RU2052039C1 - Roofing panel for slope roofs - Google Patents

Abstract

FIELD: civil engineering. SUBSTANCE: roofing panel is made of concrete panel and is used as a support for roofing cover. The panel has a reinforcement. The reinforcement has lower belt passing through the panel and a rib projecting over the panel. There are fastening members above upper surface of the panel. The members may be use to secure cross bars as support (lower) structure for roofing cover. EFFECT: labour consumption. 8 dwg

Description

 The invention relates to construction, in particular to roofing panels for sloping roofs.

 Ordinary roofs, in general, have a truss made of wooden hanging rafters and laths, which supports the roofing.

 Such a truss truss with relatively high costs should be made by carpenters. The growing shortage of workers in this specialty and the general desire to rationalize the construction of residential houses strengthens the demand for industrially manufactured roofs.

 From the laid-out description of the application of Germany 3210607 it is known the manufacture of roofing panels for inclined roofs in the form of hollow concrete slabs. Since the roofing shield, in addition to its own weight, also carries the weight of the roofing, as well as the weight of the snow load, the concrete slab must be very thick in order to withstand these loads with appropriate reliability. Therefore, the well-known roofing board is very heavy both during transportation from the factory to the construction site and during installation at the construction site is relatively difficult to maintain.

 The objective of the invention is to obtain a roofing panel for sloping roofs, which has a small dead weight, but despite this has high stability and high load-bearing capacity. At the same time, the roofing shield should be economical in manufacturing, easy and fast to install, and also have good thermal insulation.

 The problem is solved by the fact that the plate is made with reinforcement, which has a continuous inside (through) lower belts and ribs protruding from the plate, and at least a portion of the reinforcement protruding from the plate is made of corrosion-resistant steel or provided with corrosion protection , in addition, the plate between the ribs is respectively coated on the plane with an insulating material and the reinforcement above the insulating material has fastening elements to which the transverse beams can be attached as top (bottom) design for roofing.

 The advantage of the invention is, firstly, that the reinforcement perceives a significant part of the forces acting on the roofing board, so that the slab can be thin-walled and single-layer and, accordingly, can be easily transported and serviced. Secondly, the invention allows you to return in part of the slab to a long-tested structure in the construction of ceilings. While it functions there as a lower formwork for concrete to be poured at the construction site, according to the invention it is modified for use as a roofing panel by the fact that it no longer functions as a formwork shield, but is used as a holder for roofing coverings. In this case, the rest of the usual reinforcement in the form of a lattice truss should be replaced by the same reinforcement with corrosion protection, in particular galvanized reinforcement, and the cavity between the protruding ribs is filled with insulating material. Thanks to this, a roofing shield is obtained, which is self-supporting and can pass without an intermediate support over the entire height of the attic and which no longer requires the usual installation of rafters from girders and rafters. In order for the roofing shield to also have sufficient strength in the transverse direction, the crossbars that are perpendicular to the lower belt are rationally embedded in the slab. Instead, lattice mats can be taken into account.

 It is especially advisable when the reinforcement protruding from the slab passes along the roof slope. At the same time, the lower belt, covered by the plate material, perceives tensile forces, while the upward protruding rib perceives bending moments and compressive forces and at the same time carries fasteners for roofing.

 In order for the protruding parts of the roof to cause small heat losses, it is recommended that the slab in the area of the roof overhang have a transverse slot, filled with insulating material and crossed by reinforcement. For the same purpose, the slab can also have a slot in the area of the wind gable that runs along the roof slope, which must also be filled with an insulator and crossed by reinforcement, which in this case runs across. It is advisable in these two cases, the reinforcement has a lower belt and an upper belt.

 For anchoring the roofing panel, it turned out to be rational for it to have at least one metal supporting surface in its area of contact with the roof overhang, which mates with the supporting wall mounted on the ceiling. This support may have a cylindrical contact surface with a horizontal axis to facilitate the rotation of the roofing board at the desired angle. In addition, the support can be adjusted horizontally and / or vertically, in order, perhaps, to expose the roofing shield.

 In this regard, it is especially desirable when the supporting surface without protruding parts in the groove of the plate enters this support, namely, approximately, in the vertical center of the plate. This simplifies the transportation and storage of roofing shields. In addition, thanks to this, there is only one reference point for each roofing panel, which simplifies its installation as well as alignment.

Suitable fittings are, for example, T-shaped load-bearing elements, the lower belt of which is poured into the slab. But especially rational fitting of lattice-carrier elements in which the edge is formed by a rod member extending obliquely, preferably at an angle of approximately ⁴⁵ ° between the upper and lower belt, because then it is possible to apply the existing installation for manufacture of reinforced prefabricated slabs.

 To fix the transverse load-bearing elements, squares, brackets, eyes or the like can be used. in which the laths are inserted or inserted.

 When using metallic materials, fasteners may be welded; with other materials, screwing or the like is used.

 For the use of roof tiles of various shapes and sizes, it is desirable that the reinforcement at its upper edge or the outer side of its upper belt carry a wooden lath parallel to itself. Due to this, the distance between the transverse load-bearing elements, in particular ordinary laths, can be easily adjusted at the construction site.

 It is also possible to make fasteners so that they themselves function as transverse load-bearing elements. This is an inexpensive option.

 The proposed roofing shield, due to its smooth underside, is particularly suitable for finishing attics. In this regard, particularly high-quality thermal insulation is recommended. To this end, the use of not ordinary insulating mats, but the creation of insulation by direct foaming on the panel, is indicated as particularly desirable. Due to this, the rod elements protruding upward from the panel are optimally covered.

 Often the roof surface is so large that it cannot be blocked by a single roofing shield. In such cases, it is desirable that the roofing board has elements on its lateral sides, in particular concreted metal elements for a strong and compact connection with the adjacent panel. Thus, it becomes possible to form a statically uniform flat system as a roof surface.

 In order to stably support the roofing shields in the ridge zone, the panels in this zone can be made in the form of teeth, so that they overlap there with the counter component and mutually support each other. At the same time, the panels inserted into each other can also be firmly connected to each other using an appropriate bracket or using a coordinated welded base. Both on the ridge and on the sides, the fasteners for connecting to adjacent panels must be so concreted that they are aligned with the outline of the panel. They are made primarily of corrosion resistant materials.

 The proposed roofing shield in the middle zone may also have openings into which a dormer window or a quadrangular dormer window can be inserted or with which a chimney, ventilation pipe or antenna rod can be passed through the lid.

 In FIG. 1 shows a basic sketch of a house covered with roofing shields; in FIG. 2 roof section of roofing shields; in FIG. 3, section AA in FIG. 2; in FIG. 4 and 5 alternative designs of roofing shields; in FIG. 6 section BB in FIG. 5; on Fig. 7 is a bottom view of the welded base, section BB in FIG. 6; in FIG. 8 is a top view of a pullout of a roofing shield in the area of the pediment and overhang of the roof.

 In FIG. 1 is a basic sketch of house 1, whose roof structure is assembled from roofing shields 2. It can be seen that roofing shields 2 can be used both for a simple gable roof and for other forms of the roof (tent roof, etc.).

 In the presented example, several roofing shields 2, which, respectively, as a single part extend from the ridge 3 to the edge 4 of the roof overhang, are located close to each other. However, it is also possible to produce roofing shields that, as a whole, extend across the entire width of the roof.

 In FIG. 1, in one of the roofing shields 2, a quadrangular dormer window 5 is made, and an auxiliary roof 6 of the extension is also attached.

 The fillets (grooves) 7 and 8, respectively, occurring at the junction of the quadrangular dormer-window 5 and the auxiliary roof 6 with the roof shields 2, in contrast to conventional rafter structures, should not be carried out with a separate beam. These beams become redundant due to the self-supporting structure of the roof panel shield 2.

 The roofing shield has a supporting body (see Fig. 2) in the form of a panel 9 (slab) made of concrete or lightweight concrete, which is reinforced in accordance with static requirements and extends mainly in the form of an integral part, from the ridge 3 to the edge 4 of the roof overhang. On the ridge 3, the panel 9 is toothed and rests on its mating part 10 lying on the other side of the roof, and accordingly the protruding tooth on the panel 9 engages with the mating cavity on the part 10 and vice versa. The possible fastening of the panel 9 with the associated part 10 is not shown using a welded base embedded in concrete. At the other end, the panel 9 has at least one concreted metal support plate 11 located in the recess and cooperates with the support shoe 12. To be able to expose the panel 9, the support shoe 12 has a mounting bolt 13, with which the position can be adjusted through the metal plate 11 panels 9.

 The support shoe 12 can be adjusted in the vertical direction to compensate for irregularities in the upper edge 14 of the wall to which the shoe is attached. Usually, the position of the highest located support shoe is selected as the reference (reference) value, and all other shoes are then set on it by installing linings under the shoes.

 For horizontal adjustment, the support shoe 12 is made with a longitudinal hole 15, mating with the anchor bolt 16, made in the edge of the wall 14 or in the ceiling 17. On the anchor bolt 16 there is a nut 18, which presses on the washer 19 provided for the hole. The washer 19 with a geometrical closure is connected to the support shoe 12 using a notch not shown in detail and thus fixes it.

 The upper edge 14 of the wall may (as in the example presented) be closed by a ceiling 17 or the wall may be extended beyond the ceiling 17 and may form a half-floor under the roof supporting the support shoe 12 and thereby the roof. But within the framework of the invention, it is possible to abandon separate adjustable support shoes and instead support them on a steel truss extending over the entire width of the roof, so that only this steel truss needs to be leveled and horizontally installed. As a support, then it is sufficient to have a metal block protruding upward and entering into the corresponding recesses of the concrete panel and mating there with the supporting surface cast in the concrete panel.

The panel 9 is provided with reinforcement from several arranged parallel lattice trusses 20, a lower belt 21 extending respectively inside the panel and is surrounded by concrete panels, and its edge is collected from individual rods 16 which are fixedly welded to the lower belt 21 at an angle of approximately ⁴⁵ ° and protrude from the panel. The lower belts are connected to the transverse rods (not shown), so that the panel is reinforced in the longitudinal and transverse directions.

 At the upper end, the rods 22 carry a straight belt 23 extending in a straight line, onto which the beams 24, which carry a roof covering, are fixed with a rigid distance from each other. The roofing can be made of roofing tiles or other elements that are suspended on crossbars 24 or superimposed on them. With conventional tiling, the cross-beams are formed from ordinary wooden battens. The cross members 24 are nailed to the wooden battens 25, running parallel to the upper belt 17, made in the form of corrugated steel sheet (see Fig. 2 and 3). This design has the advantage that the position of the individual cross members 24 can still change at the construction site.

 In the ridge zone, the roofing shield carries a ventilation pipe 26, which makes a zone under the roofing possible. In addition, the roofing shield carries on the edge 4 of the overhang of the roof a board 27 covering the end of the shield, with the help of which the roofing shield receives an optical finish.

 On the upper side, the panel 9 is covered with an insulating material 28, which is applied mainly by foaming, as a result of which the reinforcing rods 22 are also covered by an insulating material. The insulation layer may extend over the entire height of the ribbed truss, but it may also end below the upper belt 23 in accordance with the physical requirements for the structure.

 As shown in FIG. 2, an insulating insert 29 is attached to the lower end of the insulating layer 28, inserted in the panel 9 and in the area of the roof overhang, and below it is the wall insulator 30. Thus, the house is surrounded by insulation without gaps. Thanks to the insulating insert 29, passing in the zone of support of the panel 9 at the end of the wall 14 over the entire width of the panel, thermotechnical isolation of the part 31 of the panel 9, which is released, is achieved. Thus, the panel 9 cannot remove any heat from the attic through its part 31 into the surrounding space. For the same purpose, the end panels 9 have in the area of the pediment a slot extending in the direction of inclination of the roof, which is filled with insulator 32. In FIG. 6 it can be seen that due to this, cooled roof eaves are effectively isolated from the rest of the roof.

 In both cases, it is essential that the reinforcement passes through insulation 29 and 32 to hold the roof overhangs. In this case, in the case of a roof overhang from the sides where the gutters pass, the existing fittings are still applied. Regarding the overhangs from the pediment, the transverse reinforcement passing through the panel 9 should be concreted. In FIG. 6, parts of the upper belt 33 are respectively visible from it.

 In FIG. 4, another option is proposed for securing the cross members 24. Fasteners for the cross members are welded to the upper belt 23 of the trellis truss 20 at a fixed distance. In the presented example, we are talking about curved steel strips 34 into which the laths passing across (panels) are inserted.

 In FIG. 5 and 6 show an additional embodiment of the roof construction capabilities.

 Using a round steel belt 23 made of round steel, a wooden lath 25 is fixed, which carries a crate 35 functioning as a supporting roof, covered with a layer of roofing cardboard 36. An intermediate lathing 37 is fixed on this roofing cardboard, which again carries cross members 38.

 In the example presented here, the cross-beams shown are made of curved beams made of sheet steel that extend across the entire width of the panel and can be used to hang roofing tiles like ordinary wooden battens.

 The design becomes much more desirable when the upper belt 23 has a U-shaped profile open upwards, into which wooden slats 25 are inserted, onto which the beams 24 are directly nailed. The U-shaped profile can directly function as the upper belt, t .e. replace the old compressed rod. But instead, the U-shaped profile can also be welded to the top belt of the ribbed truss.

 In FIG. 6 and 7, in addition, the joint between two adjacent panels 9 and 39 is shown. To obtain a rigid connection between the panels 9 and 39, both panels 9 and 39 have welded boxes 40 and 41 made on their lateral edges, which fit exactly when the panels are assembled to each other and are joined by their edges end to end, so that they can be firmly connected by a weld seam 42. The cavity open to the inner side of the roof and formed by welded ducts can be additionally plastered.

 To facilitate the work with panels during their installation on rafters, it is recommended to break the insulation near the side edges of the panel. Thanks to this, panels can be better captured and guided by personnel. Also, then, the connecting elements to be welded to each other, for example, weld boxes 40 and 41, will be better accessible. Then, after welding, this insulated area above the joint is filled with insulating material and, finally, the cross members 24, for example ordinary battens, are mounted on the fastening elements of the upper belt. It is advisable to prepare the roofing panel already in the manufacture for further installation of the gutter. For this, the panel 9 in the area of the roof overhang has several fastening elements passing in the transverse direction sequentially one after another, which are coaxially concreted into the panel, it is advisable on its lower side. These fasteners are made primarily of galvanized steel, stainless steel or other corrosion-insensitive materials.

 The present invention allows for extremely economical and quick construction of roofs. Until now, the necessary installation of the rafter system from girders and rafters has been saved, there is insulation made on the roofing panel, which is largely ready already in the manufacture of panels, and there is a flat lower surface of the roofing panel suitable for wallpapering.

Claims (23)

 1. A ROOF SHIELD FOR INCLINED ROOFS, including a panel from the curable material with reinforcement with insulating material laid on its surface and a roof covering, characterized in that the reinforcement extends along the roof slope and has a lower girdle inside the panel and an edge protruding from the panel with the edges above insulating material with fasteners for fastening the cross-beams as a supporting structure for the roofing, and the part of the reinforcement protruding from the panel is made of stainless steel or with corrosion protection and a panel is in place of the bearing at least one metal backing plate mating with a shoe mounted on the wall or on a ceiling, the supporting metal plate is placed in a panel formed in the through hole in the panel and concreted.  2. The shield according to claim 1, characterized in that the panel in the area of the roof slope has a slot extending across the roof slope, which is filled with an insulating insert and crossed by reinforcement.  3. The shield according to claim 1, characterized in that the panel in the area of the wind pediment board has a slot extending along the roof slope, which is filled with an insulating insert and crossed by reinforcement.  4. The shield according to claim 1, characterized in that the supporting shoe has a cylindrical supporting surface with a horizontal axis.  5. The shield according to claim 1 or 4, characterized in that the support shoe is adapted to be adjusted horizontally and / or vertically.  6. The shield according to claim 1, characterized in that the supporting metal plate is located in the vertical middle of the panel.  7. The shield according to claim 1, characterized in that the reinforcement is made of T-shaped beams, in particular of trellised trusses.  8. The shield according to claim 1, characterized in that the reinforcement ribs carry continuous upper belts on which fasteners for the cross members are located.  9. The shield according to claim 1, characterized in that the fastening elements are made in the form of squares, brackets, eyes or the like.  10. The shield according to claim 1, characterized in that the fastening elements are formed by wooden blocks passing along the upper edge of the reinforcement parallel to it.  11. The shield of claim 10, characterized in that the upper belt is made in the form of an open upward U-shaped profile with a wooden block placed in it.  12. The shield according to claim 1, characterized in that the fastening elements are made in the form of cross members.  13. The shield according to claim 1, characterized in that the panel on its sides and / or in the area of the ridge is equipped with connecting elements for rigid and tight connection with adjacent panels.  14. The shield according to item 13, wherein the connecting elements in the panel are tightly concreted and made of corrosion-resistant materials, mainly of metal.  15. The shield according to claim 1, characterized in that the panel in the area of the ridge is serrated.  16. The shield according to claim 1, characterized in that between the fasteners and the cross members is placed extending parallel to the panel lower fixing guide.  17. The shield according to claim 1, characterized in that it passes in the form of a single part from the support on the wall of the house to the ridge.  18. The shield according to claim 1, characterized in that the panel has a thickness of approximately 4 to 7 cm, preferably about 5 cm.  19. The shield according to claim 1, characterized in that the reinforcement rods are located inside the panel, extending transversely to the lower zones.  20. The shield according to claim 1, characterized in that the supporting metal plate is mounted on the lower reinforcement belts or on reinforcing bars extending perpendicular to its lower belts.  21. The shield according to claim 1, characterized in that the panel has concreted fasteners for installing gutters in the roof slope area.  22. The shield according to claim 1, characterized in that the insulation extends only over part of the width of the panel, and the longitudinal edges of the panels extending in the direction of the roof slope remain at least partially free as a grip area during installation.  23. The shield according to claim 1, characterized in that in the middle zone it has an opening for the dormer, quadrangular dormer, or the like.

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