DE6918356U - COMPOSITE BUILDING PLATE - Google Patents

Description

There are basically two types of building panels used in the construction industry.

The building panels of the first type consist of individual parts, which by means of a connecting means are connected to each other. In this way, building elements with large dimensions can be produced, e.g. one side of an apartment wall form; after they have been connected to other structural elements on the construction site, the last layer can be applied. Such plates are very heavy, which practically prohibits their transport over long distances; also need put them in place after they are created, a long and expensive finish.

The panels of the second type are lightweight elements, e.g. sandwich elements that are made of film-like material. Their width does not exceed that of the film material and is accordingly generally in the order of magnitude from 1 m. Such panels are light and easy to transport.

Your final treatment can be carried out in the construction company. However, require their small dimensions a large number of connections and, as a result, a rather long assembly time on site.

The pattern is based on the task of creating composite building panels, which have the advantages of both of the aforementioned types of building board, but avoid the disadvantages mentioned in each case, i.e. lightweight building boards should be used with large dimensions are created, from which walls without joints can be produced.

According to the pattern, several plate elements of the second are in solution to this problem Art arranged side by side and taped together to form a composite panel of the desired dimension.

For example, to create a 3 m by 4 m plate, you can put four side by side Place plate elements of 3 m χ 1 m next to each other and on each of their sides three foil strips of 4 m 1 m, preferably made of fibrous material glue crosswise. The composite panel thus obtained is rigid and light. It has the advantage of being transported over any distance and being installed quickly to be able to do without any finishing treatment on the construction site.

In a further development of the pattern, the mechanical resistance of the composite Building board improved by the fact that a pretensioning between the plate elements and the film strips that form the outer wall layers of the composite plate is created. For this purpose one can artificially increase the dryness of the plate elements by e.g. dries before the strips are glued to their two faces, so that, as a result, the pre-tension is automatically created when the original moisture is reassumed.

According to another special feature, pressurization becomes the good Carrying out the gluing of the foil strips on the plate elements is necessary, achieved in that the assembled plate or a stack of assembled panels are arranged after gluing in a room provided with a flexible wall, whereupon this room is evacuated, so that the external overpressure acts on the flexible wall. The pressure difference between the outside and the inside of this room, the flexible wall presses on the panels.

Further details and advantages of the pattern emerge from the following description of exemplary embodiments shown schematically in the drawing, with all special features arising from the description or from the drawing belong to the invention. Show in the drawing

1 shows a top view of a plate element,

FIG. 2 shows a cross section along the line II-II in FIG. 1,

3 shows a plan view of an assembled construction panel according to the pattern,

Fig. 4 shows a cross section along the line IV - IV in Rg. 3,

FIG. 5 shows a plan view similar to FIG. 3 of another embodiment and
Fig. 6 is a vertical section through a device with which in

building panels assembled during manufacture are pressurized.

The in Flg. 1 and 2 shown plate element is in the manner of a sandwich plate built up. It consists of two plate layers 1 and 2 made of foil material, which are glued to an inner core layer 3 on both sides. The film materials that can be used can be fibrous, crystalline or amorphous in nature. Man can e.g. use Ze I Iu lose materials, such as plywood panels, pressed panels Wood fibers or other parts of wood, panels made of synthetic material that are made with

Fibers of any other type can be connected, synthetic resin impregnation Cardboard sheets, thin sheets of metal or cement covered with asbestos or Cellulose fibers are connected, coated on both sides with cardboard Plasterboard, etc.

All these materials in the form of a thin semi-finished plate have in common that their width is of the order of 1 m due to the dimensions of the machines with which they are made. Otherwise they are available in any length; their length can even be unlimited if they are through Rolling, extruding, felting or any other method for producing continuous belts. The one shown in Figs The plate element has a width of about 1 m. Its length can e.g. be between 2 m and 3 m.

The inner core 3 can consist of a light and stiff filling made of cardboard impregnated with plastic or of a layer of rigid foam or made of flexible foam, such as that obtained from expansion of thermosetting or thermoplastic plastics or from expanded lightweight concrete. In general the core 3 can consist of all materials which are suitable for finally giving a composite partition wall the desired thickness, mechanical resistance and the desired thermal and acoustic insulating properties.

The connection between the core layer 3 and the plate layers 1 and 2 can generally be done by gluing using an adhesive which is responsive to the materials used. For example, one can use thermosetting plastics of the aminopiost group, polyurethanes, or epoxy resins or even thermoplastics of the vinyl group as adhesives.

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The assembled plate according to FIGS. 3 and 4 consists of four plate elements 4, 5, 6, 7 of the type shown in FIGS. 1 and 2. On each side These plate elements are two film strips 8, 9 and 10 glued flat. These film strips run perpendicular to the longitudinal axis of the individual Plate elements. The abutting edge of their adjoining edges is marked 11 designated. These strips can be made of the same materials like the plate layers 1, 2 or of a similar material, e.g. a material whose outer surface has a decorative or functional coating 'is provided. These strips are provided with an adhesive on their inside and glued to the panel elements in order to thus to connect everything into a single piece.

The width of the strips 8, 9 or 10 can correspond to the width of the plate layers and 2 be different. In general, however, it is of the order of magnitude of 1 m, since - as already stated - the largest width depends on the dimensions of the machines that produce the film materials. at 3 and 4, the plate elements have, for example, a width of 1 m and a length of 2.60 m and the film strips have a Width of 1.30 m and a length of 4 m, making a compound Slab of 4 m 2.60 m is obtained.

Figure 5 shows another composition with which larger panels can be created. For this purpose several are placed side by side Rows of plates each having a long plate element 12 and a short plate element 13, end to end. The abutting edges 14 and 15 are arranged offset from one another, as FIG. 5 shows. On every wide area the arrangement obtained in this way will be several seamlessly abutting one another

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Strips 16, 17 and 18 glued. These do not necessarily all have to be the same Have width. The abutting edges 19 and 20 of the strips are arranged offset to the abutting edges 14 and 15 of the plate elements, as for example in FIG. 5 is shown. For example, if you have five rows of panel elements in size 1 m 1.80 m or 1 m 0.90 m and strips 16 and 17 of 1 m χ 5 m and strip 18 of 0.70 m × 5 m is used, a composite Slab of 5 m 2.70 m preserved.

The strips are preferably made of fibrous material in order to give the plate good mechanical strength. In order to improve the mechanical properties, a certain prestress can be created between the plate elements and the foil strips which form the outer wall layers of the composite plate. This pretension can be obtained in various ways, e.g. by using mechanical devices to press the plate elements 4, 5, 6, 7 or 12, 13 together lengthways and / or transversely, while the strips 8, 9, 10 or 16, 17, 18 are applied to both sides and the gluing process takes place. The bias can also be achieved in a simple way by artificially increasing the dryness of the plate elements, for example by drying them, whereupon the strips 8, 9, 10 or 16, 17, 18 in their natural moisture state on both sides of the plate elements, which are arranged in the manner shown in Fig. 3 or 5, are glued. After gluing, the panel elements have a tendency to expand when they regain their natural moisture content. As a result, they put the strips 8, 9, 10 or 16, 17, 18 under tension and generate a prestress inside the assembled plate.

Carrying out the gluing operation requires that the panels be placed under pressure while the surfaces are being glued together. The squeezing

of panels with small dimensions, e.g. panel elements whose dimensions are generally not larger than 1 m χ 2.60 m, does not prepare

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Difficulty because it is carried out by means of the usual known presses can be. But this is not the case when composite panels are to be pressurized, the dimensions of which are constantly changing the size of 15 m.

Fig. 6 shows a device with which this problem can be solved. On a flat surface, e.g. a concrete slab 24, e.g. the strips 8, 9, which are to form one side of a composite slab, designed. After the upper side of these strips has been provided with adhesive, the plate elements 4, 5, 6 and 7 are arranged side by side on them, and over them the strips 10, after they are on their underside with the adhesive were provided. On the composite plate 21 constructed in this way, further composite plates 22 and can be used in the same manner 23 arrange. Several layers of composite panels are thus formed. These are covered with an air-impermeable cover 25, which on the concrete slab 24 around the slab stack! is attached, e.g. by means of rods 26 which are clamped to the concrete slab via bolts 27. To this A tight, flexible wall is created around the stack of plates, the interior of which is evacuated by means of an air pump, not shown can be. This is on a connection piece provided on the ceiling 25 28 connected. This pump can easily be evacuated to an extent sufficient for the atmospheric pressure to press the ceiling 25 onto the stack of plates. This pressure can rise to the vicinity of the prevailing atmospheric pressure. It is enough to get between the with the Adhesive-attached parts to create intimate contact during the time the adhesive is on.

As a modification of this, the blanket 25 comprising the plate stack can be in one sealed chimneys are arranged, wherein means are provided to create an overpressure in the chamber.

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It is obvious that the embodiments described are only examples. It can be modified in particular by using technically equivalent means, without leaving the scope of the principle of invention.

Claims (1)

Composite building board, especially large dimensions, especially for Creation of entire partition walls of apartments is intended thereby characterized in that they are made up of several in the longitudinal direction of the finished Building board side by side plate elements (4,5,6,7; 12,13), which extend over the width of the plate elements on film strips (8,9,10; 16,17,18) glued on both sides of the plate elements, preferably of a fibrous type, are connected to one another, each plate element having a structure, e.g. in a sandwich type, with foil strips 0/2), the in the longitudinal direction of the plate element, transversely to the connecting foil strips (8,9,10; 16,17,18) run. Building board according to claim 1, characterized in that each Plate element extends over the entire height of the assembled plate. Building board according to claim 1, characterized in that it is in their longitudinal direction composed of several rows of plot elements J> II ti t · ■ ¹ ) ^ J ι ι · ι · «· rf JIj> »I I · i -2- of which each row consists of a stacked arrangement of plate elements (12, 13) of different heights, the abutting edges (14, 15) of adjacent rows are offset from one another. 4. Building panel according to one of claims 1-3, characterized in that the connection of the panel elements (4,5,6,7; 12,13) and the film strip (8,9,10; 16,17,18) is under tension. DI «· Misdeeds <e« MlM * u «* MS Sehuftmpr.) W« e zuMzt «togmlcMe; you know the version of the ursorön <jl! ch * inq «* icwen ün» rtoo «n *. > ef "= niticne fteoeutunq der AOoftLTiq! st not" checked. The unprOngHch emgeretcnten Umeriogen cefinöer $ icn .n oen. ^ Rrrsowen. You '' .önoen "edeiesfr ohnf Nochwefc a" racMttchen Intereu "oeoOnrentret einqeseften wertten. * At ul ·" *} * etileo tuenon otich ^ MKooien ooer Röw neqoH »· tu the ubttctien fniim give tert. Owuttcnu G