NO964647L - Plate Structure - Google Patents

Description

The present invention relates to a plate structure, which comprises at least two profiled plates, where the profiling comprises substantially parallel bends and intermediate areas which are substantially parallel to the bends.

In this description, a profiled plate means plates which are rectangular in the main plane and which are mainly used on buildings, which have bends (profiles) or similar profiling designed in the plate's vertical or horizontal direction. The bends usually have a cross-section of a trapezoid, an equilateral triangle, or an arc. The bends can also include several different cross-sectional shapes, e.g. every other bend has a cross-section of a parallelepiped and every other bend has a cross-section of an equilateral triangle. Between the bends there is usually an even intermediate area, which is directed in the same direction as the bend. During the profiling, additional support is obtained for the plate in the direction of the bend, as it is possible to use a thinner plate material to provide the necessary firmness.

The profiled roof plates are usually connected to supporting beams transverse to the bending, as they simultaneously make the plates stiffer in relation to the transverse direction of the bending. In the roof structure, the area between the adjacent support beams is dimensioned according to the load required by the roof structure. In winter conditions, special attention must be paid to the snow load. A further issue that affects the distance between support beams is the thickness of the profiled sheet used. Board manufacturers state the area between the support beams for the boards produced as a function of the load. The load capacity can be increased by placing the support beams at a smaller distance from each other, but then the building cost increases to a corresponding degree.

The German patent application DE-31 10657 describes a roof structure that utilizes profiled sheets. The roof structure is formed by two slab layers that are located at a distance from each other, perpendicular to the slab surface. Thus, there is an intermediate space between the plate layers, which is at least partially filled with insulating material, such as a fire-retardant heat insulating material. At least one plate layer is formed from a profiled plate, the plate layers being attached to each other in the middle area of the bends, so that between the plate layers there are support beams in the same direction as the middle area of the bends, where the plate layers are attached. The roof structure described in this publication is relatively complicated and the installation of the support beams provides an additional, precision-demanding work phase.

It is therefore an object of the present invention to eliminate the above-mentioned mismatch and to provide an advantageous plate structure which consists of relatively few parts. The invention is characterized by the fact that the profiled plates are placed on top of each other as a layer structure so that the intermediate areas of the profiled plates that are closest to each other are placed against each other and the bends point away from each other.

A plate structure in accordance with the present invention entails significant advantages. By using the plate structure in accordance with the invention, it becomes possible, for example, to reduce the number of work phases and simplify support structures. This also reduces construction costs.

In the following, the invention will be described in more detail with the help of examples of execution and with reference to the attached drawings, there

fig. la shows a cross-section of a plate structure in accordance with the invention's first embodiment using parallel trapezoid profiled plates,

fig. 1b shows a cross-section of a plate structure in accordance with a first embodiment of the present invention using substantial arcuate bends,

fig. 2a shows a plate structure in accordance with fig. where heat-insulating material is also used,

fig. 2b shows a plate structure in accordance with fig. lb where heat-insulating material is also used, and

fig. 3 shows a plate structure in accordance with a second embodiment of the present invention.

Fig. la and lb show a plate structure 1 in accordance with a first embodiment of the present invention. The plate structure 1 comprises two plates 2, 3 which preferably have a uniform cross-section. Plates 2, 3 are produced e.g. of sheet metal by pressing them into profiled plates. In this case, the profiling comprises the bends 8 which have a parallelepiped shape

cross section. A first plate 2 comprises a first surface 4, which is an upper surface of the first plate 2 in the example of fig. la, and a second surface 5, which is correspondingly a lower surface of the first plate 2. A first surface 6 of another plate 3 is in fig. leave a lower surface for the second plate 3 and another surface 7 of the second plate is on

correspondingly an upper surface of the second plate 3.

The area which is substantially parallel to the bends, which is between the bends 8 of the plates 2, 3 is called in this context an intermediate area 9. The plate structure 1 in accordance with the present invention is preferably designed so that the outer surface 5 of the first plate 2 and the the second surface 7 of the second plate is placed against each other so that the intermediate areas 9 are in the middle of each other. Thus, the bends 8 will also be at the same place, but point away from each other. In this way, an inner space 10 is formed separately between the bends 8. The plates 2, 3 are attached to each other with the fastening means 11, such as screws or rivets. The fastening is carried out at the intermediate areas 9. A necessary number of fastening means 11 is placed in each intermediate area 9, so that the plates 2, 3 remain firmly in relation to each other.

The plate structure 1 forms a rigid structure particularly in the direction of the bends 8, as the distance of the support beams (not shown) in relation to each other can be increased in comparison with existing plate structures. Tables 1 and 2 compare the plate structure in accordance with the present invention with a conventional plate structure. The first horizontal line in the table includes various load values with which the plate structure is loaded. It is assumed that the load Q is uniformly distributed over the entire plate area. The second horizontal line shows the largest distance L max between the support beams as a function of the plate thickness T for a conventional plate structure (1-K) and for the plate structure in accordance with the present invention (2-K). The values for the plate structure in accordance with known technology are taken from tables from manufacturers of relevant plate structures. The values for the plate structure in accordance with the present invention have been obtained through testing. Table 1 shows the values for a one-hole roof where the plate structure is supported at both ends. Table 2 shows the values for two-hole roofs where the plate structure is supported at both ends and in the middle. It can be clearly shown in tables that by using the roof structure in accordance with the present invention it is possible to significantly increase the distance between the support beams, as the roof structure is simplified and becomes lighter. This makes it possible to simplify other support structures as well. Furthermore, advantages of the roof structure in accordance with the present invention are demonstrated in a complicated roof structure, after which a sufficient load is achieved with simpler support structures.

It can easily be shown e.g. on the last line of table 1, that the load Q = 1.4 kN/m<2>is the maximum distance of the support beams in the direction of the bends 5.5 m with a 1 mm thick plate structure in accordance with the known technique, and 9.9 m with a plate structure in accordance with the present invention which is formed from two 1 mm thick plate structures of known technique. The letter S in connection with the values of the tables means that the plate's bending determines the largest permissible distance Lmax. The letter T means that the support structure determines the maximum permissible distance Lmaka. Table 1 also shows the distance between the screws that act as fastening means.

Table 2 further shows the maximum distance between the support beams when the structure comprises, arranged in connection with the middle support beam, a further support piece which equalizes the load directed against the plate structure. Thus, the distance between the support beams can be increased somewhat.

Fig. 1b shows a plate structure 1 in which plates 2,3 comprise substantial arc-shaped bends 8. Otherwise, the plate structure 1 in fig. lb the plate structure in fig. let. Fig. 2a and 2b show another plate structure 1 in accordance with a first embodiment of the invention. The difference in the plate structure 1 in the first embodiment is here almost set in between two plates 2, 3 is placed insulated material, such as thermal insulation material, the smallest in the inner space 10 which is formed by the bends 9. Thus the thermal insulation of the plate structure 1 can be improved. Insulation material can also be fire-retardant or non-combustible material, as the fire tolerance of the plate structure is thus improved.

The plates 2, 3 used in the plate structure in accordance with the present invention 1 can be identical to each other and can be coated with different materials. E.g. in the roof structure, the surface that remains outside can be weatherproofed, while the surface that is in the inner area can be processed in another way, e.g. by improving the fire tolerance of the surface. Furthermore, the first surface 4, 6 of the plates 2, 3 can be surface coated in a different way than the second surface 5, 7 of the plates 2, 3. Thus, the plate structure 1 in accordance with the present invention can be applied in very different places and different circumstances.

The invention can also be applied so that more than two profiled plates are used, which are placed on top of each other as a layer structure, so that the intermediate areas 9 of the profiled plates that are closest to each other are placed against each other and the bends 8 point away from each other. Fig. 3 shows an example of such a plate structure 1 in accordance with the second embodiment of the invention. In the example in fig. 3, three profiled plates 2, 3, 12 are used. Here, a first plate 2 and a third plate 12 are placed symmetrically, i.e. in the transverse direction of the plate structure 1 in the same place, at a distance from each other. A second plate 3 is placed between the first plate 2 and the third plate 12 so that the bending of the second plate 3 is located at the intermediate area 9 of the first plate 2 and the third plate 12 in the transverse direction of the plate structure 1. Also in this plate structure 1 the inner spaces 10 can be filled with various insulating materials, as the insulating capacity of the plate structure 1 can be further increased.

The profiled plates used in the plate structure in accordance with the invention may also comprise more than one profiling. A second profiling can be arranged e.g.

essentially perpendicular to the above-mentioned profiling examples. The second profiling is preferably formed by elevations, which are noticeably lower than the elevations of the first profiling. The second profiling entails e.g. the purpose of which is that the fire tolerance of the plate structure increases, after which there are channels between the profiled plates 2, 3, 12 especially in the middle area. The channels mean that the heat conduction between the plates is worse than plates that have an even space between them.

The invention is not limited to the embodiments described above, but can be modified within the limits of the attached patent claims.

Claims (1)

1. Plate structure (1) comprising at least two profiled plates (2,3), where the profiling includes substantially parallel bends (8) and intermediate areas (9) substantially parallel to the bends (8), characterized in that the profiled plates (2, 3) are placed on top of each other as a layer structure, so that the intermediate areas (9) of the profiled plates that are closest to each other are placed against each other and the bends (8) point away from each other. Plate structure in accordance with requirement 1, characterized in that insulating material is arranged in the inner spaces (10) between the bends (8).