DE4017024C2 - Process for regenerating a mixed bed ion exchange filter - Google Patents

Description

The invention relates to a method for regeneration an ion exchange mixed bed filter, in which the cat ion exchange material and that mixed with it Anion exchange material after the loading phase from the Filter container transported in an additional container and there by means of flowing liquid as a result different specific weight to two clean zones and be separated from an intermediate zone, then ßend the ion exchange material inside a clean zone half of the additional container and the ion exchange material the other clean zone outside the additional container is exposed to a particular regenerant and there after mixing these ion exchange materials again bed filters are combined.

Ion exchange mixed bed filters are known to come there used where demineralization occurs through one  supply liquid particularly high requirements be put. The high filter quality of the mixed bed fil ters is based on the fact that the rivers to be treated countless times on a small scale changing to the the ions preferably consisting of resin particles exchange materials, usually against first a first filter layer made of cation exchange material and then in a separate filter container second filter layer made of anion exchange material is flowing. With the high-performance demineralization of Water is often a cation exchange material tender first filter container, an anion exchange material rial containing second filter container and a intimate mixture of cation exchange material and anio Third filter container containing replacement material connected in series.

The regeneration of an ion exchange mixed bed filter is always more difficult because treating the cation exchange material with acid and treating the anion exchange material with lau a clean separation of the two ion exchange materials rialien must precede. With a dirty separation the subsequent regeneration would remove the contaminating one Proportion of the other mixed bed components rather load further. In the backmixed mixed bed Filters form these portions of imperfections that work result of the mixed bed filter deteriorate, the Bela Shorten the dephase of the mixed bed filter and electrical Difference conductivity measurements for timely loading complicate the end of the loading phase.

A regeneration process of the type mentioned at the beginning is already from the patent DE 27 43 608 C2 be  knows. With the peculiarities of the known method the goal is to achieve an external regeneration of exhausted anion and cation exchange resins one Mixed bed filters free of partial quantities of the mixed zone resins perform. That is why the material of the two Impure intermediate zone separating clean zones from the additional container into another additional container transferred and later in this other additional container together with the recently depleted ion exchange rate materials of the mixed bed filter are separated, then that Material of the impure intermediate zone obtained in transferred the first additional container and later in it the Io subjected to the next loading phase combined replacement materials for segregation. The Re generating the pure cation exchange material takes place always alternately in one or another additional container instead, the regeneration of the before the impure intermediate schenzone deducted pure anion exchange material on the other hand, always in the same additional rain rier container. After all, the known procedure requires Ren to regenerate an ion exchange mixed bed film ters a handsome number of containers, one corresponding high expenditure on fittings to connect the Be container, a large space requirement for the numerous Container, an excess amount of cation exchange material and an excess amount of anion exchange material for the remaining un outside the mixed bed pure intermediate zone and ultimately one too high Apparent consumption of regeneration chemicals.

From document DE 29 36 999 A1 it is known the cation exchange material and the anion exchange material with the help of a separating layer material which is in the mixed bed filter is mixed in as a third ingredient, due to  its specific weight after segregation forms a separation layer and does not participate in the ion exchange, through a division into two in the separating layer of the entire material of the mixed bed filter completely separate from each other. The segregation by means of however, flowing fluid takes place in the filter container instead of what is appropriate there over the mixed bed filter Free space is required. After that, the easier one Anion exchange material together with an upper part the separation layer into one exclusively for regeneration transferred certain additional container. The heavier cation exchange material is in the filter container in direct current for the operating flow of the mixed bed filter from above flowed down by its regenerant. Open remains like the return of the anion exchange material into the filter container and like the backmixing of the two ion exchange materials.

From the document US-PS 26 66 741 is a method for Regeneration of an ion exchange mixed bed filter known in the case of the inert separating layer material for mutual Separation of cation exchange material and anion exchange material is used, but an interim one Outsourcing the lighter anion exchange material from the filter container into an additional container is omitted. This is a simultaneous regeneration of the two ion exchange materials are excluded complicated valve and control devices required and can also be used in the variant the upward countercurrent regeneration of the two Ion exchange materials acid and alkali breakthroughs not exclude that cause chemical losses, the filter quality deteriorate and additional rinsing processes require.

The invention is based, with a Re generation method of the type mentioned at the beginning high filter quality with a low Production costs and low equipment costs  an economical in terms of low operating costs To achieve chemical consumption.

This object is achieved in that the cation exchange material and the anion exchange material with the help of an inert interface material through a division into two in the separating layer of the entire material of the mixed bed filter completely separated from each other, a prefilter made of anion exchange material, that over a liquid permeable Intermediate floor is located in the filter container with the anion exchange material returned from the additional container regenerated in the filter tank in upward flow and when including the separating layer material Reunification of the cation exchange material and the anion exchange material to the mixed bed filter one just below the shelf in the filter container merging mixing line at the same time from the lower end of the filter container and from the lower end of the additional container is fed here.

This results in reunification after regeneration the components of the mixed bed filter in the filter container, although for this by the arrangement of the pre-filter in the filter container through which between the pre-filter and the mixed bed filter located liquid permeable Intermediate shelf and the compactness of a such a mixed bed filter downstream only takes up little space is available. Structural restoration of the mixed bed filter that follows under the pre-filter includes the inert interface material, which mixed in the mixed bed filter as a third component is in the auxiliary tank due to its specific Weight forms a separation layer and on the ion exchange  does not participate. You don't just save yourself one separate regeneration container, but also a second one Additional container for the separation of the two ion exchange materials. The only supplement to the filter container required additional container can also be depressurized operated, open and made of plastic, which makes it particularly inexpensive. Also for the filter container the mixed bed filter results in cost savings, because it becomes one with the pre-filter is summarized. At the same time, the Effort on fittings for the mutual connection of the total containers required. Savings are also made each an excess amount of cation exchange material and of anion exchange material for one outside the mixed bed remaining impure intermediate zone. That instead used inert  Interface material is comparatively cheap and leads to a small increase in volume of the Mixed bed filter. The inclusion of one component the regeneration of the mixed bed filter in the upward Counterflow regeneration of the pre-filter saves money conditions for one of the two regeneration chemicals, as these Regeneration component otherwise with about twice the rain excess surplus would have to be driven.

A due to the Er specified in the subclaims Invention configurations preferred embodiment the invention is in the schematic drawing the gradually modified pair of containers is shown and is described in more detail below. It shows

Fig. 1, the pair of containers in the preceding the erfindungsge MAESSEN regeneration loading phase,

Fig. 2 shows the transfer of the three mixed-bed constituents from the filter container into the auxiliary tank,

Fig. 3 shows the segregation of the three mixed-bed constituents within the auxiliary reservoir,

Fig. 4, the return of the ion exchange material into the filter container,

Fig. 5, the application of the two ion exchange materials with regenerating agents and

Fig. 6 shows the structural restoration of the subsequent mixed bed filter under the prefilter.

The raw water to be treated in the filter loading phase (see FIG. 1) is fed to the columnar upstanding filter container 10 at its upper line connection 11 , from there migrates in succession in the downward flow the ion exchange material of the pre-filter 12 , the liquid-permeable intermediate floor 13 , the Mixed bed filter 14 and the further liquid-permeable intermediate floor 15 and then leaves the filter container 10 as good water at its lower line connection 16 . Even before exhaustion of the ion exchange material occurs just above the lower liquid-permeable intermediate floor 15 , the loading phase is automatically ended by the signal change from an electrical differential conductivity measurement.

Subsequently (see FIG. 2) with the help of Transportwas water, the entire material of the mixed bed filter 14 is withdrawn from the filter container 10 at its lying in the region of the lower liquid-permeable intermediate floor 15 Mate outlet 17 and fed to the additional container 18 via its upper line connection 19 . The trans port water reaches the material to be transported via the lower line connection 16 of the filter container 10 and the lower liquid-permeable intermediate floor 15 of the filter container 10 and leaves the transported material via the liquid-permeable intermediate port 20 of the additional container 18 and the lower line connection 21 of the additional container 18th

In the next process step (see FIG. 3), the three components of the mixed bed within the additional container 18 are separated by means of inflowing water due to different specific weights. The water enters here via the lower line connection 21 into the additional container 18 and via the upper line connection 19 from the additional container 18 . At the end of the process, an upper layer of the light anion exchange material 22 , an intermediate layer of the medium-heavy separation layer material 23 and a lower layer of the heavy cation exchange material 24 have formed, the transitions at the layer boundaries being fluid. Due to the addition of the inert barrier layer material 23, the resulting between the clean zone of anion exchange material 22 and the clean zone of cation exchange mate rial 24 impure intermediate zone is changed so that the anion exchange material 22 and the Katio nenaustauschmaterial 24 by a change made in the release liner division of the entire material of the Let mixed bed filter 14 completely separate from each other. With a sufficiently slim additional container 18, it is sufficient if the proportion of the separating layer material 23 in the volume of the mixed bed filter 14 is fifteen to twenty percent.

The bisection of the entire material of the mixed bed filter 14 is connected in the present case with the return of the anion exchange material 22 into the filter container 10 (see FIG. 4). For this purpose, with the help of transport water at the material outlet 25 located at the pitch 25 of the additional container 18, the material located above it is successively removed and the filter container 10 is fed via the material input 26 lying just below the upper liquid-permeable intermediate floor 13 . The transport water reaches the material to be transported via the lower line connection 21 of the additional container 18 and the liquid-permeable intermediate floor 20 of the additional container 18 and leaves the transported material via the lower liquid-permeable intermediate floor 15 of the filter container 10 and the lower line connection 16 of the Fil terbehälters 10th The partial emptying of the additional container 18 which initially takes place after the separation takes place far above its lower end in the region of the separating layer. This includes that the pre-filter 12 consists of the same or different Anionenaus exchange material to combine the regeneration component of the mixing bed filter 14 to be performed outside the Zusatzbehäl age 18 with the upward countercurrent regeneration of the pre-filter 12 . This in turn opens up cost advantages for a demineralization plant in which the prefilter 12 contains a cation exchange material which is preceded by other filter containers.

While the anion exchange material 22 of the mixed-bed filter 14 with an inert separating layer material 23 inside the filter container 10 is subjected to an alkali in upward countercurrent, the cation-exchange material 24 of the mixed-bed filter 14 remaining in the additional container 18 together with an inert separating layer material 23 is treated with acid in a downward flow (see in order to get along without drainage. Fig. 5) in the auxiliary tank 18. The drainage 27 provided in the filter container 10 for carrying out the used alkali is located somewhat below the top level of the pre-filter 12 consisting solely of anion exchange resin. Since the fresh alkali after passing through the lower line connection 16 of the filter container 10 and the lower liquid-permeable intermediate floor 15 of the filter container 10 first meets the anion exchange material 22 of the mixed bed filter 14 , the regeneration effect is particularly intensive. The regenerant solutions are finally displaced by subsequent washing water. For an occasional release of the pre-filter 12 from the filter resistance increasing dirt deposits, the usual backwashing space is kept ready by an elevation of the filter container 10 . The mixed bed filter 14 is provided with a backwashing space by raising the additional container 18 . To further reduce the cost of the apparatus, an open-top container made of plastic is used as the additional container 18 .

When the separating layer material 23 is combined (see FIG. 6) of the cation exchange material 24 and the anion exchange material 22 to form the mixed bed filter 14 , a mixing line 28 which opens into the filter container 10 just below the intermediate base 13 is at the same time from the lower end of the filter container 10 and the lower one End of the additional container 18 fed here. The Mischlei device 28 begins at the merge of the material outlet 17 lying in the region of the lower liquid-permeable intermediate floor 15 of the filter container 10 and the lower material outlet 29 of the additional container 18 lying in the region of the liquid-permeable Zwischenbo dens 20 and ends at the material inlet 26 of the filter container 10 . During the residual emptying of the Zusatzbe container 18 is as in the previous Teilent emptying the additional container 18 via its lower Lei line connection 21 transport water supplied and separated from the filter container 10 via its lower line connection 16 transport water in an appropriate amount. With the help of the mixing line 28 , the return transport of the cation exchange material 24 is connected to the backmixing process for the structural restoration of the mixed bed filter 14 . The quality of the mixing of the cation exchange material 24 , the anion exchange material 22 and the inert separation layer material 23 is increased in that the material circulation taking place via the mixing line 28 lasts well beyond the time of the residual emptying of the additional container 18 . In addition, the backmixing process is supported by a distributor arm 30 rotating just beneath the intermediate floor 13 in order to accelerate the backmixing and to make the best possible use of the space between the two intermediate floors 13 and 15 formed as nozzle floors for accommodating the mixed bed filter 14 without the intended purpose operation of the mixed-bed filter is noticeably Untitled beeinträch then through the non-driven auxiliary organ fourteenth

Claims (5)

1. A method for regenerating an ion exchange mixed bed filter, in which the cation exchange material ( 24 ) and the mixed with this anion exchange material ( 22 ) after the loading phase from the Filterbe container ( 10 ) in an additional container ( 18 ) and transported there by means of flowing liquid are separated due to different specific weights to two pure zones and an intermediate zone, then the ion exchange material of one clean zone inside the additional container ( 18 ) and the ion exchange material of the other clean zone outside the additional container ( 18 ) is exposed to its respective regenerating agent and then these ion exchange materials again to the mixed bed filter ( 14 ) are combined, characterized in that the cation exchange material ( 24 ) and the anion exchange material ( 22 ) with the aid of an inert separating layer material ( 23 ) by dividing the entire materia in the separating layer ls the mixed bed filter ( 14 ) are completely separated from one another, a prefilter ( 12 ) made of anion exchange material, which is located above a liquid-permeable intermediate floor ( 13 ) in the filter container ( 10 ), together with the anion exchange material ( 22 ) returned from the additional container ( 18 ) in the Filter container ( 10 ) is regenerated in the upward flow and when the separating layer material ( 23 ), including reuniting of the cation exchange material ( 24 ) and the anion exchange material ( 22 ) to the mixed bed filter ( 14 ), a mixing line that opens into the filter container ( 10 ) just below the intermediate floor ( 13 ) ( 28 ) is fed from the lower end of the filter container ( 10 ) and from the lower end of the additional container ( 18 ). 2. The method according to claim 1, characterized in that the material circulation taking place via the mixing line ( 28 ) Ma continues well beyond the time of the residual emptying of the additional container ( 18 ). 3. The method according to claim 1 or 2, characterized in that the backmixing process is supported by a distributor arm ( 30 ) rotating just below the intermediate floor ( 13 ). 4. The method according to any one of claims 1 to 3, characterized in that an open container made of plastic is used as the additional container ( 18 ). 5. The method according to any one of claims 1 to 4, characterized in that the proportion of the interface material ( 23 ) in the volume of the mixed bed filter ( 14 ) makes up five ten to twenty percent.