DE2915977A1 - INFLAMMABLE EXTERIOR HEAT INSULATION LAYER WITH SURFACE COATING - Google Patents

Abstract

1. Noncombustible thermal-insulation layer with surface coating, to be applied externally to buildings or industrial facilities, in the form of rolls or sheets consisting of glass-fibre or mineral-fibre laminations (4) in which the direction of the fibres is set perpendicular to the surface, wherein said fibre laminations (4) are connected by at least one wide-mesh fabric (5) on the surface, the connection of the fabric (5) to the laminations (4) being by means of adhesive (6) which is applied only along the fabric threads (5) so that the spaces between the fabric threads (5) are not covered by the adhesive, the thermal-insulation layer being installed such that the wide-mesh fabric (5) is on the outside of the building or facility.

Description

It is known to make buildings and other objects from the outside with mineral fiber boards or mats to protect against heat loss. this is usually carried out in such a way that plates or rollable mats made of glass or mineral wool by gluing, nailing or Screwed to the object to be isolated, while additionally a panel on a suitable base (e.g. cement asbestos panels on slatted frames) to protect the thermal insulation and the building structure against the effects of the weather. Such a system is technically referred to as a curtain wall. However, such a construction is very complex. It was therefore an obvious choice to use the mineral fiber panels directly without the complex construction of a curtain wall to provide a protective top layer, which can consist of plaster or glued panels. However, such top layers do not have held because the mine-ralfaeerplatten as a result of their loose Binding and the direction of the fibers running parallel to the surface split very easily. The anchoring of the cover layers on the structure is therefore completely inadequate.

Attempts have therefore been made to use heat- organic foam insulation panels, such as styrene foam, polyurethane foam and others to glue or mechanically fasten to the object to be isolated and then with suitable cover layers to provide. Thermal insulation layers made from such foams are very stiff and hard and can reduce the tensile stress on the top layer easily transferred to the structure.

However, it soon became apparent that the high strength of the thermal barrier coatings made of organic foam at the same time brought considerable disadvantages. On the surface of a structure, through Solar radiation on the one hand and temperature differences due to frost on the other of 70 K and more occur. Normally this temperature is absorbed and compensated by the building structure, so that it is there are no significant temperature differences between the structure and the outer layers arise that considerable mechanical stresses occur as a result, which lead to the detachment of the plaster or panel material being able to lead.

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291597?

The situation is different, however, when between the structure and the surface layer there is a thermal insulation layer. In this case the temperature of the building remains constant while the temperature of the surface layer fluctuates considerably, because the heat transfer and thus represent Temperature equalization is prevented by the thermal insulation layer. This has the consequence that the top layer of plaster or plate material is subject to considerable changes in length depending on the effect of temperature, so that tensions arise that are unyielding Lead the substrate to the detachment of the top layer.

Also the reinforcement of a top layer of plaster mortar with fiberglass fabric and covering the joints of the thermal insulation panels with strips of fabric or fiber fleece could not remedy this problem.

For the same reason, it was also damaged when it was used the inherently soft mineral fiber panels or mats, because the top layer of the panels did not tear off here, but the panels split up themselves and thus the adhesion of the top layer to the building was interrupted.

Furthermore, insulation boards made of organic foam fail when exposed to heat in case of fire. Even if such foam sheets are made flame-retardant, a temperature of only 470 K to soften, melt or char the material: the applied top layer is peeling off and endangered the fire fighting team and other people.

The invention has now set itself the task of providing a thermal barrier coating to develop, dia the described building requirements that does not fail in the event of fire and the use of normal plastering methods as well as the attachment of panel material Binding agents or adhesives are permitted without fear of any damage.

According to the invention, the thermal insulation layer consists of mineral fiber lamellae. Mineralwolla panels are used as mineral fiber lamellas Marked cut strips of uniform width, dia around 90 rotated and lined up have a brush-like structure, the fiber direction being set perpendicular to the surface is.

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The drawings are used to explain the subject matter according to the invention Fig. 1-4 attached. Fig. 1 shows schematically the manufacturing process of lamellas and their connection with a fabric. The grain direction can be seen from the hatching. The commercially available mineral fiber plate (1) is pushed through the device (2) cut the lamellas into strips of equal width (3). Sis are turned by 90 and together to form a lamellar track (4) lined up.

The arrangement of this fiber direction has the following effects: The thermal insulation layer (4) can absorb considerable tensile forces perpendicular to the surface. Values of up to 40 N / cm were measured. With Such strengths the anchoring of a top layer on the masonry with the help of a flat connection is more than guaranteed.

On the other hand, such a lamellar layer (4) is exposed to stress very flexible parallel to the surface. The fibers act like small pendulum supports. Therefore changes in length of the Cover layer can be added without creating tension against the substrate or masonry. Thus, with one such Thermal insulation according to the invention ensures that any stiff coating, be it as plaster or as a glued-on panel, cannot detach itself from the thermal insulation layer after exposure to temperature changes.

When using such a thermal insulation system made of mineral fiber slats However, it is not possible in practice on the construction site to attach the mineral fiber lamellas (3) to the Binzeln building structure. Just as little can the individual slats (3) beforehand, for example in the factory, glued together at their contact surfaces, so that thermal insulation panels would arise, which are then fastened as a whole could become. The adhesive points hold, but the lamellas (3) break through when they are unpacked: the effect prevents the top layer from tearing off, which inevitably means that there is also little cohesion when it occurs parallel to the surface Stresses. The proposal has therefore been made in German PA 22 23 101 and US Pat. No. 3,012,923,

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Glue the Faaer lamellae (3) on one side on a flexible sheet and in this way a rollable thermal insulation mat made of mineral fiber slats to manufacture. Such a proposal is useful for general insulation technology, especially for pipe insulation, but not applicable in construction. In particular, the proposal made in German PA 22 23 101 to use a paper web makes such a system completely unusable for construction. Every such flexible, full-surface coating acts as a separating layer and endangers the cohesion of the substrate and the insulating layer and top layer. In the event of a fire, a paper layer would detach the system at even relatively low temperatures to lead.

According to the invention, this problem is now solved as follows. To ensure that the fiber lamellas (4) adhere to the substrate and in turn Adhesion of the surface coating - plaster, panels - to the fiber lamellas (4) must be ensured by the fiber lamellas directly with the binder on the structure and the plaster or the binder with which the surface panels are glued be connected. This process is shown in FIG. Fig. 4 shows schematically the detail of a with the Thermal insulation system according to the invention provided wall piece in layered Construction.

The thermal insulation layer (4) is on the masonry (1O) with the help of the Binder (11) attached. A binder layer (12) is in turn applied to the thermal insulation layer (4), which in turn the cover layer (13) securely holds. The layers (12 + 13) can also consist of a two-layer external plaster.

The thermal insulation layer (4) should be a rolled-up lamella mat (θ) be delivered to enable easy simple assembly. In order to achieve this, according to the invention, as in FIG. 1 shown, a wide-meshed fabric (5) provided with adhesive (6) and attached to the lamellar web (4) by suitable devices (7) applied so that the rollable lamellar web connected to fabric (δ) (θ), which is then delivered in roll form.

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By the trick according to the invention, only the wide-meshed fabric To provide (5} with adhesive (6), that in Fig. 2a is enlarged situation shown reached. On the lamellar web (4) the wide-meshed fabric (5) is only along the threads (5) Adhesive (6) provided so that the fibers of the lamellar plate (4) between the threads (5) are open for wetting with other binders lie. Fig. 2b shows again enlarged the integration of the fiber (s) with adhesive (6j on the lamella (4). For practical implementation According to FIG. 4, this means that the binder layers (11 + 12) adhere directly to the fiber lamellas, although the fabric (5) is glued to the lamellar track (4).

The wide-meshed fabric (5) can be made of synthetic fibers or glass fibers or mineral fibers, but not of fibers that can rot, such as hemp, cotton or the like.

According to the invention, this wide-meshed fabric (5) not only has the Task, the fiber lamellas (4) to processable units to hold together, but also to act as reinforcement for an applied binder or plaster layer (12). That's because of it possible because the binder layer (12) penetrates the wide-meshed fabric (5) and sometimes even completely encloses it, so that tensions within the binder layer (12) can be taken over by the fabric and thus crack formation in the cover layer (12 + 13) is counteracted.

Advantageously, as shown in FIGS. 3a-c, the fabric (5) cut a little wider than the lamellar track (θ)! in order to a one-sided protrusion (9) is created, which covers the abutting edges of the lamellar webs (β), as shown in Fig. 4, so that a complete plaster reinforcement is ensured. Fig. 3a shows the plan view of such a lamellar web (δ). If a fiber lamellar web (4) is on one side according to the invention with a Wide-meshed fabric provided with adhesive (ö) as in Fig. 1 and Connected to Fig. 3c, a rollable lamellar web (θ) is created. However, if the other side of the lamellar web is also based on the invention Connected with a wide-meshed fabric (5) provided with adhesive, a stiff lamellar plate is created according to Fig. 3b,

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A plate with a similar structure was already in the German Utility model 73 19 376 described. There the coating is made of glass fiber fabric of any mesh size in an adhesive layer embedded. There is no knowledge on which this request for protection is based that a wide-meshed fabric is used must be glued to the fiber lamellas in such a way that that the adhesive layer does not hinder the direct connection of plaster or binder with the fibers of the lamellar web.

Since now according to the invention according to FIG. 4, the anchorage (11) of the thermal insulation layer from Fasarlamellen (4) with the substrate (1O) and dia of the cover layers (12 + 13) with the fiber lamellas (4) directly takes place with the fiber, the adhesives (6) for connecting the wide-meshed fabric (ö) and the fiber lamellas (4) can be used as desired Be kind, as they have no influence on the cohesion of the entire system.

It can therefore be used as an adhesive (6) to connect the wide-meshed fabric (5) with the fiber lamellas (4) both organic and inorganic substances are used. Therefore, the use of hot melt adhesives, hot melt adhesives, solvent-based Adhesives, also dispersion adhesives, as well as inorganic hydraulically setting adhesives are possible. The adhesive application shown in FIG. 1 (6) by immersion is only exemplary. Likewise, dar Adhesive can be applied to the fabric by spraying, rolling or other devices belonging to the prior art. Depending on the temperature resistance of the fabric fibers (5) used, the setting or hardening process of the adhesive can involve the action of heat can be accelerated or the application is carried out in a hot process, with hardening taking place by cooling. Likewise can inorganic binders, such as phosphate binders, can be made to react at higher temperatures. The pressing process shown in FIG (7) can be combined with such a heat treatment using state-of-the-art equipment.

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in

When choosing the binder between the substrate and fiber lamellas as well as the binder for fastening the top layer or the plaster to the thermal insulation strips made of fiber lamellas are essential Consider facts to ensure the durability of such connections.

Experience has shown that alkaline substances such as portland cement and white lime hydrate can considerably attack mineral fibers, especially glass fibers. This happens in the presence of moisture and can continue until the lime in the cement or plaster mortar is completely carbonized. This attack can be complete Lead dissolution of the fibers, so that it is according to Fig. 4 at the point of contact between fiber (4) and binder (11) respectively Plaster (12) can come to the dissolution of the connection, so that the plaster (12 + 13) or the fiber lamellar web (4) falls off.

According to the invention, this risk is countered as follows. Extensive Tests have shown that the intensity of an alkali reaction with mineral fibers from different raw materials is very different. Glass fibers are the least resistant, the behavior of mineral fibers made from low-lime basalt or from raw materials is much better, which form a pozzolan after melting.

Therefore, according to the invention, mineral fiber lamellas made of basalt fibers, pozzolan fibers or alumina fibers are preferably used for such a thermal insulation system. A zirconium glass specially developed to be alkali-resistant can also be used as a fiber base. Fibers made from these raw materials can be processed according to the invention in connection with alkaline binders such as Portland cement or white lime hydrate, if these binders are added so much lime-binding substances that any free lime that escapes is reliably bound. Such lime-binding substances are pozzolans or active silicic acid. All pozzolans are known as trass, fly ash and others; silica powder or SiO ₂ dust and other SiO2 compounds can be used as silica.

Should a possible reaction between the fiber-lamellar layer (4) and Binders (11 + 12) are generally avoided, especially when

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if the fiber / lamellar layer consists of commercially available glass fiber, as a binder (11 + 12) and as a plaster layer (13) according to the invention a dispersion binder is used on the basis of various known suitable synthetic resins. Such plasters and binders do not attack ilas fibers and are weather-resistant. On the other hand, however, these binders and plasters consist of organic substances and disintegrate relatively quickly when exposed to fire. If a particularly temperature-resistant fastening and coating of the thermal insulation layer made of fiber lamellas (4) is to take place, Thus, according to the invention, high-alumina cement can be used as the binder in order to produce suitable connecting layers (11 + 12) and surface basecoats (13). Alumina cement does not contain free lime and therefore does not attack glass fibers.

The thermal insulation system according to the invention represents a considerable technical progress because it has the following properties in unites:

- Tensile connection between the subsurface and the surface

- Stress-free compensation of temperature-related changes in length the surface

- Reinforcement of the surface layer without additional effort

- high thermal insulation

- incombustible

- rot-proof components

- open porosity = · no moisture content

- Simple attachment with known binders and commercially available device

- Reactive connection of fibers and binders.

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Claims (9)

KARL-HELMUT IHLEFELD O Q I C Q 7 Quellenhof Kalistadt 6943 Birkenau Call 06201/21916 April 18, AZ: 1.25.34 PA / GM Unmistakable outer thermal insulation layer with outer surface coating PATENT CLAIMS i.j Exterior to be applied to buildings or industrial facilities Thermal insulation layer with surface coating characterized by that a) as a thermal insulation layer glass fiber or mineral fiber lamellar sheets (4J can be used in which the grain direction is set perpendicular to the surface, bj these Feser lamellae [3] through a wide-meshed fabric (5) be connected on the surface so that they can be mounted as roller tracks (Fig. 3c) or panels (Fig. 3b), wherein the connection of the fabric (5) with the lamellae (4) takes place by means of adhesive (6) which is only applied along the fabric thread (Fig. 2, 5 + 6) is applied, so that the space between the fabric threads (5) not worn adhesive (6) are covered. 2. Thermal insulation layer according to claim 1, characterized in that gskannzaichnat the mineral fiber lamellas (4) are preferably made of a wide range alkali-resistant fiber such as basalt fiber, pozzolan fiber, tonard fiber or made of zircon fiber » 030043/0524 3. Thermal insulation layer according to claim 1 + 2, characterized in that the wide-meshed fabric (5) on the lamellar webs (θ) consists of rot-resistant material such as synthetic resin threads, fiberglass or mineral fibers. 4. Thermal insulation layer according to claims 1-3, characterized in that the wide-meshed fabric (δ) only on one side of the lamellar webs (8) is applied so that a rollable mat (Fig. 3c) is created, this mat (θ) being mounted so that the wide-meshed fabric is on the outside. 5. Thermal insulation layer according to claims 1-3, characterized gekannzeichnat that the wide-meshed fabric (5) from two sides onto the lamellar web (8) is applied, so that a stiff plate (Fig. 3b) is made of lamellar strips. 6. Thermal insulation layer according to claims 1-5, characterized in that the outer fabric layer (ö) is wider than the lamellar web (4) is cut so that the abutting edges of the lamellar web or - panels (θ) covered by the protruding fabric edge (s) will. 7. Thermal insulation layer according to claims 1-6, characterized in that for fastening the fiber lamellas (4) on the structure (Fig. 4, 10) and / or surface plates (13) on the fiber lamellas (4) and / or to produce an external plaster (12 + 13) which is applied directly to the thermal insulation layer (4), binding agent (11 + 12) which are alkali-free and / or none can be used have free alkalinity, such as synthetic resin dispersion binders or plasters. 8. Thermal insulation layer according to claims 1-6, characterized in that the binder or plaster (Fig. 4, 11 -13) consists of an alkaline reacting agent Basic material such as Portland cement, white lime hydrate ader a mixture of the two, but in 030043 / 052A Sufficient amounts of lime-binding substances such as pozzolans and / or silicates are added so that any free lime that escapes or that is loosened is reliably bound. 9. Thermal insulation layer according to claims 1-6, characterized in that the binder or plaster (Fig. 4 11-13) is made with the aid of a hydraulically setting but alkali-free cement, such as high-alumina cement. Ö30043 / 052Ä