DE10064784A1 - Insulating plate for bracket-mounted, rear-ventilated facades comprises covering layer having greater strength, especially plug passage strength, than base layer - Google Patents

Abstract

An insulating plate (1), especially for bracket-mounted, rear-ventilated facades, comprises a base layer (11) and a covering layer (12), both made of the same bound mineral fibers. The covering layer has a greater strength, especially plug passage strength, than the base layer. The fibers of the mineral wool in the covering layer have a different thickness to the fibers of the base layer. The median value d50 of the fiber diameter of the fibers of the covering layer is about 50-100% greater than that of the fibers of the base layer, producing a reinforced three-dimensional supporting framework in the covering layer increasing the plug passage strength. An Independent claim is also included for a method for manufacturing the above insulating plate. Preferred Features: The median value d50 of the fiber diameter of the covering layer is 6-13, preferably 7-10, especially about 8 mu m. The median value d50 of the fiber diameter of the base layer is 3-6, preferably 4-5, especially about 4 mu m.

Description

The invention relates to a facade insulation board according to the preamble of Claim 1 and a method for their production according to claim 8.

Multi-layer insulation boards are currently mainly used as facade insulation boards or roof insulation panels. When used as facade insulation panels, and here in particular with curtain-type, ventilated facades, these become immediate attached to the outer wall of a building. The attachment takes place either the by gluing or by dowelling, the insulation panels for heat and Serve sound insulation. If they consist of mineral wool, they are according to the DIN 4102 classified as non-combustible in building material class A.

Facade insulation panels of this type are often used as weather protection Glass fleece, which means that they are classified in building material class A2. As clothing For the curtain wall elements made of flat glass, ceramic plates and Like. Are used.

When using such insulation boards play in addition to their own weight especially the wind suction forces play an important role, which is a lifting of the insulation can cause fabric panels from the outer wall. Usually, therefore, too the fixation uses several so-called insulation dowels. However, since the mine The wool panels of the insulation boards are sensitive to the effects of specific forces special precautions are to be taken, so that on the one hand a reliable Hold the insulation board against the wall and on the other hand continue to have a good insulation effect are achievable. It has been shown that mineral wool boards with a higher bulk density are better suited to be held reliably by the insulation dowels.  

However, this is disadvantageous due to a higher use of materials, which additional costs caused.

Therefore, in practice, it has gone over to forming the insulation boards in multiple layers, whereby a base layer with a relatively low bulk density ensures good insulation properties and good "clinging" to the wall even with protruding concrete or mortar residues, and on the outside there is a cover layer with a higher one Bulk density is formed. Such an insulation board is known for example from DE 37 01 592 A1. With this facade insulation board, the top layer is subjected to additional compression and possibly an additional addition of binding agent, so that there is a much higher bulk density than in the base layer, by means of which a more or less reliable hold of the insulation board can be achieved by means of several insulation dowels on the wall. How reliable this structure actually works in practice depends on the following factors:
Basically, the fixation of an insulation board improves the more insulation material anchors are used on this board. However, since attaching these insulation dowels is very labor-intensive and the insulation dowels also represent thermal bridges, efforts are made in practice to use as little insulation dowels as possible.

In particular, the problem occurs with wind suction loads that the insulation panels only held by the heads of the insulation dowels on the wall, which is why Areas of the insulation panels that are far from the heads of the insulation dowels, below can bend away from the wall due to suction. This allows the shock edges of the individual insulation boards create additional thermal bridges. To do that encounter, it is desirable that the top layer has a relatively high flexural strength has, so that the inherent stability of the insulation board opposes these suction forces. One can counteract these disadvantageous phenomena by the Bulk densities in the cover layers increased, but this leads to an increase in price. the still has to be striven for that one has sufficient bending stiffness of the cover layer  receives so that it does not bulge when wind suction forces occur. Fer A sufficient dowel pull-through strength must be guaranteed.

The insulation boards previously used in practice therefore represent a problem promiss, in which the base layer has a relatively low bulk density to a high insulation effect and the top layer due to an additional Compression and possibly an additional binder input a high bulk density has less contribution to the insulation effect, but is relatively expensive.

It is therefore an object of the present invention to provide an insulation board, in particular to provide a facade insulation panel for curtain-type, ventilated facades that with commercial dimensions with the least possible use of material and only few, especially only one insulation anchor reliably against wind suction forces and it is still inexpensive to attach to the wall. Another job The invention is a method for producing such an insulation board show.

According to a first aspect of the invention, this object is achieved by an insulation board with the features of claim 1. This is particularly characterized in that fibers of mineral wool in the cover layer have a so-called median value d _{50 of} the fiber diameter, which is 50 to 100% larger than that of the fibers of the base layer.

Here, a median value d _{50 is used} for a distribution function in which there are particularly asymmetrical distribution curves - which is the case with mineral fibers. As is known, these distribution curves indicate the so-called central value or median value. It is the maximum size d ₅₀ that is undercut by half of the fiber collective. It is the value of the mean diameter d for which the total curve reaches 50%.

With the aforementioned median value difference of <50%, the invention advantageously recognized that the inherent stability of the insulation board even with a less expensive solution instead of increasing the bulk density, namely the layers to design a different average fiber diameter, significantly increased can be.

This can obviously be attributed to the fact that the larger medium Ren diameter of the fibers in the cover layer significantly improved strength properties are achievable, namely that you get a reinforced, three-dimensional support ge set up, which counteracts the dowel passage. At the same time, the Flexural strength of the cover layer to a significant extent, so that there is a risk of being exposed bending the edge areas of the insulation board is significantly reduced.

The insulation board according to the invention therefore comes with a much smaller Number of insulation dowels from, with commercial dimensions of at for example 1,250 mm × 600 mm, a single insulation anchor is usually sufficient, to reliably attach the insulation board. This reduces costs and the assembly effort essential. At the same time, the number of heat decreases bridge by reducing the insulation dowels, which also reduces the insulation overall property significantly improved.

It has also been shown according to the invention that this effect already occurs when the median value d _{50 of} the diameter of the fibers in the cover layer is at least 50% larger than that of the fibers of the mineral wool in the base layer.

Another advantage is that the mineral wool in the base layer has to make a relatively small contribution to the inherent stability of the insulation board, which is why it can be optimized with regard to the insulation properties. At the same time make the mineral wool of the base layer sufficiently elastic so that it  concrete or mortar remnants protruding from the wall can be adjusted and the The main surface of the insulation board nevertheless comes into direct contact with the wall surface.

Since the base and top layers are the same, there is also a Product in which no different materials are combined. This reduces the manufacturing effort and also facilitates possible re-use evaluation or disposal. Finally, there are no differences Chen expansion coefficients, which lead to a deflection of a multilayer board being able to lead.

Advantageous further developments of the insulation board according to the invention result from the features of subclaims 2 to 7.

For example, particularly advantageous properties of the insulation panel have shown when the median value d ₅₀ of the diameters of the fibers is microns of the top layer 6 to 13, while the median value d ₅₀ of the diameters of the fibers of the base layer 3-6 is .mu.m. In these areas, on the one hand, particularly good insulation properties for the base layer and, on the other hand, particularly good strength for the cover layer can be achieved. A median value d _{50 of} the diameter of the fibers of the cover layer between 7 and 10 μm and in particular around 8 μm has proven to be particularly advantageous. With regard to the median value d _{50 of} the diameter of the fibers of the base layer, values between 4 and 5 μm and in particular around 4 μm have proven themselves in practice.

He can also further improve the inherent stability of the top layer target if these have a higher binder content compared to the base layer has. The ratio of the binder content of the top layer to the binder can be changed The mean content of the base layer is in a range between 1.1: 1 and 3: 1, which means that the insulation board according to the invention further with respect to each other the following properties of strength and insulation can be improved.  

In particular, it is possible that the binder content in the top layer is between 2.2% and 6% and preferably about 4%, and that the binder content in the base layer is between 2% and 5.5% and preferably about 3.5%. The insulation board produced in this way has been particularly well optimized Excellent properties.

A further improvement in the properties of the insulation board according to the invention can be achieved if the density ratio between the top layer and the base layer is set specifically. So the ratio of the bulk density of the Cover layer for the bulk density of the base layer in a range between 1.25: 1 and 5: 1 and preferably 1.5: 1, whereby the inherent stability or strength of the Top layer can be increased again.

In particular, it is possible that the bulk density of the top layer is between 40 and 100 kg / m ³ and preferably about 60 kg / m ³ , and that the bulk density of the base layer is between 20 and 80 kg / m ³ and preferably about 40 kg / m ³ is. In these bulk density ranges, particularly advantageous properties of the insulation board have been shown both in terms of the good dowel pull-through strength and bending strength as well as the insulation properties.

In addition, the cover layer can also be precompressed, as a result of which Intrinsic stability further increased.

According to a further aspect of the invention, the solution provided is Task provided a method for producing such an insulation board, which has the features of claim 8.

The method according to the invention thus provides for the first time to distribute the melt of a fiber base material to differently operating defibration stations and thus to form the same primary nonwovens, the fibers having different median values d _{50 of} the diameter. With the method according to the invention it is thus possible, with relatively small procedural changes compared to conventional procedures, to produce very diverse products whose properties are optimized, just like the insulation board according to the invention. Since the process is based on tried and tested steps that have been newly put together in this sequence, it is characterized by high process reliability with little preparation effort.

The invention is described below in exemplary embodiments with reference to the figures in FIG Drawing explained in more detail. It shows:

Figure 1 is a perspective view of a section of a curtain, ventilated facade, which is formed by several insulating panels according to the invention. and

Fig. 2 is a vertical section through the arrangement of FIG. 1.

According to the illustration in the figures, a plurality of mutually abutting insulation boards 1 are each fastened to a wall 3 by means of an insulation plug 2 . In addition, each insulation board 1 can also be glued to the wall 3 . The insulation panels 1 are present in the usual dimensions of, for example, 1,250 mm × 600 mm and a thickness of 60 mm, 80 mm, 100 mm or 120 mm.

On the outside of the facade there is also a plurality of clothing elements 4 , which are anchored in a known manner by means of anchors 5 through the insulation boards 1 in the wall. Between the insulation panels 1 and the clothing elements 4 there is a rear ventilation gap. An interior plaster layer 6 is also arranged on the inside of the wall 3 .

As can be seen in particular from the dashed line in FIG. 2, the insulation boards 1 each have a base layer 11 and a cover layer 12 . Furthermore, the insulation plug 2 passes through the insulation board 1 and anchors it to the wall 3 , a head 21 of the conventional insulation plug 2 coming to rest on the outside of the insulation board 1 .

The head 21 interacts with the cover layer 12 , which has a greater anchor strength than the base layer 11 . In the present example, the cover layer 12 has fibers with a median value d _50, the diameter of about 8 μm, a binder content of 4% and a bulk density of 60 kg / m ³ . The base layer 11 has fibers with a median value d _50, the diameter of approximately 4 μm, a binder content of 3.5% and a bulk density of 40 kg / m ³ .

The base layer 11 therefore shows good insulation behavior, while the cover layer 12 has sufficient inherent strength so that tearing out at the location of the dowel head 21 is reliably avoided at the expected wind suction forces F _SOG . As can be seen in particular from FIG. 2, such suction forces act on the entire surface of the insulation board 1 . Due to the selected characteristic data for the cover layer 12 , however, a deflection in the edge areas of the insulating boards 1 under the influence of the suction forces F _{SOG can be} reliably avoided.

These characteristic values can be varied for other application examples. On the basis of the different design of the median value of the fiber diameter of the top or base layer provided according to the invention, it is additionally possible for the person skilled in the art to adjust the product characteristics of the insulation board 1 via the binder content of the layers or the respective bulk density.

For the manufacture of the insulation board 1 two different Zerfaserungsein devices from a melting tank with the same basic material for the mine ral wool, ie acted on with the same glass composition. A fiberizing device produces fibers for the cover layer which have a greater thickness, ie a larger median value d _{50 of} the diameter, than the fibers produced by the other fiberizing device for the base layer. Furthermore, more fibers are added to the fibers in the fiberizing device for the cover layer in the chute than is the case with the fibers in the fiberizing device for the base layer.

The fiberizing device for the top layer provides one with uncured Binder-provided primary fleece for the top layer, which is then in one ß precompaction step is compressed.

Then the pre-compressed primary fleece for the top layer with the their defiberer leaving primary fleece for the base layer together quantitative results. The two primary fleeces are then used as a curing device serving tunnel furnace for curing the binder. With this step the two primary fleeces are also connected to each other at the same time.

The multilayer insulation element designed in this way is then further processed in a separating device of a conventional type, not shown here, by means of cross and / or longitudinal cuts to form insulation panels 1 with predetermined dimensions.

To set the desired according to the particular application characteristics of the insulation board 1, the fiberizing stations for the individual Pri can be märvliese selected such that a desired ratio of the median value d ₅₀ of the diameters of the fibers of the cover layer to the median value d ₅₀ of the diameters of the fibers of the base layer providable is. Furthermore, the addition of binder medium in the chute can vary. The degree of pre-compression of the primary fleece for the cover layer and possibly also a pre-compression of the primary fleece for the base layer can also influence the bulk density ratio achieved between the cover layer and the base layer.

Since the individual fibers of the cover layer are already due to their larger dimensions improved tensile and compressive strength properties compared to the fibers of the Having base layer, it is also possible to use both layers with the same raw to design density. The improvement of the properties of the insulation board regarding  The anchor strength is then determined solely by the more stable fibers in the deck layer reached.

Claims (8)

1. Insulation board ( 1 ), in particular for curtain-type, rear-ventilated facades, with a base layer ( 11 ) and a cover layer ( 12 ), which are each formed from the same material, bound mineral fibers, the cover layer ( 12 ) having greater strength, in particular dowel pull-through strength than the base layer ( 11 ), characterized in that fibers of the mineral wool in the cover layer ( 12 ) have different thicknesses than the fibers of the base layer ( 11 ), namely the median value d _{50 is} the fiber diameter of the fibers of the cover layer ( 12 ) 50 to 100% larger than that of the fibers of the base layer ( 11 ), as a result of which a reinforced three-dimensional support structure is formed in the cover layer ( 12 ) to increase the dowel pull-through strength. 2. Insulation board according to claim 1, characterized in
that the median value d _{50 of} the diameter of the fibers of the cover layer ( 12 ) is between 6 and 13 µm, preferably between 7 and 10 µm, and in particular approximately 8 µm, and
that the median value d _{50 of} the diameter of the fibers of the base layer ( 11 ) is between 3 and 6 µm, preferably between 4 and 5 µm, and in particular approximately 4 µm. 3. Insulation board according to claim 1 or 2, characterized in that the cover layer ( 12 ) and the base layer ( 11 ) have a different binder content, the ratio of the binder contents of the cover layer ( 12 ) to the base layer ( 11 ) in a range between 1 , 1: 1 and 3: 1. 4. Insulation board according to claim 3, characterized in
that the binder content in the top layer ( 12 ) is between 2.2% and 6% and preferably about 4%, and
that the binder content in the base layer ( 11 ) is between 2% and 5.5% and preferably about 3.5%. 5. Insulation board according to one of claims 1 to 4, characterized in that the cover layer ( 12 ) and the base layer ( 11 ) have a different bulk density, the ratio of the bulk density of the cover layer ( 12 ) to the bulk density of the base layer ( 11 ) in a range between 1.25: 1 and 5: 1 and preferably 1.5: 1. 6. Insulation board according to claim 5, characterized in
that the bulk density of the cover layer ( 12 ) is between 40 and 100 kg / m ³ and preferably about 60 kg / m ³ , and
that the bulk density of the base layer ( 11 ) is between 20 and 80 kg / m ³ and preferably about 40 kg / m ³ . 7. Insulation board according to one of claims 1 to 6, characterized in that the cover layer ( 12 ) is pre-compressed. 8. A method for producing an insulation board ( 1 ) according to one of claims 1 to 7, comprising the steps:
Melting of fiber base material in a melting tank ( 101 ),
Dividing the melt into at least two melt strands,
Supplying a melt strand to a first defibration station ( 103 ) for the base layer ( 11 ), defibrating the melt and producing a primary fleece provided with uncured binder for the base layer ( 11 ) with fibers whose diameter has a predetermined first median value d ₅₀ ,
Feeding another melt strand to a second defibration station ( 102 ) for the cover layer ( 12 ), defibrating the melt and producing a primary fleece provided with uncured binder for the cover layer ( 12 ) with fibers, the diameter of which has a predetermined second median value d ₅₀ , which is 50 to 100% greater than the first median of the fiber diameter of the base layer ( 11 ),
Bringing together the primary fleeces of the base and top layers,
Curing the binder to form a multilayer insulation element, and
Separate insulation panels ( 1 ) from the insulation element.