DE4343358A1 - Porous adsorbent plate or moulding useful as filter esp. for gas purification - Google Patents

Abstract

Porous plate or moulding with adsorbent properties contains granules or beads of or contg. activated charcoal (I), which are bonded together with a silicate soln.. The silicate bridges are then converted to silica gel bridges and the moulding is dried. Pref. the silicate soln. contains 10-50% finely ground (I), w.r.t. dry matter, which is incorporated in a porous SiO2 matrix during pptn.. The granules or beads consists of carbonised and activated pitch and/or ion exchanger and have a dia. of 0.2-5, esp. 0.2-2.0 mm.

Description

For reasons of environmental protection, but also for volatile products, e.g. B. Release Medium from gas or air streams to be recovered are increasingly adsorbed tion process used, wherein adsorbents such as activated carbon, molecular sieves, Aluminum oxides, silica gel, etc. are used. The classic shape the filter system is the bed (bulk filter), but always a com must be made with regard to particle size: small particles lead to a high pressure loss, but have good kinetics and high Degrees of use, while large particles have a much lower one Cause pressure loss, but the adsorption kinetics and the degree of utilization are worse.

To decouple these opposing effects, small particles were attached to one large-pore, three-dimensional matrix fixed: The kinetics are good because of the small NEN adsorber particles, the pressure loss is low due to the wide mesh trix (EP 340542). A preferred form is a large-pore, reticulated PU Foam, on the webs of which spherical activated carbon with the help of an adhesive (0.2-0.8, exceptionally up to 2 mm in diameter) is attached.

In processes in which adsorption and desorption are carried out in a regular sequence, carrier structure and adhesive are often weak points because the thermal bela damage, especially in the presence of aggressive solvents can lead. Filters with high thermal resistance can be manufactured by a wrap is made from suitable strips (e.g. mineral fiber fabric) forms, during the winding up adsorbents such as molecular sieves and Spacers are interspersed between the layers. Such filters can but only be made in the form of a wheel.

The aim of the present invention was to create thermally stable filter elements which can be produced in a wide variety of forms. It is known that "activated carbon beads" can be produced by dropping a thickened silicate solution containing finely ground activated carbon into a precipitation bath. After washing and drying, beads are obtained with 20-40% activated carbon, which is built into an SiO₂ matrix. The matrix is highly porous so that the activated carbon is very accessible. It has now been found that with a suitable increase in the concentration of the starting solution, if appropriate after adding structuring agents or thickeners, it is possible to produce thin layers of SiO₂ with built-in activated carbon, taking into account the shrinkage occurring after the precipitation and the washing process, in particular during drying is. Flat, rectangular teflon shells have proven their worth for manufacturing in the laboratory. The filter plates of 1-2 mm thickness obtained in this way are stacked into packages, a spacing of 1-2 mm being ensured by means of spacers. Such a package is shown in FIG. 1. Sides A and B are sealed. The packet filter is flowed through in the direction of C → D. The flow rate must be determined experimentally so that the dynamic cross diffusion leads to a practically complete ad sorption. The main influencing factors are the plate size and the plate spacing. However, this route is very difficult because of the high shrinkage inherent in the process. A much simpler way is that one starts from the activated carbon beads already mentioned and binds them to plates or agglomerates with the aid of a silicate solution containing activated carbon. The use of already finished, no longer shrinking activated carbon beads offers the possibility of producing bodies that no longer shrink during drying, which is of course a very important advantage. Practically, you will fill a mold with balls, then fill, cut and dry the cavities with the silicate / activated carbon solution. A form made of finely meshed PE braid simplifies precipitation. The shrinkage that occurs during drying has the result that only webs remain between the balls, where these webs are made of the same material as the balls. The maximum possible coarse porosity is obtained if the excess of the silicate / activated carbon solution is drained off. Of course, spheres or grains of pure activated carbon can also be joined together in this way to form porous bodies with adsorptive properties. Agglomerates of this type can have a wide variety of shapes and are ideally suited for the production of highly air-permeable, highly effective fillings. The beads or grains assembled into plates or agglomerates should not exceed a particle size of 5 mm for reasons of diffusion, while the agglomerates for fillings can be up to a few cm in size.

It was further found that the agglomerates according to the invention differ greatly well with substances suitable for chemosorption (potassium carbonate, phosphorus acid, iodine / iodide, etc.) impregnated, the high porosity and Hy drophilicity of the matrix certainly play a role. Basically, they are included amounts higher than with pure activated carbon and can be up to 15% gene.

example 1

A PE shell with perforated base was filled with activated carbon beads (KC dry beads AK 20 from Solvay Catalysts GmbH) with a bead diameter of 2-3 mm. Bed depth approx. 8 mm. Then this sphere was pack with an approximately 28% water glass solution (molar ratio SiO₂ / NaO₂ 2.8) of finely ground activated carbon (Pica 12/14) in an amount of 30% by weight based on dry matter and about 12% propylene carbonate as Acid spores that were added were wetted. The excess was allowed to drip off, so that after hardening and drying a plate was obtained which consisted of activated carbon pearls, which consisted of very same material as the pearls via very short connecting webs. Ten such plates were assembled into a filter package (similar to FIG. 1).

Example 2

Similarly, instead of a plate, a larger block was made, which in Agglomerates with irregular shapes were disassembled. From these agglomes rates, a fill was produced that was compared to a conventional Chen activated carbon bed with cylindrical particles of 5 mm in diameter had an eleven times lower pressure drop for the same performance.

Claims (7)

1. Porous plates or bodies with adsorbing properties, characterized in that activated carbon grains, activated carbon beads or activated carbon-containing beads or beads are adhered to one another with the aid of a silicate solution, then the silicate bridges are converted into silica gel bridges and the bodies are dried. 2. Porous plates or body according to claim 1, characterized in that that the silicate solution used to manufacture the bridges is fine ver ground activated carbon in an amount of 10-50% based on dry Contains substance and this coal when the silica is precipitated into a porous SiO₂ matrix is installed. 3. Porous plates or body according to claim 1 or 2, characterized records that the activated carbon spheres carbonized and activated pitch beads or carbonized and activated ion exchangers are and have a diameter of 0.2-2.0 mm. 4. Porous plates or body according to claim 1 or 2, characterized records that the activated carbon-containing beads from a SiO₂ Matrix exist that contains 10-50% finely ground activated carbon and that Beads have a diameter of 0.2-5 mm. 5. Adsorption filter consisting of plates arranged in parallel according to one or several of the preceding claims exist and to clean the gases flow between or past the plates. 6. Adsorption filter consisting of one or more plates after one or several of the preceding claims exist and to clean the gases flow through the plates.   7. Adsorption filter consisting of a bed of agglomerates (body) according to one or more of the preceding claims.