FI70444B - FREBAER BYGELEL - Google Patents

Description

1 70444

Free-standing building element Technical area

The invention relates to a building element, a so-called plywood element, which consists of thin metal plates as a covering material and foam concrete between them. The aim is to provide a building element which can withstand relatively high bending and shear loads as well as point loads, but which nevertheless has a low bulk density and a high heat transfer resistance. The primary applications are roof and wall elements for small and medium-sized houses, but of course other areas of use where the above-mentioned properties are valued can also be considered.

Technical background

In the construction of small and medium-sized houses, it is advantageous to use building elements. This is primarily due to perhaps economic reasons. The building elements are prefabricated in special factories and then fitted to the building on site. The requirement that these building elements must be as free-standing as possible is, of course, due to the fact that the cost of supporting the elements must be reduced as much as possible.

Building elements, on the one hand, are increasingly exposed to forces caused by wind and snow pressure and, on the other hand, to forces in smaller areas due to knocks and shocks or the weight of people rising on the elements. When the elements are most often supported from below only at their ends, these elements can be equated to a beam in which the compressive and tensile forces are concentrated on the upper and lower surfaces and in which the material between these surfaces is subjected above all to shear forces. The building elements must also be heat and sound insulating and, if possible, non-combustible or at least must not emit too harmful smoke in the event of a fire accident. In the case of these components, care must also be taken not to create clear cold bridges with all their disadvantages.

Today, there are several building element structures. The most common are made of spaced longitudinal beams covered with panels on both sides. The intermediate space of the element is filled with some insulating substance. When beams are made of steel, there are problems with cold bridges. Using wood instead causes disadvantages for living in damp wood. Simple wood joints do not always provide enough space for good insulation and when using cross wood joints, the structure becomes expensive. Special moisture barriers must also be provided in the beam structures, unless the panels can form a moisture barrier. It is not uncommon for the insulation material itself to prevent moisture penetration.

The so-called plywood structures consist only of panels with an interlayer of insulating material. There are many different structures on the market today and none of them have proven to be particularly suitable. The biggest problem seems to be to get a suitable material between the panels that meets the requirements for good insulation while having the strength properties required of a self-supporting building element. Although often used, polyurethane foam has good insulating properties, but very low compressive and shear strength and, moreover, it generates dangerous smoke in a fire. The condition for the use of this material is thus that the outer panel material practically completely absorbs any compressive or tensile load. For example, if sheet metal is used, polyurethane foam cannot completely prevent the sheet from bulging under compressive load.

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3 70444 weaving in the plane of the plate and the strength properties of the plate material cannot therefore be fully utilized. Other material with better strength properties has also been tried, but then it has been shown that it does not sufficiently meet the thermal insulation requirements instead. CH patent 446 670 mentions concrete as a filler, but on the one hand its thermal insulation capacity is not sufficient in an element subject to low heat transfer coefficient requirements, on the other hand the elements become unreasonably heavy. Light clinker concrete, such as "Leca concrete", is also proposed, but its strength properties are too poor. In addition, it has been problematic to provide a joint between the surface material and the filler. Making the connection is e.g. therefore it is necessary to be able to take advantage of the shear strength of the filler e.g. in the bending loads of the building element. One way has been, as in DE 875 403, to provide the shell with grooves which are complemented by protrusions or the like in an adjacent plate, for example in the form of a groove and a rib. However, this makes the structure unnecessarily much more expensive and, of course, reduces the insulation capacity.

Another way has been to use glue. However, the adhesive is sensitive to creep deformation. Another way has been to cut tabs from the sheet material at its edges and bend them inside the space. In addition, in order to provide a more efficient rigidity in the element, the tabs have been made so long that they can be welded together with the tabs of the opposite panel. However, the system is not suitable for economic reasons. According to SE patent application 7 706 023-4, bridges have been stamped from cover plates and pulled on the opposite side to provide the most stable building element. This, too, is economically disadvantageous and, moreover, cold bridges are created.

Summary of the Invention

Surprisingly, it has proved possible to produce a very strong and economically advantageous building element with today's insulating properties 4 70444 by using a metal plate and then primarily a steel plate as panels on both sides of the building element and filling the space between these plates with foam concrete, pure cement and a two-component foam dispenser. The invention is defined in more detail in the appended claims and the invention is described in more detail in the description below.

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More detailed description of the invention

The length of the building element can vary. If possible, for example, it is desired to cover the entire length of the element from the roof ridge to the eaves, or the entire height of the side wall. Similarly, it is often desired to use elements as wide as possible. The restrictions are, of course, due to the handling facilities available at the manufacturing and construction site, as well as the transportation facilities. Since the building element according to the invention will be relatively lighter than the elements normally used, size is probably the most decisive limiting factor. The length will hardly exceed 12 m, 4-6 m being normal and the width will not exceed 2.4 m, approx. 1.2 m being normal.

The panel board on both sides is normally completely smooth, but may be slightly profiled for appearance reasons, etc. The plate thickness can vary between 0.4 mm and 2.5 mm. The lower limit is largely determined by manufacturing reasons. It is uneconomical to roll, for example, steel sheet to thinner dimensions. The upper limit for a steel plate is normally 1.5 mm. For reasons of strength, it is not necessary to use this thicker and the structure will then become too heavy and expensive. When using aluminum, on the other hand, 2.5 mm thick plates can be forced to use, as during processing the plate easily deforms from shocks and knocks.

The heat transfer coefficient in a modern building element must not rise above 0.10 W / (m · Κ), because otherwise the elements must either be made too thick or additional insulation must be used. When a two-component blowing agent is used in the production of foam concrete, the heat transfer coefficient can be easily reduced to 0.06 W / (in * K) at a density of 200 kg / m 2 of ready-mixed foam concrete. This is e.g. practically tested in a viable foam concrete plant using the commercially available two-component blowing agent Cellex. Foam concrete preparation 6 70444 was carried out in a special machine, to which water, cement and another component of blowing agent were first added, followed by vigorous mixing of the mixture. The second component was then added with stirring and air. The foam was then pumped along hoses between the steel panels. No filler was added.

By changing the manufacturing parameters, the density of the foam concrete can be increased from 200 kg / m upwards. When manufacturing the element according to the invention, the upper limit of the density is set to 3 at 600 kg / m. Although the strength properties of foamed concrete improve with increasing density, on the other hand the heat transfer coefficient also increases with density and at a density value of 3 3 600 kg / m the desired maximum of 0.10 W / (m -K) may be exceeded. Tests in the density range of 200-600 kg / m 2 have shown that the following strength values of the foam concrete were not exceeded: compressive strength 0.3 MPa modulus of elasticity 500 MPa shear modulus 250 MPa

The adhesion between the metal surface and the two-component foam concrete proved to be perfect. Namely, the experiments showed that the fractures under shear load occurred in the foam concrete layer and not at the interface between the foam concrete and the metal sheets. Based on this and the good strength properties of the foam concrete, it has been shown that the elements can withstand high loads.

Foam concrete prevents bulging of steel sheets so that their material strength properties can be fully exploited. Due to its relatively high compressive strength, Foam Concrete creates good conditions to allow high point loads on the element. Moreover, since the foam concrete is aerated concrete with closed pores, no additional moisture or wind barrier is required.

Il 7 70444 This combination of metal sheets and two-component foam concrete provides a building element with superior strength and building physical properties at a competitive price.

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Claims (3)

8 70444 1. A non-combustible, steam- and water-tight freely supporting building element with a heat transfer coefficient of 0.06 to 0.10 W / (m · Κ), consisting of two parallel metal cover plates and the space being filled with aerated concrete, characterized in that these plates the space is filled with closed-cell foam concrete made of cement, water and a two-component foam former, and that the ready-mixed foam concrete has a modulus of elasticity of at least 500 MPa, a shear modulus of at least 250 MPa, a compressive strength of at least 200 MPa and a tensile strength of at least 0.3 MPa 600 kg / m3. Non-combustible, steam and waterproof free-standing building element according to Claim 1, characterized in that the cover plates are made of steel with a thickness of 0.4 to 1.5 mm. Non-combustible, steam- and water-tight free-standing building element according to Claim 1, characterized in that the cover plates are made of aluminum with a thickness of 0.6 to 2.5 mm.