EP0938455A2 - Biological waste water purification process and device - Google Patents

Abstract

In a waste water purification process carried out in a clarification plant with activated sludge basins more than about 5 m deep, an oxygen-containing gas with a higher oxygen content than air, or pure oxygen, is continuously or temporarily supplied to the mixture of waste water and activated sludge in at least part of the aerobic volume of the activated sludge basin.

Description

Method and device for biological wastewater treatment

The invention relates to a method and a device for biological wastewater treatment according to the preamble of claim 1.

The activated sludge process is mostly used for biological wastewater treatment in sewage treatment plants. In this process, the different water constituents are breathed in a first process stage, the so-called revitalization, by microorganisms (bacteria) floating in the wastewater in a revitalization basin or used in part to build up new biomass. Here, nitrate is converted to molecular nitrogen (denitrification) and CO _{2 is} formed. A large part of the gases is removed by ventilation and mechanical circulation and leaves the system via the gas phase. In a second process stage, the so-called secondary clarification, the bacteria are then separated from the water in a secondary clarifier by sedimentation and can then be returned to the aeration tank. Such sewage treatment plants and processes are described, for example, in "Abwassertechnik", Hosang and Bischof, 9th edition, Verlag BG Teubner, 1989.

By tightening the legal requirements for wastewater treatment and possibly increasing the pollution load of wastewater, it is often necessary to expand existing wastewater treatment plants to improve their cleaning performance. Most of the time, the pelvic volumes have to be increased. In the secondary settling tanks, an increase in the surface area is generally necessary, while in the aeration tanks, an increase in volume can also be achieved by increasing the tank depth while maintaining the same surface area, which reduces space consumption and construction costs.

It has been shown, however, that in sewage treatment plants with increasing depth of the aeration tank, the problem of sludge flotation in the secondary settling tank increasingly occurs. This creates relatively big problems with Operation of the sewage treatment plant and relatively high expenses are necessary to master such sludge flotation.

A permanent or intermittent sludge flotation can lead to an undesired discharge of the sludge from the sewage treatment plant, whereby the permissible limit values, for example for chemical oxygen demand (COD), biochemical oxygen demand (BOD ₅ ), nitrogen and suspended matter, can be exceeded. In addition, the bacterial mass decreases due to the loss of activated sludge, which reduces the cleaning performance of the sewage treatment plant.

With increasing hydrostatic pressure with increasing depth of the activated sludge tank, a higher proportion of gas is dissolved in the wastewater / activated sludge mixture, which leads to sludge flotation due to the formation of gas bubbles in the activated sludge in the less deep secondary settling tank. Furthermore, an excessively high oxygen input in the denitrification stage of the activation tank causes an impairment of the denitrification. This can result in uncontrolled denitrification in the secondary clarification tank and cause sludge flotation.

To solve the problem of excessive sludge flotation in sewage treatment plants, attempts have been made to better regulate the oxygen content or to prevent the entry of atmospheric oxygen in the denitrification stage of the activated sludge tank. It has also been proposed to use relaxation flotation instead of conventional secondary clarification or to use an additional degassing zone or a flat degassing basin with coarse or medium-bubble aeration. Furthermore, the use of a weir with a special overflow edge, a weir cascade and, if necessary, an additional baffle with a possibility to remove foam was described (correspondence sewage, 43rd year, No. 6, June 1996, page 1083-1086, working report of the ATV - Technical Committee 2.6: "Aerobic biological wastewater treatment processes"). The measures mentioned above either increase the space requirement the activation level and are costly to build and operate, or only partially prevent flotation.

DE 43 29 239 A1 also discloses a method and a device for biological wastewater purification, in which and in which water constituents are breathed in by the supply of air or oxygen, the bacteria content in the aeration tank being increased by slat packs arranged at an incline or the activated sludge is thickened and the lamella packs are arranged at a distance at the flow path end of the activated sludge tank before the discharge. This process is intended to significantly reduce the volume of the aeration tanks, with a width of 5 m, a length of 10 m and a depth of 4 m being mentioned as exemplary aeration tank dimensions. This method and device do not relate to deep activation tanks or the problem of sludge flotation.

The invention has for its object to improve the method mentioned in such a way that the sludge flotation in the secondary clarifier is avoided relatively safely. In addition, the process should not require any further process steps or complex additional installations in settling tanks.

This object is achieved in that, at least in part of the aerobic pool volume of the activated sludge tank, an oxygen-containing gas with an oxygen content that is higher than that of air or pure oxygen is fed continuously or temporarily to the waste water / activated sludge mixture. In contrast to the previously known methods for preventing sludge flotation, sludge flotation in the secondary settling tank is avoided relatively reliably by increasing the oxygen input into the activation stage. The oxygen-containing gas with a higher than air

Oxygen content or pure oxygen is added to the wastewater / activated sludge mixture until the proportion of dissolved oxygen in the total content of dissolved gases is so high that the use of nitrate or nitrite in the secondary settling tank contained oxygen is prevented by the bacteria. On the one hand, oversaturation with nitrogen can be prevented if the oxygen-containing gas or pure oxygen is used in the entire aerobic part of the activation stage. If, on the other hand, oxygen-containing gas or pure oxygen is only supplied in a section of the aerobic part of the activation stage, the preceding aeration or denitrification in the anoxic part / process step initially results in an increase in the dissolved gas content in the wastewater / activated sludge mixture, however Before leaving the aeration tank, it is reduced with the help of the oxygen-containing gas or pure oxygen. At the same time, the necessary supply with

Oxygen guaranteed. In the simplest case, the wastewater / activated sludge mixture is supplied with a large amount of the oxygen-containing gas or pure oxygen until an oxygen content of at least approximately 1 to 2 mg / l has been established therein. The optimal oxygen content and the optimal amount of oxygen to be supplied depend on the wastewater to be cleaned, the sewage treatment plant and its special procedure and can be determined by a few simple tests. A particular advantage of the method according to the invention is that, in principle, no further installations in the activation tank are required to carry it out. The oxygen-containing gas or the pure oxygen can be supplied via the same device which is also used to introduce the air into the waste water / activated sludge mixture. Thus, all conventional ventilation devices according to the prior art can be used, with devices for fine-bubble pressure ventilation, such as candle aerators or plate aerators, being preferred. It is also intended to use devices designed specifically for pure oxygen, for example a gassing hose, an ejector (pump with venturi tube and mixing chamber) or oxidizer (pressure vessel through which water flows), but preferably a gassing hose. The aforementioned devices advantageously cause relatively low investment costs and do not require any additional space. The supply of compressed air and oxygen-containing gas or the pure oxygen can be spatially separated, which means that the supply takes place in different sections of the Activation basin or different, individual basin of activation. However, the supply can also be carried out at different times, for example in a round, relatively large activation tank of a smaller sewage treatment plant. In particular when pure oxygen is used, the method according to the invention saves energy costs for the pressurized aeration, and an adequate oxygen supply to the activation stage is ensured even when the sewage treatment plant is subjected to a shock.

Pure oxygen is preferably used as the oxygen-containing gas. The term "pure oxygen" here means oxygen, which is one

Has a minimum purity of approx. 80 vol .-%. For example, technical oxygen, which is produced by liquefying the air and typically meets the purity specification "Oxygen 2.0" (minimum purity 99% by volume) or "Oxygen 2.5" (minimum purity 99.5% by volume). The use of such "technically pure" oxygen gases is possible if an economical procedure can still be achieved.

It is provided according to the invention to supply the oxygen-containing gas or pure oxygen to the waste water / activated sludge mixture until the total content of gas in the waste water / activated sludge mixture, based on the

Saturation value, less than 150%, preferably less than 110%, is before the wastewater / activated sludge mixture is sent to the clarification. The total gas content here is the sum of the gas contents in% of the partial pressure of the corresponding gas in the ambient air, which is contained in the wastewater / activated sludge mixture, based on atmospheric pressure and at a given temperature. The gases are mainly nitrogen, carbon dioxide and oxygen.

According to the invention, the oxygen-containing gas or pure oxygen is fed to the activation tank in the last third of the activation tank or in the last aerobic tank of a tank cascade. It is advantageous that the oxygen-containing gas or pure oxygen replaces the conventional ventilation only temporarily, but preferably for 15 to 45 minutes per hour. The oxygen-containing gas or pure oxygen preferably replaces the conventional ventilation with an increased hydraulic load, which can occur, for example, as a result of a rain event.

According to the invention it is provided that the addition of oxygen-containing gas or pure oxygen takes place according to the level of the sludge level in the secondary clarifier. It is also envisaged to regulate the addition of oxygen-containing gas or pure oxygen as a function of the total gas content in the wastewater / activated sludge mixture.

According to the invention, the entry of the oxygen-containing gas or pure oxygen can also be carried out according to two temporally and / or spatially separated setpoints for the oxygen content in the waste water / activated sludge mixture or according to a specified setpoint value for the oxygen content and a specified setpoint value for the total gas content in the waste water / activated sludge. Mixture can be regulated. The control is advantageously carried out in such a way that the oxygen content in the wastewater / activated sludge mixture at the outlet of the

Activation level is not less than 1 to 2 mg / l and not higher than 10 mg / l, with the total gas content in the

Waste water / activated sludge mixture is simultaneously less than 110%. Regulation according to two setpoints that are predefined in terms of time and / or space is particularly advantageous when the waste water is relatively low

Have acid capacity or are very dirty. In this case, the carbon dioxide must be removed to a sufficient extent so that the pH does not drop below about 6.5. Furthermore, such a regulation may be necessary for a special composition of waste water, for example waste water with a relatively low dirt content (COD, BOD ₅ , nitrogen and suspended matter), if the oxygen requirement is already covered before the required amount of nitrogen can be removed. The oxygen-containing gas or pure oxygen can be supplied via all conventional supply methods, for example a liquid storage tank, on-site process or a pipeline. The term "pipeline" here means an existing pipeline of a fixed pipeline network or a pipeline to a neighboring source for the oxygen-containing gas or pure oxygen, for example an adjacent air separation plant. The supply via a pipeline is preferred because it enables a relatively high level of operational security and great security of supply with a relatively low technical outlay and a small space requirement.

It is further provided according to the invention that the oxygen-containing gas or pure oxygen is additionally supplied to the wastewater / activated sludge mixture in the event of load impacts on the wastewater with an increased oxygen requirement or with an increased energy requirement of the sewage treatment plant. In such cases, for example, the pressure ventilation can be reduced or even completely interrupted and partially or completely replaced by the supply of the oxygen-containing gas or pure oxygen.

The invention is further achieved by a device for biological wastewater treatment with activated sludge tanks with a depth greater than approx. 5 m, in which the sludge tank is assigned a device for supplying an oxygen-containing gas with an oxygen content that is higher than air or pure oxygen into the waste water / activated sludge mixture , which is suitable for fine-bubble pressure ventilation. Plate aerators or are preferably used as devices for fine-bubble pressure ventilation

Candle aerator is used and the device is advantageously assigned a pipeline for supplying an oxygen-containing gas with an oxygen content that is higher than that of air or pure oxygen. It is provided according to the invention to arrange devices for measuring the oxygen content in the wastewater / activated sludge mixture in the aerobic region of the activation tank and preferably to measure the oxygen content with the aid of probes. Membrane electrodes, so-called “Clark electrodes”, can preferably be used as probes for oxygen concentration measurement. Likewise it is possible to measure the oxygen concentration with the help of the so-called "Züllig electrodes" or with potentiometric methods. These measuring devices are described, for example, in "Small Oxi Primer, Technology and Methodology for Measuring Dissolved Oxygen with Membrane Electrodes", Chem Ing. Horst Nösel, WTW GmbH, Weilheim.

The invention will now be explained in more detail using an exemplary embodiment. In sewage treatment plants with aeration tanks with a depth of 6 to 10 m, which were used for the purification of waste water with an average waste water load of approx. 200 to 300 mg / l oxygen (BOD ₅ ) and 50 to 100 mg / l nitrogen content (TKN) pure oxygen is supplied to the wastewater / activated sludge mixture via gassing hoses or aerators. A volume flow of pure oxygen of 0.1 to 0.8 kg of oxygen per m ^{3 of} wastewater was set, so that the oxygen content was always in a range from 1 to 10 mg / l. For example, in a sewage treatment plant with a

Aeration tank depth of 9.3 m, with which wastewater with an average wastewater load of approx. 2000 population values was cleaned, pure oxygen was fed to the wastewater / activated sludge mixture via fine-bubble plate aerators, the volume flow of pure oxygen being up to 0.5 m ³ oxygen per m ³ wastewater was, so that the oxygen content was always in a range of 2 to 3 mg / l. There were no problems with sludge flotation in the secondary clarifier.

Claims

Expectations

1. A method for biological wastewater treatment in a sewage treatment plant with aeration tank of a depth greater than about 5m, characterized in that at least in a part of the aerobic pool volume of the aeration tank continuously or temporarily an oxygen-containing gas with an increased oxygen content compared to air or pure oxygen to the wastewater / activated sludge Mix is fed.

2. The method according to claim 1, characterized in that technical oxygen is used as the oxygen-containing gas.

3. The method according to claim 1 or 2, characterized in that the oxygen-containing gas or pure oxygen is fed to the waste water / activated sludge mixture until the total content of gas in the waste water / activated sludge mixture is less than 150% before the waste water / activated sludge Mixture is supplied to the clarification.

4. The method according to any one of claims 1 to 3, characterized in that the oxygen-containing gas or pure oxygen is supplied to the activation tank in the last third of the activation tank or in the last aerobic tank of a pool cascade.

5. The method according to any one of claims 1 to 4, characterized in that the oxygen-containing gas or pure oxygen at intervals for one

Time of 15 to 45 minutes per hour replaces conventional ventilation.

6. The method according to any one of claims 1 to 5, characterized in that the oxygen-containing gas or pure oxygen replaces the conventional ventilation with increased hydraulic load.

7. The method according to any one of claims 1 to 6, characterized in that the entry of the oxygen-containing gas or pure oxygen is regulated according to the level of the sludge level in the secondary clarification.

8. The method according to any one of claims 1 to 7, characterized in that the entry of the oxygen-containing gas or pure oxygen is regulated according to the level of the total gas content in the wastewater / activated sludge mixture.

9. The method according to any one of claims 1 to 8, characterized in that the entry of the oxygen-containing gas or pure oxygen after two temporally and / or spatially separated predetermined values for the

Oxygen content in the wastewater / activated sludge mixture or according to a predetermined setpoint for the oxygen content and a predetermined setpoint for the total gas content in the wastewater / activated sludge mixture is regulated.

10. The method according to any one of claims 1 to 9, characterized in that the oxygen-containing gas or pure oxygen is fed to the activation tank via a pipeline.

11. The method according to any one of claims 1 to 10, characterized in that the oxygen-containing gas or pure oxygen in addition Impacts of the wastewater with increased oxygen demand or with an increased energy requirement of the sewage treatment plant are fed to the wastewater / activated sludge mixture.

12. A device for biological wastewater treatment with aeration tank of a depth greater than about 5 m, characterized in that the aeration tank has a device for supplying an oxygen-containing gas with an oxygen content that is higher than that of air or pure oxygen into the wastewater / activated sludge.

Mixture is assigned that is suitable for fine-bubble pressure ventilation.

13. The apparatus according to claim 12, characterized in that the device for a fine-bubble pressure ventilation is a gassing hose.

14. The apparatus according to claim 12 or 13, characterized in that the device for a fine-bubble pressure ventilation is associated with a pipeline for supplying an oxygen-containing gas with an increased oxygen content compared to air or pure oxygen.

15. The device according to one of claims 12 to 14, characterized in that devices for measuring the oxygen content in the wastewater / activated sludge mixture are arranged in the aerobic region of the activated sludge tank.

16. The device according to one of claims 12 to 15, characterized in that that the oxygen content in the wastewater / activated sludge mixture is measured with the help of membrane electrodes.