DE3433175A1 - Installation and reaction module for processing liquids - Google Patents

Abstract

In order to process liquids while adding reaction materials with subsequent separation of unwanted substances, an installation having a reaction module and a separator is proposed, the reaction module, by virtue of a special, meander-like flow path, achieving a sufficient residence time and a narrowly delimited residence-time spectrum, and the separator preferably being an alluvial filter. <IMAGE>

Description

System and reaction module for processing

Liquids The present invention relates to a system with a or several reaction modules for processing liquids with the addition of powdery or other reactants with subsequent deposition of these and / or other undesirable substances.

There are numerous liquids that can contain small or large amounts of contain unwanted substances with great care and up to a very high level Degree of separation must be removed. A typical use case for the present Invention relates to raw or groundwater, which can be used as drinking or high-quality Industrial water is to be used and therefore also from small amounts of impurities, z. B. chlorinated hydrocarbons, must be released. Some dissolved or suspended Impurities must first be made filterable by means of suitable reactants and then filtered off. The usual gravel or sand filters are for some fine impurities are not suitable and can only be regenerated with considerable effort will. Precoat filters, as described in German Patent 24 39 311.1 have significant advantages over the usual gravel or sand filters because they also separate very fine impurities because the used filter material Can be exchanged with little effort and because you can also use the precoat filter Can add substances that react with the impurities or they, such as z.3. powdery Activated carbon, adsorb. The dwell time or also the contact time in which there is contamination with a filter aid material such as the activated carbon, can react, but is very low with a precoat filter, because the liquid to be cleaned flows very quickly through the thin filter layer.

It is therefore useful to use a filter aid such as Active charcoal to be dosed in a container in front of the precoat filter so that it comes with remains in contact with the contaminants for a long enough time. At such a dosage in a container or in the inlet of a precoat filter, however, it is not ensured that that all liquid particles are in contact with the additive material for about the same time come. Some particles flow directly into the filter, others are swirled or flow into the filter in a roundabout way, so that only the mean residence time is kept roughly constant can be.

With different impurities in the same liquid but it has been found that not only the mean residence time is important is rather a narrowly limited residence time spectrum for a very careful separation necessary is. If the residence time is too long, individual impurities, which have already reacted with a filter additive due to other impurities repressed. On the other hand, if the residence time is too short, it is not sufficient to bind special impurities to the filter additive.

In a series of lectures by the University's Engler Bunte Institute Karlsruhe "Process engineering basics for a plant for the removal of halogenated hydrocarbons from groundwater ", published as issue 21 by ZfGB-Verlag, Frankfurt, 1983 is about the groundwater contamination that has been found in many places in recent years by halogenated hydrocarbons reported. After that you can use chlorinated hydrocarbons also remove with activated charcoal filters. The problems that arise thereby result mainly from the fact that there are still other organic substances in the water, such as B. humic substances occur. Therefore there is mutual influence in adsorption, and it is above all this fact that predicts about the filter effectiveness is made so extremely difficult. From page 119 onwards, the procedural Basics of fixed bed adsorbers for the removal of halogenated hydrocarbons reported. A turnover-time curve on page 134 shows that the The concentration of the solution in the water converges to a finite value over the course of the experiment, which cannot be undercut under the given circumstances. These curves understandably have a different course for different substances. From this and from what has already been said in the previous paragraph it follows that for sorption processes not only the residence time but also the residence time spectrum is essential.

The object of the present invention is a plant as well as suitable ones Reaction modules with a high degree of separation and a sufficient residence time with a narrowly limited residence time spectrum for the treatment of liquids with the addition of reactants with subsequent deposition of these and / or other undesirable substances, especially in a precoat filter.

To solve this problem, a reaction module after the proposed first claim. The in achievable with such a container Meandering flow ensures that the liquid to be cleaned comes into contact with a reaction substance in all its proportions and also both can react with this reaction substance for a sufficiently long time as well as not too long. The expected dwell time results from the container volume divided by the hourly throughput. The flow rate in the proposed The reaction container results from the prescribed residence time and container volume from the cross-sectional area of the flow channel and should be chosen so that solid additives or reaction products are not deposited or discharged. An increase in the flow rate can be achieved by increasing the number the baffles is enlarged, or by changing the flow not just in one, but is also meandering in two levels.

The second claim relates to the design effort particularly appropriate solution indicated.

There are a number of equally large and only horizontal guide plates arranged alternately offset from one another in the container. This solution is shown in Figure 1 and described in more detail there.

In the third claim a solution is proposed with which the overall length of the flow channel can be increased significantly compared to claim 2 and the is shown in more detail in FIG.

The dosage proposed in claim 4 at the liquid inlet can of course also be arranged outside the container in the feed line will.

The proposed in the 5th claim junction box at the liquid inlet serves to different concentrations of the reactants on the whole Distribute channel cross-section evenly, while the collector has a preferred flow should avoid to exit.

In the 6th claim a dosage for gases such. B.

Chlorine, or ozone, suggested that these gases countercurrent to the Liquid are passed and exit at the upper, open liquid inlet can.

With the intended dosage before the last flow deflection should be avoided that parts of the gas with insufficient reaction time already emerge from the lower liquid outlet.

In the 7th claim a constructive solution is proposed with the in particular, the long vertical side ends of a cuboid container reinforced can be. ttit the removable ones arranged on the upper edge of the container Tension rods make it easier to access the container for inspection or cleaning.

The circuit proposed in the 8th claim is used to adapt the Attachment to different quality of the liquid to be cleaned. When connected in series of several units, the throughput is compared to the parallel connection reduced, but the degree of separation increased. In addition, you can connect in series use different additives in the individual stages. From the beginning mentioned literature shows that the cleaning effect that can be achieved depends is on the specific added amount of, for example, activated carbon and also from the dwell time, with a finite one even with a longer dwell time The value of the degree of separation cannot be fallen below. But if you are looking for a technically meaningful residence time the adsorber material with a suitable filter separates from the liquid and then adds other adsorber material, so the solution concentration converges again to a now much lower one Value. Furthermore, the proposed multi-stage operation avoids that a strong impurity in terms of adsorber technology is a weaker impurity displaced the adsorber material.

In the 9th claim, a precoat filter is used as a particularly useful separator suggested. These precoat filters, such as those in the German patent 2 39 311.1 are too low for special adsorptive processes Dwell time because, compared to fixed bed filters, naturally the throughput time is through a only a few millimeters thick precoat filter layer is very short. Also the dwell time from a dosage in front of a precoat filter to the filter layer is low. Along with the proposed reaction modules have precoat filters, in particular in multi-stage operation, a particularly high degree of separation that of a fixed bed filter comes close without its disadvantages in regeneration or germination. The proposed Combination of reaction module and precoat filter is particularly suitable for a subsequent reverse osmosis, the membranes of which are very sensitive to fine impurities are.

Figures 1 4 show two different exemplary embodiments of the invention.

Figures 1 to 3 show a reaction module according to claim 2.

FIG. 4 shows a perspective view of the built-in components The reaction module of claim 3, wherein the container walls are omitted.

Figure 1 shows a side view, Figure 2 shows another side view and FIG. 3 shows a plan view of a cuboid container 1 which is placed on a lower Frame 2 made of square tubes rests and at its upper edge with an upper frame 3, also made of square tubes, is reinforced. Upper and lower frames are on the two long side walls reinforced by vertical ribs 4 on the top Edge of the container with screwable tension rods 5 are connected after removal this tension rods and a possibly existing but not drawn cover can the internals of the container are inspected or dismantled. During operation the tension rods should occur in a cuboid container filled with water absorb considerable forces. Inside the container are nine horizontal guide plates a 6 arranged with angles 7 on the two long side walls of the container and alternately, offset from one another, also on the short side walls of the container are attached. At the top of the container there is a pipe socket 8, the is normally used as an inlet, and at the lower end a pipe socket 9, which is normally used as an exit.

Both pipe sockets open into a distribution box 10 or

Collector 11 made of perforated sheet metal, which at this point over the entire width of the container is enough. In Figures 2 and 3 is an electrically operated pump 12, which suck the water out of the container 1 through a bend 13 and press to the filter provided. In addition, FIGS. 2 and 3 show a grid 14, which is not essential for the function of the reaction module Meaning is. In addition, both round sight glasses 15, 16 and 17 as well as elongated sight glasses 18, 19 and 20 are shown with which one the Can observe processes in the container. The liquid to be cleaned normally flows through the pipe socket 8 in the container, is with the distribution box 10 on the Width of the container distributed and then flows in a meandering manner through the offset against each other arranged baffles 6 down and leaves the container through the perforated plates of the collector 11 and the pipe socket 9. Solid reactants, expediently in slurried form and liquid, are expedient in this flow direction added through the upper metering nozzle 21, while gaseous substances get through better the lower metering nozzle 22 are added. Solid and liquid reaction substances leave the container after a dwell time determined only by the throughput rate through the pipe socket 9, while substances metered in gaseous form at 22 enter the container wander through in countercurrent and, as far as they are not detached from the liquid or are adsorbed, exit at the top of the container.

Compared to the previous figures, FIG. 4 shows a possibility with otherwise the same external dimensions the flow velocity but not the Increase dwell time. For this purpose, the solution according to Figure 4 has not only horizontal baffles 23 and 24 but also vertical baffles 25 and 26. The The liquid to be treated passes through a square indicated in this case Opening 27 at an upper corner in the container is through a perforated plate 28 distributed over the flow channel, which is square in this case, and flows first meandering through an upper level above the horizontal guide plate 23 and then enters through an opening in this sheet in a middle plane in which they also meander and then through an opening in the baffle 24 flows to the lower level, from which it is indicated by the circular one here Opening 29 leaves the container.

Claims (9)

System and reaction module for processing liquids Patent claims 1. Reaction module for the preparation of liquids with the addition of reactants with subsequent separation of these and / or other undesirable substances, thereby characterized in that in a cuboid container (1) several horizontal guide plates (6) that adjoin the walls of the container and have openings meander-like flow channels form on opposite walls. 2. Reaction module according to claim 1, characterized in that in a cuboid container (1) arranged several horizontal guide plates (6) are adjacent to the two long opposite side walls of the container (1) and alternately one adjacent to the two short side walls of the container (1) Form a meandering flow channel in a vertical plane. 3. Reaction module according to claim 1, characterized in that in a cuboid container several horizontal (23 and 24) and vertical guide plates (25 and 26) are arranged and the horizontal baffles alternate diagonally opposite corners of the Container have openings and the vertical baffles alternately on the opposite short side walls of the container have openings. 4. Reaction module according to claim 1, characterized in that on Liquid inlet, a metering device (21) for powdery or liquid reactants is available. 5. Reaction module according to claim 4, characterized in that on Liquid inlet or outlet from a distributor box (10) or collector (11) Perforated sheets or sieves is arranged. 6. Reaction module according to claim 1, d a d u r c h characterized in that a dosage at the lower liquid outlet before the last flow deflection (22) is available for gases. 7. reaction module according to claim 1, characterized in that the Container (1) at least on the two long side walls outside with vertical Ribs (4) is reinforced and opposing ribs at the top of the Container are designed to be connected to one another via tension rods (5). 8. Plant for the treatment of liquids with the addition of reactive substances with subsequent separation of the reaction products and / or undesired substances, wherein in each case a reaction module according to one or more of the preceding claims and a separator are connected in series, characterized in that that several units of reaction modules and separators, optionally one after the other or can be switched in parallel 9. Plant for processing liquids under Addition of reaction substances with subsequent deposition of the reaction products and / or undesirable substances using reaction modules and signs according to one or more of the preceding claims, characterized in that a precoat filter is used as a separator.