DE10127545A1 - Combined bio-filtration and chemical polishing process, to treat communal waste water plant outfall, employs biomass to generate carbonic acid - Google Patents

Abstract

The waste water treatment plant outfall (1) is trickled over a distribution layer (7), introducing oxygen and carbon dioxide from the air, over a large area. Large volumes are distributed intermittently, the gases being taken up in the intervals. Biomass in the distribution- and base- (6) layers reacts with residual contaminants, releasing carbon dioxide. The released carbon dioxide is converted to carbonic acid in solution, and migrates through the separation layer (5) into the absorption layer (3). In the distribution layer and the base layer, nitrogen in the form of ammonia, a residual in the outfall, is converted into the nitrate form, using the entrained atmospheric oxygen. In the absorption layer, phosphate is chemically converted and bonded with lime under partial valent forces. CO2 ions from the carbonic acid, with some of the water-insoluble calcium carbonate or magnesium carbonate, for calcium hydrogen carbonate (bicarbonate) or magnesium hydrogen carbonate. This bonds with phosphates from the outfall into insoluble calcium phosphate or magnesium phosphate. The water, now freed of contaminants, phosphates and ammoniacal nitrogen, is led off by drainage into the final outfall. The process is further detailed, in accordance with the foregoing principles.

Description

The invention relates to a method and an apparatus for further purification of municipal wastewater, after which the Have left clarification of the sewage treatment plant.

According to the current practice, the Sewage treatment plant drain after cleaning in the receiving water initiated.

This wastewater treatment plant can still have too much phosphate and Contain ammonium nitrogen and organic dirt and thus pollutes the waters.

It is known from practice to process the sewage treatment plant with iron 3 To add chloride and thus achieve phosphate precipitation. The resulting sludge settles out and has to be separated.

This procedure is very expensive. Also be so that only the phosphates are removed.

The invention is based, from which Sewage treatment plant drain the phosphates still present, the Ammonium nitrogen and the organic dirt load accordingly the territorially prescribed parameters cost-effectively remove and furthermore the sewage plant drain as far as possible sterilize.

According to the invention the task in accordance with the Process described and the associated claims Device solved.

The application of the sewage treatment plant drain on the distribution layer must always with the simultaneous introduction of atmospheric oxygen and Carbon dioxide can be linked to the chemical and adsorptive To allow processes to take place in the layers below. The implementation of the organic dirt load by the Biomass produced carbon dioxide together with the carbon dioxide from the air covers the carbon dioxide requirement of the chemical Reaction of the same with the calcium or magnesium carbonate and Phosphates in the adsorption layer. The carbon dioxide gets in Form of carbon dioxide in the adsorption layer. This is constant overstowed. Only in this way is it possible for the chemical reaction to maintain the necessary ionization throughout. The before adsorptively attached to calcium or magnesium carbonate Phosphates are chemically bound in this way.

The water leaving the chemosorptive soil filter is largely free of phosphates compared to the wastewater treatment plant outflow, The ammonium nitrogen is reduced by up to 80% and the organic dirt load is reduced by a further up to 70% that bathing water quality is achieved.  

About this effective further cleaning of the sewage treatment plant drain to achieve an exact calculation of the chemosorptive Floor filter required. The areal are to be calculated Expansion, which is dependent on the hydraulic load on the existing organic dirt load and Ammonium nitrogen load. The amount of calcium or Magnesium carbonate depends on the phosphate load in the Sewage treatment plant expiry and usage time in years. Accordingly, the required layer thickness of the lime, which should be at least 20 cm. The grain size is advantageously about 0.5 to 4 mm.

In any case, the territorial factors play a role in the calculation Water purity requirements matter.

The degree of adsorption can be influenced via the residence time. through The dwell time at the outlet can be influenced. Higher overflow lengthens this.

The adsorption layer must be dimensioned such that over the planned period of use the resulting phosphate chemically and is bound by secondary forces and stored there, without affecting the chemical and adsorptive processes become.

The invention is intended to be explained in more detail below using an exemplary embodiment are explained.

The drawing shows the structure of the chemosorptive soil filter.

The wastewater treatment plant drain 1 is largely freed of the organic dirt load, phosphates and ammonium nitrogen present by means of a chemosorptive soil filter.

The chemosorptive soil filter is a water-impermeable basin, which is advantageously at least partially or completely embedded in the soil. At its bottom there is a up to 10 cm thick collecting layer 2 made of coarse gravel for the reception of very fine particles under 0.25 mm, which are contained in the substrate used.

The adsorption layer 3 made of calcium carbonate and magnesium carbonate is arranged above this. Lime is preferably used with a CaCO ₂ content of approximately 45% and an MgCO ₂ content of approximately 25%. The lime is granulated and has a grain size between 0.5 and 4 mm. The amount of lime is variable and must be calculated according to the hydraulic load, the proportion of phosphate present in sewage treatment plant 1 and the service life of the chemosorptive soil filter. However, the layer thickness of the lime should be at least 20 cm.

In the lower area of the adsorption layer 3 is the drainage 4 , in which the cleaned water is collected and drained into the receiving water. The drain 8 of the drainage 4 is arranged at the level of the upper edge of the adsorption layer 3 in the area of the separating layer 5 , so that the adsorption layer 3 is constantly flooded.

The adsorption layer 3 is covered by a fleece, which serves as a separating layer 5 to the floor body 6 located thereon.

The bottom body 6 is a layer of sand with a grain size of less than 4 mm and a layer thickness of 60 to 80 cm. The distribution layer 7 is located thereon. It consists of gravel with a grain size of 16 to 32 mm and a layer thickness of 15 to 20 cm. The layer thickness of the base body 6 and the distributor layer 7 are constant. They are therefore independent of the area of the chemosorptive soil filter, the hydraulic load and the concentrations of the phosphates, ammonium nitrogen and the organic dirt load. The area of the floor body 6 and the distributor layer 7 and thus of the entire chemosorptive floor filter depend on the maximum hydraulic load, the maximum organic dirt load, and the maximum load of ammonium nitrogen and phosphates.

The chemosorptive soil filter is a vertically flowed bottom filter.

The wastewater treatment plant drain 1 is rained over the distributor layer 7 . As a result, atmospheric oxygen and carbon dioxide from the air are introduced into the distributor layer 7 and the soil body 6 .

In another procedure, the wastewater treatment plant drain 1 is applied in larger quantities to the distributor layer 7 and this is flooded with wastewater treatment plant drain 1 . This takes place intermittently in order to fill up the free pores in the distributor layer 7 and the base body 6 with atmospheric oxygen and carbon dioxide from the air after the phases of the hydraulic loading. The running water sucks in the air. The renewed hydraulic load compresses the sucked-in air and lets it rise in fine bubbles.

If the oxygen demand is particularly high, it is also possible to combine the two processes described and to rain the sewage treatment plant 1 intermittently.

By means of these described procedures, the degradation of the organic dirt load still present is achieved. In the soil body 6 and the distributor layer 7 , the organic dirt load is broken down by the biomass present there and its filtering action also disinfects the sewage treatment plant drain 1 .

The wastewater treatment plant drain 1 is applied to the distributor layer 7 . As described above in the different methods, atmospheric oxygen and carbon dioxide are introduced into the distributor layer 7 and the bottom body 6 . Due to the biomass present there and the oxygen that is present, the dirt load that is still present is broken down, which releases further carbon dioxide, which combines with water to form carbon dioxide. The carbonic acid reaches the adsorption layer 3 with the water through the separation layer 5 . Furthermore, the ammonium nitrogen is broken down in the bottom body 6 and the distributor layer 7 . The ammonium nitrogen reacts with the atmospheric oxygen to form nitrate nitrogen. In this way, approximately 80% of the ammonium nitrogen is removed.

NH ₄ N + 2O ₂ ↔ 1 / 2NO ₂ + 2H ₂ O

Now only the phosphates are still contained in the water, which diffuse through the separating layer 5 into the adsorption layer 3 . In addition to the adsorption process, a chemical reaction also takes place there. The CO ₂ ions that have been released during the biological conversion of the organic dirt load, or that come from the air, react with a part of the water-insoluble calcium carbonate to form calcium hydrogen carbonate, which then forms water-insoluble calcium phosphate with the phosphates. If the amount of calcium carbonate, based on the amount of phosphate and the working time, of the chemosorptive soil filter has been correctly calculated in years, it can be assumed that the phosphate is fully converted.

H ₂ CO ₃ ↔ 2H ⁺ + CO ₃ ^2-
CaCO ₃ + 2H ⁺ + CO ₃ ^2- ↔ Ca ²⁺ + 2HCO ^3-
3Ca ²⁺ + 2PO ₄ ^3- ↔ Ca ₃ (PO ₄ ) ₂

With the magnesium carbonate present in the lime, an analog one runs chemical reaction, as with calcium carbonate. In that case the water-insoluble magnesium phosphate is formed.

The adsorption takes place by means of physical surface forces of the adsorbent.

The lime activity is included in the intended adsorption about 5%.

The phosphate is bound to the lime by non-valent forces and stays there for the entire time the chemosorptive soil filter is designed. Usually you can Be 20 to 30 years old.

The thus purified effluent 1 is withdrawn after cleaning on the drain 4 as pure water and passed to receiving waters.

The residence time in chemosorptive soil filters is dependent on the throughput speed through the distributor layer 7 and the soil body 6 and on the free pore volume in the adsorption layer 3 . But it should be at least four hours.

Since the amount of sewage treatment plant drain 1 , its exposure to phosphates and ammonium nitrogen as well as organic dirt load and its period of use vary from application to application and the qualitative requirements for the wastewater to be discharged into the receiving water can vary from place to place, the chemosorptive soil filter is appropriate for each application to calculate specific conditions. This affects its areal expansion and especially the amount of lime to be mixed.

List of the reference numerals used for the invention

1

effluent

2

trapping layer

3

adsorption

4

drainage

5

Interface

6

sediment

7

distribution layer

8th

procedure

Claims (16)

1. A method for further purification of municipal wastewater, characterized in that
the wastewater treatment plant drain is raining over a large area with the entry of atmospheric oxygen and carbon dioxide from the air or
is applied in large quantities but intermittently to the distributor layer, the wastewater treatment plant drain sucking in atmospheric oxygen and carbon dioxide during the breaks in the order and
in the distribution layer and in the soil body using the biomass located there, the remaining organic dirt load is broken down with the participation of the atmospheric oxygen released, releasing carbon dioxide, which converts to carbon dioxide in the water and migrates through the separation layer into the adsorption layer and
in the distribution layer and in the soil, the ammonium nitrogen, which is still in the wastewater treatment plant drain, combines with the atmospheric oxygen to form nitrate nitrogen and
the phosphates are chemically converted in the adsorption layer and bound to the lime by means of secondary forces by
the CO ₂ ions from the carbonic acid form part of the water-insoluble calcium carbonate or magnesium carbonate calcium hydrogen carbonate or magnesium hydrogen carbonate, which then combines with the phosphate in the sewage treatment plant to form water-insoluble calcium phosphate or magnesium phosphate and
The water freed from biological dirt, phosphates and ammonium nitrogen is drained into the receiving water via the drainage. 2. The method according to claim 1, characterized in that the Sewage treatment plant drain intermittently above the distribution layer is raining. 3. The method according to claim 1 and 2, characterized in that the wastewater treatment plant drain through the filter effect of the soil body and the distribution layer is sterilized. 4. The method according to claim 1 to 3, characterized in that the phosphate to the calcium or Magnesium carbonate is bound and throughout Operating time of the chemosorptive soil filter remains there.   5. The method according to claim 1 to 4, characterized in that the areal expansion of the chemosorptive soil filter as well as the amount of in approach bringing calcium carbonate or magnesium carbonate depending on hydraulic load, phosphate load and Ammonium nitrogen, the organic dirt still present as well as the territorial requirements for that in the receiving water water to be discharged is calculated. 6. Device for further purification of municipal wastewater, characterized in that the device is a vertically flowed through chemosorptive soil filter, which is water-impermeable at its lateral boundaries and its lower boundary and at least partially or completely embedded in the ground and in its lower part is a collecting layer ( 2 ), above it an adsorption layer ( 3 ), in the lower area of which there is a drainage ( 4 ), and above the adsorption layer ( 3 ) there is a separating layer ( 5 ) and on the separating layer ( 5 ) there is the bottom body ( 6 ), which is covered by the distributor layer ( 7 ). 7. The device according to claim 6, characterized in that the collecting layer ( 2 ) is an up to 10 cm thick layer of coarse gravel. 8. The device according to claim 6, characterized in that the adsorption layer ( 3 ) consists of granulated calcium carbonate or calcium and magnesium carbonate or magnesium carbonate with a grain size between 0.5 and 4 mm and the layer thickness of the adsorption layer ( 3 ) is variable, but at least Is 20 cm. 9. The device according to claim 8, characterized in that the adsorption layer ( 3 ) preferably consists of lime. 10. The device according to claim 8 and 9, characterized in that the thickness of the adsorption layer ( 3 ) is dependent on the phosphate load of the sewage treatment plant drain and the intended usage time of the chemosorptive soil filter, in years. 11. The device according to claim 6, characterized in that the outlet ( 8 ) of the drainage ( 4 ) is at the level of the separating layer ( 5 ), so that the adsorption layer ( 3 ) is stony. 12. The apparatus according to claim 6, characterized in that the separating layer ( 5 ) is a fleece which consists of a moisture-resistant plastic. 13. The apparatus according to claim 6, characterized in that the bottom body ( 6 ) is a 60 to 80 cm thick layer of sand, with a grain size below 4 mm. 14. The apparatus according to claim 6, characterized in that the distributor layer ( 7 ) consists of a 15 to 20 cm thick gravel layer with a grain size of 16 to 32 mm. 15. The apparatus according to claim 6, characterized in that the The area of the chemosorptive soil filter depends on the maximum hydraulic load, the maximum organic Dirt load, as well as the maximum load Ammonium nitrogen and phosphates. 16. The apparatus according to claim 6, characterized in that the residence time of the sewage treatment plant drain ( 1 ) in the chemosorptive soil filter depends on the throughput speed through the distribution layer ( 7 ) and the soil body ( 6 ) and on the total volume of the free pores in the adsorption layer ( 3 ) and that it is at least 4 hours.