SK60195A3 - Heat insulating slabs for facades - Google Patents

Abstract

An insulating slab (1) for facades (6) is made of ground polystyrene foam waste bound by cement paste. The grain size of the polystyrene foam waste is 2 mm to 15 mm and the insulating slab has an apparent density of 0.2 to 0.35 kg/l.

Description

Technical field

The invention relates to thermal insulation boards for facades.

BACKGROUND OF THE INVENTION

Previously known thermal insulations on facades, which are made of polystyrene thin lightweight boards or as extruded lightweight boards, are glued and laminated to the facades. Fiberglass or mineral wool is also attached to the façade using lattice grates, which are additionally provided with a weatherproof cover, which protects the façade against rapid cooling.

However, these and similar measures are unsuitable for the facades of tall buildings. In particular, they are unsuitable for the retrofit of tall buildings made of prefabricated solid concrete.

Equally, from the point of view of fire safety, it is not allowed to fit building facades with foam boards, as a protection of the facade, from a height of approximately eight meters above the foundation. The use of mineral wool or glass wool also raises the problem that if the wall cladding is soaked, these materials will lose the thermal insulation properties and the weight of the water-absorbent cladding of the façade may be so large that the structure is no longer capable of holding. to withstand this load, creating a risk of collapse of the structure. This danger also persists in the event of icing.

Likewise, the additional casting of the lining masonry, the purpose of which in some cases is to produce an operationally safe thermal insulation façade, especially in tall buildings, is uneconomical. In new buildings, however, this system is used, and as a filler to achieve the thermal insulation effect is used any kind of light building auxiliary material.

However, the known thermal insulation systems for improving the thermal insulation of a façade exhibit the disadvantages that, after construction, they themselves need an overlap which, on the one hand, prevents moisture penetration into the insulating material and on the other hand gives the facade an appearance. In addition, the so-called complete thermal protection of the façade lining of expanded polystyrene foam also requires a protective coating made of a building screed adhesive with an interwoven mesh, whereby the flammable foam material is both fire-protected and UV-protected. A protective coating is also necessary to prevent mechanical damage from the outside. The protective coating also fulfills the task of the desired color formation of the facade.

In this case, it is necessary that all the overlays or protective coatings of the thermal insulation system of the facade are treated with extreme precision, since any minor unevenness or each smaller hairline or the like. are recognizable by the eye. For example, joint joints on the exterior walls of buildings made in the construction of large prefabricated concrete buildings cannot be permanently clad without cracks, as the reinforcing mesh of the protective coating cannot assume the forces of shrinkage and expansion of the concrete prefabricates. .

SUMMARY OF THE INVENTION

The aim of the solution according to the invention is to eliminate the above mentioned disadvantages and to create heat insulating boards of the kind mentioned at the outset which are easy to manufacture and install. This is achieved by the features set forth in the first claim.

These heat-insulating boards according to the invention are distinguished by their large dimensions and good thermal insulation while being easy to install. These heat insulating boards can be fixed with dowels in combination with gluing. In addition, due to the use of the cementitious adhesive as a binder of the polystyrene foam, it is also guaranteed that it does not become soaked in water. Furthermore, the heat-insulating boards mentioned above guarantee frost resistance, which boards can be easily machined because they are not brittle. The thermal insulation boards of the invention can also be used to clad facades of tall buildings. The boards from 15 cm thick are also suitable as fire protection boards, which can also protect reinforced concrete skeletons from fire damage.

The proposed thermal insulation boards also have the advantage that polystyrene foam waste can be advantageously used in their construction, which is environmentally friendly. For example, crushed foam containers may be used for processing.

Similarly, the cost of producing the thermal insulation of the façade of the thermal insulation boards according to the invention is lower due to the simpler installation than in the known systems, although the façades can be shaped. Thermal insulation boards are usually provided with profiling since their assembly.

The features set forth in the second claim have the advantage that the heat insulating boards thus produced receive virtually no water, since the particles on the surface of the polystyrene foam are glazed. Here, the strength of the thermally insulating boards produced is increased by sintering the particles on the surface of the polystyrene foam. A smaller amount of polystyrene particles may be admixed in the production of the thermal insulation boards.

The heat insulating boards according to the invention can be machined very easily, for example by milling. Boards with a format of, for example, 40 cm * 80 cm * 15 cm can be provided with a profile edge on all four edges from the outside. In order to produce the profile edges, it is essential that the panels are only fastened to the facade.

By the features set forth in the third claim, the advantage is achieved that the chipping of particles from the cut surface is prevented.

Due to the use of a white cementitious adhesive as a binder of the polystyrene foam particles, the advantage is achieved that the heat insulating boards can be provided with less coverminers.

In particular, the features set forth in the fifth patent claim provide a simple assembly.

Another object of the invention is to provide a method of insulating a façade using the thermal cladding boards according to the invention, which allows easy installation of the insulating boards.

According to the invention, this object is achieved by the features contained in the sixth claim. In this connection, a secure fastening of the thermal insulation boards is achieved by said installation.

year may

Depending on the features of the seventh patent, it is possible to omit the layering being applied to the boards, the paint which also causes the layers of the heat insulating boards, the wicking of the dispersion can penetrate into the

Thus, heat capillary blackened concrete slabs, used around 0 fasteners, can be used. The paint that disperses the exterior as a result of being especially reinforcing or fabric depth tiling the facades to a remarkably very kg / l.

boards easy

At the same time, it is hot to be on the heat plates, for example, in air with a processing density, only the thermal adhesion of the applied paint coatings is increased, especially when these surfaces are pre-treated with a base dispersion.

In particular, a simple assembly of the thermal insulation boards is achieved by the features set forth in the eighth claim.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is further elucidated with reference to the drawings, in which:

Fig. 1 shows a thermal insulation board according to the invention, FIG. 2 is a schematic representation of a facade lined with the heat insulating panels of FIG. 1, FIG. 3 shows the assembly aids, FIG. 4 is a cross-sectional view of the mounting device of FIG. 3, FIG. 5 shows a detail of the connection of the individual thermal insulation boards, FIG. 6 is a front view of the facade lined with the thermal insulation boards of FIG. First

Examples of the invention

In FIG. 1 shows a thermally insulating slab 1 made of polystyrene foam-lightweight concrete. In this case, the shredded polystyrene waste is bonded by means of a cementitious adhesive or a white cementitious adhesive. The cladding panels 1 have a density of from 0.2 to 0.35 kg / l, their thermal conductivity being about 0.065 W * m- ² * K- ¹ .

In the case of a façade lined with heat-insulating boards 1, a reduction in heating energy expenditure of up to 40% is achieved. The polystyrene foam particles have a grain size of from 8 to 5 mm.

The heat insulating boards 1 are preferably treated with hot air, which sealed and glazed pores exposed by cutting off the waste of polystyrene foam. This virtually prevents their soaking up with water.

The thermal insulation boards 1 may be provided with profiles 2 formed by milling. In FIG. 2 the openings 3 formed in the side walls 4 of the heat insulating plates 1 are further shown. These openings 4 serve to accommodate obliquely inserted dowels 5 which extend into the façade 6, as is further illustrated in FIG.

2. In this case, the edges of the sides of the façade cladding can be covered with shaped parts 7.

In the side walls 4 of the heat-insulating plates 1, plates 8 are provided, which are provided with a groove 9, in which recesses 10 are provided with openings 11, which serve to guide the drill bit to make holes for receiving dowels 5. side with tips and blades 13 which, due to the curvature of the sheets 8, penetrate into the thermal insulation boards 1 and ensure a secure holding of the sheets 8.

As shown in FIG. 4, the recesses 10 formed in the sheet 8 also serve as a support for the heads of the screws 5 screwed into the dowels 14.

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As can be seen further from FIG. 5, the side walls 4 of the thermal insulation boards 1 may be provided with a groove 16.

into which the flexible strip 17 is inserted.

The assembly of the thermal insulation boards 1 is carried out in such a way that the thermal insulation board 1 is glued to the facade with a frost-resistant adhesive and at the same time the thermal insulation board 1 is additionally secured with dowels 14 and screws 15.

FIG. 6, it is also evident that the thermal insulation boards 1 can be machined to the desired size either by cutting or milling without any problems. In this case, it is advantageous to treat the cutting points with hot air, since the polystyrene foam particles are glazed at the cutting points. Furthermore, the heat insulating boards 1 can be provided with paint, in particular by spraying with a dispersion paint, thereby increasing the strength of the surfaces of the heat insulating boards thus treated.

Claims (6)

PATENT Thermal insulation boards for a facade, characterized in that the thermal insulation boards (1) are made of crushed waste of cement-bonded polystyrene foam, the grain size of the polystyrene foam waste being 2 to 15 mm and the density of the thermal insulation board ( 1) is 0.2 to 0.35 kg / l. Thermal insulation boards according to claim 1 or 2, characterized in that the polystyrene foam particles are heat-treated or sintered. Thermal insulation boards according to claim 1 or 2, characterized by cut off heat-melted parts. and by i zolačnej that boards surfaces (1) are on the- 4. Thermal insulation boards according to any of the on the- years 1 to 4, confess ignating s a team J that waste polystyrene foam bonded bud with normal cement, or white cement. 5. Thermal insulation boards according to any of the on the- 1 to 3, characterized in that the thermally insulating boards (1) are provided with grooves (16) on their side walls (4) for the insertion of flexible strips (17). 6. Method of insulating the facade by means of thermal insulation9 The heating plates according to any one of claims 1 to 5, characterized in that the heat-insulating plates (1) are glued to the facade (6) and subsequently fixed to this by means of dowels (14). Method according to claim 6, characterized in that after fixing, the thermal insulation boards (1) are provided with a color coating. Method according to claim 6 or 7, characterized in that in the side walls (4) of the heat-insulating plates (1), the plates (8) are provided with a groove (9) which serves to guide the drill during making the holes (11) for dowels (14).