DE4407773A1 - Post-purificn. system for waste water, following activated sludge process - Google Patents

Abstract

A group of vessels carries out: preliminary denitrification; nitrification; clarification; recirculation of activated sludge and nitrified waste water. Recirculation is induced with the air of pneumatic energy, the air being introduced at one or more locations within the vessel unit. Processing proceeds in an alternating series of aerated and non-aerated vessel units. The tank unit in which the processes take place is also claimed. In the first non-aerated vessel, waste water is mixed with activated sludge, constituting a denitrification stage. From here, the next vessel is an aerator, where nitrification takes place and then there is a non-aerated clarification zone follows. The recycled activated sludge and nitrified waste water, are sent to an activated sludge aeration region. This and the nitrified waste water are recirculated into a non-aerated tank unit. Waste water - activated sludge mixture from the non-aerated vessel is introduced in the lower region of the aerated vessel unit. Waste water - activated sludge mixture from the aerated vessel enters the upper region of the non-aerated vessel. Air is blasted in, as fine bubbles for aeration, also achieving density reduction and a degree of lift, to move the fluid.

Description

The invention relates to a method and a device for cleaning of wastewater using the activated sludge process with nitrification and upstream denitrification.

Wastewater, which still has a high proportion of deductible substances is successively under anoxic and aerobic conditions with activated sludge treated. Animated return sludge from a clarification zone and nitrate-containing Recirculation water quantity is treated under aerobic conditions and in the anoxic basin is recirculated.

There are a variety of methods known in which wastewater with Activated sludge from a secondary clarifier is treated. These include u. a. also activated sludge process with common aerobic sludge stabilization, Contact sludge process with regeneration of the recirculated Activated sludge under aerobic conditions and in particular methods for Nitrogen elimination by nitrification and upstream denitrification.

In the upstream denitrification treatment of the Waste water successively under anoxic and aerobic conditions. Two Separate circulation streams, nitrate-containing wastewater activated sludge mixture and The activated sludge separated in a clarification zone is recirculated. The Training anoxic and aerobic zones in separate pool units due to the conflicting environmental conditions procedurally advantageous. The usual, dissolved construction offers the possibility to expand individual plant parts separately, but is especially for small and Average plant sizes less economical. The promotion of Nitrate recirculation water volume (about 200 to 300%) requires additional mechanical engineering investment and operating costs.

The invention is based on the object, a method of the initially specify type mentioned for sewage treatment, in the procedural favorable environmental conditions for denitrification, nitrification and Clarifications are guaranteed and that the return of activated sludge and nitrate-containing wastewater to simple, economical and the Activated activated sludge flakes gentle way.

The problem underlying the invention is characterized by in the Characteristics of claim 1 given teaching solved.

The invention is also based on the object, a device for Indicate the implementation of the procedure.

The advantages achieved by the invention are particularly in the small and medium plant size considerable Investment and operating costs to see and explained below.

Due to the compact arrangement of the pool units are hydraulic Losses between pools are minimized. The circulation flow promotion takes place by utilizing the oxygenation of the aerobic processes anyway to be applied pneumatic energy input into the fine bubbles ventilated pool units. This eliminates return sludge and Recirculation pumps including reserve capacity and control technology as well ongoing maintenance and energy costs for their operation.

The compact arrangement of the aeration tanks and the secondary settling tank allows a reduction in the construction costs and the Land consumption. In particular, an external secondary clarification zone and at Design of the plant for aerobic sludge stabilization the primary treatment.

An arrangement of two groups can be around as a pump sump serving central pool unit done. By recycling wastewater Activated sludge mixture from the denitrification and / or clarification zone, the Central pool unit at the same time as anaerobic zone to biological Phosphorelimination be used.  

Due to the square plan of the pool units is a Expansion by the cultivation of individual pool units possible. In particular, with tank units in container design arbitrarily Expandable pelvic configurations of four, six, eight or nine units and thus a gradual expansion can be realized. Also one about it Extensive expansion is possible.

Hereinafter, the method and the apparatus will be referred to explained in more detail on drawings and practical examples. It shows

Figure 1 is a schematic section through a pumping stage of an unvented and a ventilated pool unit.

FIG. 2 shows a schematic section through a group of four pool units; FIG.

Figure 3 is a schematic plan view of a group of four Beck units.

Figure 4 shows an embodiment for a group of four Beck units.

Figure 5 is a schematic plan view of two groups of nine Beck units.

Fig. 6 shows an embodiment of two groups of nine pool units.

Fig. 1 shows a pneumatic pumping stage of an unventilated and a ventilated pool unit.

Between basin (A) and (B) flows a quantity of water Q with a local flow _loss p _vö , so applies

p _A = p _B + p _vö

The density ρB of the aerated water with a volumetric air fraction b is less than the density ρ _{A of} the non-aerated water

ρ _B = ρ _A (1-b).

With h = p / ρ the water level difference is

h _B -h _A = b × h _A -h _vö

The maximum water quantity Q _u = h by pneumatic energy input as a perfect attack by h _B - can be promoted in the subsequent non-aerated basins h _A is calculated as

Q = 2/3 × h _ü ^1.5 x c × W × √ (2 × g)

where c is the raid coefficient and B is the width of the raid threshold.

With a usual volumetric air fraction b of about 1%, a local loss height h _vö of about 0.7 cm and a water depth h _A of up to 8 in a maximum of 36 l / s per m _{seizure threshold} promoted.

The non-ventilated pool unit can be equipped with mechanical circulation units provided as a fully mixed denitrification or with a adjustable drain threshold provided serve as a clarification zone. The ventilated Pelvic unit can be equipped with fine-bubble ventilation units as Nitrifikations- or return sludge aeration zone serve. A group of Pelvic units can be alternately unventilated from any number and ventilated pool units.

Fig. 2 shows the schematic representation of a group of four pool units with denitrification (A), nitrification (B), secondary clarification (C) and return sludge aeration zone (D).

The feed water quantity (Q _to ), the return sludge and the nitrate recirculation amount (Q _RS + Q _RZ ) are introduced into the fully mixed, non-aerated denitrification zone (A), where nitrate is denitrified to molecular nitrogen. The water enters the nitrification zone (B) in the lower part of the basin where organic compounds are broken down and nitrogen compounds are nitrified to nitrate. The water is introduced into the secondary sedimentation basin (C) in the upper part of the basin. The purified wastewater (Q _ab ) flows through a controllable rollover threshold, while the activated sludge settles. Return sludge and nitrate recirculation water volume (Q _RS + Q _RZ ) flow at the basin bottom in the aerobic return sludge aeration zone (D), in which depending on the operation of the plant an aerobic sludge stabilization, return sludge regeneration and / or additional nitrification takes place and from where they have a raid threshold in the denitrification zone (A) are introduced.

Advantageous embodiments of a device for carrying out the Procedure and hydraulic design are illustrated by two examples explained.

example 1

Fig. 3 shows a schematic plan view of a group of four pool units, in which the recirculation takes place.

A practical embodiment of a single-flow sewage treatment plant, which was dimensioned according to ATV A126 for a plant size of about 1000 ECW with simultaneous aerobic sludge stabilization, is shown in FIG .

The dimensions chosen for a pool unit are L × W × H = 5.00 m × 5.00 m × 8.00 m. The process engineering and hydraulic Rated variables are listed in Tab.

Conventional ceramic gassing units achieve a fine bubble of about 2 mm and thus a bubble ascent rate of 24 cm / s.

It was further assumed that a flow velocity of about v = 0.3 m / s, in order to avoid back mixing of oxygen into the non-aerated zone, and thus a local loss height h _vö of about 0.7 cm.

Rated values Example 1 design values Qt (m³ / d) 346 BOD (kg / d) 60 Nges (kg / d) 11 B _TS (kg BOD / kg TS d) 0.04 TS content (kg / m³) 4.00 Air requirement (m³ / d) 2100 Bubble diameter (mm) 2.00 Aufstiegsgeschw. (Cm / s) 23,90 b (%) 0.25 h _A (m) 8.00 h _ve (cm) 0.70 h _ü (cm) 1.30 B (m) 5.00 Raid coefficient c (-) 0.64 Q _{RS + RZ} (m³ / d) 1210 Q _{RS + RZ} (% of Qt) 350

Example 2

Fig. 5 shows a schematic plan view of two groups of nine Beck units in which the recirculation of a group is carried out in the other.

The waste water (Q _to ) is distributed symmetrically between the two denitrification zones from the central tank unit (PS) serving as pump sump. By opening the shut-off device (I), sludge deposits from the clarification zone (C) can be returned to the pump sump. By opening the shut-off device (I) or (II) discontinuously activated sludge can be passed into the sump and thus the process an anaerobic zone for biological phosphorus elimination according to the Phoredox or UCT principle.

A practical embodiment of a two-way sewage treatment plant, which was dimensioned according to ATV A131 for a plant size of about 5000 EGW, is shown in FIG .

The dimensions chosen for a pool unit are L × W × H = 5.00 m × 5.00 m × 8.00 m. The process engineering and hydraulic Rated variables are listed in Tab. 2.

Rated values Example 2 design values Qt (m³ / d) 1730 BOD (kg / d) 300 Nges (kg / d) 55 B _TS (kg BOD / kg TS d) 0.10 TS content (kg / m³) 4.00 Air requirement (m³ / d) 10500 Bubble diameter (mm) 3.00 Aufstiegsgeschw. (Cm / s) 23,90 b (%) 0.50 h _A (m) 8.00 h _ve (cm) 0.70 h _ü (cm) 3.30 B (m) 5.00 Raid factor c 0.64 Q _{RS + RZ} (m³ / d) 4900 Q _{RS + RZ} (% of Qt) 550

Claims (22)

A process for purifying wastewater by the activated sludge process in a group of pool units
with an upstream denitrification,
with a nitrification,
with a clarification and
recycled recycle sludge and nitrified wastewater;
characterized in that the recirculation is achieved by introducing pneumatic energy into at least part of the pool units. 2. The method according to claim 1, characterized in that alternately unventilated and ventilated pool units in the direction of circulation consecutive. 3. The method according to claim 1 and 2, characterized in that in at least one first non-ventilated Activated sludge mixture is formed. 4. The method according to claim 3, characterized in that the first unventilated pool unit forms a denitrification area. 5. The method according to any one of claims 1 to 4, characterized in that the wastewater activated sludge mixture in at least one first aerated Pelvic unit is initiated. 6. The method according to claim 5, characterized in that the first ventilated Pelvic unit forms a nitrification area. 7. The method according to any one of claims 1 to 6, characterized in that the wastewater activated sludge mixture in at least one non-aerated Clarification area is initiated. 8. The method according to any one of claims 1 to 7, characterized in that the activated return sludge and the nitrified wastewater in at least a return sludge aeration area is initiated. 9. The method according to any one of claims 1 to 8, characterized in that the activated return sludge and the nitrified wastewater into at least one unventilated pool unit is recirculated. 10. The method according to any one of claims 1 to 9, characterized in that the sewage activated sludge mixture from the non-aerated to the ventilated Pelvic units in the lower part of the pelvic units is initiated. 11. The method according to any one of claims 1 to 10, characterized in that the sewage activated sludge mixture from the aerated to the non-aerated Pelvic units in the upper part of the pelvic units is initiated.   12. The method according to any one of claims 1 to 14, characterized in that the ventilation of the ventilated pool units is fine-bubble. 13. Apparatus for carrying out the method according to one of claims 1 to 12, with a plurality of separate pool units with square plan, each with at least two in the direction of circulation successive pelvic units are interconnected, characterized characterized in that at least one pool unit means for entry having pneumatic energy. 14. The apparatus according to claim 13, characterized in that as means for Entry of pneumatic energy fine bubble fumigation in the area serve the bottom of the pelvic units. 15. Device according to one of claims 13 and 14, characterized that several pool units form a group with at least one Denitrification, nitrification, clarification and return sludge aeration zone form, in which the recirculation takes place. 16. Device according to one of claims 13 to 15, characterized in that at least two groups succeed one another in the direction of circulation are arranged so that the recirculation of each group in the others take place. 17. Device according to one of claims 13 to 16, characterized that the pelvic units are arranged around a central pelvic unit, the serves as a pump sump. 18. The apparatus according to claim 17, characterized in that the central Pelvic unit serves as an anaerobic zone, in the activated sludge from a Denitrification zone and / or clarification zone is traceable. 19. Device according to one of the preceding claims, characterized characterized in that an inflow from an unvented to a ventilated one Pelvic unit over a arranged in the bottom region of the pelvic unit Inflow device takes place. 20. Device according to one of the preceding claims, characterized characterized in that an inflow from a ventilated to an unvented Pelvic unit over a arranged in the upper part of the pelvic units Inflow device takes place. 21. The apparatus according to claim 20, characterized in that the Inflow device is a raid threshold. 22. Device according to one of claims 13 to 21, characterized that the group can be expanded by adding further pool units.