HU222839B1 - Method and apparatous for treating of waste water - Google Patents

Abstract

The subject of the invention is a process for biological wastewater treatment, especially for wastewaters with a low organic carbon content in terms of total nitrogen, in such a way that after the wastewater has been subjected to pre-denitrification, it is aerated and then recirculated in the treated water part and returned to the pre-denitrification, while the remaining part is treated with another denitrification (post-denitrification), and post-aeration is carried out before being sent to the post-settler. The process of the invention is characterized by the fact that, after subaeration, but before recirculation, the treated waste water is passed through an oxygen-poor, ideally oxygen-free zone (adaptation zone), while the microflora of the system is set to nitrate consumption. A further method of the invention is characterized by the fact that the adenitrification and/or adaptation steps are carried out in a closed system that limits the ingress of air (oxygen). According to the invention, the device consisting of one or more pre-denitrification reactors (3), aeration reactor(s) (4), and post-denitrification reactor(s) (6) and equipped with a recirculation line (7) is characterized by the fact that aeration reactors (4) and post-denitrification reactors (6) an intermediate adaptation reactor (5) is included, or the closing section of the last aeration reactor (4) is converted into an anaerobic zone and serves as an adaptation reactor, and the starting point of the recirculation line (7) is in the adaptation reactor (5) or the adaptation zone and the post-denitrification reactor(s) (6) ) is between ŕ

Description

BACKGROUND OF THE INVENTION The present invention relates to a biological wastewater treatment process and apparatus, particularly for treating wastewater with a low organic carbon content based on total nitrogen, wherein the process comprises pre-and post-denitrification steps which are interrupted by an aeration process step and again by an aeration step.

New tasks have arisen in wastewater treatment. As water sources become narrower, service providers continue to increase their water charges, reducing the amount of water discharged into the sewer system, thereby increasing the time it takes for sewage to reach the treatment plant, but at the same time increasing the total nitrogen concentration in the wastewater. On the other hand, the sewers are connected to the sewerage network from an increasingly large area. The organic carbon content of wastewater is decomposed by the presence of oxygen or anaerobic processes in the longest channel sections and with increasing residence times, but the total nitrogen content remains virtually unchanged, and therefore the amount of nitrate formed by nitrification of ammonia is only b and can be reduced to a value that meets strict standards by a costly process. The known processes employ pre- and / or post-denitrification in combination with the aeration process, which usually requires one aeration. [Barnard, J.L .: Biological Denitrification, J. of Intem. Wat. Poli. Contr Fed. 6, 1973]. In order to be sufficiently effective in pre-nitrification, most of the water needs to be recycled because the nitrate to be denitrified to be converted to nitrogen gas by the organic carbon source is formed from the ammonia content of the waste water in the aeration step. [Sedlak, R.I .: Phosphorus and Nitrogen Removal, written by Municipal Wastewater; Principles and Practice ”II. edit. Lewis Publ. Michigan (1991)]. Alternative carbon sources such as methyl alcohol are also commonly used in the subsequent denitrification. The solutions known from scientific publications are used in a number of practical solutions. EP 509609 discloses a combined nitrification and denitrification system wherein intensive aeration with additional carbon source addition is used in the nitrification step. Recirculation from the denitrification unit is used and from the nitrification unit the treated waste water passes through a phase separator to a second denitrification unit. From here the wastewater that has already been treated will be drained off. DE 3933326 relates to combined phosphorus and nitrogen removal. Organic acids liberated during anaerobic treatment of raw water are added as an additional carbon source during the denitrification phase. DE 4407773 also relates to a combined process of nitrification and denitrification, in which the aerobic and anaerobic treatment stages follow one another. In the aerobic section air blowing is used, in the anaerobic section propeller blending is used. Recirculation starts from an anaerobic settler, but the fluid is moved by pneumatic energy (air).

A common feature of the known nitrification and denitrification processes is that the nitrified water-activated sludge mixture is recirculated at the end of the aeration, i.e. recirculation from the aeration reactor. The original bioavailable carbon content of the wastewater is thus consumed by the subsequent denitrification. The rate of nitrate consumption by so-called endogenous processes is low, and this is compensated by the addition of an external source of so-called replacement carbon. Such solutions have a constant carbonde deficiency due to the rapid decomposition of organic carbon. As a result, the residence time of waste water is long and both investment and operating costs are disproportionately high.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a wastewater treatment process and apparatus which, in the case of low organic carbon wastewater, eliminates the disadvantages of the prior art in denitrification, ensures that the original carbon source is preserved as much as possible and at least substantially eliminates additional carbon source feed. .

The invention is based on the discovery that the biomass developed in the purification system can be most advantageously used in recirculation wastewater treatment processes when denitrification is carried out with the organic carbon present in the wastewater, such as the oxygen acceptor of nitrates, with the greatest possible . Our experiments have shown that the consumption of biomass during endogenous metabolism is uneconomical because the process is slower and more expensive due to the increase in residence time. Therefore, it is an object of the present invention to optimally preserve the organic carbon contaminant of wastewater for denitrification, since the use of a replacement carbon source to reduce residence time significantly increases the operating cost associated with a given purification efficiency. However, the carbon source can only be preserved if the microflora is adapted to nitrate as an energy source instead of dissolved oxygen, which, in turn, requires an appropriate transformation and adaptation time. Most microorganisms used for biological wastewater treatment have the potential to alternatively consume denitrification and oxidation organic matter, but use of oxygen is more advantageous, so nitrate is not used in the presence of dissolved oxygen. In the absence of oxygen, however, conversion from one to the other takes place, but this is done by modifying their enzyme system, which is time-consuming and time-consuming. In our experience, a combination of aeration and denitrification is misapplied in poorly functioning purification systems because it does not allow the microflora to adapt to nitrate.

The invention is further based on the discovery that recirculation used in the prior art to recycle nitrate wastewater to the pre-nitrification step for the most complete nitrate decomposition is detrimental because the water recirculated from the end of the aeration stage carries a significant amount of oxygen to the process. which removes organic carbon so useful for nitrate removal. Instead, use a recirculation that is oxygen deficient if it can be oxy2

GB 222 839 B1 introduces non-GM water into the process with biomass adapted for nitrate.

It is also our discovery that the time required to modify the enzyme system, i.e., to adapt the microflora, can be reduced if the amount of dissolved oxygen is suddenly reduced by the addition of a non-microbial anti-microbial chemical that is useful in the wastewater treatment process. In our experiments, a moderately reducing inorganic compound, such as an iron (II) salt, can be used very advantageously, and its use is advantageous for the subsequent removal of phosphate, which is also known to prevent eutrophication of the recipient.

If the wastewater to be treated no longer contains sufficient organic carbon to decompose total nitrogen, the use of an additional reducing agent, known as a replacement carbon source, cannot be avoided, but the correct choice of dosing site provides the opportunity to minimize or, preferably, eliminate.

In our experiments, denitrification of the system by sealing the system with ambient air significantly increases the speed of the process, reduces the required residence time, and reduces the amount of additional carbon source to be added.

Based on the foregoing findings, the present invention provides a process for biological wastewater treatment, in particular for wastewater with low organic carbon content based on total nitrogen, such that, postnitrification) and post-aeration prior to release to the post-settler. The process is characterized in that after aeration, but before recirculation, the treated waste water is passed through an oxygen-depleted, ideally oxygen-free zone (adaptation zone), while the microflora of the system is converted to nitrate consumption, ie the activated sludge of advanced or recirculated will decompose it and carry out the purification process using the oxygen of the nitrate.

Advantageously, the method of the invention comprises adjusting the residence time of the treated wastewater in the adaptation zone to the nitrate adaptation time of the microflora, i.e., determining the adaptation time of the microflora to nitrate consumption in a manner known per se and adjusting the residence time of the treated wastewater into the adaptation zone.

Advantageously, said process is further characterized in that a reducing agent (s), preferably iron (II) salt, is added to the effluent prior to the adaptation zone.

Advantageously, the process further comprises adding a source of carbon monoxide, such as methanol, to the treated waste water during the post-adaptation step after the adaptation zone, preferably at the beginning.

Advantageously, the process is further characterized in that the denitrification and / or adaptation process phases are carried out in an air-free manner, i.e. excluding oxygen dissolution.

A further preferred embodiment of the process according to the invention is characterized in that the denitrification and / or adaptation steps are carried out in a suitably sealed system that restricts the dissolution of air (oxygen).

The present invention also relates to an apparatus for biological wastewater treatment, in particular low organic carbon wastewater with one or more pre-nitrification reactors connected to one or more post-denitrification reactors, one or more reactors being added, and the apparatus is provided with a recirculation line to the wastewater inlet or to the first pre-nitrification reactor, characterized in that an adapting reactor is inserted between the aeration reactors and the post-denitrification reactors, or the final aeration reactor The starting point of the recirculation line is in the adapting reactor or between the adapting zone and the successive nitrification reactors.

Advantageously, the device according to the invention is characterized in that the pre- and / or post-denitrifiers and preferably the adapting reactor are enclosed in ambient air.

The invention is illustrated in detail by the following examples and the accompanying drawings, without, however, limiting the scope of the invention or the scope of the claimed examples.

Example 1

The wastewater to be treated with a yield of 2000 m ³ daily has a COD of 1100 mg / l and a BOD load of 250 mg / l which is ca. It corresponds to 92 mg / l of biologically available dissolved organic carbon, 110 mg / l of total nitrogen, of which 87 mg / l is in the form of ammonia-N. The wastewater with a temperature of 20 ° C is combined with a stream of sludge recirculation (2000 m ³ / d) and recirculated treated water (6000 m ³ / d) in two rows of 200-200 m ³ mixed, non-aerated reactors where the denitrification process takes place in the oxygen-free medium and with an input soluble carbon content of about 4 g / l the biomass content of the system decomposes 70% of the total nitrogen content into nitrogen. The denitrification reactors are preferably kept covered and kept away from the open air space. The treated wastewater is then passed through a series of two aeration reactors (candles, flutes) of 900-900 m ³ connected in series, keeping the dissolved oxygen level at about 2 mg / l. During the final 13% volume separation of the second aeration reactor, the aeration rate is reduced so that the dissolved oxygen level drops sharply, preferably close to 0. The treated wastewater is then fed to an adapting reactor (also known as a switching reactor), which is

HU 222 839 B1 with a volume of 100 m ³ . 30 mg / l Fe (II) sulfate as an auxiliary reducing agent is added to the treated effluent in a reduced aeration space prior to the adaptation reactor. Using recirculation from the adapting reactor, 60% (6000 m ³ / d) of the flow rate is continuously recycled to the beginning of the pre-nitrification reactor at or near the wastewater inlet. The remainder of the flow is passed through another series of 100 and 200 m ³ so-called post-denitrification reactors connected in series. The purification process is completed by passing it through a 100 m ³ post-aeration reactor. The water entering the recipient is ammonia-N 0.6 mg / L, nitrate ion concentration 35 mg / L, COD 40 mg / L, all below safe limits.

Example 2

A model experiment was conducted to study the effect of air leaching on the rate and extent of nitrate removal. We operated two systems at the same time, each with a volume of 2 liters, one open to the airspace and the other covered. The biomass for biodegradation was taken from a municipal wastewater treatment plant and used at a concentration of 1.5 g / l; and wastewater from a treatment plant with a BOD value of 75 mg / l, approx. Corresponds to a biodegradable organic carbon content of 30 mg / l. Potassium nitrate corresponding to 180 mg / l nitrate was added. This amount of nitrate is stoichiometrically generated from 41 mg / l of ammonium ion nitrogen in a wastewater treatment plant during nitrification. Biomass was suspended in the mixture to give the indicated concentration. The nitrate content was measured in the supernatant of the samples taken every 30 minutes and centrifuged. The results showed that the covered system achieved a valid limit value of 40 mg / l for the treated wastewater within 5 hours and reduced the nitrate concentration to 0 within 7.3 hours. After 8 hours in the free-surface, only mixed system, the nitrate concentration was still 58 mg / L, which required a methanol dose of 13 mg / L to reduce the value to 40 mg / L, which is very high because of a 7000 m ³ / d for a wastewater feed system, it requires 120 l / d methanol.

Example 3

At a municipal wastewater treatment plant, a model experiment was conducted with two simultaneously operating systems, both of which were connected to the inlet of the plant in a continuous operation. Both systems consisted of two 2-2 liter pre-nitrification reactors, two 7-7 liters aeration, two 2.5-2.5 liter post-denitrification reactors and one 1 liter post-aeration reactor. Conventionally, the sludge recirculation from the post-settler and the recirculation of the nitrified mixture from the second aeration reactor to the pre-nitrification reactor were introduced into the pre-nitrification space. Sewage flow rate: 15 1 / d, sludge recirculation is also set. The recirculation of the nitrified mixture is 60 L / d, which is four times the waste water.

With an average of 280 mg / l BOD ₅ , 900 mg / l COD and 65 mg / l total nitrogen inputs (where all nitrogen is predominantly ammonia), the ammonia concentration and COD of the effluent in each case are within the prescribed 2 mg / l BOD NH ₄ nitrogen and 50 mg / L COD. However, the nitrate ion concentration was on average 73 mg / l, against the limit of 40 mg / l.

As the total nitrogen input to the water increased to 80 mg / l with unchanged BOD ₅ (i.e., the available organic carbon content), the nitrate concentration continued to increase. The concentration of nitrate ion in the effluent was stabilized at about 105 mg / l.

Subsequently, one of the two parallel systems is left unchanged and the other is arranged in accordance with the present invention. During the rearrangement, the second one of the two aeration units was divided into 6 and 1 liter units, and in the latter unit aeration was minimized and sludge settling was prevented by stirring. In the first stage of the post-denitrification reactor, a 1 liter section was separated into an adaptation (switching) space, the nitrate recirculation tube returning to the pre-nitrification space was led out of the final flow section of said adaptation space.

In the unchanged reference system, the nitrate ion concentration in the effluent continued to fluctuate around 100 mg / l for several days.

In the modified system, while maintaining the previous favorable parameters, the nitrate ion concentration in the effluent was reduced to a value in the range of 35-38 mg / l within 48 hours.

Example 4

The favorable results of the system modified in accordance with the present invention as described in Example 3 were further improved by adding 30 mg / l iron (II) sulfate to the 1 liter oxygen depleted space separated from the aeration reactor.

Example 5

The favorable results obtained in Example 3 with the system modified according to the present invention were further improved when all non-aerated reactors in the system were covered, preferably with a floating roof.

Figures

Figure 1 An outline of a preferred embodiment of the apparatus of the invention.

A preferred embodiment of the apparatus 1 according to the invention consists of a series of pre-nitrification reactors 3 connected thereto, aeration reactors 4 connected thereto, subsequent adaptation reactors 5, post-denitrification reactors 6 and post-aeration reactors 8, wherein A recirculation line 7 from its final space is connected to the flow-first section of the first pre-nitrification reactor 3. The water to be purified comes from the waste water inlet 2, which is connected to the first pre-nitrification reactor 3. Purified water is one

EN 222 839 B1 is discharged from the unit 1 via a purified drain. The apparatus 1 is also provided with the known conventional post-settler and the resulting sludge recirculation line, which is not shown in the drawing for simplification.

In a further preferred embodiment of the device according to the invention, the flow end terminal of the second aeration reactor 4 is disconnected and formed as an oxygen-free or oxygen-free space. It is also possible to arrange this embodiment in which the adaptation reactor 5 is omitted and the starting point of the recirculation line 7 is the separated section of the second aeration reactor 4.

In another preferred embodiment, the pre-nitrification reactors 3, the adaptation reactor 5, and the post-denitrification reactors 6 can be covered, preferably with a floating lid.

The wastewater to be treated at the inlet 2 to the plant 1 to be treated, mixed with the nitrified water returning to the recirculation line 7 and the recirculated sludge, enters the pre-nitrification reactors 3 where nitrates are decomposed depending on the waste water conditions and system setup. The treated water passes into the aeration reactors 4 where the ammonia, the ammonium compounds are oxidized to nitrite, nitrate. Going forward, the microflora present in the oxygen-depleted and deoxygenated zones converts ("switches") its enzyme system from an oxygen source to a nitrogen source, and the adaptation reactor 5 ("switching reactor") provides the time required for the conversion. Consequently, the mixture returning to the pre-denitrification reactors 3 on the recirculation line 7 is oxygen-depleted, preferably oxygen-free and nitrate-adapted microflora, which positively influences the pre-nitrification and utilization of the organic carbon content of the incoming wastewater. The post-denitrification reactors 6 receive well-treated treated water similar to the recirculated mixture, so that denitrification can be completed here.

The wastewater technology advantage of the process and apparatus of the invention is that it is possible to solve the purification of bioavailable organic carbon which is poor but has a relatively high total nitrogen content, which has been an unresolved task. It also has the advantage that it solves the task with great reliability and in a manner easily understood by one skilled in the art. The solution does not require special equipment and does not require extra chemicals, and even reduces the need for chemicals and auxiliaries. The solution is varied if the equipment features of a particular wastewater treatment plant allow for a simpler and more demanding version of the equipment or the implementation of the process.

Claims (8)

PATENT CLAIMS 1. A process for biological wastewater treatment, in particular for wastewater with a low organic carbon content based on total nitrogen, such that after the wastewater has been pre-nitrified, it is aerated and the treated water is partially recirculated to and a post-aeration prior to discharge into the post-settler, characterized in that after the aeration, but before the recirculation, the treated waste water is passed through an oxygen-deficient, ideally oxygen-free zone (adaptation zone). Method according to claim 1, characterized in that the time needed for the microflora to adapt to nitrate consumption is determined in a manner known per se and the residence time of the treated waste water in the adaptation zone is set for this period. Process according to claim 1 or 2, characterized in that a reducing agent (s), preferably iron (II) salt, is added to the waste water before the adaptation zone. 4. A process according to any one of claims 1 to 4, characterized in that during the post-adaptation step of the post-adaptation zone, preferably at the beginning, a source of carbon substitute, such as methanol, is added to the treated waste water. 5. A process according to any one of claims 1 to 3, characterized in that the denitrification and / or adaptation process steps are carried out in an air-free manner, i.e. excluding oxygen dissolution. 6. A process for biological wastewater treatment, especially for wastewater with a low organic carbon content based on total nitrogen, such that, after the wastewater has been pre-nitrified, it is aerated, and the treated water is partially and carrying out a post-aeration prior to introduction into the post-settler, characterized in that the denitrification and / or adaptation steps are carried out in a sealed system that preferably restricts the dissolution of air (oxygen). 7. Apparatus for biological wastewater treatment, in particular low organic carbon wastewater, with one or more pre-nitrification reactors connected to it, followed by one or more post-nitrification reactors and one or more post-air reactors, The apparatus is provided with a recirculation line flowing into the waste water inlet or the first pre-nitrification reactor, characterized in that an adaptation reactor (5) is inserted between the aeration reactors (4) and the post-denitrification reactors (6) or , serves as an adaptation reactor, and the starting point of the recirculation line (7) is in the adaptation reactor (5) or between the adaptation zone and the post-denitrification reactors (6). Apparatus according to claim 7, characterized in that the pre- and / or post-denitrifiers (3, 6) and preferably the adaptation reactor (5) are closed off from the ambient air air by means of a cover.