RU115801U1 - PROFILE SHEET AND STRUCTURE OF THE JOINT BETWEEN PROFILE SHEETS - Google Patents

Abstract

1. Profiled sheet (1), forming the plane (9) of the roof, containing longitudinal profiling (4), passing in the direction of the first and second side edges (2, 3), containing waves (12), and one or more transverse profiling (7 ), passing in the direction of the upper and lower edges (5, 6), with a certain design, if you look at the roof plane (9) from above, characterized in that the longitudinal profiling (4) of the profile sheet on the second side edge (3) in the side direction (T) of the profiled sheet ends with a substantially full wave (12), and at the first lateral edge (2) with a substantially truncated wave (13) to form a joint (15) extending in direction (L) of the lateral edges of the profiled sheets. ! 2. Profile sheet according to claim 1, characterized in that the width (W2) of the truncated wave (13) of the first lateral edge (2) is less than half the width (W1) of the full wave (12), i.e. W2 <W1 / 2. ! 3. Profile sheet according to claim 1 or 2, characterized in that at the second lateral edge (3) the longitudinal profiling wave (4) is complete and contains the upper part of the full wave (12) and two slopes (17) of the wave passing downward from the upper part of the full wave, with one of the slopes (17) forming the lateral edge of the profile sheet. ! 4. Profile sheet according to claim 1 or 2, characterized in that at the first lateral edge (2) in the longitudinal profiling, the wave is a truncated wave (13), which consists of a truncated upper part of the wave and only one of the slopes (17). ! 5. Profiled sheet according to claim 1, characterized in that the shape of the transverse profiling (7) extending in the direction of the upper and lower edges (5, 6) is undulating when viewed from the roof plane (9) from above to provide support between neighboring

Description

The technical field to which the utility model relates.

The invention relates to joints extending in the direction of the side edges of the profile sheets used as roof material, and to support the profile sheet in the direction of the roof ridge. In particular, the utility model relates to profile sheets made of sheet metal according to the preamble of paragraph 1 of the utility model formula having a certain design in the direction of the roof ridge, i.e. to profile sheets profiled in the transverse direction. In addition, the present utility model relates to the junction between the profile sheets according to the preamble of paragraph 9 of the utility model formula.

State of the art

Profile sheets used as roof material almost always have only a design perpendicular to the direction of the roof ridge, which in the present context is called longitudinal profiling. It serves as a drain, as a form that gives rigidity to the profile sheet, and / or as a connecting means in the junction between the profile sheets adjacent to each other in the direction of the roof ridge. This longitudinal profiling often makes the profile sheet a so-called wavy sheet containing waves traveling in a direction perpendicular to the roof ridge. Profile sheets are often made from wound steel strip of standard width. The achievable effective width depends on the chosen design of the profile and on the overlap between adjacent profile sheets.

It is well known that the overlay of profile sheets used to cover the roof adjacent to each other in the direction of the roof ridge is performed in such a way that the side edges of these profile sheets adjacent to each other in the direction of the roof ridge are superimposed at least on the width of one wave. In other words, the extreme waves of adjacent profile sheets are placed one on top of the other, i.e. they are superimposed, whereby support is provided in the direction of the roof ridge between adjacent profile sheets and a simple joint between the profile sheets. A disadvantage of this prior art solution relating to the achievable effective width is the method of applying sheet material used at the joint.

A transversely profiled profiled sheet is also well known in which transverse profiling has a shape when viewed from the roof plane from above, making a straight line in the direction of the roof ridge, i.e. the formed rise of the profile sheet does not contain profiling in the direction of the lateral edge, if you look at the roof plane from above. In this technology, the prior art tried to solve the above drawback by forming a joint between the profile sheets adjacent to each other in the direction of the roof ridge, so that the profile sheets overlap less than half the wavelength. However, a drawback of such a prior art solution is that the support of the profile sheets in the direction of the roof ridge is weak, since the joints between adjacent profile sheets provide a weak supporting effect. Thus, the support of the profile sheets in the direction of the roof ridge is based solely on the forms of longitudinal profiling and the support provided by the fixing screws.

Utility Model Disclosure

The objective of this utility model is to eliminate the drawbacks of prior art solutions and create a profile sheet and a joint between profile sheets using minimal overlay of sheet material, while providing significant support in the direction of the roof ridge for profile sheets in the joints between the profile sheets.

The problem of the utility model is solved by means of the profile sheet and the junction between the profile sheets according to independent paragraphs 1 and 9 of the utility model formula. Preferred embodiments of the utility model are presented as objects of the dependent claims.

The utility model is based on providing such a design of the longitudinal profile in the region of the lateral edges of the profile sheet containing transverse profiling when viewed from the roof plane from above, which makes it possible to superimpose profile sheets adjacent to each other in the direction of the roof ridge, so that the waves of the longitudinal profile only partially superimposed. This achieves a large effective width and improved support of adjacent profile sheets in the direction of the roof ridge.

Regarding the utility model, an unexpected observation was made, according to which, with the specified partial overlap, a sufficient level of resistance of the joint between the profile sheets to weather conditions is achieved if the profile sheets are designed according to the present utility model. Due to the design of the transverse profiling of the profile sheet, the joint between adjacent superimposed profile sheets provides excellent support for the profile sheets in the direction of the roof ridge, so that the likelihood of a joint displacement perpendicular to the roof ridge is minimized, and the conditions for reducing overlap in the joint are improved. In addition, the transverse profiling design of the superimposed profiled sheets provides an excellent fixing effect during mounting of adjacent profiled sheets.

According to a utility model, the technical effective width of the profile sheets can be increased with a constant width of the steel strip, and this technical solution reduces the amount of sheet material used for the roof surface.

Brief Description of the Drawings

Figure 1 shows a profile sheet according to a utility model.

Figure 2 shows in more detail the shape of the transverse profiling of the profile sheet according to the utility model.

Figure 3 shows a truncated wave at a first lateral edge of a profile sheet according to a utility model.

Figure 4 shows the joint between the profile sheets according to the utility model.

Figure 5 shows a front view in the direction of the roof plane of the longitudinal profiling of the profile sheet according to the utility model.

The list of positions:

1. Profile sheet

2. The first lateral edge

3. Second lateral edge

4. Longitudinal profiling

5. Top edge

6. Bottom edge

7. Cross profiling

9. Roof plane

10. The first profile sheet

11. The second profile sheet

12. The wave

13. Truncated wave

14. Drain

15. Joint

16. Part of the transverse profiling extending essentially in the direction of the side edges

17. Slope waves

W1 - wavelength

W2 - incomplete wavelength

H - center line of the wave

Utility Model Implementation

Figure 1 shows a profile sheet 1 according to a utility model, comprising longitudinal profiling 4, which contains waves 12 extending in the direction of the first and second side edges 2, 3, and transverse profiling 7 with a specific design, when viewed from the roof plane 9 from above, in the direction of the upper and lower edges 5, 6. In other words, the transverse profiling 7 is not straight, if you look at the plane of the roof 9 from above, but has, for example, a wavy shape. A profile sheet according to a utility model is formed from sheet metal, preferably from coated steel sheet, 0.4-1 mm thick.

A preferred form of longitudinal profiling is shown in figure 5, in which the longitudinal profiling 4 contains upward waves 12, ending in the lateral direction T of the profile sheet with ramps 17 of the waves. The longitudinal profiling extends towards the lateral edges 2, 3. Preferably, the longitudinal profiling waves have the same shape, with the exception of the lateral edges 2, 3 of the profile sheet. On the lateral edges of the profiled sheets, the longitudinal profiling waves 12 end in the lateral direction T of the profiled sheet in a special way, since the extreme waves form a joint 15 between the profiled sheets adjacent to each other in the direction of the roof ridge.

From figure 4, showing the junction 15 between the profile sheets adjacent to each other in the direction of the roof ridge, it is seen that at the lateral edges 2, 3 of the profile sheet, longitudinal profiling in the lateral direction T of the profile sheet ends so that at the second side edge 3 a wave of longitudinal profiling is complete, having a complete upper part of the wave and two slopes 17 directed downward from the upper part of the wave, moreover, one of the slopes 17 preferably forms a lateral edge of the profile sheet.

At the first lateral edge 2, the longitudinal profiling wave is a truncated wave 13, i.e. incomplete wave. In other words, the truncated wave 13 contains the truncated upper part of the wave and only one of the ramps 17 of the wave (not both). This wave ramp 17 located at the first lateral edge 2 does not form a lateral edge of the profile sheet, as a result of which the lateral edge is formed by the truncated upper part of the wave.

Preferably, the width W2 of the truncated wave 13 is less than half the width W1 of the full wave 12, i.e. W2 <(W1 / 2), due to which, according to the utility model, a large effective width is achieved with a constant web width. In other words, at the junction 15 between the profile sheets according to the utility model, the truncated wave 13 does not pass beyond the center line H of the full wave 12.

Preferably, the truncated wave 13 at the first lateral edge contains a drain 14, which is guaranteed to collect all capillary rising water. Most preferably, the drain 14 is formed in a truncated wave 13 so that the drain 14 is not located at the very edge of the profile sheet, and therefore, the truncated wave 13 contains a part rising up from the drain, as shown in figure 4.

Figure 3 shows an embodiment of a truncated wave 13 of a profile sheet according to a utility model in which a gutter 14 is formed. In this embodiment, the truncated wave 13 ends with a gutter 14. At the junction between the profile sheets, the ramp 17 of the truncated wave 13 is snug against the bottom surface of the full wave 12 of the other profile sheet.

At the junction 15 between the profile sheets, according to the utility model, the profile sheets 10, 11 are superimposed in such a way that the overlap area is less than half the wavelength (W1), and so that the full wave 12 on the second side edge 3 of the first profile sheet 10 lies on top of the essentially truncated wave 13 at the first edge of the second profile sheet 11. In other words, the amount of overlap <(W1 / 2).

Figure 2 shows a detailed view of the shape of the transverse profiling of the profile sheet 1 according to a utility model, which has a certain design, when viewed from the roof plane 9 from above. In other words, in the direction of the upper and lower edges 5, 6, if you look at the roof plane from above, the shape of the transverse profiling 7 is not straight, but partially oriented in the direction of the side edges 2, 3, for example, wavy or angular. In other words, the wavy shape of the transverse profiling 7, or, preferably, the wavy shape of the transverse profiling 7, having a portion 16 substantially parallel to the side edges, supports the mutually superimposed profiled sheets in the direction of the roof ridge. A support reaction occurs at the junction between the profile sheets 1 adjacent to each other in the direction of the roof ridge when two or more profile sheets 1 are joined in the direction of the roof ridge. This support compensates for the weakening of support in the direction of the roof ridge due to the small overlap between the profile sheets adjacent to each other in the direction of the roof ridge. Most preferably, the transverse profiling portion 16 substantially parallel to the lateral edges is located on the ramps 17 of the longitudinal profiling waves 12. Most preferably, the portion 16 parallel to the side edges is straight when viewed from the roof plane 9 from the top and comprises a flat surface substantially perpendicular to the roof plane 9 to further improve support in the direction of the roof ridge. If several profile sheets 1 are joined one after another in the direction transverse to the roof ridge, overlapping in such a way that the profile sheets 1 are superimposed in the area between the upper edge 5 and the first transverse profiling 7 (if counted in the direction of the side edges 2, 3 from this upper edge) of the lower sheet, a mutual blocking between the joined profile sheets is ensured, which additionally prevents the profile sheet from being displaced in the direction of the roof ridge.

The term "transverse profiling" means profiling or design in the direction of the upper and lower edges of the profile sheet. Preferably, the transverse profiling comprises one or more stepwise elevations, or simply elevations, as shown in the figures. Preferably, the plane formed by the lifts is substantially perpendicular to the plane of the roof 9. The shape of the transverse profiling 7 is continuous along the entire plane 9 of the roof, i.e. stepped lifts are the same. According to a utility model, between the upper and lower edges 5, 6 there can be one or more transverse profiling 7. Preferably, the lower edge 6 of the profile sheet has a design with a shape corresponding to the transverse profiling 7, i.e. with a stepped rise, whereby the profile sheet through its lower edge 6 can be attached to the first transverse profiling 7, i.e. the stepwise rise of the lower profile sheet, if we count from the upper edge of this lower profile sheet.

The term "roof plane 9" means the surface of the profile sheet 1, which is inclined, for example, from the ridge of the roof, in the direction of the angle of the roof slope. The terms “upper and lower edges 5, 6 of the profile sheet” mean edges parallel to the roof ridge or roof surface. The terms "first and second side edges 2, 3 of the profile sheet 1" mean edges extending at right angles to the ridge of the roof.

The term "profiling" means a design that is independent of the production method used. Preferably, the longitudinal profiling is performed by shaped rolling, and the transverse profiling is performed by compression.

For a person skilled in the art it is clear that with the help of developing technologies the basic idea of a utility model can be implemented in many different ways. Therefore, the utility model and its implementation options are not limited to the examples described above, but are limited only by the scope of the utility model formula.

Claims (10)

1. A profile sheet (1) forming a plane (9) of the roof, containing longitudinal profiling (4), passing in the direction of the first and second side edges (2, 3), containing waves (12), and one or more transverse profiling (7 ), passing in the direction of the upper and lower edges (5, 6), with a certain design, if you look at the plane (9) of the roof from above, characterized in that the longitudinal profiling (4) of the profile sheet on the second side edge (3) in the side the direction (T) of the profile sheet ends essentially with a full wave ( 12), and on the first side edge (2), a substantially truncated wave (13) to form a joint (15) extending in the direction (L) of the side edges of the profile sheets. 2. A profile sheet according to claim 1, characterized in that the width (W2) of the truncated wave (13) of the first side edge (2) is less than half the width (W1) of the full wave (12), i.e. W2 <W1 / 2. 3. A profile sheet according to claim 1 or 2, characterized in that on the second lateral edge (3), the longitudinal profiling wave (4) is complete and contains the upper part of the full wave (12) and two slopes (17) of the wave extending downward from the upper part of the full wave, moreover, one of the slopes (17) forms the lateral edge of the profile sheet. 4. A profile sheet according to claim 1 or 2, characterized in that on the first side edge (2) in longitudinal profiling, the wave is a truncated wave (13), which consists of a truncated upper part of the wave and only one of the slopes (17). 5. A profile sheet according to claim 1, characterized in that the shape of the transverse profiling (7) extending in the direction of the upper and lower edges (5, 6) is wave-like when viewed from the roof plane (9) from above to provide support between adjacent profile sheets in the direction of the roof ridge. 6. A profile sheet according to claim 5, characterized in that, if you look at the plane (9) of the roof from above, the shape of the transverse profiling (7), passing in the direction of the upper and lower edges (5, 6), contains parts (16), essentially parallel to the side edges (2, 3), to further improve the support of adjacent profile sheets in the direction of the roof ridge. 7. A profile sheet according to claim 6, characterized in that, if you look at the plane (9) of the roof from above, the shape of the transverse profiling (7), passing in the direction of the upper and lower edges (5, 6), on the slopes (17) of the wave (12) a longitudinal profiling (4) extending in the direction of the side edges, comprises parts (16) substantially parallel to the side edges (2, 3). 8. A profile sheet according to claim 1, characterized in that the truncated wave (13) contains a drain (14). 9. The joint (15) between the profile sheets, which contain passing in the direction of the first and second side edges (2, 3) longitudinal profiling (4) containing waves, and passing in the direction of the upper and lower edges (5, 6) at least one transverse profiling (7) of a certain design, if you look at the plane (9) of the roof from above, and in the joint, the profile sheets (10, 11) are laid one on top of the other in the joint between the side edges (2, 3) of the adjacent profile sheets, different the fact that at the junction (15) profile sheets (10, 11) are superimposed in an area smaller than half the wavelength (W1), so that the full wave (12) located on the second side edge (3) of the first profile sheet (10) is placed on top of the substantially truncated wave ( 13) located on the first side edge (2) of the second profile sheet (11). 10. The joint according to claim 9, characterized in that, if you look at the plane (9) of the roof from above, the shape of the transverse profiling (7), passing in the direction of the upper and lower edges (5, 6) of the profile sheets, contains parts (16) extending essentially parallel to the side edges (2, 3), to further improve the support of adjacent profile sheets in the direction of the roof ridge.