DE4204955C2 - Process for removing nitrogen and carbon compounds from waste water - Google Patents

Description

The invention relates to a method according to the preamble of Claim 1 (DE-OS 39 25 091).

Through increasingly stringent environmental protection requirements wastewater treatment is also of increasing importance. From the wastewater organic and inorganic ingredients as much as possible be removed before it reaches the receiving water. Organic substances can be broken down by oxidation. Inorganic nitrogen compounds (ammonium) can Nitrification can be converted to nitrate. By Denitrification can convert the nitrate to nitrogen gas will. For the individual cleaning steps are included different milieu and operating conditions required, so that the required, contained in the activated sludge Microorganisms find optimal reaction conditions.

The carbon oxidation is, for example, by heterotrophic microorganisms carried out in an aerobic environment. The microorganisms need dissolved in wastewater, elemental oxygen to react with the organic Carbons that act as hydrogen donors. This serves to cover energy requirements. As implementation products carbon dioxide and water are generated. The organic carbon is still needed for cell formation.

Nitrification is used, for example, by chemo lithoautotrophic bacteria carried out in an aerobic environment. Of the Energy is required through the oxidation of an inorganic Covered with nitrogen compound. Carbon dioxide is used to build cells needed. The implementation is due to a low energy gain and thus characterized slow cell growth. That's why nitrification is preferred only when none easily degradable organic carbons in wastewater are included. The ammonium becomes in two steps Nitrate oxidizes.

The denitrification is again carried out by, for example heterotrophic microorganisms in the imperative absence of elemental oxygen and the presence of nitrate carried out. This milieu is called anoxic. Optionally anaerobic bacteria can be used in these conditions switch from oxygen breathing to nitrate breathing. she use the oxygen bound in the nitrate as hydrogen Acceptor for the implementation with the organic carbon.

Taking into account the facts described is a Numerous process engineering concepts implemented been. Corresponding systems can be numbered the sludge cycles and the arrangement of the Denitrification level in the flow chart with respect to the Classify nitrification. With a one-sludge system the activated sludge passes through all reactors before the Sludge recirculation takes place. In the multi-sludge system Reactors separately supplied with their own biocenosis. This gives the bacterial culture a specialization. In practice, one-sludge systems are much more common to be found.

With the downstream and also the upstream Denitrification becomes a separate one for nitrate reduction Reactor provided so that optimization of the implementation is possible. The downstream denitrification offers the Advantage that complete nitrogen elimination is possible is when organic carbon in the denitrification stage is available in sufficient quantity. This will do so achieved that in the denitrification stage organic Carbon, e.g. B. methanol is metered. That requires an additional expenditure on equipment and is with a Increase in operating costs.

DE-OS 38 33 185 describes a method for biological Wastewater treatment, in which the wastewater is initially under anaerobic conditions in contact with anaerobic sludge is brought so that no degradation of the organic substances of the waste water takes place. The one freed from the anaerobic sludge Wastewater then becomes one under aerobic conditions operated nitrification stage and then one under denitrification stage operated under anoxic conditions fed. The sludge separated from the waste water becomes the Denitrification stage fed directly. The solved organic carbon compounds are used in this Processes absorbed and stored by sludge organisms, which are also able to store phosphate. With this known method is not a controlled elimination of the Carbon possible. It works in the first stage low reaction speed so that it is a big one Must have construction volume. Since the first stage operated anaerobically there is also an odor nuisance. Finally can in the first stage only a special and therefore sensitive biocenosis can be used.

In the known method according to the aforementioned DE-OS 39 25 091 also works the first stage anaerobically. The bacteria contained in the activated sludge are in this Process selected so that from the carbon compounds lower fatty acids are formed in the waste water. The Fatty acids are released from phosphate by phosphate stored back-dissolving bacteria. In the Denitrification level are the stored in this way Carbon compounds oxidized. A separate feed from Carbon is therefore not in the denitrification stage required. With this known method is also no controlled elimination of carbon is possible. It works in the first, anaerobically operated stage as well the method already described with lower Response speed. There is also an odor nuisance unavoidable here and it can be in the first stage also only a special and therefore sensitive biocenosis be used.

The invention has for its object that to further develop the described method so that it is used of highly resilient reactors with increased performance.

This task is done according to the characteristic Features of claim 1 solved.  

Using this method is unnecessary - just like with known methods described above - the separate Supply of carbon in the denitrification stage. It will rather the organic carbon contained in the wastewater exploited and in the required amount by adsorption on the Activated sludge bypassing the nitrification stage in the Denitrification level introduced. The on the activated sludge too adsorbing amount of carbon can be limited the oxygen supply (partial oxidation) in the first stage to be regulated for complete denitrification of the nitrate or nitrite formed in the nitrification stage is sufficient. The nitrification in the Nitrification level with a correspondingly reduced level Oxygenation only to be carried out up to the nitrite. Like nitrate, nitrite is used in the denitrification stage completely removed.

With this procedure it is possible in all three Treatment stages to use high-performance reactors and thus a compact system size with a relatively small construction volume achieve. There is a complete elimination of Nitrogen and carbon from wastewater. The adsorption of organic carbon to the activated sludge is with the Oxygen limitation easy to carry out. The operating costs a corresponding system can be replaced by the additional dosage of carbon in the Denitrification level can be reduced. Because of the limitation the supply of oxygen can be saved ventilation energy.

Advantageous embodiments of the invention are shown in the Sub-claims emerge.

The method according to the invention is illustrated in the drawing explained as an embodiment. The only figure of the Drawing shows a plant for performing the method in Form of a block diagram.

At the beginning of the process (start), ammonium and organically polluted wastewater A together with activated sludge B the first stage I fed to a wastewater treatment plant. The activated sludge B consists, for example, of a Mixed population of heterotrophic microorganisms that predominantly have facultative anaerobic properties. In theory, activated sludge B could also be dispensed with will. However, it then takes a long time for the procedure to close leads to a usable result. In the first stage I will for example, a submerged reactor is used. The Oxygen S is fed into the submerged reactor. The The amount of oxygen should be limited in a defined manner. This oxygen limitation occurs in addition to the Partial oxidation of the organic matter in wastewater A an adsorption of the same on the activated sludge B. To the submerged reactor fulfills the following criteria, for example:

• - High-performance reactor with space loads of approx. 60 kg COD / m ³ d
• - good mass transfer properties of k _L a at least 500 h ^-1
• - Constant shearing of the bacterial flakes for production a large adsorption surface, for example using liquid blasting or with a stirrer.

In it are:
COD = chemical oxygen demand
d = 1 day (24 hours)
k _L = mass transfer coefficient
a = volume-related exchange area
h = hour.

In such a submerged reactor, the regulation of entered amount of oxygen a targeted amount organic substances adsorbed on the bacterial surface will.

The suspension of wastewater A and now loaded Activated sludge B arrives after the submerged reactor Intermediate clarification Z. There, the loaded activated sludge from separated the clear phase that no redissolution of the adsorbed Fabrics can be made. This can be done by setting the dwell time of the Activated sludge B in the intermediate clarification Z, while measuring the Solid level can be reached. After the first stage I are organic substances through the cleaning mechanisms Partial oxidation and adsorption largely from the clear phase been removed.

The clear phase is given to a nitrification stage II. This consists, for example, of a flooded one Fixed bed reactor that is supplied with oxygen. On the Fixed beds are autotrophic nitrificants as activated sludge located. The fixed bed reactor is, for example carried out as follows:

• - High-performance reactor with room loads of 4 kg NH ₄ -N / m ³ d
• - internals with a high mass transfer surface
• - internals with good adhesive properties for the Microorganisms.

After passing through nitrification stage II, the ammonium is converted into nitrate or nitrite. The cheapest is Oxidation of the ammonium only up to the nitrite. That can be done by Compliance with predeterminable values for the pH and the Oxygen concentration of the wastewater and the feed Amount of ammonium reached per unit of time and volume will. These parameters are measured continuously.

The nitrate or nitrite-containing wastewater is fed to a third treatment stage, denitrification stage III. This consists, for example, of a non-aerated submerged reactor with a subsequent separation of the activated sludge. The loaded activated sludge from intermediate clarification Z, which is led in a bypass 1 to the nitrification level II, is also given to the denitrification stage III. A pump 2 can be arranged in the bypass 1 . The organic carbon adsorbed on the activated sludge now serves as a reactant in the denitrification. The submerged reactor is constructed, for example, as follows:

• - High-performance reactor with a space load of 5 kg NO ₃ -N / m ³ d
• - good mass transfer properties of k _L a at least 500 h ^-1
• - oxygen exclusion.

After denitrification, the now unloaded activated sludge is separated from the clarified wastewater in a final clarification N. The organic contaminants and nitrogen compounds are removed from the wastewater and can be fed to a receiving water. The unloaded activated sludge can be returned to the first stage I by means of a pump 3 , where a new loading can take place. Excess sludge can be removed from the process.

The wastewater can from stage I to intermediate clarification Z, from there to nitrification level II and from there to Denitrification stage III are carried out by overflow, see above as shown in the drawing. However, it is also possible to use pumps between these stages.

Claims (7)

1. A process for removing nitrogen and carbon compounds from wastewater, with which the wastewater is mixed with activated sludge in a first stage, with which the clear phase of the suspension thus formed is separated from the activated sludge in an intermediate clarification, with which the separated clear phase in a nitrification stage is brought into contact with an aerobic environment with further activated sludge and with which the nitrified wastewater, together with the activated sludge separated in the intermediate clarification, is fed into a denitrification stage with an anoxic environment, characterized in that
that oxygen is added to the mixture of waste water (A) and activated sludge (B) in the first, aerobically operating stage (I) in such a limited amount that, in addition to partial oxidation of the organic carbon compounds contained in the waste water, adsorption thereof to the activated sludge (B ) in an adjustable amount and
that the oxygen supply and thus the amount of carbon compounds adsorbed on the activated sludge (B) are regulated in such a way that complete denitrification of the nitrate or nitrite formed in the nitrification stage and elimination of the carbon are achieved. 2. The method according to claim 1, characterized in that the one separated after the denitrification stage (III), unloaded activated sludge in the first stage (I) is returned. 3. The method according to claim 1 or 2, characterized in that the bacterial flakes contained in the activated sludge (B) in the first stage (I) during the oxygen supply are constantly being shattered. 4. The method according to any one of claims 1 to 3, characterized characterized in that the oxidation of ammonium in the Nitrification stage (II) up to the nitrite is carried out. 5. The method according to any one of claims 1 to 4, characterized characterized in that the loaded activated sludge (B) in the Intermediate clarification (Z) thus separated from the clear phase is that no redissolution of the adsorbed Carbon compounds are made. 6. The method according to any one of claims 1 to 5, characterized characterized in that for the wastewater receiving first stage (I), the nitrification stage (II) and the Denitrification stage (III) high-performance reactors be used. 7. The method according to any one of claims 1 to 6, characterized characterized in that in high performance reactors Internals arranged with a large mass transfer surface will.