DE29805509U1 - Frame construction - Google Patents

Description

YY 1/13 *··

Frame construction

The invention relates to a frame construction for fastening self-supporting roof elements or the like, consisting of at least one longitudinal side profile and at least one transverse head profile, each of which rests on a part of the roof with an angled base surface and has a support surface connected to the base surface via a web.

Frame constructions for fastening self-supporting roof elements, for example light strips made of polycarbonate hollow chamber panels or glass elements, are well known and usually consist of rectangular frame profiles. The parallel longitudinal profiles are connected to one another at their free ends via transverse head profiles, so that an overall box-shaped construction is created. The rungs of the roof elements, which can consist of special aluminum profiles, for example, can then be attached to this construction, creating an overall stable structure. The dead weight and the snow and wind loads are transferred via the rungs to the frame profiles, which are therefore subject to particularly high static loads.

The frame profiles used so far have a more or less U-shaped cross-section, with the two parallel support surfaces connected to each other by a right-angled, straight web. The lower support surface of the frame profiles is screwed to the roof and thus stiffened, while the upper support surface is used to attach the roof elements. To securely attach the roof elements, the upper support surface is folded again so that the upper part of the frame is also U-shaped. The frame profiles used must be extremely stable, as the loads that occur, for example in the event of snowfall or strong wind, can be very high. In order to ensure sufficient stability, the

Profiles are made from at least 3 mm thick sheet steel, resulting in a very heavy construction overall. The use of thick steel or aluminum sheets not only makes the production of the profiles more difficult, but also makes transport and assembly more difficult due to the high weight. In addition to high material costs, there are also particularly high manufacturing, transport and assembly costs.

The invention is therefore based on the object of creating a particularly lightweight frame construction for fastening self-supporting roof elements, whereby the profiles have at least consistently high stability and load-bearing capacity with a lower dead weight.

According to the invention, in order to achieve the object, the foot and support surface of the side profile are arranged parallel to the axis and are connected to one another via a web which has at least one edge.

In the case of self-supporting roof elements, in particular roof light strips made of curved polycarbonate hollow chamber panels or glass elements, the deadweight, snow and wind loads that occur are transferred to the frame profiles. The static forces act vertically, horizontally and in a superimposed direction. While the entire profile cross-section has a load-bearing effect in the vertical plane, the U-shaped frame upper section is mainly loaded in the horizontal plane, with the bending stresses of both systems overlapping in the middle of the frame. In the frames used to date with an overall U-shaped profile cross-section, sheet thicknesses of at least 3 mm are required to absorb these forces. Surprisingly, by introducing bends in the area of the web of the side profiles, a significant increase in the static load-bearing capacity of the entire profile cross-section can be achieved. Both the forces acting on the vertical plane and the superimposed bending stresses can be optimally absorbed by this design of the side profiles. The lateral protrusion of the foot area caused by the edging and the resulting partial

The inclination of the web of the side profile results in an improved transfer of the outward-acting load forces, which are transferred from the usually curved rungs of the roof element primarily to the side profiles of the frame construction.

In a special embodiment, the side profile has an obtuse-angled edge in the area of the web, with the inner angle of this edge and the inner angle between the web and the base surface adding up to 270 degrees. In this way, the static load-bearing capacity of the entire frame construction can be increased so that a sheet thickness of 1.5 to 2 mm is sufficient for the frame profiles to compensate for the loads that occur. While the stability and load-bearing capacity of the frame construction remains at least the same, this measure can surprisingly significantly reduce the weight of the frame profiles. Lighter profiles can therefore be used to attach self-supporting roof elements, which above all makes transport and assembly of the frames easier and also enables a significant reduction in costs overall.

In a particularly advantageous embodiment of the invention, it is provided that the obtuse-angled edge is designed to point outwards and the edge of the web has a preferred angle of 150 to 170 degrees and the angle between the web and the base surface is 100 to 120 degrees. In this embodiment, the load-bearing capacity of the side profiles is very high, since the outward-directed, superimposed bending stresses are optimally absorbed here.

In a further advantageous embodiment of the invention, it is provided that the support surface of the side and head profile is connected to the web at right angles and has a section running at right angles in the direction of the base surface and parallel to the web. This design of the upper part of the frame optimally absorbs the forces acting on the horizontal plane. Furthermore, the support surface of the profiles serves to attach the roof elements, with the angled section serving to securely anchor the roof element.

In a special embodiment of the invention, it is provided that the section running parallel to the web has a section at its free end that is angled in the direction of the web. This measure can further improve the anchoring of the roof element, so that a more stable and safer construction is created overall.

In a further particularly advantageous embodiment of the invention, it is provided that the head profile has a substantially straight web and at least one of its outer, lateral ends a shape adapted to the edge of the web of the side profile, as well as a foot surface angled at an angle of 90 degrees. Since the head profiles of the frame construction in self-supporting roof elements are less stressed by outward-directed forces, but primarily by loads on the horizontal plane, the use of a straight web and a foot surface arranged at a right angle has proven to be advantageous here. The head profile must be adapted at both of its lateral ends to the shape of the side profiles, which have an edged web. The head profiles therefore have a correspondingly angled cut so that they can be connected to the side profiles in a form-fitting manner. The adapted shape of the head profiles means that a closed and outwardly sealed frame construction can be produced. The adaptation to the side profiles is maintained even if the construction is aligned accordingly on pitched roofs. A positive connection between the head and side profiles is guaranteed both when the frame profiles are aligned horizontally and at an angle.

In an embodiment of the invention, it is provided that the profiles are made of sheet steel with a thickness of 1.5 to 2 mm. As already explained, the special shape of the frame profiles makes it possible to use sheet steel with this low thickness, so that an overall light construction is created.

In an embodiment of the invention, it is further provided that the profiles are formed in one piece or consist of individual sheets welded together.

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One-piece profiles are preferably made from uncut, wound steel sheets, which only need to be cut to the appropriate length and then bent several times. Alternatively, sheets can also be welded together, although one-piece profiles can take on higher loads.

In a special embodiment of the invention, it is provided that the profiles have a height of 300 to 500 mm, in particular 350 or 400 mm. The height of the profiles can be adapted to the respective application and the manufacturing process.

In order to create a safe and stable construction, the profiles in the area of the base are screwed, welded or otherwise attached to a part of the roof.

The invention is explained in more detail below using the figures provided. It shows

Figure 1 is a perspective view of a side profile,

Figure 2 is a side view of a side profile according to Figure 1,

Figure 3 is a perspective view of a head profile,

Figure 4 is a side view of a head profile according to Figure 3 and

Figure 5 is a perspective view of part of a frame construction.

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Figure 1 shows a perspective view of a side profile 1. It is clear that the base surface 2 and the support surface 3, which are arranged parallel to the axis, are connected to one another via the web 4. The base surface 2 rests on a part of the roof, which is not shown here, and is screwed, welded or otherwise connected to it. The web 4 has a bevel 5 in its upper third, with the bevel 5 facing outwards in relation to the inner side 6 of the side profile 1. It should be noted here that the inner side 6 of the side profile 1 is actually positioned on the outside after the entire frame construction has been completed, so that the term "inside" in this context refers exclusively to the profile and not to the entire frame construction. Alternatively, it is possible to insert several bevels into the web 4, whereby these can be directed both outwards and inwards.

The edge 5 forms the inner angle α on the inner side 6, which can be, for example, 150 to 170 degrees. The web 4 and the base surface 2 form the inner angle ß, which, depending on the inner angle α, can be, for example, 100 to 120 degrees. In order to achieve an optimal static load capacity of the side profile 1, the sum of the inner angles α and β must be 270 degrees. If a web with multiple edges is used as an alternative, these angle dimensions are of course no longer valid. Since the support surface 3 is arranged at a right angle to the web 4, the axes of the support surface 3 and base surface 2 run parallel. The support surface 3 has the section 7, which is arranged at a right angle to the support surface 3 and thus runs parallel to the web 4. The section 7 is also edged at its free end, so that the short section 8 is created. The side profile 1 is thus folded 5 times in total and is particularly suitable for the stable and statically particularly resilient fastening of roof elements due to its special shape. The folding 5 is particularly advantageous for compensating the loads that occur. The support surface 3 with section 7 or partial section 8 is used to fasten the roof elements and at the same time to absorb the vertically acting forces. The side profiles are in

They are usually made of steel sheets, and can be made in one piece or assembled from individual sheets. Alternatively, other materials, such as aluminum, can be used.

Figure 2 shows a side view of the side profile 1 according to Figure 1, whereby the edge 5 and the inclination of the web 4 in the lower area can be seen particularly clearly. The inner angle α of the edge 5 determines the inclination of the web 4 below the edge 5 and the size of the inner angle β between the web 4 and the base surface 2. The angle α is the decisive size for the static properties of the side profile 1. In addition, the stability of the frame profiles is contributed to by the fact that the base surface 2 runs parallel to the axes of the support surface 3. The inner side 6 of the side profile 1 is on the outside when the frame construction is completed, while the outer side 9 of the side profile 1 is arranged inside the construction. It is also clear here that the side profile 1 consists of the one-piece steel sheet 10. This steel sheet 10 is folded 5 times and only needs to be cut to length if the width is appropriate. The sheet thickness can be between 1.5 and 2 mm, so that an overall very light profile is created.

Figure 3 shows a perspective view of a head profile 20. In contrast to the side profiles, the web 21, which connects the base surface 22 to the support surface 23, is straight and therefore has no edging. The support surface 23 with the section 24 and the partial section 25 is constructed in the same way as the side profile 1 from Figures 1 and 2. The base surface 22 of the head profile 20 is arranged at right angles to the web 21 and is screwed, welded or otherwise connected to a part of the roof. At its outer, lateral end 26, the head profile 20 has an incision 27, the shape of which is adapted to the shape of the web of the side profiles. The angle γ of the incision 27 has the same value and is at the same height in relation to the base surface 22 as the inner angle α of the edging of the side profiles. Thus, the head profile 20 fits snugly to the

appropriately shaped side profiles, whereby these can be connected to one another in a particularly advantageous manner. This positive fit is advantageously also maintained when the head part 20 is adapted to the roof pitch, i.e. the construction is not aligned horizontally.

Figure 4 shows a side view of the head profile 20 according to Figure 3. Clearly visible is the straight web 21, which is designed without any bends and connects the two surfaces 22, 23 arranged at right angles. As with the side profiles, the inner side 28 of the head profile 20 is on the outside of the frame construction, while the outer side 29 is arranged within the entire construction. The head profile 20, like the side profiles, consists of 1.5 to 2 mm thick sheet steel 30 and is also designed in one piece in this embodiment. However, other materials can also be used.

Figure 5 shows a perspective view of a part of a frame construction 40 with side profile 1 and head profile 20. Here it is clear that when the entire frame construction 40 is put together, a positive connection is created between the side profile 1 and the head profile 20. The head profile 20 is adapted at its outer, lateral end 26 to the shape of the side profile 1 in such a way that a close connection is possible, which is ensured both when the frame construction 40 is aligned horizontally and when the head profile 20 is adapted to a sloping roof.

List of reference symbols

1 Side profile 2 Foot area 3 Support surface 4 web 5 Edging 6 inside 7 Section 8th Subsection 9 Outside 10 Sheet steel 20 Head profile 21 web 22 Foot area 23 Support surface 24 Section 25 Subsection 26 End 27 incision 28 inside 29 Outside 30 Sheet steel 40 Frame construction

Claims (12)

Protection claims 1. Frame construction (1, 20, 40) for fastening self-supporting roof elements or the like, consisting of at least one longitudinal side profile (1) and at least one transverse head profile (20), each of which rests on a part of the roof with an angled base surface (2, 22) and has a support surface (3, 23) connected to the base surface (2, 22) via a web (4, 21), characterized, that the foot (2) and support surface (3) of the side profile (1) are arranged parallel to the axis and are connected to one another via a web (4) which has at least one edge (5). 2. Frame construction according to claim 1,
characterized, that the side profile (1) has an obtuse-angled edge (5) in the area of the web (4), the inner angle (α) of this edge (5) and the inner angle (ß) between the web (4) and the base surface (2) adding up to 270 degrees. 3. Frame construction according to claim 2,
characterized, that the obtuse-angled edge (5) is designed to point outwards. 4. Frame construction according to claim 3,
characterized, that the edge (5) of the web (4) has a preferred angle α of 150 to 170 degrees and the angle β between the web (4) and the base surface (2) is 100 to 120 degrees. 5. Frame construction according to one or more of claims 1 to 4, characterized in that that the support surface (3, 23) of the side (1) and head profile (20) is connected at right angles to the web (4, 21) and has a section (7, 24) running at right angles in the direction of the foot surface (2, 22) and parallel to the web (4, 21). 6. Frame construction according to claim 5,
characterized, that the section (7, 24) running parallel to the web (4, 21) has at its free end a partial section (8, 25) angled in the direction of the web (4, 21). 7. Frame construction according to one or more of claims 1 to 6, characterized in that that the head profile (20) has a substantially straight web (21) and, on at least one of its outer, lateral ends (26), a shape adapted to the edge (5) of the web (4) of the side profile (1). 8. Frame construction according to claim 7,
characterized, that the head profile (20) has a foot surface (22) angled at an angle of 90 degrees. 9. Frame construction according to one or more of claims 1 to 8, characterized in that that the profiles (1, 20) consist of sheet steel (10, 30) with a thickness of 1.5 to 2 mm. 10. Frame construction according to one or more of claims 1 to 9, characterized in that that the profiles (1, 20) are formed in one piece or consist of individual sheets welded together. 11. Frame construction according to one or more of claims 1 to 10, characterized in that that the profiles (1, 20) have a height of 300 to 500 mm, in particular or 400 mm. 12. Frame construction according to one or more of claims 1 to 11, characterized in that that the profiles (1, 20) in the area of the base surface (2, 22) are screwed, welded or otherwise fastened to a part of the roof.