NL9420007A - Method and materials for the remediation of spaces contaminated with harmful substances. - Google Patents

Description

Short indication: Method and materials for the remediation of spaces contaminated with harmful substances.

DESCRIPTION

The invention relates to a method for remediation of spaces charged with harmful substances, as well as to materials used for that purpose.

Increasing environmental awareness as well as highly sensitive analytical methods have increasingly brought public attention to the burden on our environment from harmful substances. With regard to buildings burdened by harmful or malodorous substances, there was an increased need to clean them up with as little effort as possible. In addition, it was recognized that it is necessary to determine the presence of harmful substances with simple means, in order to meet the need for remediation or repairs. register the remediation result. Harmful substances are considered here which already cause minor irritations, allergies or diseases in humans. These include, for example, wood preservatives such as pentachlorophenol (PCPs) and lindane, plasticizers such as polychlorinated biphenyls (PCBs) as well as formaldehyde; the latter was and is used in chipboard and is now considered to be a possible carcinogen. Hydrocarbons, which are optionally aromatic, or chlorinated derivatives thereof, as harmful substances in the above sense, e.g. escape from lacquers, paints or glues.

Particularly problematic pollutants are PCBs that have been used, for example, as plasticizers in joint sealing compounds, in particular when building buildings from ready-made elements. New insights have shown that the PCBs diffuse over time from both the sealing compound into the adjacent concrete elements and from the joint seals are released to the ambient air. The air charged with PCBs is distributed throughout the building via ventilation. The PCBs thus released by the joint seals, the so-called primary sources, deposit partly bound to particles in the rooms, but also largely dissolve in wall paints and plastics. As a result, a series of so-called secondary emission sources have been formed some time after the release, in particular painted wall and ceiling surfaces being mentioned here. These secondary sources then generally have such a large amount of PCBs and form such a large emission surface that removal of only the joint seals cannot effect a decrease of the PCB concentration in the air of the rooms below the safety values.

A further source of harmful and malodorous substances can be floor carpets. The emission is caused, for example, by the fact that starting materials of these products react under the influence of moisture and / or the influence of components of the substrate material. Even after the floor covering has been removed, the bottom will furthermore cause malodour or respite. harmful substances, so far either the entire floor had to be removed or an intermediate floor with aeration behind it had to be constructed.

A further source of emissions for unpleasant, sometimes also health-damaging emissions are additives from the building material itself. For example, many buildings have been affected by ammonia fumes, which can be traced to the use of ammonium salts, urea or organic amines in the furthest sense, such as in antifreeze for concrete and mortar. In addition, the cause of the amine exhalation can often also be referred to as an earlier use of a space for, for example, animal husbandry, which leads to the building elements being permeated with the pollutants from the air for a long time. When the sources of these substances were removed, such as for example a zoning change from a stable building to a residential or business space, the substances were re-emitted by the secondary sources, wall and ceiling surfaces. The cause and effect of this situation can be compared with, among other things, the problem of the PCB load.

DE-A-38 18 993 discloses a method for the remediation of spaces charged with harmful substances. Here, however, the space charged with harmful substances is cleaned. This takes place because air is passed past adsorbents by suitable measures in an artificial manner or only by passive circulation. The air polluted with harmful substances is for instance forced through adsorption towers provided with adsorbents. Another possibility known therefrom consists in conveying the air along large-area flat materials loaded with adsorbents, such as curtains, for example. However, this method has the decisive drawback of only engaging the already loaded air in the room. This leads to the fact that the cleaned air mixes again and again with the air polluted with harmful substances and that, in the best case, a dilution effect is achieved.

A possibility for cleaning up of pollutant-containing joint sealing compounds is described in DE-A-40 28 434. The sealing compound, the primary source, is cut and cleaned up by suitable measures. However, the method therefore only focuses on the primary source. However, as already described above, the pollutants from the secondary sources, wall and ceiling surfaces, also place a significant burden on the air in the room; these secondary sources cannot be remediated with the aforementioned method.

The object of the present invention is to provide a method for the remediation of spaces charged with harmful substances. This object is achieved in that the ejection source is directly covered with a material containing adsorbent particles. The essential advantage here is that suitable materials according to the invention prevent the harmful substances from escaping through the covering layer and thereby prevent the harmful substances from migrating to the air in the room. The method according to the invention therefore takes a step earlier in the remediation of the pollutant-polluting sources than the methods known in the prior art. Thus, in the method according to the invention, the harmful substances are prevented from entering or even slightly entering the air of the room. can form secondary sources of emission, while the methods described so far rely on the removal of harmful substances from the polluted air in the room.

The complete covering of the emission source according to the invention has two decisive advantages: No more harmful substances enter the room and adsorption takes place where the concentration of harmful substances is highest.

For example, the method according to the invention allowed the radon concentration in residential buildings to be reduced to such an extent that limit values, which serve as health precautions, could be respected even in spaces that were heavily loaded before.

An embodiment of the method according to the invention consists in additionally covering the elements or objects located in the vicinity of the primary emission sources with materials containing adsorbent particles. This cover should prevent the release of harmful substances, which arise because harmful substances from the primary emission sources diffuse into these surrounding elements and can be released into the air from the room during migration on the surface of these building elements.

In a further embodiment of the present invention, the material is selected from the group of open-pore foams, nonwovens, and inorganic and organic binders. In particular, it is an open pore foam of 0.5 to 5 mm thick, preferably a cross-linked PU foam, which contains finely ground adsorbent particles and a binder. The material may as well comprise a fibrous web with a thickness of 0.1 to 2.0 mm, which comprises the adsorbent particles and the binder. According to a further embodiment, the material is a paint layer, a plaster layer, a sound-proof plaster layer or a floor plaster, which contains the adsorbent particles. The material according to the invention comprising the adsorbent particles may just as well be a legible material, preferably a floor covering backing.

The term binders means all substances that connect substances of the same or different types. For example, in the case of a plaster layer according to the invention, they are all non-hydraulic, hydraulic and latent hydraulic binders (gypsum, water glass, sorel cement, anhydride, magnesia binders, whitewash, water lime, cement, blast furnace slag, etc.). In the case of open-pore foams and nonwovens, the binders are, for example, all natural or synthetic substances, which act as solutions, dispersions, molten masses or liquid reactive plastic systems after assembly (e.g. by suitable resins and plasticizers and sometimes also by pigments and fillers) are used for the connection of materials of different types.

As regards the use of a plaster layer or floor plaster comprising the adsorbent particles for the method according to the invention, such compositions have preferably proved to be satisfactory, which at the same time serve as a sound-insulating plaster layer. One reason for this could be the high porosity, which at the same time allows good accessibility to the adsorbent. The plaster layer is generally supplied as a dry mixture with up to 50% by weight of adsorbent particles and made into a dough before use. Likewise, the substrate to be remediated can be covered by an additional floor plaster, which comprises up to 50% by weight of adsorbent particles, by the method according to the invention.

A further embodiment of the method according to the invention consists in that the adsorbents can also be incorporated in a wallpaper paste. This paste may consist, for example, of a 40% ethyl acetylate dispersion in which 60% by weight of milled and water-emulsified activated carbon is added. With this, walls and ceilings with a layer of 300 μτη thick can be covered and a normal wallpaper can be applied to this layer. The adhesion is good.

If moisture-insensitive molecular sieves are used as adsorbents, a white base color is obtained, to which arbitrary color pigments can be added. It remains important to control the thickness of the layer effectively, to avoid local weak spots due to insufficient quantities of adsorbents.

The adsorbent materials can, however, also be incorporated in a paint instead of in wallpaper paste, which then has to be applied with sufficient thickness. Because of its appearance, hardly any activated carbon will be used for this, but molecular sieves. Paints are especially suitable if irregular resp. non-flat bodies (cables, pipes) or breaks must be covered. In the manufacture of materials for the process according to the invention, care should be taken that the adhesive mass or binder does not contain substances which can be absorbed by the adsorbent particles. The person skilled in the art knows suitable solutions, which need not be further explained here. It is nevertheless recommended, however, to confirm the choice of binder by, for example, a preview.

A further embodiment of the method according to the invention consists in that the material with the adsorbent particles is a wallpaper on which a cross-linked PU foam of 1 to 5 mm loaded with adsorbent particles is applied. Such foams are preferably extruded and dried with a mixture of ground activated carbon and a binder dispersion. In this case, a charcoal loading of up to 200 g / m2 is achieved, the binder / charcoal ratio on the dry matter ranging from 1: 1 to 1: 5.

A further embodiment according to the invention consists in that the material comprising the adsorbent particles is a support layer of a flat support material from the group of paper, paper wallpaper or flat textile assemblies, such as for example fabrics, knitted fabrics, non-woven fabrics or glass fiber fabrics, and adsorbent particles are applied to this carrier layer. This carrier layer preferably forms a test strip with the particles applied thereon, which is applied to the covered or uncovered building parts to determine the escape of environmental poisons by sealing layers or to determine the release of environmental poisons.

A flat support material to be used for the process according to the invention, which comprises activated carbon spheres, is described in EP-A-118 618 and in EP-A-90 073.

With regard to the emission source with the adsorbents, these test strips according to the invention can be used both outwards and inwards, for example in the latter case to detect escapes through a wallpaper with adsorbent properties or by floor coverings with adsorbent properties. As a test strip, a strip of 20 x 100 mm, containing about 0.5 g of activated carbon, has proved to be very effective and easy to handle. An embodiment according to the invention consists of a double-sided adhesive tape, one side of which is provided with adsorbent particles and the other is covered with a siliconized protective paper to be removed before use. The strip is packaged in a gastight envelope, which protects the activated carbon until use and is also used for returning the strip to the analytical laboratory. For example, the strips can be applied to the underside of chairs, tables, etc. by applying some pressure and also removed again.

Another application for this test strip is the monitoring of the remediation of buildings polluted with pollutants, which is made clear by means of an example. As already described above, evaporation of PCBs in plate construction caused large surface-fighting contamination of walls and ceilings, which can be neutralized by covering the contaminated surfaces with wallpaper containing activated carbon. It is expedient to be able to determine the possible escape of PCBs by the wallpaper in time. For this purpose, the test strip with the adsorbent particles in the direction of the wall is adhered to the surface of the adsorbent wallpaper. Preferably, an adhesive strip overlapping the test strip (1 cm overlap on all sides) is preferably used, so that the adsorption layer does not come into contact with adhesive. In addition, a sealing layer, for example an aluminum foil, can be provided on the side facing the interior to increase the effectiveness of the strip.

With regard to the remediation of a floor or floor covering that emits malodorous or harmful substances, an embodiment of the method according to the invention consists of laying a layer or a material between the contaminated floor or floor covering and the new carpet or other new floor covering. whereby the malodorous and harmful substances are adsorbed. For this method according to the invention, for example, on a flexible support material, granular resp. spherical adsorbents, preferably activated carbon, but also porous polymers, glued and covered with an easily permeable textile material. A flat support material which can be used for this method according to the invention and which contains activated carbon spheres is described in EP-A-118 618 and in EP-A-90 073.

Another possibility is to provide the carrier material with a water-vapor-permeable coating, which acts as an adhesive for the adsorbents. The adsorbents are sprinkled in this coating; after drying, the resulting layer of adsorbents is covered with a slightly flat textile composition. In addition to the layer of the adsorbents, this completely covering coating means that an additional sealing layer is built in which, on the basis of its water vapor permeability, allows the floor to "breathe". The use of an adsorbent material, which does not form part of the floor covering, subsequently makes it possible to lay any floor covering on this material. However, the adsorbents can also be applied directly to the floor covering. A requirement for this is a high-quality back cloth, which at the same time is an adhesive for the adsorbents. This back covering can also be covered by a slightly flat textile assembly. In this method, the adsorbents are at least 50%, preferably between 70 and 80% freely accessible. This is advantageous in view of the adsorption kinetics, since it is not necessary to migrate through an adhesive layer. Activated charcoal, which is incorporated into the back upholstery, for example, in powder form, is less effective in comparison, on the basis of reduced accessibility of the outer surface.

A further embodiment of the method according to the invention consists in that the material, which contains the adsorbent particles, is a combined material, which consists of a carrier layer of a flat carrier material from the group of paper, paper wallpaper, or flat textile compositions, such as for instance fabrics, knitted fabrics, non-woven fabrics or glass fiber fabrics, a layer which is present on this carrier layer and which contains the adsorbent particles and a covering layer applied to this layer which contains the adsorbent particles. This combined material therefore has a sandwich structure of a carrier layer, adsorbent particles and a covering layer. Preferably, the adsorbent particles are applied to the support layer by means of a composition containing an adhesive. The adhesive mass is organic binders, in particular a plastic dispersion or a solvent-free two-component system, or it is selected from the group of latices, such as, for example, natural latex. This preparation containing the adhesive compound can be applied either pointed or as a completely covering coating. Because the permeability to water and air of the materials used in the building industry plays an important role for building physics reasons, the adhesive mass must be permeable to water vapor, in particular with a covering coating.

The cover layer, which is used in the materials to be used for the method of the invention, is a flat support material from the group of paper, paper wallpaper or flat textile compositions, such as, for example, fabrics, knits, non-woven fabrics or glass fiber weave. This cover layer can preferably be adhered with a hot-melt adhesive tip or with a thin hot-melt adhesive fleece to the material containing the adsorbent particles.

A combined material to be used for the method according to the invention can for instance be manufactured as follows: The interior-facing support (flat textile assembly, special paper or glass fiber fabric) is provided with a water-vapor permeable fully covering coating, which at the same time adheres to the granular or spherical adsorbents. The coating is sprinkled with the adsorbents before drying. The excess is extracted. The adsorption layer is then covered, for example by a light textile, to protect it from the adhesive, with which the combined material is adhered to the building component. Light, fine-meshed polyester fleeces with a printed melt adhesive are preferably suitable as a cover.

The fully covering coating has the decisive advantage that it can also be coated using an open textile backing material, without the wall paint occupying, damaging or in some way rendering the harmful substances to be adsorbed inaccessible. . Dispersions with which water-vapor permeable coatings can be produced are, for example, the Plextolen from Rohm GmbH or Impranilen, respectively. Impra permtypes from Bayer AG.

Another possibility, to protect the adsorbent particles in the material for the process according to the invention from paint penetration, is the following construction: The carrier layer of the adsorbent material faces the wall and the adsorbent material itself is outer material covered, using as a bond between the adsorbent material and the outer material a slit hotmelt adhesive film. This ensures that sufficient moisture can penetrate, but not the paint. For the paint, however, low-solvent resp. solvent-free dyes.

In a further embodiment of the invention, an additional sealing layer, preferably a water vapor-permeable sealing layer, is provided on the side of the combined material facing away from the ejection source, i.e. on the carrier or the covering layer. The barrier layer is generally introduced within the combined material on the side of the adsorption layer facing away from the ejection source.

The invention also relates to an adsorbent material which comprises a flat support material formed as a water vapor-permeable sealing layer and an adsorbent particle-containing layer thereon. In a further embodiment according to the invention, this adsorbent material can contain an additional covering layer, which is applied to the layer containing the adsorbent particles.

A further adsorbent material according to the invention in the form of a combined material comprises a flat support material, an additional water vapor-permeable sealing layer applied thereon, and an adsorbent particle-containing layer present on this sealing layer. In a further embodiment according to the invention, this adsorbent material may comprise an additional covering layer, which is applied to the layer containing the adsorbent particles.

The barrier layer aims to increase the contact time between the pollutants and the adsorbents by slowing the migration rate of the pollutants from the emission source to the surface of the combined material. A further advantage of the barrier layer is to prevent hardly volatile gases from the interior air, which can be permanently adsorbed, from migrating into the adsorption layer and thereby reducing the adsorptive effect, eg with regard to wall removal radon released. It is preferably used when porous, air-permeable flat products are used as the support material. Such a sealing layer is efficiently permeable to water vapor so as not to prevent the breathability of the wallwork.

The sealing layer can at the same time be the adhesive mass for the adsorbent particles. However, the sealing layer may also consist of a slit film adhered to the inner side of the outer layer of the combined material, preferably of a hot-melt adhesive film, provided with slits, which is connected on the other side to the adsorbent particles. In a further embodiment, the closing layer may be a latex layer or a latex paint layer applied to the exterior of the combined material facing the interior of the room.

With regard to the adsorption of radon by means of the method according to the invention, it has been found that the use of a slit hot-melt adhesive film as a sealing layer with which the outer facing layer applied to the adsorption layer is adhered to is very effective. Depending on the adhesive temperature, the air flow is reduced by around 90% and at the same time radon adsorption is substantially improved. The moisture permeability is more than sufficient, so that there is no risk of moisture accumulation in the wall work. A further method according to the invention for the purpose of radon adsorption may consist in the use of a material, wherein the rear side of the outer material is provided with a water-vapor-permeable coating, which simultaneously serves as an adhesive layer for the adsorption granules, respectively. -beads. A cover, which may for example be a piece of textile or a piece of paper, is then glued onto the adsorption layer formed after the coating process. In both cases mentioned above, the radon comes into contact with the adsorption layer first. The part of the radon, which has not yet been fully adsorbed, collides with the sealing layer, respectively. is slowed down by this, so that the adsorption process can continue.

In a further embodiment of the method according to the invention and of the adsorbent materials according to the invention, the side of the material or the side facing the ejection source is respectively. combined material (carrier or cover layer) a separating layer, the purpose of which is to allow removal of the combined material in such a way that the latter can be removed from the emission source and cleaned up. The removal can be regarded here in such a way that in particular the adsorbent particles in the combined material with the carrier layer can be completely removed from the emission source. This separating layer can preferably be a splitting paper or a splitting fleece or it consists of two easily separable fibrous membranes.

Practical tests by the applicant have shown that in the case of adsorption of PCBs to activated carbon, the PCBs are "sucked out" from the emission source (for example an infected wall) due to the favorable adsorption equilibrium and that after a few years the wall is virtually PCB-free is. The purpose of the separating layer in particular is, for example, to be able to tear off a wallpaper from the emission source in a simple manner, to clean it up in a manner suitable for harmful substances, for example by disposing of it in a waste incineration for hazardous waste materials. The PCB-containing adsorbents should be fully included if possible. In order to achieve this goal, a weak spot (tear point) in the connecting material of the support material resp. the wallpaper to be built in. This possibility is offered by the following exemplary structure: the outer textile material carries adsorbent granules on the side facing the wall which adhere to the textile material with a discontinuously applied adhesive. The adsorbents are in turn covered with a splitting paper. Cleavage papers have a relatively well-glued surface, but are hardly glued internally and therefore splittable. When tearing off, one half remains on the wall and can serve as a substrate for a new wallpaper, while the other half still covers the adsorbents; this avoids any loss of adsorbents.

Another possibility, for example, to peel off a wallpaper without loss of adsorbents, consists in making the covering of the adsorbents facing the wall sufficiently strong so that it does not tear when the wallpaper is peeled off. Preferably, the adhesive substrate can be pre-wetted.

An advantage of the above-described combined material is generally that the harmful substances within the adsorption layer can move freely until the moment of adsorption. If, on the basis of a special quality of the emission source, more harmful substances are released locally, these may arise due to the sealing layer resp. sandwich structure in the adsorption layer, unobstructed lateral expansion (no local overload). A large amount of adsorbents is always available in all directions, which enable an even distribution of harmful substances. Sealing without applying an adsorbent material, for example with an aluminum foil, results in migration effects and enormous escapes when damaged.

On the other hand, minor local damages of the combined material of the invention by e.g. boreholes are completely harmless, because the action of e.g. an adsorptive wallpaper is based on the binding of harmful substances close to the emission source, and is not dependent on a fully covering intact shield .

A further embodiment of the method according to the invention consists in that the materials containing the adsorbent particles exist in the form of strips, which are placed, for example, over the joints which are sealed with sealing compound containing harmful substances. pressed into these joints. These strips can preferably be covered again with a material suitable for the method according to the invention, in order thereby to preclude the escape of harmful substances into the spaces with absolute certainty. Since the joint sealing compound is generally applied somewhat deeply, there is sufficient space for a thick strip of adsorbent material; larger levels of adsorbent particles can be accommodated in this floor, so that security can be guaranteed even after many years.

The resp. To be used for the process according to the invention and for the adsorbent materials according to the invention. Adsorbent particles to be used are powdered activated carbon, activated carbon spheres, activated carbon granules, carbonized and activated ion exchangers, pitch-based ball carbon, hydrophobic molecular sieves, briquettes from hydrophobic molecular sieves or porous polymers. The adsorbent particles, in particular the activated carbon, preferably have an internal surface of at least 900 m2 / g. The activated carbon pellets resp. granules preferably have a diameter of 0.1 to 2.0 mm, in particular 0.3 to 1.0 mm. The adsorbent particles are preferably present in an amount of 5 to 400 g / m2, in particular 10 to 250 g / m2.

The manufacture of carbonized and activated ion exchangers is described in DE-A-43 04 026. The materials of the invention generally contain up to 70% by weight of adsorbent particles.

Numerous methods are suitable for applying the adsorbent particles, for example on the carrier material. For example, as described in DE-A-32 11 322, an activated carbon paste and a binder dispersion can be printed in packs by rotary screen printing, whereby print runs of up to 100 g / m2 can be achieved. The use of spherical activated carbon, which is adhered to a flat textile assembly by a pointed mass, is described in DE-A-33 04 349.

An adsorbent well suited for the present invention is pitch-based ball-coal. For example, when using a ball-coal with a diameter of 0.3 to 0.8 mm, up to 1000 balls per cm2 can be applied to the support material of the test strips or of the combined material according to the invention. This corresponds to more than 20 mg / cm2 of activated carbon, which is practically freely accessible, because the adhesive mass seals only 10 to 15% of the pores. With an internal surface of 1000 to 1200 m2 / g and a micropore volume of 0.3 ml / g with a pore diameter of 0.5 to 1.2 nm, mainly from 0.8 to 0.9 nm, the ball-coal is particularly well suited for the application according to the invention. It is important that the micropores are relatively narrow because the adsorption forces are then the strongest. On the other hand, the micropores must be large enough to accommodate the not very small harmful substance molecules, for example the PCB molecules. Therefore, pore diameters from 0.6 to 1.0 nm are very favorable. Such pore diameters are found, for example, in activated carbon on a pitch basis (ball-coal), on the basis of coconut husks and on the basis of certain coal.

Harmful substances are strongly adsorbed in these materials and are retained for a long time.

Important for the effectiveness of the combined material is a homogeneous loading of the carrier layer with the adsorbent particles. This is guaranteed in particular when using spherical activated carbon.

In addition to the ball-coal, in principle it is also possible to use granular-carbon or splinter-carbon (with a particle size of 0.3 to 2 mm). However, the ball-coal is preferred because of its smooth friction-resistant surface as well as because of the optimum manner of utilizing the location to be achieved therewith.

In order to be able to adsorb certain harmful substances, it may be necessary to impregnate the adsorbent particles and to use different adsorbent particles: pure activated carbon for high-boiling harmful substances, for example PCBs and PCPs; pure activated carbon, preferably with very small micropores, for solvents; acid-impregnated activated carbon, for example, with phosphoric acid for the adsorption of ammonia and amines; basic impregnated activated carbon, for example impregnated with potassium carbonate, for acidic gases; carbon impregnated with 2-amino-1,3-propanediol or trimethanolamine for the adsorption of formaldehyde; sulfur-impregnated carbon for adsorption of mercury vapors; activated carbon impregnated with copper salts to adsorb sulphurous and nitrogenous pollutants; to name just the most important.

In view of the exhalation of ammonia from the wall work, the application of wallpaper containing phosphoric acid-impregnated activated carbon particles has proved very satisfactory. In principle, such wall coverings have the sandwich structure described above, in which granular resp. spherical adsorbents are present between two planar textile or paper materials, one of which is the carrier layer for the adsorbents and the other for the cover layer for the adsorbents. Porous polymers such as the XUS resins from the DOW Chemical Company are also suitable for adsorbing high-boiling pollutants according to the process of the invention. Carbonated and activated cation exchangers, for example based on sulfonated styrene / divinylbenzene copolymers, which are very similar to activated carbon in terms of physical properties, are also suitable.

For the purposes of the method according to the invention and of the material according to the invention, the outer surface of the adsorbent particles is preferably at least 50%, in particular between 75 and 80%, freely accessible to the harmful and malodorous substances.

Emission sources, which are remediated with the method according to the invention or with the materials according to the invention, are in particular construction elements and building materials containing odoriferous and harmful substances, such as walls, support elements, ready-made walls, concrete slabs, floors , wooden beams, wooden planks, wooden floors, joints, sealing compounds, filler compounds and joint sealing compounds.

Harmful substances within the meaning of the present invention include, in particular, harmful substances which are adsorbable to powdered activated carbon, activated carbon spheres, activated carbon granules, carbonized and activated ion exchangers, pitch-carbon ball, hydrophobic molecular sieves briquettes from hydrophobic molecular sieves or porous polymers. These harmful substances include, in particular, polychlorinated phenols (PCPs), polychlorinated biphenyls (PCBs), chlorinated hydrocarbons (CKWs), polyconfused aromatics (PAHs), chloroalkanes, phthalates, amines, 2-ethylhexanol, ammonia and radon.

Example 1

The interior walls of a building consisting of ready-to-use elements, which had been contaminated by the incorporation of PCB-loaded air into the room for many years, were fully covered with a dispersion adhesive for heavy wallpaper. A flat filter according to EP-A-118 618 was embedded in the adhesive bed, which consisted of a glass fabric wallpaper, which was loaded on one side with 210 g / m2 activated carbon pellets with a diameter of 0.5 mm with activated carbon adhesive. mm and covered with polyester fleece. After this work was carried out, the PCB concentration in the air of the room dropped from about 10,000 ng / m3 to below 300 ng / m3 and also remained below this value in the following time. The covering material gave the impression of a textile wallpaper.

Example 2

The material with adsorbent particles to be used for the process according to the invention consisted of soundproofing plates which on the wall facing side with activated carbon granules with a diameter of 0.5 to 1.2 mm with a covering weight of 190 g / m2 were loaded. The further steps in the method were the same as in the above example. Due to the fully covering cover, the PCB concentration could also be reduced to below 300 ng / m3.

Example 3

As a covering material, a carpet covering the entire floor, the back of which was loaded with activated carbon spheres, was placed on a PCB-contaminated concrete floor. The escape of PCBs was completely prevented.

Example 4

A polyester web material web with a surface weight of about 100 g / m2, on which about 200 g / m2 of ball-coal (average diameter 0.55 mm) adhered, was cut into strips, the joints to be covered on both sides overlapped around 1.5 cm. The strips were fixed with adhesive strips, over which a wallpaper according to example 1, which in turn was provided with 200 g / m2 ball-coal, was applied.

Example 5

Siliconized protective paper was divided into three strips on an adhesive strip of 10 cm wide: in a strip of 7 cm wide and on the left and right of this a strip of 1.5 cm wide (1.5 cm + 7.0 cm + 1.5 cm = 10 cm). The middle strip of protective paper was gradually peeled off and at the same time the adhesive strip was sprinkled with the ball coal of Example 4, which adhered well immediately. The strip with ball-coal could be rolled up without any problem. At the site of application, the side protection papers were removed and the strips were applied so that the coal layer overlapped the joint by about 1.5 cm. As in Example 4, this strip was wallpapered over.

Example 6

A 1 cm thick web of a cross-linked, large-pore PU foam (liter weight 30 g, porosity 15 ppi) was permeated through with an adhesive compound (Impranil HS 62 + Imprafix HSC, 30 g / l). Then 200 g of ball-coal per liter of foam material were fed in a shaker. After removing the excess and thermally curing the adhesive mass, the web was cut into 4.5 cm wide strips, which were then pressed into approximately 4 cm wide joints. The strips were fixed with an adhesive strip as an attachment. These strips were wallpapered as in Examples 4 and 5.

Example 7

The equal PU foam as used in Example 6 was impregnated with a paste consisting of ground activated carbon, water and a binding dispersion and freed from excess on a press. After drying the material web, it was cut into strips and processed further as in example 6. A typical pasta recipe is as follows:

Activated carbon 315 g (dry)

Water 435 g

Acrylic binder A (soft) 40 g

Acrylic binder B (hard) 80 g

Thickener solution (4% in water) 100 g

Lubricant (polyamide base) 15 g

The methods according to the invention indicated in Examples 4 to 7 were used to remediate PCB-contaminated sealing compounds in construction works in which plates were used. In these examples no PCBs could be detected on the outside of the cover after applying the methods according to the invention.

Laboratory-scale analog tests have shown that moisture-resistant molecular sieves can be used instead of activated carbon in the same manner as described in the examples.

As shown in the above-mentioned examples, the emission of harmful substances, such as for instance from PCBs, can be suppressed very strongly by the method according to the invention and can also be completely prevented. In comparison with the prior art passive collectors, the method according to the invention provides a direct adsorption of practically 100% of the harmful substances diffusing from the emission source. In particular, fast-boiling harmful substances are hereby permanently retained. Applicant's tests have shown that harmful substances up to an amount of 10% by weight, based on the adsorbent particles, are permanently adsorbed. A carbon quantity of 200 g / m2 can therefore permanently harm up to 20 g / m2 of harmful substances. Since such amounts never occur in practice, the activated carbon never runs out.

Claims (51)

Method for controlling the emission of malodorous and harmful substances, characterized in that the emission source is directly covered with a material containing adsorbent particles. 2. A method according to claim 1, characterized in that the elements or objects which are situated directly next to the ejection sources are additionally covered over a large area with materials containing adsorbent particles. A method according to claim 1 or 2, characterized in that the material comprising the adsorbent particles is selected from the group of open-pore foams, nonwovens and inorganic or organic binders. Method according to claim 3, characterized in that the material is an open-pored foam, preferably a cross-linked PU foam, of 0.5 to 5.0 mm thick, comprising finely ground adsorbent particles and a binder . A method according to claim 3, characterized in that the material is a 0.1 to 2.0 mm thick nonwoven fabric comprising finely ground adsorbent particles and a binder. Method according to claim 3, characterized in that the material is a paint, a plaster material, a sound-absorbing plaster material or floor plaster, which comprises adsorbent particles. A method according to claim 3, characterized in that the material is a legible material comprising adsorbent particles, in particular a back covering of floor covering. A method according to any one of claims 3-7, characterized in that the material comprises up to 70% by weight of adsorbent particles. A method according to claim 1 or 2, characterized in that the material comprising the adsorbent particles is a support layer of a flat support material from the group of paper, paper wallpaper or flat textile compositions, such as fabrics, knits, nonwovens or glass fiber weave requirement, and that the adsorbent particles are applied to this carrier layer. Method according to claim 9, characterized in that the carrier layer with the adsorbent particles applied thereon forms a test strip which is used for determining leakages of environmental toxins through sealing layers or for determining the release of the environment. - poisons are applied to the material containing the adsorbent particles. A method according to claim 1 or 2, characterized in that the material comprising the adsorbent particles is a combined material which consists of a carrier layer of a flat carrier material from the group of paper, paper wallpaper or flat textile compositions such as fabrics, knits, nonwovens or glass fiber fabrics, a layer containing the adsorbent particles and a covering layer placed thereon, are present on this carrier layer. A method according to any one of claims 9-11, characterized in that the adsorbent particles are applied to the carrier layer by means of an adhesive mass. Method according to claim 12, characterized in that the adhesive mass is a plastic dispersion, a solvent-free two-component system or a latex, e.g. natural latex. Method according to claim 12 or 13, characterized in that the adhesive mass is applied in a pointed manner. Method according to claim 12 or 13, characterized in that the adhesive mass is a water vapor-permeable fully covering coating. Method according to one of Claims 9-15, characterized in that the layer of the material (carrier or covering layer) remote from the ejection source is designed as a water vapor-permeable sealing layer. Method according to any one of claims 9-15, characterized in that an additional water vapor-permeable sealing layer is placed on the side of the material (carrier or covering layer) facing away from the emission source. Method according to claim 16 or 17, characterized in that the sealing layer is the adhesive mass for the adsorbent particles. A method according to any one of claims 16-18, characterized in that the sealing layer consists of a slit foil adhered to the inner side of the outer layer, in particular a slit hot-melt adhesive foil, which on the other side is the adsorbent particles are attached. Method according to any one of claims 16-18, characterized in that the closing layer is a latex paint, in particular a latex color paint, which is applied on the side facing the space. Method according to any one of claims 11-20, characterized in that the covering layer is made of a flat support material from the group of paper, paper wallpaper or flat textile compositions, such as, for example, fabrics, knits, non-woven fabrics or glass fiber weave. Method according to claim 21, characterized in that the covering layer is adhered with hot-melt adhesive points or with a hot-melt adhesive network on the material comprising the adsorbent particles. A method according to any one of claims 9-22, characterized in that the side of the combined material (carrier or cover layer) facing the ejection source is a separating layer, which removes the combined material from the ejection source and allows its clearance. A method according to claim 23, characterized in that the separating layer is a splitting paper, a splitting fleece, or consists of two fiber membranes which are easy to separate. A method according to any one of the preceding claims, characterized in that the adsorbent particles of activated carbon, activated carbon pellets, activated carbon granules, carbonized and activated ion exchangers, pitch carbon ball, hydrophobic molecular sieves, briquettes from hydrophobic molecular sieves or porous polymers. A method according to claim 25, characterized in that the activated carbon has an internal surface of at least 900 m2 / g. A method according to claim 25 or 26, characterized in that the activated carbon pellets resp. granules have a diameter of 0.1 to 2.0 mm, preferably 0.3 to 1.0 mm. 28. A method according to any one of the preceding claims, characterized in that the adsorbent particles are in particular impregnated with phosphoric acid, potassium carbonate, trimethanolamine, 2-amino-1,3-propanediol, sulfur or copper salts. A method according to any one of the preceding claims, characterized in that the adsorbent particles are present in an amount of 5 to 400 g / m2, preferably 10 to 250 g / m2. 30. A method according to any one of the preceding claims, characterized in that the adsorbent particles comprising materials are in the form of strips, which are applied or applied over the joints sealed with pollutant-containing sealing compounds. are pressed into these joints. A method according to any one of claims 9-30, characterized in that the surface of the adsorbent particles is at least 50%, in particular between 75 and 80%, freely accessible to the harmful resp. malodorous substances. A method according to any one of the preceding claims, characterized in that the emission sources are malodorous and harmful substance-containing building elements or building materials, such as walls, carrier elements, ready-made walls, concrete slabs, floors, ceilings, wooden beams, wooden planks, wooden floors, joints, sealing compounds, filler compounds, joint sealing compounds. 33. A method according to any one of the preceding claims, characterized in that the harmful substances present in the emission source can be adsorbed by the adsorbent particles. 34. A process according to claim 33, characterized in that the harmful substances are polychlorinated phenols (PCPs), polychlorinated biphenyls (PCBs), chlorinated hydrocarbons (CKWs), polycondensated aromatics (PAHs), chloroalkanes, phthalates, amines, 2 -ethylhexanol, ammonia or radon. 35. An adsorbent material comprising a flat support material which is constructed as a water vapor permeable barrier layer and an adsorbent particle containing layer thereon. 36. An adsorbent material comprising a flat support material, an additional water vapor-permeable barrier layer applied thereto, and an adsorbent particle-containing layer disposed thereon. Adsorbent material according to claim 35, characterized in that it comprises an additional covering layer applied to the adsorbent particles-containing layer. Adsorbent material according to claim 36, characterized in that it comprises an additional cover layer applied to the adsorbent particles-containing layer. Adsorbent material according to one or more of claims 35-38, characterized in that the flat support material is from the group of paper, paper wallpaper or flat textile compositions, such as fabrics, knits, non-woven fabrics or glass fiber fabrics. Adsorbent material according to one or more of claims 35-39, characterized in that the sealing layer is the adhesive mass for the adsorbent particles. Adsorbent material according to one or more of Claims 35 to 40, characterized in that the sealing layer consists of a slit foil, in particular a slit hot-melt adhesive, which is glued to the inner side of the outer layer the other side is connected to the adsorbent particles. Adsorbent material according to one or more of claims 35 to 41, characterized in that the sealing layer is a latex paint, in particular a latex color paint, which is applied on the side facing the space. Adsorbent material according to one or more of claims 35 to 42, characterized in that the adsorbent particles of activated carbon, activated carbon pellets, activated carbon granules, carbonized and activated ion exchangers, pitch carbon ball carbon, hydrophobic molecular sieves, briquettes from hydrophobic molecular sieves and / or porous polymers. 44. The adsorbent material according to claim 43, characterized in that the activated carbon has an internal surface of at least 900 m2 / g. 45. The adsorbent material according to claim 43 or 44, characterized in that the activated carbon pellets resp. granules have a diameter of 0.1 to 2.0 mm, preferably 0.3 to 1.0 mm. Adsorbent material according to one or more of claims 43 to 45, characterized in that the adsorbent particles are in particular impregnated with phosphoric acid, potassium carbonate, trimethanolamine, 2-amino-1,3-propanediol, sulfur or copper salts . Adsorbent material according to one or more of claims 43-46, characterized in that the adsorbent particles are present in an amount of 5 to 400 g / m2, preferably of 10 to 250 g / m2. Adsorbent material according to one or more of claims 37-47, characterized in that the cover layer consists of a flat support material from the group of paper, paper wallpaper or flat textile compositions, such as fabrics, knits, non-woven fabrics or glass fiber fabrics. Adsorbent material according to one or more of Claims 37 to 48, characterized in that the cover layer is adhered with hot-melt adhesive points or with a hot-melt fleece on the material comprising the adsorbent particles. Adsorbent material according to one or more of claims 35 to 49, characterized in that the side of the adsorbent material (carrier or cover layer) facing an ejection source is a separating layer, which removes the adsorbent material from the ejection source and makes it possible to clean it up. An adsorbent material according to one or more of claims 35-50, characterized in that the separating layer is a split paper, a non-woven fabric or consists of two easily separable nonwoven fabrics.