DE4308159A1 - Process for decreasing the COD load in wastewater - Google Patents

Abstract

A process is described for decreasing the COD load in wastewater (effluent) in which an oxidation step, in particular an ozonation step, is provided upstream of a biological filter (17), the biocoenosis of which can catabolize carbon. The ozonation leads to partial decrease of COD and to a structural change in the remaining COD so that it is broken down by the biocoenosis in the biological filter (17). <IMAGE>

Description

The invention relates to a method for reducing the COD Pollution in wastewater with at least one biological Filter is provided, which is both a chemical causes physical as well as biological cleaning.

The wastewater treatment process can be either classic, i.e. H. with a one-stage revitalization with a dimensioning according to Worksheet A 131 of the Sewage Technology Association (ATV) or two-stage, d. H. with a downstream biological filter. In both cases it often happens that due to industrial influences or of conditions related to the structure of the catchment area  lie, the water-soluble COD portion is increased. In addition that comes with separate sludge treatment resulting cloudy water that is fed back to the sewage treatment plant also contains COD, which means that the COD burden in the Inflow is increased even further.

If the COD load exceeds a certain threshold, can they can no longer be eliminated because, on the one hand, the Degradation capacity of the filter is exhausted and on the other hand the COD-degrading microorganisms only at low loads, i.e. H. at relatively low COD burden, are active.

The maximum permissible COD concentration in the drain is in the legal minimum requirements defined as 75 mg COD / l. With one or two-stage wastewater treatment plants you can reach at Low load depending on the nature of the waste water from 60-70 mg COD / l. The regional surveillance authorities but can, e.g. B. when the water pollution is particularly high is to lower the minimum requirement even further. For This minimum requirement can be met in the clear water drain An activated carbon filter is activated at the end of the sewage treatment plant the dissolved COD components in an adsorptive way their concentration decreased. Alternatively, powdered coal, for example in precoat filters. Due to the limited adsorption capacity of the activated carbon for However, COD leads to frequent regeneration or high levels Dosage quantities of powdered coal and therefore too considerable Operating cost.  

The object of the invention is to provide a method of the above. Kind of like that to improve the COD burden even at an increased COD cargo in the supply already within the biological Preparation levels reliably and cost-effectively is reduced below 60 mg COD / l.

The solution to the problem is that an oxidation step is connected upstream of the biological filter, in which the waste water is treated with an oxidizing agent. The oxidizing agent is preferably ozone, but hydrogen peroxide (H ₂ O ₂ ) is also suitable.

The oxidation has two effects. On the one hand, it leads for a direct reduction of the COD load depending on the dosage by about 10 to 50%. The remaining COD, on the other hand, will especially through the extremely reactive ozone, the one strong oxidizing agent is changed in its structure, open-minded and thus more easily degradable for microorganisms. The chemical change in the COD also means that its possibly inhibiting influence on the metabolism of the COD-degrading microorganisms can be eliminated. Of the biological filters must be ventilated if not in the inlet enough residual oxygen from the oxidation is contained to to ensure the COD reduction. By coupling the Oxidation to a downstream biological filtration the structure of the CSB will be changed from that on the  So filter material immobilized microorganisms mined more reliably and effectively.

The additional cleaning stage in the form of oxidation is integrated at any point in the normal operation of the sewage treatment plant and is less expensive than e.g. B. an activated carbon filter. This is because no complete decomposition of the COD by ozone or H ₂ O _{2 is} required, which would also require large quantities of these substances which are not cheap either, but only just enough to achieve partial oxidation and to improve the biodegradability. A further advantage of the oxidation is that no residues in the form of sludges etc. are produced, or no complex measures for air pollution, as are required for the thermal regeneration of activated carbon. In addition, the oxidation leads to other effects that improve the wastewater quality or facilitate the treatment. The following are particularly worth mentioning: discoloration, disinfection and microflocculation.

The oxidation step advantageously takes place in one Fumigation chamber, in a partial flow or if ozone is used in a deep reactor. The deep reactor has that Advantage that he has a very good reaction management guaranteed an almost ideal plug flow. Thereby you can work with a smaller reaction volume. Of the Mass transfer of the ozone is more than 95%.  

The specific ozone dose is advantageously 0.5 to 1.5 mg O ₃ / mg DOC, in particular 0.7 mg O ₃ / mg DOC. Of course, higher doses are also possible.

The ozone is preferably used in a manner known per se Silent electrical discharge in the ozonizer tube Medium frequency range generated. This results in a high one specific ozone production even at relatively low Tensions, e.g. B. 9 kV. This also means there are no carbon copies to fear d. H. is the life of the ozonizer tube quite high. Such a device has a small size specific energy requirements and enables a compact Construction.

It is particularly cheap to add ozone from technical oxygen generate the liquefied by fractional distillation Air is produced. As a rule, 6% by volume of ozone is obtained; a maximum of about 8 vol% ozone can be reached.

In the following an embodiment of the inventive method using the attached Drawing described in more detail.

Fig. 1 shows schematically a fumigation chamber 12 and a processor coupled to the expiry of 15 biological filter 17, which is controlled so that the immobilized microorganisms aerobically there NH ₄ -N to NO ₃ -N implement and remove carbon compounds. The gassing chamber 12 and the biological filter 17 are part of a two-stage biological sewage treatment plant, the biological filter 17 belonging to a second biological cleaning stage which is connected downstream of a first biological cleaning stage or activation stage. It goes without saying that the gassing chamber 12 can be integrated into any biological cleaning stage.

The gassing chamber 12 has an inlet 11 and an outlet 15 for the waste water. It is divided into two chambers 31 , 32 by a vertical partition 30 , which does not extend all the way to the bottom. In the inlet 11 adjacent chamber 31 opens an ozone supply 13 , which comes from an ozonator, not shown, and continues in one or more distribution lines 14 , which carry porous fumigation body 14 '.

In the biological filter 17 , a granular filter material 22 is piled up on an approximately 30 cm high supporting gravel layer 21 approximately 3 m high. The supporting gravel layer in turn lies on a nozzle base 18 in which scavenging air nozzles 19 are embedded. A waste water inlet 16 and a purge air supply 20 are located under the nozzle base 18 . A rinse water inlet 27 opens into the wastewater inlet 16 and is fed with rinse water for backwashing the biological filter via a rinse water pump 28 . A process air distributor 23 with process air nozzles 24 is embedded in the supporting gravel layer 21 . A process air supply 25 opens into the process air distributor 23 . At the upper end of the biological filter there is an outlet 26 for the clear water and a rinse water outlet 29 .

The waste water passes through the inlet 11 into the chamber 31 of the gassing chamber 12 , flows downwards along the partition 30 , enters the chamber 32 and flows up there to the outlet 15 . At the bottom of the chamber 31 , the wastewater is mixed with the ozone which emerges from the fumigation bodies 14 'and rises in the chamber 31 . Wastewater and ozone are therefore countercurrent. The chamber 32 serves as a post-reaction container in which slower reactions between the dissolved ozone and the organic water content take place.

The wastewater treated with the ozone now passes through the inlet 16 into the biological filter 17 . There it passes through the nozzle base 18 into the filter material 22 and finally reaches the outlet 26 at the upper end of the biological filter. In the meantime, the biological filter 17 is ventilated via the process air distributor 23 . In the biological filter, the carbon pollution of the incoming wastewater is biodegraded on the one hand by the microorganisms immobilized on the filter material 22 and on the other hand by the retention effect for suspended substances of the filter material 22 .

A specific ozone dose of 0.7 mg 03 / mg DOC at 6 g O ₃ / m ^{3 has} proven to be very effective for direct degradation at an inlet concentration of 35 mg / l COD. At a reaction temperature of 12 ° C, a pH of 7.1 and an ozonation time of 28 min, a _total COD degradation rate of approximately 40% and a COD _dissolved - a degradation rate of approximately 30% can be observed by ozonation alone. The change in the COD structure is evidenced by the decrease in the UV absorption of the waste water constituents in drain 15 . This observation indicates a reduction in the number of conjugated double bonds and the ring systems in the organic compounds in question.

In the outlet 26 of the biological filter 17 , a further reduction in the carbon load is observed, which is greater than that of biological filters without an upstream ozonation and below 40 mg / l.

Reference list

10 wastewater treatment plant
11 inflow of 12
12 fumigation chamber
13 ozone supply
14 distribution line
14 ′ fumigation body
15 expiry of 12
16 Inlet of the biological filter
17 biological filters
18 nozzle base
19 purge air nozzles
20 Purge air supply
21 gravel support layer
22 filter material
23 Process air distributor
24 process air nozzles
25 Process air supply
26 Process of the bioreactor
27 rinse water inlet
28 rinse water pump
29 Rinse water drain
30 partition
31 chamber
32 chamber

Claims (5)

1. A process for reducing the COD load in wastewater, in which at least one biological filter ( 17 ) is provided, which brings about both chemical-physical and biological purification, characterized in that an oxidation step before the biological filter ( 17 ) is switched, in which the waste water is treated in a reaction vessel ( 12 ) with an oxidizing agent. 2. The method according to claim 1, characterized in that the oxidizing agent is ozone or hydrogen peroxide. 3. The method according to claim 1 or 2, characterized in that the reaction vessel ( 12 ) is a gassing chamber, a partial flow or a deep reactor. 4. The method according to any one of the preceding claims, characterized in that the specific ozone dose is 0.5 to 1.5 mg O ₃ / mg DOC. 5. The method according to any one of the preceding claims, characterized in that ozone in  Medium frequency range and / or from technical Oxygen is generated.