FI119652B - Wall construction - Google Patents

Description

WALL STRUCTURE - GREAT STRUCTURE

The invention relates to a wall structure according to the preamble of claim 1.

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Particularly in the shipbuilding industry, efforts are made to streamline and simplify the interior of ships and the like while maintaining good fire safety and sound insulation properties of structures. Installation will be easier and the weight of the structures will be reduced if the walls of cabins and similar structures can be made thin.

DE 3903511 discloses a box-like structural element in which the edges are folded and the short side edge extension is extended by another fold parallel to the plane of the surface plate. US 3596424 discloses a casing structure with edge folds, to which vertical stiffening elements are separately added. CH 538024 also discloses closed cell structures with edge folds. The vertical stiffener has only been used to form an angular structure on the wall.

The object of the invention is to provide a wall structure which is sufficiently rigid both vertically and horizontally, which has good fire safety and good sound insulation properties, but which is still thin and quite light. The aim is to ensure that the wall structure has a high degree of fire safety and that sound insulation is good, especially in the frequency range of 100 ... 200 Hz.

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Characteristic features of the present invention are set forth in the characterizing part of claim 1. According to the invention, the surface plate of a wall element is fixed, for example, by gluing it to two side surfaces of a vertical stiffening element at one of its edges. The horizontal folds of the corrugation plate 30 are up to 20mm in height and are glued to the surface plate by gluing. The two right angled folds on the vertical edges of the face plate have another right angled fold parallel to the plane of the face plate. For joining adjacent wall elements, the folds of their opposite vertical edges can be matched to one another and the folds 5 parallel to the surface of the face plate are superimposed so that the folds of each wall element can each be supported by the vertical stiffening element of the other wall element.

Thus, in wall constructions, a very thin 10 corrugated sheet is used for horizontal stiffening. This means that the ridges and waves of the corrugated board are at least essentially horizontal. In addition, the structure includes a conventional surface plate to which the corrugation plate is glued. The face plate is preferably bonded to the vertical stiffening element, although this adhesive attachment should be secured by a screw attachment or the like for good fire safety. The surface plate attached to the vertical stiffening element, which is glued horizontally with a stiffening corrugated sheet, forms a structure so rigid that its thickness in many applications can only be 5 ... 10 mm. A soft insulating layer, for example 20 layers of glass wool or rock wool, may be glued or otherwise attached to this structure, preferably having a thickness of about 10 mm. Both fire safety and sound insulation are improved if two or more superimposed layers of insulation are used. Such a structure has proven to be very advantageous both as a wall structure to be erected at the installation site and also in the wall structure of prefabricated units such as 25 passenger cabins.

The preferred embodiment of the invention is a relatively thin wall. If you want a wall that is very strong and extremely resistant to fire, the thickness of the corrugated board can be up to 20 mm. Generally, however, it is not advisable to use a corrugated board 15 mm thicker. Normally, the corrugated board has a height of not more than 8 mm, preferably not more than 6 mm. Hereby, for example, a wall made of steel has a sufficiently good stiffness and at the same time good sound insulation and fire resistance. The non-combustible insulating layer added to the steel wall improves these properties. Rock wool is a reliable insulation material. The fire safety of glass wool is 5 lower because glass wool melts at a much lower temperature than rock wool.

A simple rock wool mat or sheet is usually sufficient for the insulation layer. It preferably has a density of 100 to 300 kg / m3, preferably 150 to 200 kg / m3. Heavier insulation is usually better as a fire insulation than lighter insulation.

When fixing the corrugated sheet, it is preferable that the corrugating sheet has a sufficiently large gluing surface. It is therefore recommended that the tops of the corrugations 15 to be glued to the surface board have a planar surface which is at least a few millimeters wide, preferably at least 5 mm wide, adjoining the surface board. This results in a very reliable and durable bonding of the corrugated board.

The corrugated sheet may also have angular or trapezoidal folds. 20 In this case, the portions between the peaks of the corrugations are essentially straight. The angle of these parts to the wall plane should not be made too large, since too much angle makes it difficult to drill and insert screws through the wall structure. A suitable angle is preferably 30 ° to 45 °, preferably 30 ° to 40 °.

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Both the corrugated sheet and the surface sheet are preferably made of a coated steel sheet. Coating refers in this context to all kinds of surface treatment operations such as painting, galvanizing, plastic coating, etc. The surface plate may be 0.7 mm or 0.6 mm PVC coated steel sheet. The corrugated sheet may be, for example, 0.5 mm galvanized sheet steel. The material thicknesses are selected so that sufficient stiffness and 4 fire safety are achieved. The stiffness is substantially affected by the distance between the vertical stiffening elements. If a particularly lightweight wall structure is desired, aluminum sheets can be used as surface and / or corrugated sheets, but this is a much more expensive solution compared to a sheet steel structure.

The vertical stiffening elements can advantageously be made of a steel tube of rectangular cross-section. Other profile steel or metal may be used. In order to achieve sufficient stiffening, it is preferable that the vertical stiffening element has a significantly greater dimension perpendicular to the wall plane than the thickness of the corrugated sheet of the wall structure. This creates a space between the vertical stiffening elements in which the insulating material of the wall structure can be easily placed.

A wall according to the invention may be assembled from wall elements to be fastened side by side, each having a vertical stiffening element at one of its edges. The surface plate is attached to this stiffening element, for example by gluing, and also the surface plate of the adjacent wall element, preferably by screws. Both fasteners can be best accomplished by having a folded point on both sides of the face plate which is flush with the vertical stiffening element. This fold can also be extended with another fold that is parallel to the rear surface of the vertical stiffening element. These folds stiffen the wall element and facilitate their connection.

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The horizontal width of the wall elements in the wall plane can be selected to suit any modular system. Too wide wall elements are difficult to handle. Width of wall element is recommended 80 ... 150 cm, preferably 85 ... 100 cm.

In a preferred embodiment, the corrugated sheet is inserted between the vertical stiffening element of the wall element 30 and the angled portion of the wall plate at the opposite edge from a wall plane. In this case, it is preferable that the horizontal length of the corrugated sheet as closely as possible corresponds to the dimension of the space for the corrugated sheet. Thus, the clearance 5 required for the installation of the corrugated board is kept to a minimum. This provides the best sound insulation and fire safety. For the same purpose, the flexible insulating layer to be bonded to the corrugated board can be made slightly oversized in relation to its space. The horizontal dimension thereof prior to its installation is then somewhat larger than the corresponding 10 dimensions of the corrugated sheet.

The fire resistance of the wall structure can be increased by securing the adhesive fastening of the corrugated board and the insulating layer with heat-resistant fastening members, for example screwed or riveted to the vertical stiffening elements. These 15 are particularly necessary if two overlapping layers of insulating material are used in the wall, only one of which is glued to the corrugated board and the other is mainly applied to it by frictional forces only.

The invention will now be described in more detail with reference to the accompanying schematic drawing, in which Fig. 1 is a partially sectional side view of the wall structure according to the invention; 4, Figure 4 shows a vertical sectional view of a wall structure 30 according to the invention.

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In the drawing, there are 1 wall structure surface plate, 2 wall structure corrugated plate, 3 wall structure insulation layers and 4 wall structure vertical stiffening elements. In the embodiment shown, the face plate 1 is a 0.7 mm PVC-coated steel sheet. The corrugated sheet 2 is 0.5 mm thin 5 galvanized sheet steel. Too thick a layer of zinc can be detrimental to the fire safety of the wall structure. The folds are horizontal. Their shape is shown in Figure 4. The vertical stiffening elements 4 are essentially 25 x 25 mm square steel tubes. The insulation layer 3 is 10 mm thick rock wool.

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Figures 2 and 3 show how the surface plate 1 is folded at the other vertical edge of the wall element 5. There are provided two rectangular folds resulting in a fold 6 perpendicular to the wall plane and a fold 7 parallel to the plane plane. In the embodiment 15 of the drawing, each wall element has only one vertical stiffening element 4 having two side faces 4a and 4b. Instead, there is a gap of a few millimeters between the rear surface 4c of the vertical stiffening element and the fold 7 of the surface plate, which is intended to facilitate the assembly of the wall element.

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The adjacent wall element 5a also has two folds 6a and 7a at the vertical edge without the vertical stiffening element. Of these, the fold 6a is dimensioned such that the fold 7a rests on the fold 7 when the face plate 1 of both wall elements 5 and 5a is in the same plane.

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According to Fig. 3, the connection of wall elements 5 and 5a about 100 cm wide is secured to one another by a plurality of fixing screws having different positions at line 9. At the same time, the screws secure the adhesive attachment of the surface plate to the vertical stiffening element 4. The gaps 10 and 11 between the corrugated plate 2 and the fold 6a 30 and the corrugated plate and the vertical stiffening element 4 are kept as small as possible. There is no corresponding gap in the vertical edges 7 of the insulating layer 3, but the insulating layer is slightly pressed between the vertical stiffening element 4 and the fold 6a. If two overlapping layers of insulation are to be used, one of them is installed only after the screws 9 are already in place.

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Fig. 1 illustrates how the adhesive attachment of the corrugated sheet 2 and the insulating layer 3 can be secured, for example, by a metal fastener element 15. The figure shows only one such, but is preferably used in each of the vertical stiffening elements 4. It is also possible to increase their dimension 10 vertically so that the elements 15 become rib-like. The elements 15 are used in particular when another separate insulation layer is placed on the insulating layer 3. The fastening element has a central portion 16 over the folds of the vertical stiffening element 4 and the face plate 1, if necessary, on both sides 15 of which has a relatively wide support flange 17 which supports against the insulating layer 3. The center portion 16 is secured to the vertical stiffening element 4 on its side or sides by screws or rivets 18, provided that there is sufficient space on the side surface. Otherwise, the attachment is made to the rear surface 4c of the vertical stiffening element 4.

Fig. 4 shows a corrugated board 2, the folds of which are formed by bending the board so that a plurality of nearly 5 mm wide planar surfaces 12 and 13 are provided on both sides of the board, suitable for gluing fastening. and 13 may have small holes, recesses, or other irregularities to provide a larger adhesive surface for the adhesive. The use of inorganic adhesive increases fire safety, but organic adhesives can also be used in many cases, e.g. polyurethane adhesives. The corrugated sheet 2 has a total thickness of about 7 mm. The corrugated board portions 14 between the surfaces 12 and 13 are at an angle of about 40 degrees to the wall plane 30.

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The invention is not limited to the embodiments shown, but many variations are contemplated within the scope of the appended claims.

Claims (10)

A wall structure made of fire-resistant material, comprising at least two interconnected wall elements (5) having a thin sheet metal face plate (1) having a vertical bend (6,6a) at each of its vertical edges, a separate vertical stiffening element (1) attached to the face plate (1). 4), as well as a horizontally stiffening corrugation plate (2) having horizontal corrugations attached to the surface plate (1), characterized in that the surface plate (1) of the wall element (5) is secured, for example, by gluing it to two lateral surfaces (4) 4a, 4b), that the horizontal corrugations of the corrugation board (2) have a height of not more than 20mm and are glued to the surface board (1), that the right-angled folds (6,6a) in the vertical edges of the board (1) parallel fold (7.7a), and that for connecting adjacent wall elements (5.5a) to their the folds (6,6a) of the stepped edges (6,6a) can be matched to one another and the folds (7,7a) parallel to the plane of the surface plate (1) are superimposed so that the folds (6,6a) of each wall element (5,5a) 5) a vertical stiffening element (4). Wall construction according to Claim 1, characterized in that the second fold (7a) of the fold (6a) of the second wall element (5a) at right angles to the plane of the surface plate (1) is arranged so that it is seated on the second wall element (5). on top of the fold (7) in the direction of the plane of the second surface plate (1) at right angles, when the surface plates (1) of both wall elements (5.5a) are in the same plane. Wall construction according to Claim 2, characterized in that the wall elements (5.5a) have a width of 80 cm to 150 cm in the horizontal plane of the wall structure. Wall construction according to Claim 1, characterized in that the corrugations of the corrugated board (2) have a height between 5 mm and 20 mm at most. Wall structure according to Claim 3, characterized in that the vertical stiffening element (4) has a greater dimension perpendicular to the plane of the wall structure than the thickness of the corrugated plate (2). Wall structure according to Claim 4, characterized in that an elastic insulating layer (3) is glued on the opposite side to the surface plate (1) of the corrugation plate (2), the dimension of which is slightly larger than that of the corrugation plate (2) measure. Wall structure according to one of the preceding claims, characterized in that the top to be glued to the corrugated surface of the corrugated plate (2) has at least a few millimeters wide, substantially flat mounting surface (13) parallel to the plane of the corrugated plate (1). the inter-peak portions (14) being substantially rectilinear and forming an angle to the plane of the corrugated plate (2), which is between 30 ° and 45 °. Wall structure according to one of the preceding claims, characterized in that both the surface plate (1) and the corrugated plate (2) are sheet or steel. Wall structure according to one of the preceding claims, characterized in that the vertical stiffening element (4) is a steel tube or other profile steel or metal having a substantially rectangular cross-section. Wall construction according to one of the preceding claims, characterized in that the corrugated board (2) and the insulating layer (3) are secured in place by heat-resistant fastening elements (15) fixed to the vertical stiffening elements (4).