DE19533464A1 - Filter material with high affinity and capacity for adsorbing radon from air stream - Google Patents

Abstract

Filter material (A) comprises a highly air-permeable carrier with granular or spherical adsorbent (I) bonded to its webs with an adhesive, in which (I) has a special pore structure giving a high affinity for Rn. Also claimed is filter material comprising (B) a bed of (I) with a particle size of <= 2 mm, pref. in the form of agglomerates of 5-50 particles; and (C) a web (woven, knitted or nonwoven fabric) of activated charcoal in which >90% of the pore vol. is in the form of micropores with an average dia. of 7, pref. 6 ?A.

Description

The noble gas radon is a decay product of uranium. Radon occurs in houses then when this is built on uranium soil or uranium containing construction materials were used. The danger to humans is that inhaled radon z. T. in the body in solid radioactive daughter nucleids disintegrates, which are no longer excreted and which are immediate Damage nearby cells. That is why radon is next to smoking the second leading cause of lung cancer.

It is known that activated carbon provides protection against radon by the it is held in the micropores long enough to become solid To decay daughter nucleids that are deposited and whose radiation we is harmless due to the greater distance. So in the DE 40 20 428 A1 flooring and home textiles described as Samm Radon and contain activated carbon. DE 44 32 834 A1 for its part describes barrier layers for radon, which apply the same principle reason lies.

That there are still no air filters with high air permeability for radon, has its reason z. T. in the fact that suitable adsorbents, the radon enough tie for a long time, missing. The barrier layers already mentioned include hence a layer that passes through the adsorption layer brake and give the activated carbon a greater chance.

The aim of the present invention was to create filters that radon from air stream can filter out.

Surprisingly, it has now been found that adsorbents, which by Smoldering and activation of styrene-based cation exchangers from the gel Type obtained under certain conditions, one versus the other  conventional activated carbon has an enormously increased radon affinity and capacity Zen. Their use in filter systems, as described in DE 38 13 563 A1 ben, led to astonishingly good results: With a contact time of 1 s should break down more than 90% of the radioactivity of approx. 1 MBq / m³ air be (preliminary test). The cation exchangers were divided into two stages (to 400 ° C and 400-900 ° C), but in the first stage essentially the volatile constituents including sulfonic acid groups have been driven off and a strong network took place. In the second stage, those arise large condensed aromatic systems with cavities in between, the micro pores. These storage locations are only targeted by activation - a more targeted one Burn-up - accessible for adsorption. Is this carried out so that a inner surface of 900-1.100 m² / g, preferably 950-1.050 m² / g, is reached, the accesses to the pores act like a bottleneck where is increased by the dwell time of radon. With increasing activation The inner surface is increasing, but at the same time the ability is increasing ability to bind radon.

Similar behavior was also observed for methane and butane, where the Adsorption capacity also goes through a maximum: it increases to one inner surface area of about 1,000 m2 / g to with increasing activation just take it off again. This can be done by enlarging the mic pore diameter or opening of "bottleneck" passages well explained Ren. Due to this correlation, the difficult measurement Solution of radon adsorption replaced by that of butane or methane you want to determine the optimal level of activation for radon. He According to experience, the maximum butane capacity is 50-55 mg butane per g Coal if you put it at 25 ° C, a butane concentration of 76 ppm and one r.F. = 35% determined.

It was found that by smoldering and activating macroporous Ka tion exchangers these values can hardly be achieved. Most likely is here  the "bottleneck effect" is not so pronounced.

The described production of the adsorbents is not intended to be a limitation on the starting material understood gel-like cation exchangers the. It is important to recognize that when activating for radon a maxi mum is run through and that this maximum approximately with the adsorp tion maximum for difficultly adsorbable hydrocarbons, such as. B. methane, correlated.

The adsorbents with optimal radon capacity can be ventilated sigen carrier are fixed in accordance with DE 38 13 563 A1, the Carrier preferably an open-pore, reticulated PU foam with approx. 8- 30 ppi (pores per inch). Systems with a high degree of adhesion have become Proven adhesion, especially those based on masked polyisocyan ate that are crosslinked with a polyamine or based on polyisocyanates, that crosslink under the influence of moisture. But also thickened lattices are usable adhesive. The adhesive is applied before preferably through a paste tube and then squeezing the Foam. The wetted PU foam is then loaded with the adsorbers scatters and the excess "shaken". Spherical adsorbents with one Bulk density 0.70-0.75, an average diameter of about 0.5 mm, can fixed in a 20 ppi foam in an amount of 300-350 g / l foam will.

A very suitable adhesive is also highly viscous water glass an SiO₂ matrix is implemented. Water glass with a keel is preferred Celic acid / alkali ratio 3-4, which is an acid donor, e.g. B. 5-10% propylene Carbonate is added to accelerate the formation of the SiO₂ matrix. This adhesive has a great advantage: Since it is itself a highly porous  Structure, the accessibility of the adsorbents is not affected in any way prevents what is not the case with polymer adhesive compositions. Liability for Koh le is very good, not to the carrier foam. With sufficient quantity (30-100 g / l) it forms its own self-supporting structure, which is rigid and at ho stress breaks.

Although filter media according to DE 38 13 563 A1 can be preferred fillings from granular adsorbents can also be used. To the front parts of small particles (2 mm) should be able to use larger ones Agglomerates are summarized, which consist of 5-50 particles. So high air permeability can be achieved despite small particles (DE 43 31 586 A1).

The high effectiveness of the spherical carbon made from ion exchangers is to be shown in the following comparative test:

The test is that a primary signal is generated in a 50 liter steel vessel becomes. The vessel is over a diffusion area (fine sieve) with a 5 l Container (secondary container) connected in which the diffusion radioactivity is measured. Then in the diffusion area a 3 cm thick layer (= 500 cm³) of the adsorbent to be examined brings. This considerably reduces the reactivity in the secondary container and after some time reaches the equilibrium con centers.

Table 1

The results clearly show that the spherical coal is based on Pechba sis four times more effective and those based on ion exchangers even three is ten times more effective than lignite-based. One can assume that hen that the same ratio in effectiveness when passing through Ad sorption filter with activated carbon is present, only in this case the measuring technology is on agile.

One can ask the question, why does one coal cut so well, the other so bad again. The reason is to be found in the pore system. Each the smaller the micropores, the stronger the adsorption of the radon and the longer the dwell time on the coal (more decay). Table 2 ent considers the average micropore diameter for the tested coals.

Table 2

Since the measurements at an r.F. = 100% were carried out also plays here the pore system plays a role; this time it's the transport pores, especially the mesopores (20-500 Å). In these it easily comes to one Kind of capillary condensation, giving access to the adsorption site zen is blocked. The pitch coal has only a few mesopores, while the Coal made from cation exchangers has practically only micropores. A special, hydrophobic surface of the micropores is probably one less play a major role as is always assumed.

Due to the finding that activated carbon, the pore system for the most part only are very suitable for radon adsorption from very narrow micropores,  were other systems with such pore structures in a first Tested a series of preliminary tests. It has been found that moderately active fourth activated carbon fleece (1,000 m² / g), which is known to have hardly any meso and ma have corpores, should be very suitable for radon adsorption.

The shape of the pores also plays a role. There is much to suggest that at the preferred coal at the entrance of the micropores be a bottleneck stands, so a certain similarity to carbon molecular sieves or Mo lecular sieves at all. In fact, it was found in orientational experiments that carbon molecular sieves, but also hydrophobic molecular sieves be, with opening 6 Å, in particular 5 Å, for the inventive An are suitable.

A completely different type of adsorbents is just after the first preliminary tests if appropriate: porous polymers consisting essentially of styrene with some Di built up vinylbenzene and their polymer chains crosslinked via CH₂ bridges are. Such a product is, for example, under the name "Sorbathene" is offered and is actually used for solvent recovery has been developed. The pronounced hydrophobic character also likes here play a positive role.

Finally, it should be mentioned that it is not absolutely necessary for Ka tion exchangers. It was found that anions Exchangers or precursors to ion exchangers, i.e. without them Exchange groups, in excellent spherical adsorbents cien can be implemented if a few percent in the pyrolysis Sulfuric acid can be added. Because here too a very high butane capa due to what has already been said, Ra don’t expect very good values.

Claims (15)

1. Filter material for the adsorption of radon in air streams, consisting of a highly air-permeable support frame, on the webs with the help granular or spherical adsorbents are attached to an adhesive, which have a high affinity for radon due to their special pore structure exhibit. 2. Filter material for the adsorption of radon in air streams, consisting of a bed of granular or spherical adsorbents due to their special pore structure have a high affinity for radon, a Have particle size of 2 mm and preferably in the form of Ag glomerates consisting of 5-50 particles are used. 3. Filter material according to claim 2, characterized in that the micropo ren have an average diameter of 6 Å, preferably 5 Å. 4. Filter material according to claim 2, characterized in that the micropo There are narrowing of 3-4 Å in diameter at their entrances sen. 5. Filter material according to claim 2, characterized in that the adsor bens is a spherical carbon with a diameter of 0.2-1.0 mm. 6. Filter material according to claim 5, characterized in that the ball coal is essentially made from pitches. 7. Filter material according to claim 5, characterized in that the ball coal is made from ion exchangers. 8. Filter material according to claim 7, characterized in that the ball coal is made from a gel type cation exchanger.   9. Filter material according to claim 7, characterized in that the ball coal from an anion exchanger of the gel type with the addition of Sulfuric acid is produced. 10. Filter material according to claim 7, characterized in that the ball coal from the precursor of a gel-type ion exchanger under Zu administration of sulfuric acid. 11. Filter material according to claim 2, characterized in that the active carbon is a carbon molecular sieve with openings of 3-4 Å. 12. Filter material according to claim 1, characterized in that the adsor bens is a hydrophobic molecular sieve. 13. Filter material according to claim 12, characterized in that the opening Molecular sieve approx. 6 Å, preferably 5 Å gene. 14. Filter material according to claim 1, characterized in that the adsor bens a porous polymer, the polymer chains of which consist of styrene with some divinylbenzene, are cross-linked via CH₂ bridges. 15. Filter material for the adsorption of radon in air streams, consisting of an activated carbon sheet (fabric, knitted fabric, fleece), thereby ge indicates that more than 90% of the pore volume in the form of micro pores is present, the mean diameter of which is 7 Å, preferably 6 Å exceeds.