CS240757B1 - Sewage biological activation treatment method with denitration in circulation system and equipment for performance of this method - Google Patents

Abstract

At least one local zone with intensive turbulence is provided, where particles of activated sludge are exposed to shearing forces which disintegrates said particles to release gaseous nitrogen which has penetrated into the structure of the particles in the course of denitrification. <IMAGE>

Description

Method for biological activation wastewater treatment with denitrification in a circulation system and apparatus for carrying out this method

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a biological activation wastewater treatment plant with denntrification in a circulating system and an apparatus for carrying out the method and is intended for the complete biological treatment of wastewater treated with both carbonaceous and nitrogenous substances. It is characterized in that at least one local area of intense turbulence is formed in the purification system in which the activated sludge particles are subjected to shear forces which disintegrate the particles.

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BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for the biological activation treatment of wastewater having a deficiency in a circulating system and an apparatus for carrying out the method. is intended especially for complex biological treatment of waste waters contaminated by both carbonaceous and nitrogenous substances. such as sewage, food industry waste water and zootechnical waste water.

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Methods for the removal of nitrogenous substances by biological activation purification are known. For activating nitrification and denitrification processes were developed two methods: one uses ... appliances for ^p ojenýoh. ^Star vs RII and Ruha ^d. oi-circulating system. in the latter case, a specific activated sludge is used in each apparatus, while a uniform activated sludge is used in the recirculation system.

Unified activated sludge in activation circulation systems_кWater purification with denitrification consists of heterotrophic and autotrophic species of microorganisms that are homogeneously distributed throughout the volume of the activation mixture. Heterotrophs grow and oxidize carbon^substances both nitrification and denit using dissolved oxygen in the activation mixture in n^andtr^ifikand^Czone^kywith^lík from nitrate^at in^den^itr^ifika^Cn^andzone. Auto-trophy grow only inside^ifand^toand^Cn^and zones^E and v^yat^žívaj^anddissolved oxygen from the activation mixture and inorganic carbon for ammonia nitrification.

The recirculation - uniform sludge system has the advantage of utilizing - organic substances in waste water as hydrogen donors for denitrification processes. This eliminates the need to add additional organic substances, as is the case with the method with serially connected separate apparatuses, and reduces them. energy requirements for supplying oxygen to the activation mixture. Raw water is therefore to be ^straight even in the events ^{ADETO t} ri ^fik and the ^No. of ^about NY.

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A well-known example of a circulating system with denitrification in a uniform activated sludge is an oxidation ditch under the conditions that both aeration creates both a dissolved oxygen zone in the activation mixture and a dissolved oxygen-free zone and feeds raw water into the denitrification zone perfect mixing with the activation mixture.

Furthermore, there are known devices where two separate tanks are included in the circulation system, one of which operates without oxygen supply and with raw water supply as denitrification and the other works as aerated activation with denitrification.

Circulation systems with denitrification, however, exhibit a significant deterioration of activated sludge properties compared to activation systems without denitrification. These systems produce light voluminous activated sludge, which results in a high sludge index value.

Thus e.g. when cleaning of food waste water from slaughterhouses containing about 150 ml g ^"1 nitrogenous substances expressed in values THR, the identified value of the sludge index in the circulation activating cleaning with denitrification about 150 ml g" \ against a value of 50 inl. g “* ^ when activating treatment of the same water without denitrification · The inclusion of denitrification in the circulation system also affects the properties of activated sludge in the treatment of other types of waste water with a lower content of nitrogenous substances, eg sewage. For example, sludge index values for oxidation ditches for municipal waters are normally above 100 ml.g ', and values close to 500 ml.g are no exception. \

The high sludge index has a negative effect on the operation of biological treatment plants in more ways. The main negative effect is manifested on the separation of activated sludge and its return to activation. An increase in the sludge index will be proportionally reflected in the reduction of the material surface load of the separation and hence the separation capacity.

Another negative effect results from the tendency of light activated sludge to flotation in the separation, which significantly reduces the separation efficiency. The high sludge index further limits the achievable limit of activated sludge concentration in the activation.

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The reduced separation efficiency and the low activated sludge concentration limit are then reflected in the low activated sludge concentration achieved in the activation. Because processes. nitrification / denitrification largely depends on the sludge age, large volumes of equipment must be used to achieve the required sludge index value at low activated sludge concentration. The large volumes of the equipment then have a negative effect on the high cost of the equipment and on the large exchange of heat with the environment, which is very unfavorable, especially in the winter, due to the significant dependence of nitrification / denitrification processes on temperature.

The overall effect of the high sludge index of activated sludge in denitrification circulating systems is to reduce the capacity of the plant at the bitter quality of the purified water, especially in value. suspended solids and secondarily also BOD ^ and COD values. This quantitative and qualitative deterioration in the operation of the plant is so great in some waste waters with a higher content of nitrogen substances and at higher temperatures of the activation mixture that it practically disables the function of circulation systems with denitrification. These are the explanations of the observed instability of the oxidation ditch function.

It is an object of the present invention to overcome these drawbacks. The essence of the process according to the invention is that it is in detergents. .

At least one localized area of intense turbulence is generated with an absorbed power of more than 300 watts per liter of liquid with activated sludge particles in which the activated sludge particles are subjected to shear forces which disintegrate the particles.

Another feature is that the pressure of the activation mixture entering or in part of the local area of intense turbulence is lower than the pressure in the local area of intense turbulence.

Another feature is that the action of the local area of intense turbulence is intermittent, respectively. fluctuating. According to the invention, it is also advantageous that the local area of intense turbulence is formed in the activation mixture flowing from denitrification to nitrification or from nitrification to denitrification, respectively. that the local area of intense turbulence in the activation mixture flowing from denitrification to nitrification is supplied with air.

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Also preferred is a process according to the invention wherein the local area of intense turbulence acts in the perimeter of activated sludge from its separation system, or wherein the local area of intensive turbulence acts in the activation mixture pumped from the fluid filtration separation system below the fluid filter to denitrification or nitrification.

Another possible feature is that during the local area of intense turbulence, the inflow of raw water is reduced or interrupted.

The principle of the device according to the invention consists in that the source of the local area of intense turbulence is formed by a nozzle, connected to a cyclone arranged above the level of the aerated activation space and connected to the discharge of the pump connected to the lower part of the denitrification space. connected to the aerated activation space by a return pipe into which the raw water inlet is connected.

Another device for carrying out the method according to the invention consists in that the source of the local area of intense turbulence is formed by a stirrer connected to the discharge of the pump, the collection of which is connected to the lower part of the denitrification space.

The principle of another device for carrying out the method according to the invention consists in that the source of the local area of intense turbulence is formed by a nozzle connected both to a pump, which is withdrawn from the orifice into the denitrification space and to the air distribution pipe. or that the source of the local area of intense turbulence is arranged in a connecting shaft for discharging the activated sludge from the separator into the aerated activation space.

Examples of apparatus for carrying out the method according to the invention are schematically shown in the accompanying drawings, in which Fig. 1 shows a device for activating waste water treatment with denitrification in a circulating system for food waste water in vertical axial section. Fig. 1 shows a cross-sectional view of another embodiment of a source of intense turbulence working mechanically;

5 240 757 is a vertical cross-section, FIG. 5 is a plan view of a device for the treatment of large volumes of less polluted wastewater, eg co-munal, and FIG. 6 shows a detail of an intensive turbo source in a leno combined with aeration device particularly suitable for the device shown; 4 and 5.

The apparatus of FIGS. 1 to 3 is particularly suited for the treatment of moderately polluted waste water of smaller capacity, such as food waste water. The apparatus consists of two cylindrical tanks with a vertical axis, the tank with jacket 1 serving for aerated activation space 2, also called nitrification, and tank with jacket 3 for denitrification space 11, also called denitrification. The aerated activation space 3 and the denitrification space 4 are interconnected into the circulation circuit by withdrawal 5 from the bottom of the denitrification space 4 by a pump 6, with a discharge 7 terminated. via a nozzle 8 opening into a cyclone J located above the surface of the tank and the casing J. and then a return line 20 which connects the aerated activation space 2 with the upper part of the denitrification space 4 The raw water supply 11 flows into the return line 10. The return line 10 is directed to the denitrification space 4 horizontally, under a small angle. to the wall 2, the denitrification chamber 4 is provided with a conical bottom 12 in its lower part. Instead of the nozzle 8 and the cyclone 9, another solution, shown in Fig. 3, consisting of two rotors 13 may be used. A known aeration device consisting of aeration elements 15, a manifold 16a of a blower (not shown), is incorporated in the aerated activation space in the pl.

In the upper part of the aerated activation space 2 there is a activated sludge separation system, e.g. a separator 27 formed by a conical partition wall 18 which passes into a connecting shaft 19, which opens into the lower part of the aerated activation prostoary. The separator 17 is provided with bypasses. 20th canals that are connected at the top with an aerated activating space 2 holes - 21 and the bottom of the outcome .22 »which opens into the bottom д * <· ^part. of the separator 17, the marine portion of the separator ¹⁷ is positioned ^to engrave

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23. covering the entire surface of the fluid filter. with the level 24 in the separator 17 with the level 25 of the purified water which is fixed by the collecting trough 2a in the outlet 27 of the purified water. 2 °) of activated sludge from the fluid filter is placed. Both withdrawals 28. 29 are led to the expansion tank 30 with the outlet 31. sludge ·

The apparatus described in FIGS. 1 to 3 operates as follows:

The raw water flows through the inlet 11 into the return line W, where it mixes with the activation mixture and flows into the denitrification space 4. This provides the necessary excess of carbonaceous substances for denitrification in the denitrification space 4. Carbon dioxide resulting from oxidation of organic substances in both denitrification space. in aerated activation space: ioi_2, serves. then as the main source of inorganic carbon for nitrification of ammonia in the activation space.

^C to ^T, and iv ^{kt N NU} mixtures aerovaráho asset whom you ^ Ostor ^No. 2 passes through the overflow apertures 21 and channels 20 of outlets 22 in the bottom portion of the separator 17th

In this separator, the activated sludge is separated in the fluid filter from the treated water, which is taken from the separator via a collecting trough 26 and drained through the drain 27. The activated sludge separated in the separator 17 from the purified water is returned via the shaft 19 to the aerated activation space.

The aerated activation space 2 and the denitrification space 14, which are interconnected, form a circulation system for activating purification water with denitrification. This system of activation water purification works with a uniform activated sludge consisting of a mixture of hetertrophic and autotrophic species of microorganisms. He0er10rops oxidize carbonaceous substances as in the aerated activation space. 2 as well as in the denitrification space 4, whereby for their life processes oxygen in the activation mixture utilizes a vaporized activation space 2a nitrate oxygen in the denitrification space 4.

Autotoorfy grow ^p nitzlfitaění nly in the zone and to use oxygen dissolved in the activation mixture and inorganic carbon for nitrification of ammonia · This nitrogenous substances from waste water of the oxidation 7,240,757 accumulate into the aerated activation area at 2 'nitrates, in the denitrification zone is reduced to nitrogen gas and thus are removed from the treated water.

The formation of gas takes place mainly on the surface of activated sludge particles, but partly also in the structure of these particles. The resulting nitrogen bubbles, which are on the surface of the activated sludge particles, are mostly released by turbolization as the activation mixture moves in the denitrification space 4 and the aeration space 2 and thus enter the free atmosphere. However, the intensity of this turbulence is not sufficient to release the nitrogen gas bubbles adhered to or incorporated into the activated sludge structure. therefore, these bubbles accumulate in the activated sludge without any additional means and gradually deteriorate its properties.

To remove this portion relatively strongly bound nitrogen is in čisHcím ^Y ST ^E had created ESPO and ^{L N} is ^d at the pubs intensive turbulence zone in which activated sludge treated na'částice shearing "forces which these particles disturb - disintegrate. and they release nitrogen gas that has grown through the structure of these particles during nitrification. To achieve this, it is necessary to induce turbulence with an intensity exceeding 300 Wl *, normally up to 1000 Wl * or more, as required by the degree of nitrogen gas removal from the activated sludge.

An essential feature is that said shear action takes place at a certain limited location through which the activated sludge liquid passes. This location may be at any point in the circulation circuit between the aerated activation space 2 and the denitrification space 4 and situated such that it passes through all or part of the circulation stream. It is equally possible to locate a local area of intense turbulence, i.e., shear forces in the discharge of activated sludge from the separation, e.g., sludge separated in separator 17, or an extra circulation branch between the top of the fluid filter and the aerated active space 12, or denitrification. space -4, respectively. directly in the nitrification or denitrification area.

Because the ingrowth of activated sludge by micro-bubbles of nitrogen 8 240 7S7 ku is a longer-term process, shearing forces can be applied intermittently for a time sufficient to transfer the entire activated sludge stock through a place of intense turbulence.

At higher activated sludge concentrations, it is preferable to include a local area of intense turbulence, t, j, instead of shear forces in the connection of the aerated activation space 2 and the denitrification space 4.

In a plant where a higher concentration of activated sludge cannot be achieved, especially in the case of older plants, it is advantageous to apply shear forces to the activated sludge taken from the separation space.

Increase. the energy consumption of well-designed denitrification circulation system with shear forces applied to the activated sludge exceeds 15-30%. This energy is sufficient to completely remove nitrogen gas particles from the activated sludge, resulting in a sludge index value practically equal to that of Activation wastewater treatment without denitrification, for example, in the treatment of slaughterhouse waste water, when the inclusion of denitrification increased the sludge index from about 50 _{-1 -1} ml.g to 150-180 ml.g, after the application of shear forces with a turbulence intensity of about 1000 W, l ¹ achieved a reduction to about ⁵⁰ ml ^{, g} " ¹ .

The intensity of the turbulence is decisive for achieving the desired effect. The technical solution of the place where this turbulence is produced can be implemented in various ways. One possibility is shown in Figs. 1 and 2, where the energy for turbulence is supplied by a centrifugal pump 6 with an additional discharge height and the turbulence is created by a nozzle leading to the cyclone, i.e. in combination with this cyclone 9. to the free liquid level, where the separation of nitrogen bubbles due to shear forces occurs at atmospheric pressure and underpressure in the pump suction and in the nozzle, which expands the nitrogen bubbles to aid in their release. mechanical mixing with two or more counter rotating rotors Ό, .14, or a combination of rotors and stators in a suitable chamber. An example of this solution is shown in Fig. 3,

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Because in terms of cost is the energy needed to create^ŘMeasurement of turbulence. while ^ z^hice^andwith^toand the results are roz fitting intensity of turbulence is appropriate. apply turbulence in such a way that the intensity of the energy consumption is as high as possible - or that the required turbulence intensity is achieved with the least possible energy consumption. This can generally be achieved by dissipating energy in as little volume as possible. For example, the same intensity of turbulence with less energy consumption can be achieved by using several smaller nozzles instead of one larger nozzle. .

The method and apparatus according to the invention are not limited to the described apparatus shown in Figs. 1 to 3. The circulation circuit can, for example, be designed such that a turbulence-inducing device, e.g. a nozzle 1, is at the pump discharge 7 which runs tangentially into the lower part. denitrification chamber 4, wherein the pump 5 draw-off 5 is discharged from the aerated activation space 2 of the conduit 10 then: it connects the upper parts of the spaces 2.a_4. In this case, the raw water inlet 11 is connected to the nozzle 8.

The apparatus for carrying out the method according to the invention can further be solved, for example, in that the local area of intense turbulence is situated in the outlet of activated sludge separated in the separator 17, ie in the connecting shaft 19. It is also possible to place the source of intense turbulence in a separate circulation branch. has an activated sludge withdrawal 29 in the upper part of the separator 17 below the level of the fluid filter 24 and which either flows into the denitrification space 6 or into the aerated activation space 2,

In this case, it may be advantageous to operate the recirculation branch intermittently and to perform this operation during periods of reduced or even intermittent inflow of raw water into the plant so that the hydraulic separation load is not disproportionately increased during operation of the branch. *

It will further be appreciated that the application of the present invention is not limited to the separator 17 of FIG. 1, but is applicable to any separator when a source of intense turbulence is included to remove the returned sludge from the separator or to any fluid filtration separator. If an intense source of turbulence is applied in the above-described special circulation branch.

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The exemplary device shown in FIGS. ⁴ to 6 is intended, in particular, for the activation treatment of large volumes of less polluted water, eg municipal waste water.

In a single shell tank, the walls 34 and 35 divide the volume of the shell into longitudinally arranged functional spaces, namely an aeration-activation space 2, a denitrification space 4 and a separator 17 in the upper part. At both ends, the adjacent spaces and the aerated activation space are interconnected via passages 36 and 37. The separators 17 communicate with the aerated activation space 2, the overflow channel 20.

The aerated activating space 2 is present a combined apparatus for forming a local zone of intense turbulence with simultaneous ^ ovzdutnování and ^KTI va ^{N NU} mixture ^of a ^p ro ^p Risun acid ^divided to into the aerated activating space 2, this is shown in detail in FIG. 5 and consists of a nozzle 8 connected to the pump 6 by a discharge 7. The pump 5 draws off into the denitrification space 4. The nozzle 8 is provided with an air distribution pipe 16 from the blower 38. The air supply may be non-pressurized when the nozzle 8 is formed as a known ejector with atmospheric air suction. Nozzle 8. is located in the ejector 41.

The raw water inlet 11 is fed to a manifold 39 from which the raw water is fed through the partial inlets 40 before the denitrification chamber 4. The fluid filter separator 17 has a fluid filter level 24 and a purified water level 25 with collecting troughs 26. It is equipped with a cover 23 and 28, carried out by sampling the slurry with -ex ^p anzní reservoir 3 ° and odvo ^d em-3 sludge. ^ ^^ era is for n ^b ud back into the aerated activation space .2, or taken out of the system. The lower part of the separator 17. is connected via an overflow channel 20 to the aerated activation space 10.

The apparatus shown in Figures 4 to 6 operates as follows!

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The pump 6 pumps the activation mixture by taking 5 from the denitrification chamber 4 and blows it through the nozzle 8 into the ejector 41. At the same time, the air supplied through the distribution line 16 is added to this mixture.

The activation mixture stream with air flows from the ejector 41 into the aerated activation space2 thereby. oxygen is introduced into the aerated activation space 2, and at the same time the activation mixture is circulated between adjacent longitudinal

240,757 functional spaces formed by interposed walls. 34 and 35. In the aerated activation space 2, the oxygen introduced is consumed by microorganisms to oxidize the organic substances and ammonia present. This reduces its concentration during the flow of the activation mixture through the 'aerated activation' space 2. In the region where the oxygen concentration is already low enough, the feed mixture stream is a partial feed. 4. Raw water is fed and mixed into the entire activation mixture stream.

With an excess of organic matter, the microorganisms rapidly consume the rest of the oxygen, thereby creating a space in the other part of the activation mixture stream without the presence of dissolved oxygen, which functions as a diaphragm space. 4.

Nitrates formed in the activation mixture by oxidation of ammonia and nitrogen-containing organic matter in the aerated activation space 2 are reduced to nitrogen gas by heterotrophic microorganisms in the absence of oxygen and excess organic matter from the raw water in denitrification space 4.

The remaining organic substances from the raw water, which are not consumed, are then transferred from the denitrification space to the aerated activation space, where they are oxidized by the stream of the activation mixture.

Part of ^the VA and ^{N NU} mixtures ^monthly. from him and aerated ^é ^ dačního chamber ² passes through the overflow channel. 20 to a separator 17 where the activated sludge is separated from the purified water.

Purified voda'je discharged from separator 17 collecting trough 26 while separovaný.aktivovaný sludge sinks back into přepourtěoího channel 20 and the lower part of this channel sevrací back into the aerated activation space .2 ^ply nn ^eh portion of nitrogen ^at vzMkrajíího's ^{T d} r ^ifik ac ^i, se. precipitates on the surface of the activated sludge particles in the form of bubbles, similar to that already described in the apparatus of FIGS. 3. These bubbles are liberated ^{even when 'p} turbulent oh ^y bu. activation mixtures, in aerated activation space 2.

However, another part of the resulting nitrogen gas is excreted within the activated sludge particles in the form of microbubbles that grow through the structure of the particles, as already described in the embodiment of Figure 1. The accumulation of these microbubbles would increase the sludge index value and The microbubbles can be released and removed from the activated sludge only by sufficiently intense turbulence which, as already mentioned, exposes the activated sludge particles to shear and releases these microbubbles. For this purpose, a stream of water emerging from the nozzle 8 serves as a source of the local area of intense turbulence. This stream flows so rapidly that it creates on the periphery a high-cone turbulence space, which then extends throughout the conical widening liquid stream. The turbulence intensity at the nozzle orifice below &lt; 1 is substantially above 1000 W, which is already sufficient to achieve the described effect.

Because the process of activated sludge ingrowing with nitrogen micro-bubbles takes a long time, it is not necessary to apply intense turbulence to the activated sludge at each rotation of the activation mixture in the circulation circuit when treating less polluted effluents such as municipal sewage through the site of intense turbulence. This results in substantial energy savings with sufficient control of the activated sludge property.

The energy efficiency of the described process greatly depends on the concentration of activated sludge in the activation mixture. Therefore, the use of the described method of applying intense turbulence is economically feasible, particularly in the case of high activated sludge concentration. This is achieved in integrated plants with the incorporation of a very effective separation with the return of the activated sludge back into the activation process. For this purpose, separators 17 formed by the interposed walls 34 and 35 in the upper part of the tank are used practically over the entire surface area of the device. High - performance separation by fluid filtration in

and, together with a large separation surface, it allows the operation of the plant with a high concentration of activated sludge, allowing a reduction

The 'energy to remove nitrogen applications intense turbulence at an acceptable economic rate of energy consumption by ¹⁵ - ^30% vyssši than ^p ro ^ Iastní provztošňování assets ^No N s směsdL. E ^F ek: ^fik tes t denitri per ^Currently con ^t rol ^y -kalového index provides such improved quality of treated water - and - only in the content. nitrogenous substances, as well as carbonaceous substances - that increase the zdůvod13 spo ^class Eby energto the above ^e mnototví. ⁽⁵⁷⁾

The described device in Figures 4 to 6 thus allows the use of denitrification even for large volumes of less polluted waste water economically. This is important where higher quality of purified water is needed, eg in the protection of stagnant water from eutrophication. Likewise, the high quality of purified water opens up new possibilities for the solution of waste-free technologies with closed circuits and water circuits.

The method of the invention is not limited to the exemplary apparatus described. In older types of equipment where the required high concentration of activated sludge cannot be achieved, eg in activation ditches, shear forces can be applied to the thickened sludge returning from separation to activation.

Likewise, the device described in Figures 4 to 6 need not have a source v and the aeration device can be solved separately.

The method and apparatus of the invention have numerous advantages. One of the important advantages of denitrification activating purification methods with a circulation system is its general applicability. The process according to the invention can be applied for the treatment of low-contaminated waste water, such as sewage, moderately contaminated eg food waste water, as well as heavily contaminated, such as liquid excrements of farm animals.

For all these types of water, the process according to the invention represents an economic way of intensifying the purification, which not only results in a reduction in the nitrogen content but also in other pollution parameters such as suspended solids and organic substances, expressed in BOD and COD values.

Achieving a higher quality of the treated water opens the way for wasteless technology of reuse of purified 'water in the closed ^row enýc ^{s h} o u r ^{k L} and ^C n ^Ch species. ^What enables the achievement ^f measurement saving and environmental protection.

In addition to these qualitative advantages, the use of the method according to the invention brings preconditions for achieving significant cost savings. This qualitative and quantitative effect is due to a significant decrease in the sludge index of activated sludge in the denitrification circulation system. E.g. for certain food waste waters, such as the waste water from the meat industry,

- 14..240 757 a reduction of the sludge index value to 1/2 to 1/3 of the value that would be achieved without using the method according to the invention can be achieved,

Said improved sludge properties achieve generally improved process parameters. The reduced sludge index improves the separability of the activated sludge that is manifested. by increasing the material surface load of the separation and thus the possibility of achieving a higher concentration of activated sludge in the activation, which is a significant intensifying factor in the whole range of the activation treatment process, especially nitrification and denitrification, which is directly dependent on the sludge age;

The resultant effect is the possibility of significantly reducing the volume of the activation device against the denitrification device without applying the method of the invention.

Reducing the dimensions of the device will favorably not only in cost device, but also in reducing dependence devices atmospheric effects, reducing the heat transfer, in high dependency of nitrification and denitrification processes on temperature - increased ^width measurement ^t e ^p ture of ¹⁰ ° C, ^BC represents zrychlerá these ^p ocho ^Importan by about 100% - size reduction device brings considerable savings, especially in winter, while increasing the cleaning efficiency

By decreasing the value of the sludge index the tendency of sludge to flotation decreases significantly, manifesting itself in undesirable leakage of suspended solids into the purified water. The result is a significant improvement of separation efficiency, which enables to reduce the size of the separation system and improve the quality of treated water. ,

Claims (12)

SUBJECT OF THE INVENTION 240 757 1. A method of biological activation wastewater treatment, with nitrification and denitrification in a circulation system connected to an activated sludge separation system, characterized in that, in the purification process, it is purified by means of a sewage treatment plant. At least one localized area of intense turbulence is created with the absorbed power of more than 300 watts per liter of liquid with activated sludge particles, in which the activated sludge particles are subjected to shear forces that disintegrate the particles. 2. A method according to claim 1, wherein the pressure of the activation mixture entering or part of the local area of intense turbulence is lower than the pressure of the local area of intense turbulence. 3. Method according to claim 1, characterized in that the action of the local area of intense turbulence is intermittent or fluctuating. 4. The method of claim 1 wherein the local area of intense turbulence is formed in the activation mixture flowing from denitrification or nitrification to denitrification. 5. A method according to claim 4, characterized in that air is supplied to the local area of intense turbulence in the activation mixture flowing from denitrification to nitrification. 6. The method of claim 1, wherein the local area of intense turbulence acts to remove activated sludge from the sludge separation system. 7. The method of claim 1, wherein the local area of intense turbulence acts in the activation mixture pumped from the fluid filtration separation system below the fluid filter to denitrification or nitrification. 240 7S7 8. The method of claims 1, 3 and 7, characterized in that the inflow of raw water is reduced or interrupted during the application of a local area of intense turbulence. У. Device for carrying out the method according to claim 1, characterized in that the source of the local area of intense turbulence is formed by a nozzle (8) opening into a cyclone (8). 9) arranged above the level of the aerated activation space (2) and connected to the discharge (7) of the pump (6), the sampling of which is connected to the lower part of the denitrification space (4), the upper part of which is connected to the aerated activation space (2) (10) into which the raw water supply (11) is connected. Device for carrying out the method according to claim 1, characterized in that the source of the local area of intense turbulence is formed by a stirrer (13, 14) connected to the discharge (7) of the pump (6), the collection of which is connected to the lower part of the denitrification space (4). . Apparatus for carrying out the method according to claim 1, characterized in that the source of the local area of intense turbulence is formed by a nozzle (8) connected both to a pump (6), the discharge of which is connected to the denitrification space (4) and 16) of air, the nozzle (6) being arranged directly in the aerated activation space (2). Device for carrying out the method according to claim 6, characterized in that the source of the local area of intense turbulence is arranged in the connection shaft (19) for the discharge of activated sludge from the separator (17) to the aerated activation space (2).