DE20108311U1 - Impact sound insulation - Google Patents

Description

The present innovation concerns an impact sound insulation body which contains expanded polystyrene polymer.

Impact sound insulation bodies are used, for example, with stone slab coverings, on steps, and together with or without tiled coverings. Such coverings are not very effective in reducing the passage of sound, so that extremely high impact sound is generated with such coverings. In order to insulate the impact sound with tiled coverings, for example, these are placed on a sound insulation layer. A well-known sound insulation layer of this kind consists of panels made of an expanded, i.e. foamed, styrene polymer. In such panels, i.e. impact sound insulation bodies, the styrene polymer generally has a density of less than about 15 kg/m^ and is elasticized.

However, the use of styrene polymers for the production of thermal insulation bodies is also known. Such a styrene polymer differs from the impact sound-absorbing styrene polymer in that it has a density of more than 15 kg/m^, for example a density in the range of 15 - 40 kg/m-3.

It is therefore known that two different types of insulating bodies made of expanded styrene polymer can be used when constructing a building, namely expanded styrene polymer with a density of < 15 kg/m^ for impact sound insulation bodies and expanded styrene polymer with a density in the range of 15 - 40 kg/m^ for thermal insulation bodies. Consequently, it has been necessary to use two different materials in this regard when constructing such a building, which obviously has an impact on the costs. Furthermore, because no difference can be seen between such bodies made of styrene polymer with the naked eye, the

AMS/db 10.05.2001

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There is a risk that the styrene polymer particles could be confused with harmful consequences on a construction site. This is where the innovation aims to remedy the situation. The innovation is characterized by the styrene polymer having a density of less than 15 kg/m3 and at least one particulate additive being evenly distributed in the styrene polymer, the density of which is higher than the density of the styrene polymer.

The advantages achieved by the innovation are essentially that, since different tasks can be fulfilled using only one type of body made of styrene polymer, considerable savings in manufacturing costs can be achieved. There is also no risk of confusion between bodies made of styrene polymer that cannot be distinguished with the naked eye in different applications.

Until recently, a thermal resistance of Λ = 0.039 W/m/°K was achieved with a thermal insulation body made of a styrene polymer. In new designs, especially with athermanous additives, the thermal resistance is now Λ = 0.033 W/m/°K.

It has been recently recognized that such styrene polymers containing athermanous additives, although they have a density of 15 kg/m^ or more, are excellently suited for impact sound insulation.

In the following, the innovation is explained in more detail using a drawing showing an implementation path.

The single figure shows a section through a corner area of a body made of expanded styrene polymer with additives, some of which are drawn at an enlarged scale.

The starting material for producing the impact sound insulation body according to the innovation is in the form of a granulate, which is expanded, i.e. foamed, to finally form the impact sound insulation body. The expansion or foaming of styrene polymer in the form of a granulate is known; reference is made, for example, to EP-A-O 177 621, EP-A-O 679 488, CH-A-668 033, CH-A-676 446. These documents also show that the impact sound insulation body according to the innovation can also be present as part of a molded body made from different styrene polymers, possibly even recycled plastic.

The figure shows a section through a corner area of a body made of expanded styrene polymer, which body is an impact sound insulation body.

The expanded and melted regions of styrene polymer are indicated with the reference number. According to the innovation, this styrene polymer has a density of less than 15 kg/m^. At least one athermanous substance is now embedded in this styrene polymer as an additive.

With such materials, a distinction is made between infrared-reflecting and infrared-absorbing materials.

Now assume that in a basic implementation of the innovation at least one additive is an infrared-reflecting substance. This additive is in the form of metal particles 2, for example aluminum or bronze.

In the illustrated version, this additive consists of aluminum in platelet form. Aluminum has a density of about 2700 kg/m^, which is much higher than the styrene polymer. These aluminum platelets 2,

which are shown exaggeratedly large, have dimensions in the range of 1 to 15 μ, wherein the diameter of the aluminum plates 2 is at least 10 times their thickness.

Based on the polymer, 0.3-1 wt.% of aluminum particles are contained, although in other versions a proportion in the range of 0.05 - 4 wt.% and up to approx. 6 wt.% is provided.

A further additive is an infrared absorbing substance which is arranged in the form of fine grains and is indicated by the reference number 3. This substance can be a metal oxide, e.g. A^C^, a non-metal oxide, aluminum powder, antimony sulfide, or a carbon-containing substance such as carbon black or graphite.

Only one of the additional additives can be present in the impact sound insulation body, or several such additives can be present at the same time. In any case, the total proportion of the one or more additional additives is a maximum of approx. 2% by weight based on the polymer.

A particularly preferred additional additive is antimony sulphide, which is in the form of fine grains with a grain size in the range of 10 - 60 µm.

Other such additives are carbon-containing substances, especially soot and graphite.

To produce the impact sound insulation body, a granular styrene polymer is foamed with at least one of the additives mentioned in the specified quantities, then cooled and relaxed. The relaxed foam body is then compressed to make it elastic. An impact sound insulation body can be produced in the form of a panel, for example, or as an impact sound insulation body made of various types of plastic.

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ink product, analogous to the manufacturing processes evident from the documents cited at the beginning.

Claims (8)

1. Impact sound insulation body comprising expanded styrene polymer, characterized in that the styrene polymer has a density of less than 15 kg/m ³ and at least one particulate additive is evenly distributed in the styrene polymer ( 1 ), the density of which is higher than the density of the styrene polymer. 2. Impact sound insulation body according to claim 1, characterized by at least one infrared-reflecting or infrared-absorbing additive. 3. Impact sound insulation body according to claim 1 or 2, characterized in that at least one infrared-reflecting substance is present in the form of metal particles ( 2 ). 4. Impact sound insulation body according to one of the preceding claims, characterized in that at least one infrared-reflecting substance is present in the form of platelet-shaped metal particles ( 2 ). 5. Impact sound insulation body according to one of the preceding claims, characterized in that at least one infrared-reflecting substance is aluminum, which is present in a proportion of less than 6 wt.%, preferably 0.05-4 wt.%, in particular 0.3-1 wt.% based on the polymer. 6. Impact sound insulation body according to one of the preceding claims, characterized in that at least one infrared-absorbing substance is a metal oxide, non-metal oxide, antimony trisulphide, carbon black or graphite. 7. Impact sound insulation body according to one of the preceding claims, characterized in that at least one infrared-absorbing substance is present in the form of grains ( 3 ). 8. Impact sound insulation body according to one of the preceding claims, characterized in that a respective infrared-absorbing substance or several infrared-absorbing substances are present with a total proportion of less than 2 wt.% based on the polymer.