NL1012302C2 - Improved cassette system. - Google Patents

Abstract

The invention relates to a wall, comprising an inner skin manufactured substantially from plate material and an outer skin manufactured substantially from plate material, wherein: an insulating layer manufactured from mineral wool is placed between the inner skin and the outer skin; the inner skin is provided with noses placed at regular distances and directed toward the interior of the wall; the noses are connected to the outer skin by means of pointed connections; and the noses are located at a distance from the outer skin, wherein the insulation layer has a greater density on the outside than on the inside and the pointed connections are adapted to absorb forces in the direction parallel to the plane of the wall. As a consequence of these measures a greater lateral rigidity of the wall construction is obtained. The density of the layer of mineral wool preferably progresses smoothly from a low density on the inner skin to a high density on the outer skin.

Description

IMPROVED CASSETTE SYSTEM

The invention relates to a wall, comprising an inner skin mainly made of sheet material and an outer skin mainly made of sheet material, wherein: - an insulation layer made of mineral wool is placed between the inner skin and the outer skin, - the inner skin is provided of regularly spaced noses directed towards the interior of the wall, - the noses are connected to the outer skin by means of pointed connections, and - the noses are located at a distance from the outer skin.

Such a wall is known from EP-A-0 801 190.

In this prior art wall, the density of the mineral wool layer is constant over the entire cross section of the wall. The choice of the density of this insulating layer is therefore determined by the thermal insulation value in conjunction with the lowest possible cost price.

It is noted here that thermal insulation value not only refers to the normal measurable insulation value, but also that the fire retardancy plays a major role. After all, it is of the utmost importance to ensure that the construction is as fire-resistant as possible.

The fire retardancy often plays a major role, due to legal provisions.

Experience has shown that with wind load 35 of this prior art wall construction it collapses faster than is desirable. Research has shown that this is due to the fact that the stiffness of the structure in the lateral direction, ie the ability to absorb shear forces between the outer skin and the inner skin, is not optimal.

The object of the present invention is to provide such a construction, in which the resistance to wind load is much greater without the noses having to be placed considerably closer together, or the pointed connections getting a high density or being dimensioned excessively heavy. .

After all, these last two measures lead to a sharp fall in the thermal insulation value and in particular to a shortening of the fire retardation time, which is highly undesirable.

This object is achieved in that the insulating layer has a greater density on the outside than on the inside and that the pointed connections are adapted to absorb forces in the direction parallel to the plane of the wall.

As a result of these measures, a greater, lateral stiffness of the wall construction is obtained. On the one hand, the combination of the measures ensures that lateral forces are absorbed at least in part by the pointed connections without the pointed connections having to be excessively heavy. The compressive forces are absorbed by the high-density mineral wool and transmitted to the underlying layer of lower-density mineral wool on the one hand and to the noses on the other.

It is noted that it is of course possible to fill the entire wall construction with mineral wool with a high density. This naturally leads to a firmer construction. However, increasing the density 35 leads to higher costs.

EP-A-0 849 420 discloses a construction in which mineral wool is used on the outside with a higher density, albeit in conjunction with a 1012302 3 screw connection which is not suitable for absorbing lateral forces. With this, an attempt is made to obtain a combination of a thick layer of mineral wool on the inside with acceptable thermal insulation and low cost, and a thinner, outer layer of mineral wool with a greater density to obtain a firmer construction and a optimal thermal insulation.

Although these measures lead to an improvement of the result, the results are not yet optimal; because the pointed connections can hardly absorb any lateral forces, the lateral pressure is transferred without significant reduction to the underlying layer of wool with a smaller density. The present invention shows a surprisingly large reduction in these forces, which are largely absorbed by the pointed connections. In doing so, they absorb these forces because they are loadable in the lateral direction.

However, an optimum result has not yet been obtained, because the transition between the high-density layer and the low-density layer is not optimally mechanically loadable. After all, there is a discontinuity here.

The associated problems are avoided by the measure according to a first preferred embodiment of the invention, wherein the density of the mineral wool layer continuously varies from a small density on the inner skin to a large density on the outer skin. This avoids discontinuities and the associated uneven loading.

The forces perpendicular to the plane of the wall are transmitted through the uniform transition of the density without discontinuity of continuity. A good distribution takes place over the surface of the wall.

According to a first preferred embodiment, on the inner side of the wall, the density is substantially constant over a substantial part of the total distance from the outer side.

This leads to an optimization of the thermal insulation and to material savings.

According to a further preferred embodiment, the substantially constant density part extends at least up to the noses.

This achieves that the introduction and fixation of the during the construction of the insulating layer 10 into the inner skin with the noses attached thereto takes place more easily; after all, the noses can engage in the mineral wool, where it still has a small density.

Furthermore, it is achieved that the entire space in the cassette is filled. This prevents the formation of longitudinal channels, which can lead to convection.

According to yet another preferred embodiment, the small density is between 30 and 40 kg / m3. Experience has shown that in combination with an insulation layer with a greater wall thickness, optimum thermal insulation is obtained.

Optimization on the other hand, namely a sufficiently high density to obtain the mechanical strength necessary there and yet a contribution to the thermal insulation, is obtained when the high density lies in the range between 55 and 85 kg / m3.

An optimization of this value is obtained when the high density lies in the range between 3 65 and 75 kg / m3.

According to a last preferred embodiment, the specific fiber direction of the mineral wool extends transversely to the main face of the wall.

This provides a greater mechanical load-bearing capacity, since this fiber direction leads to a maximum strength and a high resistance to lateral loads, ie shearing in the directions of the plane of the wall construction.

The present invention will now be elucidated with reference to the annexed drawings, in which 5 represent: figure 1: a partly broken away, perspective view of a wall construction according to the present invention; and Figure 2: a graph of the density course 10 of the mineral wool for explaining the present invention.

Fig. 1 shows a wall construction indicated in its entirety by "1", which is attached to vertically extending profiles 2. To the vertical profiles 2 is attached an inner skin 3, which is formed by cassettes extending mainly in horizontal direction. The cassettes are provided with a wall fixed to the profiles and with bent noses, indicated in their entirety with "4". On the outside, an outer skin 6 is provided, which is formed by a metal plate. It is preferably fluted.

The outer plate 6 is connected to the noses by means of screw connections 7.

Thus far, the construction corresponds to the construction described in EP-A-0 801 190.

A block of mineral wool 8 is arranged in the space between the inner skin 3 and the outer skin 6. According to the present invention, the density of the mineral wool block extends in the direction transverse to the direction of the wall construction from a low value of about 35 kg / m3 on the inside to a high value of about 65 kg / m3 on the outside. This course is continuous to avoid discontinuities, especially in the force course. Furthermore, in this configuration, the density from the inside to the length of the noses 4, the density is essentially constant at the low value.

1012302 6

This makes it possible to easily insert the mineral wool sheet behind the noses into the cassettes.

Figure 2 shows a graph of the density. This shows that over a total length of approximately 90 mm, being the thickness of the noses 4, the density is virtually constant. The density then increases in a continuous curve to the preferred value of 65 kg / m3.

This provides the advantages that have been explained in the preamble.

1012302

Claims (8)

Wall, comprising an inner skin mainly made of sheet material and an outer skin mainly made of sheet material, wherein: - an insulating layer made of mineral wool is placed between the inner skin and the outer skin, - the inner skin is provided with spaced at regular intervals, noses directed towards the interior of the wall, - the noses are connected to the outer skin by means of pointed connections, and - the noses are located at a distance from the outer skin, characterized in that the insulation layer has a higher density on the outside then on the inside, and that the pointed connections are adapted to absorb forces in the direction parallel to the plane of the wall. 2. Wall as claimed in claim 1, characterized in that the density of the layer of mineral wool continuously varies from a small density on the inner skin to a high density on the outer skin. Wall as claimed in claim 1 or 2, characterized in that the density on the inside is substantially constant over a considerable part of the total distance from the outside. 4. Wall according to claim 3, characterized in that the part of almost constant density extends up to the noses. Wall according to any one of claims 1-4, characterized in that the low density lies in the range between 30 and 40 kg / m3. Wall as claimed in any of the claims 1-5, characterized in that the high density lies in the range between 55 and 85 kg / m3. λ λ i 2 3 0 2 «· Wall according to claim 6, characterized in that the high density lies in the range between 65 and 75 kg / m3. Wall according to one of the preceding claims, characterized in that the specific fiber direction of the mineral wool extends transversely to the main face of the wall. 1012302