DE19505174B4 - adsorption - Google Patents

Abstract

Adsorption filter, consisting of stacked strips of a carrier material loaded with adsorbents, whereby the strips can be flowed through parallel to the carrier layer, characterized in that the adsorption filter contains at least 250 g adsorbents per liter and that the ratio of pressure loss in Pascals, measured at 1 m / s , to dynamic butane capacity in g / kg adsorbents, measured at a concentration of 76 ppm, a flow rate of 62 cm / s, a temperature of 23 ° C and 35% relative humidity, is less than 10.

Description

The present invention relates to an adsorption filter according to the preamble of claim 1.

An important application of adsorption filters is cleaning air flows, which headed inside become. In addition to particles that are removed with particle filters, contains the air contains a number of pollutants in low concentrations in the ppm and ppb range. Among these are those that because of their volatility are difficult to adsorb. Here you can help yourself with impregnation (Chemisorption), sometimes with very narrow micropores, in which the adsorption particularly pronounced is. Narrow micropores in the A area are for example for the sorption of low concentrations in road traffic occurring benzene of absolute necessity. It is common that Micropores measured by the dynamic butane capacity, for example at a concentration of 76 ppm, a flow rate of 62 cm / s, a temperature of 23 ° C and a relative humidity of 35%. butane is a gas that is difficult to adsorb (boiling point - 0.5 ° C). The dynamic butane capacity is therefore a measure of the ability to especially volatile Hydrocarbons, and is therefore a quality feature of Filter.

Another characteristic of the quality of a filter is the pressure drop, usually measured at 1 m / s. A high butane capacity requires a considerable mass of adsorbents, which must not be too compact in order not to unduly reduce the air permeability. The principle of the 'fixed expanded bed' ( EP 340 542 ), where adsorbents are fixed to a three-dimensional support structure: the spaces between the particles guarantee high air permeability, while Brownian molecular motion nonetheless leads to an excellent degree of separation. The pressure loss / butane capacity ratio is therefore an important criterion for filter quality.

The aim of the present invention was to find new filter constructions in which there is a favorable ratio of air permeability to butane capacity, the following guide value being sought:

The German publication DE 40 20 427 A describes a filter, characterized in that a strip-shaped, air-impermeable material is coated on one side with adsorbents and wound up into a disc or a cuboid. A pressure-sensitive or hot-melt adhesive is preferably applied to the side not covered with adsorbents, and the filter is bonded to a solid block that can be cut into slices. The adsorber particles serve as spacers between the carrier webs. The filter flows through parallel to the air-impermeable carrier elements covered with adsorbents. It is thus clear that the air resistance primarily depends on the adsorbents serving as spacers, in particular their quantity, size and shape, and therefore fluctuations in their dimensions must lead to fluctuations in the air permeability which cannot always be controlled. On the other hand, the one-sided loading leads to a less than optimal weight ratio of adsorbents / total weight. This simple and easy to manufacture filter design should be improved in light of the new findings.

Object of the present invention is thus an adsorption filter according to claim 1. Further advantageous Refinements are the subject of the dependent claims.

First, the carrier material was tried to be loaded on both sides with adsorbents. This is best done by squeezing (gusset) the carrier web with a highly viscous Adhesive and double-sided sprinkling with adsorbents. Have as glue so-called "high Solids "PU coatings well proven by Bayer because they have high initial stickiness as well as when curing viscosity minimum go through, which leads to a high adhesion of the particles to the carrier as well leads to the formation of "support bases", the latter the accessibility the adsorber particles increased. Other suitable adhesive compositions are available to the person skilled in the art, so that the mentioned High solids are not a limitation may be considered.

So that air permeability not exclusively depends on the occupancy of adsorbents, it is advantageous that support web to shape. If the adhesive, as suggested, applied with squeeze rollers will have to be made sure that the embossing "gets up" after squeezing. That is for example the case with embossed PES or PA knitwear or nonwovens made of the same material: the embossing, e.g. a knob embossing, is flattened out, but emerges after a few moments. The embossing has preferably a height from 2 to at most 5 average particle diameters with a width of one to four times the height. The shape of the embossing are fundamental no limits. In addition to the pimples, zigzag embossing can also be used.

If the adsorbents themselves are to act as spacers between the layers, they must not be less than a certain size. For example, particle sizes are from 0.3 to a few mm suitable. The same applies here as for the bed: the smaller the particles, the better the kinetics, but also the higher the pressure loss in the filter. One way of keeping the pressure loss within limits despite small particles is to apply the adhesive mass in a punctiform manner so that the adsorbents are not in full area but in piles and there are free passages between them. Brownian movements ensure that adsorption still occurs.

The carrier webs covered with adsorbents must then be processed into filter elements. As already mentioned in the DE 40 20 427 A1 was stimulated by winding around a core, whereby round, oval or rectangular filter disks can be produced depending on the requirements.

Another option is that of the adsorbents to lay the load-bearing web in parallel layers. All embodiments has in common that Filter element parallel to the carrier layer and not through the carrier layer flows through becomes.

The following examples are intended to show how the desired quality criterion was achieved. In all examples, fine-pored activated carbons (granular and spherical carbon) with a butane capacity (76 ppm, 62 cm / s, 23 ° C) of 40-60 g / kg were used. The grain coal was made from coconut shells and had an inner surface of approx. 1,100 m ² / g. The spherical carbons had surfaces of around 1,000 m ² / g and pitches and polymers as the starting product. A description of spherical carbons can be found, for example, in German Patent P 29 32 571 and US Patent 4957897.

Other adsorbents, e.g. moisture-insensitive molecular sieves, various impregnated Activated carbons etc. are used as needed, so that the examples itself not as a limitation may be considered.

example 1

An approximately 110 g / m ² heavy polyester knit was provided with a 1.5 mm high embossment. The roughly hemispherical knobs had a diameter of 3 mm. The roller temperature was 180 ° C. The embossed web was then squeezed off with a mixture of 100 parts Impranil NS 62 and 6.2 parts Imprafix HSC. Squeezing effect approx. 100%. The carrier web, which was acted upon with a sticky adhesive and thus sealed, was sprinkled with granular carbon - average particle size 1.1 mm - on both sides and the adhesive was condensed out. The 40 cm wide product was cut into 5 cm wide and 20 cm long strips, which were piled up in a stack of 15 cm high. The stack consisted of 50 layers, each of which contained approximately 8.8 g of activated carbon. The stack was welded to the 5 cm long edges (hot melt adhesive) and pressed into a frame. The stack was flowed through parallel to the layers. The pressure loss was 240 Pa at 1 m / s. The dynamic butane capacity (76 ppm, 62 cm / s, 23 ° C and 35 rF) was 26.4 g.

Example 2

A 90 g polyester fleece was squeezed off with the same knob embossing as in Example 1 and with the same adhesive. Squeezing effect approx. 100%. The sticky nonwoven web was then sprinkled with a spherical carbon with an average diameter of 0.55 mm on both sides. The coal coating was 510 g / m ² . 5 x 20 cm strips were made which were stacked into a 15 cm high stack which then contained 73 layers. The amount of coal in the package was 375 g. As in Example 1, the stack was flowed through parallel to the views. The dynamic butane capacity (76 ppm, 62 cm / s, 23 ° C and 35% rh) was 23 g, the pressure drop (1 m / s) 170 Pa.

Example 3

A paper web was dot-printed with a 6 mesh stencil with the adhesive of Example 1 (overlay 50 g / m ² ). The hemispherical piles of adhesive were sprinkled with the same grain coal as in Example 1 and the material was condensed. A coal coating of 220 g / m ^{2 was} achieved. Then part of the web was turned over and printed on a soft pad on the back with glue and sprinkled with coal. The coal bed totaled 430 g / m ² . The web printed on one side had a thickness of 1.6 mm, the web printed on both sides had a thickness of 3 mm. As in Example 1, a stack of 92 or 49 strips was made. The filter contained 215 g activated carbon in the first case and 211 g in the second. The pressure loss at 1 m / s was 180 Pa and 130 Pa. 13 g were found for the butane capacity (76 ppm, 62 cm / s, 23 ° C and 35% rh).

Example 4

The same paper as in Example 3 was coated on both sides with the same adhesive as in Example 1 and sprinkled with spherical carbon. 90% of the balls had a diameter of approx. 0.55 mm and 10 in diameter of approx. 1.2 mm. Separation was carefully avoided. After the adhesive was condensed out, the web was cut into 5 × 20 cm strips, each of which contained 4.9 g of coal. 88 strips were piled up in a stack. The stack contained 430 g of carbon balls. The butane capacity (76 ppm, 62 cm / s, 23 ° C and 35% RH) was 25 g with a pressure drop of 210 Pa (1 m / s).

Example 5

As in the example, adhesive was applied to both sides of a paper web and sprinkled with spherical carbon (Ø 0.3-0.8 mm). The amount of coal was 490 g / m ² . The coal-loaded material was again cut into 5 × 20 cm strips. On the other hand, strips of 6 × 20 cm were punched out of a 0.1 mm thick aluminum foil which had a 1.4 mm high zigzag embossing. A stack was formed as in the other examples, the aluminum foil serving as a spacer between the strips loaded with coal. The layers could be interlocked somewhat by pressure, so that a 15 cm high stack containing 76 layers with activated carbon was obtained, which contained 372 g of activated carbon balls. 22 g of butane could be adsorbed, while the pressure drop at 1 m / s was 190 Pa. The good thermal and electrical conductivity of the aluminum intermediate layers enables uniform heating, which can be done both with warm air and through the passage of electrical current. For this purpose, the film strips protruding from the narrow sides of the block were electrically connected on both sides and connected to a control transformer. With a recording of 150 watts, temperatures above 100 ° C could be reached within 10 minutes. This allows the desorption of many medium-volatile substances, which would, for example, considerably increase the service life of a filter for automotive interiors. The DE 42 25 272 A1 describes a filter in which the metallic support structure for the adsorbents can be heated. The adhesive is sometimes overused. In the present example, the aluminum intermediate layers are heated, which come into contact with the coal but not with the adhesive.

Claims (14)

Adsorption filter, consisting of stacked strips of a carrier material loaded with adsorbents, whereby the strips can be flowed through parallel to the carrier layer, characterized in that the adsorption filter contains at least 250 g adsorbents per liter and that the ratio of pressure loss in Pascals, measured at 1 m / s , to dynamic butane capacity in g / kg adsorbents, measured at a concentration of 76 ppm, a flow rate of 62 cm / s, a temperature of 23 ° C and 35% relative humidity, is less than 10. Adsorption filter according to claim 1, characterized in that this support material is airtight. Adsorption filter according to claim 1, characterized in that this Adsorption filter contains at least 300 g adsorbents per liter. Adsorption filter according to claim 1, characterized in that the backing has a nub structure, the height of the nubs is at least two and at most five middle ones The diameter of the adsorber particles and the base of the knobs (Diameter) one to four times larger than the height. Adsorption filter according to claim 1, characterized in that the Adsorbents consist of small and large particles, whereby the big ones Particles less than half make up the total amount and at least double the diameter of the small particles. Adsorption filter according to claim 5, characterized in that the huge Particles make up less than a third of the total. Adsorption filter according to claim 5 or 6, characterized characterized that the huge Particles at least three times the diameter of the small particles to have. Adsorption filter according to claim 1, characterized in that the Adsorbents are arranged in nests. Adsorption filter according to one or more of the preceding claims, characterized in that the adsorbents activated carbon in the form of granular or spherical coal, agglomerated moisture-insensitive che molecular sieves or porous polymers. Adsorption filter according to one or more of the preceding Expectations, characterized in that the Adsorbents a particle size of 0.2 up to 10 mm. Adsorption filter according to claim 10, characterized in that the Adsorbents a particle size of 0.3 up to 2 mm. Adsorption filter according to one or more of the preceding Expectations, characterized in that between the layers carrying adsorbents are embedded in smooth foils, that serve as spacers. Adsorption filter according to claim 12, characterized in that the Foils embossed are. Adsorption filter according to claim 12 or 13, characterized characterized that the embedded foils are made of metal and can be heated electrically.