DE19533370C2 - Process and plant for the biological mineralization of sludge in standing and flowing waters - Google Patents

Description

The invention relates to a method for biological mineralization richer in nutrients Sludge deposits in standing and flowing waters as well as a system for Execution of the procedure.

As a result of decades of over-fertilization of the waters by the most varied The causes are enormous nutrient-rich sludge deposits in the water accumulated.

Due to the annual cycle and the non-eliminated nutrients in the water, large amounts of algae form. During and after the death of these algae in the The mineralization can use up the dissolved oxygen during the annual cycle that the overturning of the water becomes inevitable. Especially the one below Redissolution of phosphate in the water enables the formation of new algae, so that the Cycle begins again. By binding or eliminating the released nutrients to interrupt the cycle described in order to achieve the required water quality for flora and Preserve or restore fauna in the water.

The possibility of reducing the nutrients from the sludge deposits simultaneous reduction of nutrients from the body of water, using the existing microorganisms for the aerobic degradation processes is an advantage.

A device and method according to DE 39 26 829 is known which comprises a capsule with e.g. B. Lime is used to kill the algae. The disadvantage here is the poor control by Residues.

Night DE 25 22 868 becomes pneumatic / hydraulic sludge to keep fairways clear Ships are pumped out. For still waters, this device is included because of the turbulence not suitable for the described process.

OS 36 20 700 provides for the collection of gravel, sand, stones, wood, etc., which in the Mud is hidden, picked up and separated. The process is complex and therefore expensive and questionable to use.

DE 39 23 113 presents a mechanical sludge removal that is complicated and appears to be energy consuming.

DE 37 24 629 a method with device is presented, which by Oxygenation in the body of water, the aerobic mineralization processes and To promote phosphate degradation. The disadvantage is that sediments are disregarded. The covering with gas-permeable film, as described in DE 40 02 090, appears in view of areas over several ha questionable, especially the sealing on the drains  other. Intended sealing with sediments has the consequence that this is due to penetrate into the mud at their higher density.

The procedure shown in DE 41 24 779, to initiate a denim trification, implies the breakdown of carbon-containing compounds in the sludge and the Um conversion of ammonium nitrogen to nitrite or nitrate in advance. The necessary for this Microorganisms must have a certain sludge age in order to form nitrate can. According to the illustration, this is not the case in the punctual procedure described possible. It is to be feared that the disadvantages critically assessed in other methods also occur here.

The object of the invention is always for the annual development cycle of algae available nutrients from the sludge deposits, but also from the body of water, via aerobic nutrient degradation, nitrification and denitrification and to withdraw the binding of free phosphate from the circulation. These are then one uncontrollable algae growth is no longer available.

According to the invention the object is achieved in that laminar oxygen-rich water 10 is introduced from the surface of the water into the nutrient-rich sludge deposits 3 via a flexible pipe system which is located in the nutrient-rich sludge deposits. As a result of the difference in density (temperature and oxygen) of the water introduced, the specifically lighter water gently rises through the sludge deposits 3 above. The mineralization of the sludge deposits takes place through the oxygen depletion of aerobic microorganisms. In addition to the formation of new aerobes, these are also introduced into the sludge deposit by introducing the oxygen-rich water 10 . This process is supported by the simultaneous introduction of thermal energy of the specifically warmer surface water 10 of the body of water. After the carbon compounds contained in the biological active region 37 have been broken down, the nitrogen present in the form of NH ₄ -N can be nitrified to NO ₃ -. Due to the further buoyancy of the specifically lighter but low-oxygen water, the microorganisms developing in this area switch to nitrate breathing, with existing carbon being consumed in this area. The resulting elementary nitrogen (denitrification) escapes into the atmosphere and is no longer available to the nutrient cycle. The phosphate required for the biomass build-up is removed from the water body 2 when the biomass is formed and is therefore no longer available for the further formation of algae. After mineralization of the sludge deposits 3 , a redissolving of phosphate is hardly possible. The mineralization results in a volume contraction of the sludge deposits 3 in the biological effective area 37 with the result of trough formation. Further sludge deposits 3 can follow into these depressions.

In the case of shallower water 2 or sludge deposits 3 , the supply of oxygen-rich water 10 must be temporarily interrupted. If in the nearer surroundings of the metering lines 16 there are no longer sufficient carbon compounds available, then oxygen water 19 is temporarily introduced in order to enable denitrification by converting the microorganisms to nitrate breathing. The proportion of carbon required for this is entered with the oxygen-poor water 19 . This process must be carried out in alternation, so that the sequence described also leads to simultaneous dismantling processes.

The end of the process chain is the dosing of lime milk in excess Binding of free phosphate or to avoid possible redissolutions the mineralized mud.

With a constant change of the processes described, the lime milk addition also improves the acid capacity of the water and has a positive influence on nitrification. This process must be repeated until the majority of the sludge deposits 3 is mineralized.

The invention is explained in more detail below in an exemplary embodiment. In the associated figures are shown:

Fig. 1: System according to the invention in longitudinal section

Fig. 2: Plant according to the invention in plan view

Fig. 3: Basic representation of the process flow

The described method is Sieren with the embodiment shown in Figs. 1 and 2 plant to reali. For this purpose, surface water can be enriched with oxygen if necessary with additional aeration 9 , which is to be installed in a fixed or floating manner. The oxygen-rich no / low water / 10 19 initiated first by flexible supply lines 15 and finally 16 in metering the slurry 3 through a pumping station 12th The depth of the metering lines 16 in the sludge 3 is dependent on the thickness of the sludge deposits 3 and can be adjusted via a rope 21 located on the metering line 16 and attached to a buoy 13 at the other end. The metering line 16 should generally be set as deep as possible in the sludge 3 . The change from oxygen-rich water 10 to oxygen-poor water 19 takes place via the adjusting flap 26 , in which the oxygen-deficient water 19 is sucked in via the suction pipe 25 . Lime milk is added to the water via a metering station 8 .

If a partial area of the nutrient-rich sludge deposits 3 is mineralized in the biological effective area 37, the mineralization process can be continued at another point in the water by laying the metering line 16 until the nutrient-rich sludge deposits 3 have largely been broken down into aerobically stabilized sludge 32 .

Reference list

1

Water surface

2nd

Body of water

3rd

Nutrient-rich sludge deposits

4th

Body of water

5

shore

6

Muddy water / mud-water contact zone

7

Water inlet

8th

Lime milk dosing station

9

Additional ventilation

10th

Oxygenated water

11

Electrical supply

12th

Pump station

13

buoy

14

pump

15

Flexible supply line

16

Dosing line

17th

Dosing holes

18th

Inert growth carrier

19th

Low oxygen water

20th

Rope for tensile stress

21

Rope for depth adjustment

22

Transition piece

23

Bracket

24th

pontoon

25th

Intake manifold

26

Butterfly valve

31

Reduced sludge deposits / trough formation

32

Stabilized mud

33

Edge area

34

Area of denitrification

35

Area of nitrification

36

Aerobic recovery area

37

Biological scope

38

Measurement, control and regulation technology

Claims (15)

1. A method for the biological mineralization of nutrient-rich sludge deposits in standing and flowing waters, characterized in that

• 1. The oxygen-rich / low-oxygen water ( 10 ) / ( 19 ) required for biological mineralization flows through the metering lines ( 16 ) positioned in the nutrient-rich sludge deposits ( 3 ) and in the biological effective range ( 37 ) via the metering holes ( 17 ) from the inert Escaping growth carrier ( 18 ) escaping, the nutrient-rich sludge deposits ( 3 ) penetrating in the direction of the body of water ( 2 ) without extensive, laminar,
• 2. Mostly the oxygen naturally introduced from the water surface ( 1 ) is used,
• 3. the introduction of the oxygen-rich / low-water ( 10 ) / ( 19 ) takes place over the full length of the metering lines ( 16 ),
• 4. the specifically larger amount of heat of the introduced oxygen-rich / low-water ( 10 ) / ( 19 ) promotes the activity of the microorganisms located in the nutrient-rich sludge deposits ( 3 ),
• 5. the supply of the microorganisms with oxygen-rich / poor water ( 10 ) / ( 19 ) the specific low density of the water supplied is used,
• 6. an additional ventilation ( 9 ) and / or technical oxygen is used only when needed.

2. The method according to claim 1, characterized in that the plant nutrients and microorganisms originating from the water surface ( 1 ) and located in the oxygen-rich water ( 10 ) settle there by the shift into the biological activity range ( 37 ) and in the process of aerobic mineralization be included. 3. The method according to claim 1 and 2, characterized in that with the introduction of oxygen-rich water ( 10 ) in the biological range of action ( 37 ) under oxygen depletion mineralization by aerobic microorganisms begins and continues in the area above as nitrification. 4. The method according to claim 1 to 3, characterized in that after the dissolution of the dissolved oxygen by nitrifying in the biological range ( 37 ), the reduction of the nitrate (denitrification) takes place simultaneously and the elemental nitrogen released thereby escapes via the surface of the water ( 1 ) and is no longer accessible to plants as a nutrient. 5. The method according to claim 1 to 3, characterized in that the available free phosphate in the area of aerobic utilization ( 36 ) mainly for the biomass build-up of the microorganisms and the unusable part of the free phosphate bound by suitable precipitants in excess after appropriate dosage becomes. 6. The method according to claim 1 to 5, characterized in that the phosphate precipitation products are retained inaccessible to light and plants by the filterability of the stabilized sludge deposits ( 32 ) in the biological range of action ( 37 ). 7. The method according to claim 1, characterized in that with the coordinated supply of the introduced oxygen-rich / poor and specifically warmer water ( 10 ) / ( 19 ) in the biological range of action ( 37 ) the smooth, laminar buoyancy is ensured. 8. The method according to claim 1, characterized in that the introduction of the acid-rich water ( 10 ) into the biological activity range ( 37 ) after evaluation of measurements via a suitable control takes place without interruption or is temporarily interrupted. 9. The method according to claim 1, characterized in that the introduction of the acid-rich / low-water ( 10 ) / ( 19 ) into the biological activity range ( 37 ) after evaluation of measurements via a suitable control alternately. 10. The method according to claim 1, characterized in that oxygen-poor water ( 19 ) is removed from the deeper layers of the body of water ( 2 ). 11. The method according to claim 1 to 10, characterized in that as a result of the mineralization in the area of biological activity ( 37 ) along the metering lines ( 16 ) a trough ( 31 ) is formed, in which the mud-like water ( 6 ) collects and at the same time is mineralized. 12. The method according to claim 1 to 11, characterized in that after successful mineralization of the nutrient-rich sludge deposits ( 3 ) to an aerobically stabilized sludge ( 32 ) and the binding of the still free phosphate in the biological range of action ( 37 ) relocated the metering lines ( 16 ) in order to continue mineralization in a further biological sphere of activity ( 37 ). 13. System for carrying out the method according to claim 1 to 12, which for its compactness and buoyancy consists of pontoons and has anchoring options, in your structure has chambers and devices for additional oxygenation and the metering of precipitants and with a measuring, control - And control technology for checking and controlling the method is equipped, characterized in that

• 1. Pump stations ( 12 ) are integrated, because there is a pump ( 14 ) with a pipe connection for the flexible supply line ( 15 ),
• 2. after the transition piece ( 22 ) with the clamp ( 23 ) the metering line ( 16 ) begins,
• 3. the metering bores ( 17 ) are machined on the underside of the metering lines ( 16 ),
• 4. the distribution of the delivered amount of water ( 10 ) / ( 19 ) via the metering holes ( 17 ) is realized,
• 5. the number and size of the metering holes ( 17 ) depends on the length of the metering line ( 16 ) and the amount of water ( 10 ) / ( 19 ) delivered.

14. Plant according to claim 1 to 13, characterized in that the metering lines ( 16 ) are wrapped with an inert growth carrier ( 18 ) for microorganisms. 15. Plant according to claim 1 to 14, characterized in that the metering lines ( 16 ) by means of buoys ( 13 ) and the ropes for depth adjustment ( 21 ) in the biological range of action ( 37 ) are adjustable.