PL70325Y1 - Profiled sheet for roof covering - Google Patents

Description

PL 70 325 Y1 2 Description of the design The subject of the utility model is a profiled sheet for roofing. The utility model covers profiled sheets used as roofing that have a particular shape in the direction of the roof ridge, that is, sheets profiled in the transverse direction. Profiled sheets used as roofing almost exclusively have a shape perpendicular to the direction of the roof ridge, which, in this context, is referred to as the longitudinal profiling. This serves as a water channel, a stiffening of the shape of the profiled sheet, and/or as a means of connecting the joints between adjacent profiled sheets in the direction of the roof ridge. This longitudinal profiling often gives the profiled sheet the shape of a so-called corrugated sheet, having a plurality of folds extending in a direction perpendicular to the roof ridge. Profiled sheets are often manufactured from rolled steel strip of standard width. The effective width that can be achieved will depend on the selected profile shape and the overlap of adjacent profiled sheets. It is well known that the overlap of profiled sheets used for roofing, adjacent to each other towards the roof ridge, is performed so that the lateral edges of the profiled sheets adjacent to each other towards the roof ridge overlap by at least one fold. In other words, the outermost folds of adjacent profiled sheets will be positioned on top of each other, i.e., they will overlap, thereby providing support towards the roof ridge between adjacent profiled sheets and a straight joint between the profiled sheets. A disadvantage of this prior art solution, regarding the effective width achieved, is the overlap of the sheet material used in this joint. Also well known is a cross-profiled profiled sheet, where the cross-profiling has a shape, when viewed from above the roofing surface, that is, the offset of the profiled sheet is shaped without any profiling towards the edge, when viewed from above the roofing surface. This prior art technology attempts to solve this disadvantage by shaping the joint between the profiled sheets, abutting each other towards the roof ridge, so that the profiled sheets overlap only by less than half the width of the fold. However, a disadvantage of this prior art technology is that it provides poor support for the profiled sheets towards the roof ridge, as the joints between adjacent profiled sheets provide a weak supporting effect. Thus, the support towards the roof ridge of the profiled sheets is based solely on the shapes of the longitudinal profiling and the support provided by any fastening screws. The purpose of the utility model is to address the shortcomings of the prior art and provide a profiled sheet while maintaining significant support towards the roof ridge. According to the utility model, the profiled sheet forming the roof covering surface has a longitudinal profiling extending towards the first and second side edges, which longitudinal profiling comprises folds having a complete ridge portion and two downwardly sloping surfaces from the complete ridge portion of the fold. At the second lateral edge, in the transverse direction of the profiled sheet, the longitudinal profiling of the profiled sheet terminates in a complete fold, and at the first lateral edge it terminates in a partial fold comprising a fragmentary ridge portion of the fold and only one descending surface of the fold, for forming a joint extending towards the lateral edges of adjacent profiled sheets. Furthermore, the profiled sheet has at least one transverse profiling extending towards the upper and lower edges, having a particular shape when viewed from above the roofing surface. The profiled sheet is characterized in that the shape of the transverse profiling extending towards the upper and lower edges when viewed from above the roofing surface is wavy and has support towards the ridge between adjacent profiled sheets. The partial fold of the first lateral edge has a width (W2) less than half the width (W1) of the complete fold, i.e. W2 < (W1/2). At the second lateral edge, the complete fold of the longitudinal profiling comprises a complete ridge portion, and from the complete ridge portion extend two falling surfaces, one of which constitutes the other lateral edge of the profiled sheet. PL 70 325 Y1 3 At the first lateral edge, the partial fold of the longitudinal profiling consists of a fragmentary ridge portion and only one falling surface. The shape of the transverse profiling, extending towards the upper and lower edges, in a plan view of the roofing surface, comprises support portions, approximately parallel to the lateral edges, for additional support towards the ridge of adjacent profiled sheets. The support portions of the transverse profiling extending towards the upper and lower edges, in a plan view of the roofing surface being approximately parallel to the lateral edges, are located on the falling surfaces of the folds of the longitudinal profiling. The partial fold of the longitudinal profiling provides a path for water. The utility model provides stable support when two or more profiled sheets are connected together in the ridge direction. This support compensates for the weakening of the support in the ridge direction caused by the partial overlap of the profiled sheets adjacent to each other in the ridge direction. Furthermore, in the region of the lateral edges of the profiled sheet, the shape of the longitudinal profiling of the profiled sheet, comprising a transverse profiling in a plan view of the roofing surface, the sheet is shaped to enable the profiled sheets adjacent to each other to overlap in the direction of the roof ridge, such that the folds of the longitudinal profiling only partially overlap. Thus, a greater effective width and improved support in the direction of the roof ridge of the adjacent profiled sheets are achieved. Surprisingly, it has been observed in this utility model that a sufficient level of weather resistance of the joint between the profiled sheets is achieved with partial overlap when the profiled sheets are designed in accordance with the utility model. Thanks to the transverse profiling shape of the profiled sheet, excellent support is provided towards the roof ridge, which minimizes potential movement of the sheets forming the joints perpendicular to the roof ridge and improves the conditions leading to reduced overlap of the joint sheets. Furthermore, the transverse profiling shape of the overlapping profiled sheets ensures an excellent fastening effect during the installation of adjacent profiled sheets. According to the utility model, the technical effective width of the profiled sheets can be increased for the same width of steel strip, which, as a technical solution, reduces the amount of sheet material used for the roofing surface. The subject matter of the utility model is illustrated in an embodiment in the drawing, in which: Fig. 1 shows a profiled sheet according to the utility model; Fig. 2 shows, in more detail, the shape of the transverse profiling of the profiled sheet according to the utility model; Fig. 3 shows a partial fold at a first lateral end of the profiled sheet according to the utility model; Fig. 4 shows a joint between the profiled sheets according to the utility model; Fig. 5 shows a front view towards the roofing surface of the longitudinal profiling of the profiled sheet according to the utility model. Fig. 1 shows a profiled sheet 1 according to a utility model, comprising a longitudinal profiling 4 having folds 12 which extend towards the first and second side edges 2, 3, and a transverse profiling 7 shaped, in a plan view of the roofing surface 9, as extending towards the upper and lower edges 5, 6. In other words, the transverse profiling 7 is not straight in a plan view of the roofing surface 9, but has, for example, a wavy shape. The profiled sheet 1 according to the utility model is formed from sheet metal, in particular from coated steel sheet with a thickness of 0.4 - 1 mm. The shape of the longitudinal profiling 4 is shown in Fig. 5, where the longitudinal profiling 4 consists of upwardly directed complete folds 12 ending, in the transverse direction T of the profiled sheet 1, in the falling surfaces 17 of the folds 12. The longitudinal profiling 4 extends towards the side edges 2, 3. The complete folds 12 of the longitudinal profiling 4 are of identical shape, except for the side edges 2, 3 of the profiled sheet 1. The end folds 12 of the longitudinal profiling 4, in the transverse direction T of the profiled sheet 1, end in a special way at the side edges 2, 3 of the profiled sheets 1, because the outermost folds form a joint 15 between the adjacent profiled sheets 1 towards each other towards the roof ridge. At the joint 15 between the profiled sheets 1 abutting each other towards the roof ridge, shown in Fig. 4, it can be seen that at the side edges 2, 3 of the profiled sheet 1 the longitudinal profiling 4 in the transverse direction T of the profiled sheet ends in such a way that at the second side edge 3 the fold 12 of the longitudinal profiling 4 is complete and comprises a complete ridge part 18 of the fold 12 and two sloping surfaces 17 directed downwards from this complete ridge part 18 of the fold 12, one of which sloping surfaces 17 constitutes the second lateral edge 3 of the profiled sheet 1. At the first side edge 2, the fold of the longitudinal profiling 4 is a partial fold 13, in the sense that the partial fold 13 is incomplete. In other words, the partial fold 13 comprises a fragmentary ridge portion 19 of the fold and only one falling fold surface 17, not both. This falling fold surface 17, situated at the first lateral edge 2, does not constitute the first lateral edge 2 of the profiled sheet 1, the first lateral edge 2 being formed by the fragmentary ridge portion 19 of the fold. The width W2 of the partial fold 13 is less than half the width W1 of the complete fold 12, i.e. W2 < (W1/2), as a result of which, according to the utility model, a greater effective width is achieved with the same web width. In other words, in the joint 15 between the profiled sheets according to the utility model, the partial fold 13 does not extend beyond the centerline H of the complete fold 12. The partial fold 13 has a water path 14 at the first lateral edge 2 which collects capillary rising water in a controlled manner. The water path 14 is formed in the partial fold 13 such that the water path 14 is not located directly on the edge of the profiled sheet 11, so that the partial fold 13 comprises a portion rising upwards from the water path 14, as shown in Fig. 4. Fig. 3 shows an example of an embodiment of a partial fold 13 of a profiled sheet according to the utility model, in which fold the water path 14 has been formed. In this embodiment, the partial fold 13 terminates in the waterway 14. In the joint 15 between the profiled sheets, the descending surface 17 of the partial fold 13 will be positioned in close contact with the lower surface of the complete fold 12 of the second profiled sheet. In the joint 15 between the profiled sheets, according to the utility model, the profiled sheets 10, 11 are overlapped over an area smaller than half the width (W1) of the fold, so that the complete fold 12 at the second side edge 3 of the first profiled sheet 10 is laid on top of the partial fold 13 formed at the first edge 2 of the second profiled sheet 13. In other words, the amount of overlap is smaller than (W1/2). Fig. 2 shows a detailed view of the shape of the transverse profiling of the profiled sheet 1 according to the utility model, which shape has a particular pattern in a top view of the roofing surface 9. In other words, in the direction of the upper and lower edges 5, 6, in the top view of the roofing surface, the shape of the transverse profiling 7 is not straight but partially has a shape such as a wave or an angular shape in the direction of the side edges 2, 3. In other words, the wave-like shape of the transverse profiling 7 has a support portion 16, approximately parallel to the side edges, which supports the mutually superimposed profiled sheets in the ridge direction. When two or more profiled sheets 1 are connected to each other in the ridge direction, a support reaction occurs at the joint between the profiled sheets 1 adjacent to each other in the ridge direction. This support compensates for the weakening of the support in the ridge direction caused by the partial overlap of the profiled sheets 1 abutting each other in the ridge direction. A support part 16, approximately parallel to the side edges 2, 3 of the transverse profiling 7, is situated on the falling surfaces 17 of the folds 12 of the longitudinal profiling 4. The support part 16, parallel to the side edges 2, 3, is straight in a top view of the roofing surface 9 and comprises a flat surface approximately perpendicular to the roofing surface 9 in order to further improve the support in the ridge direction. In the case where several profiled sheets 1 are connected one after the other in a direction transverse to the direction of the roof ridge, overlapping each other so that the profiled sheets 1 overlap the area between the upper edge 5 and the first transverse profiling 7, in the direction of the side edges 2, 3, counting from the upper edge of the lower profiled sheet 1, a form locking is formed between the connected profiled sheets 1, which form locking further prevents movement of the profiled sheet 1 in the direction of the ridge. The term transverse profiling 7 denotes the profiling, or shape, in the direction of the upper and lower edges 5, 6 of the profiled sheet. The transverse profiling 7 comprises one or more terraced steps, or simply steps, as shown in the figures. The surface formed by the steps is approximately perpendicular to the surface of the roof covering 9. The shape of the transverse profiling 7 is continuous over the area of the surface of the roof covering 9, i.e. the terraced steps are identical. According to the utility model, one or more transverse profilings 7 may be located between the upper and lower edges 5, 6. The lower edge 6 of the profiled sheet 1 has a pattern with a shape corresponding to the transverse profiling 7, i.e. a terraced step, as a result of which it can, by means of its lower edge 6, be connected to the first transverse profiling 7, i.e. a terraced step, measured from the upper edge of the profiled sheet 1 mounted below the previous profiled sheet 1. The roof covering surface 9 defines a surface of the profiled sheet 1 that is inclined, for example, from the roof ridge in the direction of the roof slope. The upper and lower edges 5, 6 of the profiled sheet define edges parallel to the roof ridge or the roof covering surface. The first and second side edges 2, 3 of the profiled sheet 1 are edges extending at right angles to the roof ridge. The profiling defines a shape independent of the manufacturing method used. The longitudinal profiling is produced by rolling, and the transverse profiling by extrusion. Numbers 1. Profiled sheet 2. First side edge 3. Second side edge 4. Longitudinal profiling 5. Upper edge 6. Lower edge 7. Transverse profiling 8. Roof covering surface 9. First profiled sheet 10. Second profiled sheet 11. Complete fold 12. Partial fold 13. Water path 14. Joint 15. Supporting part of the transverse profiling, extending towards the side edges 16. Falling surface of the fold 17. Complete ridge part 18. Fragmentary ridge part W1 Width of the complete fold W2 Width of the partial fold H Center line of the fold T Transverse direction PL PL PL PL PL PL PL PL PL PL PL PL PL PL PL PL

Claims (1)

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