sectional view of a fifth embodiment of a roof rail 8 according to the invention. This support plate 8 has a reinforcing bar 8.10 extending between two plate plates 8A, 8B over substantially the entire height of the support bar 8y, which serves to increase the compressive strength and stiffness of the support plate 8. The reinforcing bar 8.10 is made to prevent cold or heat The bridges are made of a material having substantially the same insulating properties as the highly compacted mineral wool material of the carrier lamella 8 or 8A, 8B. Here, for example, a lightweight or non-foamed plastic can find its use.

In general, however, the reinforcing partition 8.10 may also consist of other materials, such as high density mineral wool, in particular greater density than other mineral wool material of the carrier lamella 8y of wood, in particular plywood or particle board, paper, paperboard, gypsum board, metal or the like; as well as combinations thereof. The stiffening beam 8.10 is connected by a suitable fastening means, for example by gluing 24, to the lamella plates 8A, 8B of the carrier lamella 8y consisting of a highly compacted mineral wool. The stiffening beam 8.10 also has relief holes in this case. These are shown in FIG. 8 marked 8.12. Instead of one reinforcing partition, a plurality of reinforcing walls may also be used, for example two reinforcing walls which sandwich the lamella plates 8A, 8B in a sandwich manner.

Fig. 9 shows a schematic perspective view of a sixth embodiment of a roof rail 8 according to the invention. In this embodiment, the reinforcing strip 8.2, on its side facing the roofing support arrangement, is provided with a shop pre-formed hole pattern 34, 36 for simplified positioning and positioning of the fastening means of the support slats, for example in relation to FIG. 1 and FIG. 2 of the nails 14 and / or screws described. The hole pattern 34, 36 is already covered in detail with the strip film 8.4 explained in detail, which is only partially shown in the drawing for a better overview.

As shown in FIG. 10, which shows a schematic section BB of FIG. 9, the hole pattern in this case is formed by a plurality of through holes 34 to the plane E of the reinforcing strip in the reinforcing strip 8.2, or through holes with a recess 36 extending to the lower edge of the reinforcing strip positioned at a predetermined angle α. These holes 34, 36 are easily visible through the belt lining 8.4 and the belt lining 8.4 located above the hole 34, 36 can be easily punctured to accommodate the attachment nail 1,4 or screw. Said recess 36 having a predetermined cone angle β may be, as shown in FIG. 10, located on the side of the reinforcing strip facing and / or facing away from the roof tile support arrangement. The relevant angle of inclination of the through holes 34, or the angle of the corresponding β-conical recess 36, ³ and in particular adapted to the pitch of the roof and in relation to FIG. 1 of the overcharging and / or unscrewing barrier pattern described. Instead of the previously described through holes 34, blind holes may also be used in accordance with the invention. This solution is particularly recommended if no belt covering covering holes 8.4 is envisaged. The blind holes, not entirely permeating the reinforcing strip 8.2, then ensure that the lamellar material of the carrier lamella 8 below the reinforcing strip 8.2 is well protected from assembly. The hole pattern 34, 36 explained above is expediently adapted to the shape of the carrier plates 8 and / or their reinforcing strip used 8.2. In the shape of the carrier plates according to FIG. 7, at least a few holes have also been considered in the section of the material forming the integral base lath 10 of the reinforcing strip 8.2, and in the variant of FIG. 8, it is recommended to place holes in the side of the reinforcing partition 8.10. The hole pattern of the invention may have a regular and / or irregular hole pattern.

The invention is not limited to the above-described embodiment, which is merely a general example of illustration. On the contrary, the invention may differ significantly from this embodiment within the scope of protection. The invention is applicable not only to the rafter roof described above, but also applicable to sham roof rafters, purlin roofs, steel purlin roofs, mansard roofs, solid pitched roof structures and similar structures. The height, width and length of the carrier plates or segments of the carrier plates may differ from the above dimensions. Furthermore, the support strip may have other suitable cross-sectional shapes than those explained above. Instead of nails or screws used in the embodiment of FIG. 1, other suitable fasteners, in particular mechanical fasteners, can also be used in the context of the invention, in order to connect the load-bearing slats to rafters or a comparable substructure, and to accommodate the roof load induced by the roof elements and it was transferred to the rafters, or to the substructure. In addition, other insulating materials, such as the mineral wool felt described, for example foam boards or the like, can also be used to form an insulating layer which is located between two adjacent supporting slats.

The reference numerals in the claims, the description and the figures serve only to better understand the invention and are not intended to limit the scope of protection in any way.

Claims (26)

PATENT CLAIMS 1. Roof construction for pitched roofs. or the like, covered with roofing tiles (26), substantially - truss comprising several rafters (2), - supporting shoring (4) arranged on the rafters (2), - moisture-proof foil insulation (6) on the supporting sheet (4), and - on the supporting sheet (4) and the foil insulation (6) against moisture, directly above the rafters (2) arranged substantially parallel to them and in the slope of the roof running and connected to the rafters (2) (14), (8) of highly compacted mineral wool, which absorb the roof load of the roof panels (10, 12, 26) lying above the load-bearing lamellas (8), introduced by the roof structure (10, 12) as well as the insulating material (16), located between each of the moisture-insulating support lamellas (8), with weather-resistant and / or waterproof laminating (16.2) open for diffusion, located on the side facing the roof tile support arrangement (10, 12), which is directly and / or indirectly connected (8.6) to the carrier plates (8). Roof structure according to claim 1, characterized in that the support strip (8) has a substantially upright fiber arrangement (F). Roof structure according to claim 1 or 2, characterized in that the mineral wool material of the carrier lamella (8) has a density of approximately 25 to 100 kg / m ³ . Roof structure according to one or more of the above claims, characterized in that the support strip (8) comprises one or more vertically arranged lamella boards (8A, 8B). Roof structure according to one or more of the preceding claims, characterized in that the support strip (8) has at least one reinforcing beam> (8.10) extending substantially over the entire height (H) of the support strip. Roof structure according to one or more of the preceding claims, characterized in that the support strip (8) on its side facing the roof covering support arrangement (10, 12) has at least one weather-proof and / or waterproof laminated roofing. reinforcement band (8.2). Roof structure according to claim 6, characterized in that the reinforcing strip (8.2) is formed wider than the support strip (8) and overlaps it with the lateral overlap (U). Roof structure according to Claim 6 or 7, characterized in that the reinforcing strip (8.2) has fasteners (28, 30) on its end faces facing the longitudinal dimension of the support strip (8). Roof structure according to one of Claims 6 to 8, characterized in that the reinforcing strip (8.2) is made of wood, in particular particle board. Roof structure according to one of Claims 6 to 9, characterized in that the reinforcing strip (8.2) is made of fire-resistant material. Roof structure according to one or more of the above claims, characterized in that the reinforcing strip (8.2) of the carrier plate (8) is provided with a foil or fleece weatherproof and / or waterproof lining (8.4), which comprises hinged the joints (8.6) with the adhesive tape, the joints (8.6) extending substantially parallel to the longitudinal direction of the reinforcing strip (8.2) along its free lateral edges, and the adhesive strips of the joint overlap (8.6) are connectable to the insulating layer (16) laid between the carrier plates (8) on the insulation (6) against moisture. Roof structure according to claim 11, characterized in that a further contact overlap (8.8) is provided at at least one front end of the reinforcing strip (8.2) of the support strip (8), which serves to create an overlap with the same formed support strip (8). ), which is mounted on said support plate (8). Roof structure according to claim 11 or 12, characterized in that the foil or fleece lining (8.4) is disposed between the support strip (8) and the reinforcing strip (8.2). Roof structure according to claim 11 or 12, characterized in that the foil or fleece lining (8.4) is arranged on the side of the reinforcing strip (8.2) facing the roofing support arrangement (10, 12), and this substantially overlaps the entire surface. Roof structure according to one or more of the above claims, characterized in that the reinforcing strip (8.2) of the carrier lamella (8) comprises, on its side facing the roof tile support arrangement (10, 12), a basic lath (10). extending substantially parallel to the length dimension of the carrier lamella (8). Roof structure according to claim 15, characterized in that the base lath (10) is an integral part of the reinforcing strip (8.2) of the carrier strip (8). Roof structure according to one or more of the preceding claims, characterized in that the reinforcing strip (8.2) is provided on its side facing the roof support structure (10, 12) with a predetermined hole pattern (34, 36) for simplified construction. positioning and locating the fastening means (14) of the carrier plates. Roof structure according to claim 17, characterized in that the one or more holes (34) of the hole pattern are at a predetermined angle (a) to the plane (E) of the reinforcement strip located in the reinforcement strip (8.2), and / or The side facing the roof tile support arrangement (10, 12) is provided with a recess (36) with a predetermined cone angle (β) extending substantially up to the lower edge of the reinforcing strip. Roof structure according to one or more of the preceding claims, characterized in that the support plates (8) are connected to the rafters (2) by means of mechanical fastening elements (14), the fastening elements (14) absorbing the roof load of the roof panels lying above the insulating layer introduced through the support arrangement (10, 12). Roof structure according to claim 19, characterized in that the fastening elements are nails (14) and / or screws. Roof structure according to claim 20, characterized in that. nails (14) and / or bolts, when viewed from a side view of the rafters in the truss pattern, are overrun or bolted over the support strips (8) with the rafters (2), the overrun or bolting serves to fasten the support strips (8) and retaining the roof load of the roof panels over the insulating layer introduced through the support arrangement (10, 12). Roof structure according to one or more of Claims 1 to 21, characterized in that the supporting sheeting. (4) consists of a fire-resistant material and / or at least on the side facing the space (18) formed by the roof structure, it is provided with a fire-resistant layer (4.2). Roof structure according to one or more of Claims 1 to 22, characterized in that the supporting shoring (4) consists essentially of a particle board whose binder comprises fire-resistant particles. Roof structure according to one or more of the above claims, characterized in that the insulating material (16) is always laid between the supporting lamellas (8) for the insulation (6) against moisture, made of a felt insulating material strip (R). mineral wool, available in the form of bales, with diffusion-open lamination (16.2) covering the mineral wool felt, the insulating material web (R) having only laterally extending, extending in the longitudinal direction of the web and onto the web (R) Insulating material folding overlap (16.6) with adhesive tape. Roof structure according to claim 24, characterized in that the lamination (16.2) and / or the mineral wool felt of the insulating material strip (R) is provided with vertical strip marking (16.4) running vertically to the longitudinal direction of the strip. Roof structure according to claim 24 or 25, characterized in that the insulating material (16) laid between the supporting slats (8) for the insulation (6) against moisture is formed by one or more strips (16), separated by an overlap transversely to the longitudinal direction of the strip from the strip (R) of the insulating material, which is a clamping effect based on the overlap and consistency of the insulating material, being self-retained fixed between the carrier plates (8).