CH683263A5 - Porous dimensionally stable body. - Google Patents

Description

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CH 683 263 A5

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description

The invention relates to an open-pore body, in particular for filtering liquid or gaseous substances, as a catalyst support, as a storage medium, for example for liquids, as an insulation material or as a lightweight material.

A well-known filter body is made of fibers and is used for individual or climate filters. Open-pore foams are also used to manufacture filters. The absorption characteristics of the fiber structures and the known foams mean that the fiber surfaces load relatively quickly with particles of polluted air. Particle bridges are formed between the fibers and the flow resistance increases very quickly. This means that a filter change is required before the entire filter membrane is fully loaded with particles. The same applies to open-cell foams, in which the lobed pores are clogged with particles very quickly. Filters with a filter matrix made of fibers or open-pore foamed plastics must therefore be described as uneconomical.

The invention can be preceded by the task of creating a body of the type mentioned, which at the same time has a higher storage capacity with a less rapid increase in flow resistance. The object is achieved by the invention according to claim 1.

In the body according to the invention, an open porosity with concave pores causes the particles to settle in the depth of the pores. The central connection space between the pores remains open for a long time and is only moved when all the pores are loaded with particles. It has been shown that a concave porous body has a lower flow resistance with a higher absorption rate of particles than a filter matrix made of fibers or foamed plastic. In the case of a filter with concave pores, a more optimal surface / oil relation of the absorbing pores can be achieved compared to the known filters. It has been shown that a pore volume of approximately 80% or greater of the total volume can be achieved with sufficient volume stability of the body at the same time. Correspondingly, less starting material is required for the production of such a body, which simplifies production and disposal and makes it more cost-effective.

According to a development of the invention, the body has concave cavities or pores with a width of 20-60 n (micrometers) and between these passages with a width of 10-50 n. For example, air flowing through can swirl in the concave cavities and the particles to be filtered can be deposited on the walls and in the depth of the cavities. With a high pore volume, each concave cavity is simultaneously connected to several adjacent cavities via short passages. Since there are therefore a large number of passages, the flow resistance is comparatively small even if some of these passages are clogged with particles. With adjacent cavities, the passages are much wider than long. The liquid or gaseous substance to be filtered can therefore pass from one cavity to another without great resistance. In the case of gaseous substances, the swirling mentioned above nevertheless leads to very rapid settling of the particles on the walls and in the depth of the pores or cavities. With a comparatively low flow resistance and high storage capacity, the body according to the invention is nevertheless extremely effective.

If, in accordance with a further development of the invention, the body is also made from a biodegradable plastic, this allows the filtered particles to be released without any significant expenditure of technical energy. A conventional combustion of the filters to be disposed of can thus be avoided. A loaded filter membrane, for example, can be hydrolyzed in a natural environment and the particles can be released. The released particles can be separated and recovered or compacted by chemical or physical processes. The particle-laden body can, for example, be placed in a water basin, where after the filter matrix has been hydrolysed, particles of different weights can be separated and obtained by sedimentation. The filtered particles can thus be released by autoseparation without the need for technical energy.

A suitable starting material for the production of a body according to the invention consists of a largely homogeneous mixture of in particular salt crystals of approximately the same size and a degradable matrix. It has been shown that such a starting material can be processed very easily and can be brought into the appropriate shape, for example by injection molding, pressing or extrusion. In order to produce a body according to the invention from the shaped starting material, it is then only necessary to detach the crystals, for this purpose the crystals are preferably water-soluble. The crystals can be salt crystals, for example of sodium chloride or potassium chloride. However, they can also consist of glucose.

According to a suitable method for producing the body according to the invention or the starting material, the crystals are mixed with a preferably degradable matrix and the mixture of crystals and matrix is shaped and finally the crystals are washed out. The degradable matrix can be, for example, a beta poly hydroxybutyrate.

Salt crystals can also be mixed into the solution of the polymer and the solvent evaporated. By selecting larger or smaller salt crystals, the pore size can be changed and the absorption characteristics can be adjusted to the particles to be filtered.

It is also advantageous to be able to produce filter supports and fastening parts from the body in one or more work steps

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to equip various existing filter housings. Such filter housings are already common in the automotive industry, for example.

Further advantageous features result from the dependent claims, the following description and the drawing. An embodiment of the invention is explained below with reference to the drawing. Show it:

1 shows a section through part of a known filter matrix,

2 shows a section through part of a body according to the invention on a greatly enlarged scale,

3 shows a section through part of a body loaded with particles, on a scale according to FIG. 2, and

4 shows a section through part of a starting material for producing the body according to the invention.

Fig. 1 shows a filter matrix 1 made of a foam 2 with lobed pores 3, which are interconnected. The pores 3 also lead to the outside, so that the filter matrix 1 is open-pore. The connections of the pores 3 to the outside and inside the matrix 1 are predominantly mixed narrow and tubular and to a small extent bubble-shaped.

2 shows a filter matrix 4 according to the invention which, with a volume fraction of preferably greater than 80%, has concave pores 7 which are connected to one another and to the outside of the matrix 4 via short passages 6. Each approximately spherical pore 7 is connected on average to several adjacent pores 7. The width A of the passages 6 is preferably about 10-50 p. and the width B of the pores 7 is preferably on average about 20-60 (i. The length of the passages 6 is very small, preferably several times smaller than their width A. This pore size and pore shape are simple by the choice of suitable salt crystals The salt crystals are preferably ground and sieved according to the desired grain size.

The width B is selected so that air passing through it can swirl in the pores 7 and, as shown in FIG. 3, particles 8 can settle in these pores 7. The particles 8 are, for example, carbon particles that occur in appropriately polluted ambient air.

As FIG. 3 clearly shows, even with a filter matrix 5 loaded with particles 8, numerous passages 6 are open, which allow liquid or gaseous substances to flow through. The fiiter matrix 4 preferably consists of a biodegradable plastic 5. A beta-poly-hydroxybutyrate or the plastic manufactured by ICI under the name "Biopol" is particularly suitable for this. These plastics can be degraded bacterially and / or by hydrolysis in a natural environment. This can take place in a water basin or the faecal basin of a sewage treatment plant. The released particles 8 can be recovered or compacted by chemical or physical separation processes. Depending on their density, which is different from that of water, the particles settle on the ground, float on the surface or remain suspended.

The degradation rate and thus the release rate of the particles can be set by a suitable choice of the plastic 5, for example by copolymerizing it more or less with valerate. A filter matrix 4 can thus be produced which decomposes solely through the action of atmospheric moisture or which requires a special microbial environment for degradation. The degradation rate depends on the intended use.

Suitable manufacturing processes are described below with reference to FIG. 4.

According to a first method, salt crystals with an average diameter of about 45 h are mixed with a biopol granulate. The salt crystals consist, for example, of sodium chloride or potassium chloride. The weight fraction of the salt crystals is preferably more than 80%. The largely homogeneous mixture is then shaped, for example pressed. The salt crystals are then washed out with water, which can be done at room temperature or elevated temperature. If necessary, the filter matrix 4 is dried.

According to a further process, the salt crystals are wetted with a solvent, preferably with dichloromethane, or coated with a lubricious plastic before mixing. After mixing with the Biopol granulate, the homogeneous mixture is also shaped and then the salt crystals are washed out.

In a further process, the salt crystals are stirred into a melt made of, for example, bio-poi plastic. The melt is then shaped and cooled and the salt crystals are washed out.

According to a further process, the salt crystals are mixed in a solution of the polymer, which is dissolved in an organic solvent, and the solvent is evaporated off by increasing the temperature or by reducing the pressure. With this method, a particularly homogeneous distribution of the salt crystals in the polymer is achieved.

The production processes mentioned allow a largely closed process cycle. For this purpose, the brine obtained after washing is heated, the evaporated water is condensed and the recrystallized salt is ground again. The ground salt is then mixed again with a Biopol granulate. The evaporated water can also be reused to wash out salt crystals.

A plastic suitable for producing the filter matrix 4 is preferably thermoplastic. Cellulose compounds, cellulose acetates, lactic acid compounds, butyric acid compounds and glycolic acid compounds are preferably suitable for this.

FIG. 4 clearly shows the dense arrangement of the crystals 10 embedded in the matrix 4, which form the starting material 9. The points of contact

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After the crystals have been washed out, 11 of the crystals 10 form the passages 6 shown in FIG. 2. The width and shape of the pores or cavities 7 of the filter matrix 4 are of course determined by the shape and size of the crystals 10. It has been shown that the filter matrix 4 is dimensionally stable even with very high proportions of crystals 10, for example up to a weight fraction of approximately 95%.

The starting material 9 shown in FIG. 4 can be processed in various ways and brought into the appropriate form. For example, the starting material 9 can be processed by injection molding, roll casting, cold pressing and the like. The appropriate shape can also be obtained by extrusion, cold or hot pressing. The filter matrix 4 can have the shape of a film, for example.

In the shaping of the starting material 9, the filter matrix 4 can also be used to simultaneously form filter carriers or fastening parts. The filter matrix 4 then forms, for example, a frame of a filter in some areas. For example, tabs or similar fastening parts can also be molded on. Such a filter is particularly suitable for filtering supply air in motor vehicle cabins.

To improve the dimensional stability, fibers (not shown here) can be added to the body 4. These fibers are preferably also degradable and, for example, made from milk or butyric acid polymers. However, carbon, glass, aramid fibers or other directional reinforcement elements are also conceivable. The proportion of fibers depends on the application of the body and especially the load to be carried.

The body according to the invention is also suitable as an object in which the lightweight construction is essential, for example as dishes, cutlery, packaging material, sound insulation material, as a household item or as a food carrier or as a container. In the case of a food and medicament carrier, it is also possible to dispense the food or medicament in doses as a result of the open porosity.

Claims (14)

Claims 1. Open-pore dimensionally stable body, in particular for filters for filtering liquid or gaseous substances, as a catalyst support, as a storage medium, for example for liquids, as an insulation material or as a lightweight material, characterized in that it is concave-porous. 2. Body according to claim 1, characterized in that it has concave cavities (7) with a width (B) of 20-60 p and passages between the cavities with a width (A) of 10-50 p. 3. Body according to claim 1 or 2, characterized in that the pore volume is at least about 80% of the total volume. 4. Body according to one of claims 1 to 3, characterized in that it consists of a degradable and in particular biodegradable or hydrolytically degradable plastic. 5. Body according to claim 4, characterized in that the plastic is microbially degradable. 6. Starting material for the production of a body according to one of claims 1 to 5, characterized in that it is an essentially homogeneous mixture of crystals of the same size and a matrix made of plastic. 7. Starting material according to claim 6, characterized in that the crystals are water-soluble salt crystals. 8. Starting material according to claim 7, characterized in that the crystals consist of sodium chloride or potassium chloride or glucose. 9. A process for producing a body according to claim 1, characterized by the following process steps: a) Crystals with an outer diameter of about 20-60 p on average are used with a Mixed plastic, b) the mixture is extruded, pressed, rolled or by injection molding into a predetermined Shaped, c) the crystals are washed out. 10. The method according to claim 9, characterized in that the crystals and the plastic are mechanically mixed as a powder or granules. 11. The method according to claim 9, characterized in that the crystals are stirred into a melt. 12. The method according to any one of claims 9 to 11, characterized in that the crystals are wetted with a solvent prior to mixing, or coated with a lubricious plastic. 13. The method according to claim 9, characterized in that the crystals are mixed with a solution of the degradable plastic, which is dissolved with a solvent, and the solvent is removed, for example evaporated, after the mixing. 14. Filter from a body according to one of claims 1 to 5, characterized in that filter carriers or fastening parts are formed on the body and these carriers or parts consist of the same material as the filter part. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 4th