WO2006069961A1 - Building board - Google Patents

Abstract

The invention relates to a building board for use in interior construction which is selected from the groups comprising mineral fibre boards, plaster fibre boards and cement boards containing 1 - 25 wt % zeolites.

Description

 building board

The present invention relates to structural panels.

Building boards are widely used in the construction industry for the production of floors, walls and ceilings or ceiling and wall cladding.

For various applications there are various optimized plates, for example plates with increased moisture stability, plates with increased fire resistance or with reduced sound transmission behavior.

There are different manufacturing processes for cement boards. All these methods have in common that the binder is premixed with various additives. This mixture is mixed with water and applied on a Abbindeband, which may for example be segmented, surface. For reinforcement, a fiberglass scrim or fabric may be required as the cladding. The fiberglass scrim or fabric is then placed on the binding tape immediately prior to application of the binder-aggregate mixture. After application of the binder-aggregate mixture, a second fiberglass scrim or fabric is optionally applied as a finishing layer. The sandwich element thus formed may pass through an extruding or smoothing unit which causes compaction and smoothing of the plates. The raw plates produced in this way can still be separated in the wet state by running saws or separated after complete setting. Typically, cement boards have a cement content of about 30 wt .-%, the rest are mineral fillers, such as sand or Kalksteinkörnungen.

Mineral fiber boards consist of mineral fibers, composed of eg stone and / or glass wool fibers, cellulose fibers, clay aggregates, lightweight aggregates such as perlite, other mineral aggregates and fillers and starch as a binder. Mineral fiber boards are mostly used for the production of ceiling tiles. The mineral fiber plate production runs analogous to the production of paper or cardboard on screening machines, eg Langlochsiebmaschinen. Plates of sufficient strength are made by combining several thin layers Generates and passes through various compaction and drying units. The rope-shaped web is separated by cutting or sawing devices. The resulting individual plates can finally be coated, colored and textured.

Gypsum fiber boards consist predominantly of stucco gypsum, CaSO ₄ ^• Λ h H ₂ O as a binder and 10 to 20% cellulose fibers. The production of the gypsum fiberboards takes place either in accordance with the semi-dry process, known by the name Siempelkamp-Fermacell process or Schenck process, and by wet technology, in the form of a flow-on, winding roll or hat-check technique. All these methods have in common that intimate mixtures of the binder with the pulp, which is produced dry by grinding or by wet pulping by Pulpung produced. These are applied flat by spreading technology in the dry state or wet as a slurry on a moving binding tape. In the case of semi-dry process, the "cake" applied to the belt is then moistened and pressed, with most of the mixing water being squeezed out.

Object of the present invention was to provide structural panels with improved properties. Surprisingly, it has been found that structural panels containing 1 to 25% by weight of zeolites can lead to a reduction of indoor air pollutants. Preferred zeolite contents are at least 5% by weight, more preferably at least 10% by weight, more preferably the ranges are 5 to 20% by weight and 10 to 15% by weight.

Particularly high levels of zeolites (> 30% by weight) make the plate mechanically unstable, since they do not undergo any binding interactions with the remaining plate matrix.

The contents refer to the proportion of zeolite in the entire plate, after drying (atro).

The zeolites used according to the invention can be premixed in the production of cement boards together with the binder and the aggregates. In the case of mineral fiber boards, the zeolites can also be mixed with the other auxiliaries, such as lightweight aggregates, etc., and used in the production.

In the case of gypsum fiber boards, the zeolites may be added to the stucco, for example, and the gypsum fiber board may be produced in the usual way.

WO 2004/033385 discloses an artificial stone slab. This contains zeolites in the range of 40-50% by weight, which are mixed with white cement and an acrylate emulsion in order to achieve a bond between the white cement, the zeolite and the aggregate. The zeolites support the connection between cement and aggregates. It is crucial that the artificial stone is particularly light because it is attached to a wall for decoration. By contrast, the cement boards according to the invention represent the building material for the wall itself and can remove static loads.

The structural panels according to the invention preferably contain less than 5% organic admixtures, preferably less than 3%, and most preferably are substantially free of organic ingredients, especially film-forming organic binders such as latex, acrylates, styrene acrylates. Surprisingly, in the structural panels according to the invention, the zeolites are inserted relatively loosely into the panel matrix, which can be observed by scanning electron microscopy. This explains the activity of the zeolites.

The cement board according to the invention preferably has a density of 800 to 1200 kg / m ³ .

Particular preference is given according to the invention to using natural zeolites, ie zeolites which are not synthetically produced (for example synthetic preparation: by reacting SiO ₂ -containing and Al ₂ O ₃ -containing substances with alkali metal hydroxides at temperatures greater than 50 ^° C. in an aqueous phase) , Natural occurring zeolites are therefore those that are mined from deposits.

Particularly suitable as zeolites are those with a mineral phase composition which is selected from the group consisting of clinoptilolite, hay Landite, chabazite, phillipsite, morderite and mixtures thereof. The zeolites are not only thermally activated, ie thermally dehydrated, but surprisingly also natively usable.

In a particularly preferred embodiment, the zeolites are used natively, i. without thermal activation or drainage. A thermal pretreatment of the zeolites is not necessary. Surprisingly, it has been found that during the drying of the structural panels according to the invention at least a partial dewatering of the zeolites takes place, which is sufficient for a catalytic degradation of pollutants. The open plate structure allows the air pollutants to interact with the embedded zeolite particles. Film-forming organic binders, as used in WO 2004/033385, would exclude or disturb this.

Surprisingly, activation of the zeolites appears to occur during the preparation / drying of the products. The dehydration of zeolites may e.g. measured by thermogravimetric analysis (TGA).

Nevertheless, such a zeolite in the building board according to the invention exhibits the activity required according to the invention for reducing air pollutants.

The construction boards preferably contain zeolites with a particle size <200 .mu.m, preferably less than 150 .mu.m. This can most easily be achieved by fine grinding.

Particularly suitable zeolites have d50 values between about 30 and about 90 microns, more preferably between 40 and 70 microns.

The zeolites preferably have an oil number (determined in accordance with DIN 53199) of not more than 25 g / 100 g of zeolite, preferably not more than 10 g / 100 g of zeolite.

The materials used according to the invention preferably contain less than 3% diatomaceous earth and the zeolites are not mixed with 'antibacterial cations'. The present invention also relates to the use of the structural panels according to the invention for reducing indoor air pollutants. Air pollutants that can be successfully removed from the indoor air are, for example, formaldehyde, benzene, ammonia and tobacco smoke. Even odors, such as fishy odor, can be reduced, as could be demonstrated experimentally by the degradation of triethylamine. Thus, the plates are also suitable for reducing odor nuisance from the food and hygiene sector (manure, toilet areas, etc.).

Surprisingly, the air pollutants are not bound to the materials, but degraded / decomposed, so that no saturation of the materials occurs.

For formaldehyde, the maximum permissible workplace concentration (MAK value) is 600 μg / m ³ . In a smoking room is at an air exchange rate of 0.5 changes / hour, the average formaldehyde content at 220 ug / m ³ . The WHO assumes a guideline value of 100 μg / m ³ for health protection. A desirable value in apartments is about 60 μg / m ³ .

An average benzene content in a smoking room at an air exchange rate of 0.5 changes / hour is about 45 μg / m ³ . The desired value in apartments is <10 μg / m ³ .

By using the building boards according to the invention, correspondingly reduced values can be obtained.

example

Gypsum board panels with 10% natural zeolites (native ie, non-dewatered) microns with a maximum grain size of 200 and a d ₅₀ of 40 microns were laid out in a room with normal air, whereby on 1 m ³ chamber volume 1.23 m ² gypsum fiber board surface was , In this room was by continuous supply of a defined Schadgasgemisches a respective noxious gas concentration with the noxious gases formaldehyde and benzene and a noxious gas mixture set from cigarette smoke. The air exchange rate of the respective mixture was 0.5 changes / hour, ie the pollutant mixture was completely renewed within two hours. In the effluent mixture, the remaining pollutant value was measured as the gas concentration.

Due to the contact with the structural panels, the noxious gases were largely degraded and it turned out in the system a noxious gas concentration from the initial value (inflowing mixture) to the equilibrium value (effluent mixture)

in the case of formaldehyde from 600 μg / m ³ to <100 μg / m ³ 220 μg / m ³ to <50 μg / m ³

for benzene from 45 μg / m ³ to <10 μg / m ³

one.

In cigarette smoke also a significant reduction of odor (smell of cold smoke) was detected by the contact of the smoke with the gypsum fiber board according to the invention by olfactometry.

In the test series it was also determined that the pollutants are not stored in the building board, but reactively converted into harmless compounds.

Experiments with altered zeolite contents in the slabs and cement slabs or mineral fiber slabs yielded similar results.

Claims

claims 1. Building board for interior design selected from the group consisting of mineral fiber plates, gypsum fiber boards and cement boards containing 1 to 25% by weight of naturally occurring zeolites. 2. Building board according to claim 1, characterized in that the zeolites have a particle size <200 microns. 3. Building board according to one of claims 1 or 2, characterized in that the zeolites have a d50 value between 30 and 90 microns. 4. Building board according to one of claims 1 to 3, characterized in that the zeolites have a mineral phase composition which is selected from the group consisting of clinoptilolite, heulandite, chabazite, Phillipsit, morderite and mixtures thereof. 5. Building board according to one of claims 1 to 4, characterized in that the zeolite is used natively. 6. Building board according to one of claims 1 to 5, characterized in that it is a mineral fiber board. 7. Building board according to one of claims 1 to 5, characterized in that it is a gypsum fiber board. 8. Building board according to one of claims 1 to 5, characterized in that it is a cement board. 9. Building board according to one of claims 1 to 8, characterized in that <3 wt .-% organic substances are contained, in particular based on film-forming organic binder. 10. Use of a building panel according to at least one of claims 1 to 9 for the reduction of indoor air pollutants. 11. Use according to claim 10, characterized in that the air pollutants consist of formaldehyde, benzene, ammonia, tobacco smoke and mixtures thereof. 12. Use of a building panel according to one of claims 1 to 9 for the reduction of disturbing odors in interiors. 13. Use according to claim 12, characterized in that the odors originate from the food or hygiene sector.