DE3018965A1 - CARRIER MATERIAL FOR AN INSULATING ELEMENT - Google Patents

Description

3018960

Ing.Klaus Rö'thel, Heintzmannstr. 152, 4630 Bochum, Germany Carrier material for an insulating element

The invention relates to a carrier material for an insulating element according to the preamble of claim 1.

Insulation elements are used, for example, to cover roofs, walls and ceilings as well as pipes and ventilation ducts. You can use at least three layers as a base have water-vapor-proof carrier material, which with an insulating material made of glass and / or mineral fibers. Of the three layers of the carrier material, the outer layers are made of metal foils, thin metal strips, chemically treated or untreated papers and plastic films are formed. Which materials each are used, usually depends on where they are used. In principle, however, they should have properties such as that they meet the respective requirements in terms of strength and temperature, fire and chemical resistance suffice. They also serve as transport protection, installation aids, visible surfaces and fire protection. In particular, the outer layers but exercise the function of a so-called vapor barrier, i.e. they should have two mostly different climates to both Clearly separate the sides of an insulation element from one another.

To produce an insulating element, e.g. two full-surface layers of material, for example made of aluminum foil, are first required connected to one another, for example glued. Then one of the outer layers of the glass and / or Mineral fibers, for example from rock wool, existing insulating material attached.

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For this purpose, the two full-surface material layers are replaced by a suitable one in a first treatment section Adhesive or connected to one another by a sealing compound and then in a second treatment section that is formed multi-layer carrier material provided with a coating that ensures adhesion of the insulation to the carrier material.

In this context, it is known to first coat the carrier material in a sealable manner independently of the insulating material. For this purpose, the roller application process or the pressing of the sealing compound through a slot nozzle is usually chosen. The carrier material pretreated in this way is then used for the purpose of joining with the insulation material in a later operation heated with the aid of a heating roller, for example, so that the sealing compound is plasticized, thereby a Compounds with the insulation material and causes the insulation material to adhere to the carrier material when it cools down. - Further it is known, shortly before the connection of the carrier material with the insulating material, the carrier material, which is usually in the form of a sheet, with aqueous or dissolved adhesives such as dispersions, emulsions or water glasses. The lanes occupied in this way become immediate then brought into contact with the insulation material and then dried.

Regardless of which application or coating process is used, however, this means high material and Litigation costs associated. In particular, if adhesives are used to attach the insulation material, this requires application and drying after the insulation material has been attached to the carrier material, high-quality technical equipment and an exact one

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Monitoring. Then there are the energy costs for the Drying.

In addition to the production-related disadvantages, another significant disadvantage of the known insulating element is seen in that they do not meet more highly qualified fire protection requirements. There is a risk that it will run along the sealing layer between the insulating material and the adjacent material layer a flame can continue to eat because you no barriers are opposed here.

Now it is possible to apply a coating to one of the outer layers even with a three-layer carrier material, which is both flame-retardant or at least flame-retardant, as well as perfect adhesion of the insulation material to the carrier material permitted. Such a coating is, however, disproportionately complex and consequently with additional costs, a lot of time and the use of special machines.

The invention is accordingly based on the object of providing a carrier material for a sound and / or thermal insulation To create an insulating element that requires considerably less effort in terms of production technology and which one too A connection with an insulating material that meets the high requirements of fire protection is guaranteed.

The solution to this problem is according to the invention in the features of the characterizing part of claim 1.

The core idea of the measure according to the invention is therefore the utilization of the material coming into contact with the insulating material.

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determine the material layer on another full-surface material layer, sealing compound also applied over the entire surface as a means for fastening the insulation material to the carrier material. So it can be done for the purpose of another coating of the carrier material Determination of the insulation material can be dispensed with. This eliminates the need for additional work steps and corresponding machines. Staff and Material such as adhesives or sealants are saved, so that the overall production costs of insulating elements are ultimately significantly reduced.

By warning of at least three-layer carrier material (two outer layers, one connecting layer), two of which are full-surface and therefore adequate water vapor tightness have, the requirements placed on a carrier material can be applied in a particularly suitable manner to the various layers be distributed.

To connect the carrier material to the insulating material, only the perforations are made when the sealable mass is heated into contact with the insulation material, so that only certain areas of adhesion are present. It is of particular importance that the training, size and distribution of these traps in the plane of the material layer adjoining the insulating material is made in such a way that taking into account the location of the complete insulation element, the local conditions depending on the training of the materials of the carrier material as well as the character of the sealing compound at the place of use Expected fires a spread of flames from trap to the point of trapping is perfectly prevented. The uninterrupted surface areas form when they consist of an incombustible Layer, such as a metal foil, exist, therefore, to a certain extent, flame barriers, which prevent the flames from spreading in the Level of the insulation

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Safely prevent elements. One with the carrier material according to the invention The insulation element provided therefore also meets very high requirements for preventive fire protection.

The sealable full-surface layer between the perforated material layer and the adjacent full-surface material layer must enter into a good connection with the insulation material in suitable sealing temperature ranges and also after cooling down Ensure perfect connection of the material layers. It is therefore advantageous if the sealing compound is high-pressure or low-pressure polyethylene is. Polyvinyl chlorides and polyvinylidene chlorides are also conceivable. Furthermore, polyesters, polyamides, polypropylene or mixtures or copolymers of these substances can be used as well as synthetic resins and ionomers can be used. The material layers held together by the sealable mass consist of Substances that meet the requirements of the respective place of use in terms of strength, temperature, fire and chemical resistance suffice. This can be metal foils, thin metal strips, chemically treated or untreated papers as well as Plastic films and fiberglass fleece or fabric act. These materials not only ensure problem-free processing of the carrier material when connecting to the insulation material, but they are also extremely pliable, flexible and resilient. Furthermore, they have a high resistance to tearing and tear propagation, and in particular a good barrier property against water vapor.

Although it is usually sufficient that the carrier material consists only of the perforated material layer and another, exists due to the sealable mass with this connected full-surface material layer, it can be advantageous in some applications be that between these material layers to increase the Fe-

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a fabric, individual longitudinal threads, a lattice, a Layers or fiber fleece can be inserted. The outside can be used the full-surface material layer, possibly also as a visible surface are used, so that certain symbols or signs on this area, for example in the context of advertising, can be applied.

A flame spread in the plane of an insulating element is according to an advantageous embodiment of the invention this reliably prevents the ratio of the perforated surface areas to the non-perforated surface areas of the outer layer is measured approximately as 2: 8 to 8: 2.

According to the invention, the openings can be individual larger openings. However, there is also the possibility summarize smaller breakthroughs in groups. It is essential for both embodiments that sufficient large, non-perforated surface areas between the individual perforations or between the different ones Detention site groups are present that further spread effectively prevent a flame front.

In this context, the perforations can then be distributed uniformly or unevenly in the plane of the material layer be arranged. They can also have a uniform or a non-uniform contour. Right-angled, round, oval or any angular openings.

The breakthroughs can be formed by perforation or by punching a material layer that is full-surface in the initial state be. The resulting material particles can then advantageously be recycled.

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Furthermore, it is possible for the perforations to be made in areas on a full-surface material layer Strips of material are formed. It is also conceivable that the openings through intersecting strips of material are formed. This can already be done, for example, during the production of the carrier material from across to with the sealing compound coated material layer displaceable rollers run, so that then patterns arise in which the material strips superimpose crosswise or at least approximately crosswise and in this way openwork and non-openwork Surface areas arise.

Finally, an advantageous embodiment can also consist in that the openings are provided with transverse slots subsequent lengths of a full-surface material layer are formed. The transverse slots are expediently arranged in rows with one another offset. Their length depends on the dimensions of the openings required in the processing state. she however, must not run across the entire width of a web of material. After slitting, the entire web or the respective track section lengthened. In the process, the path or the path section narrows and the slots widen to breakthroughs. In this state of affairs, the train or the track section is connected to a full-surface layer of material.

The invention is explained in more detail below with reference to the exemplary embodiments shown in the drawing. Show it:

Fig. 1 in perspective in multiple enlargement a detail of an insulating element in vertical section;

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Pig. 2 shows, in a reduced plan view, a length section of a perforated material layer of an insulating element;

FIG. 3 shows a length section of a perforated material layer according to FIG. 3 again in a reduced plan view another embodiment and

Fig. H

and FIG. 5 shows longitudinal sections of a reduced plan view

transversely slit material layer before and after the length.

The insulation element 1 illustrated in detail in FIG. 1 consists of a three-layer carrier material 2 and one insulation material 3 connected to this carrier material 2

The carrier material 2 has a full-surface outer layer 4 made of an aluminum foil and a material layer 6 provided with openings 5, which is also made of an aluminum foil consists. The two aluminum foils 4, 6 are sealed with a sealant 7 made of polyethylene, which is applied over the entire surface to the outer layer 4 has been connected to each other.

When the carrier material 2 is connected to the insulating material 3, which consists for example of rock wool, the carrier material 2 heated so far that the polyethylene 7 is plasticized and therefore with the insulating material 3 in the area of the perforations 5 can connect. After cooling, the insulating material 3 then adheres firmly to the carrier material 2.

From FIG. 2 it can be seen that the openings 5 in the material layer 6 that is in contact with the insulating material 3

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can be designed and grouped in different ways. That is, there can be openings 5a distributed individually over the surface be provided. The openings 5a can have a uniform or irregular contour. You can go about the length of a Insulating element 1 can be distributed regularly or irregularly or combined in groups 5b.

As FIG. 3 shows, it is conceivable that the openings 5 can also be produced by laying strips of material 8 crosswise. These material strips 8 then form the material layer 6th

In Fig. 4, a material layer 6 is shown with rows transverse slots 9 offset from one another are provided. This material layer is then elongated in order to produce perforations or stretched so that the slots 9 become perforations 5c expand, but the material layer becomes narrower.

In all embodiments, it is important that the The distance between two adjacent individual openings 5, 5a, 5c or between adjacent groups of openings 5b is so great that these surface areas are unambiguous Flame arresters are effective.

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Claims (1)

Patent claims: IJ carrier material for an insulating material made of glass and / or Mineral fibers, which are water-vapor-tight and at least three-ply is formed and is connected to the insulating material to form an insulating element for sound and / or thermal insulation, thereby characterized in that one of the two outer layers (4, 6) of the carrier material (2) perforations (5, 5a, 5b, 5c) as Adhesion points between the insulating element (3) and a perforated outer layer (6) on a full-surface material layer (4), also has a full-surface layer (7) made of a sealable mass. 2. Support material according to claim 1, characterized in that the ratio of the perforated Surface areas (5, 5a, 5b, 5c) to the uninterrupted surface areas of the outer layer (6) approximately like 2: 8 to 8: 2 is dimensioned. 3. Carrier material according to claim 1 or 2, characterized in that the openings (5b, 5c) are grouped together. H. Carrier material according to claim 1 or one of the following claims, characterized in that the openings (5, 5a, 5b, 5c) are distributed uniformly or unevenly. 130048/0201 mm O mm 5. Support material according to claim 1 or one of the following Claims, characterized in that the openings (5, 5a, 5b, 5c) have a uniform or a have a non-uniform contour. 6. Carrier material according to claim 1 or one of the following claims, characterized in that the openings (5j 5a » 5b) are formed by perforating or punching a full-surface layer of material. 7. Carrier material according to one of Claims 1 to 5 _}, characterized in that the perforations (5) are formed by material strips (8) applied in areas to a full-surface layer of material. 8. Carrier material according to one of claims 1 to 5 or "J _3, characterized in that the openings (5) are formed by intersecting strips of material (8). 9 · carrier material according to one of claims 1 to 5 » characterized in that the openings (5c) by transverse slots with the following lengths of a full-surface material layer are formed. 130048/0201