WO2000048950A1 - Improvements to purification of effluents with activated sludge - Google Patents

Abstract

The invention concerns a method for purifying effluents with activated sludge comprising a step which consists in an activated sludge treatment followed by a separation by filtering the suspended matter, characterised in that the activated sludge, before passing through the filtering separation, is subjected to aeration for a time interval ranging between a few minutes and several tens of minutes.

Description

 Improvements to the treatment of waste water by activated sludge

The present invention relates to improvements made to processes for the purification of waste water by activated sludge using a stage of treatment by activated sludge followed by a stage of separation of suspended solids.

We know that, in an activated sludge treatment system, it is not possible to achieve a high and permanent level of purification of waste water (urban and industrial), in particular in terms of concentration of suspended matter, by limiting the increase in the water to be treated (therefore the energy cost) to a few centimeters.

The purification of waste water, whether of industrial or urban origin, by activated sludge, is a technique well known to those skilled in the art. The processes implemented in this technique essentially comprise a phase of bringing the water to be purified into contact with a bacterial flock in the presence of oxygen (activated sludge pool), followed by a phase of separation of the floc (separator or clarifier ).

There are numerous publications which refer to processes using separation of the sludge by decantation (clarification) preceded by aeration.

FR-A-2 313 322 describes a continuous process for the treatment, by activated sludge, of contaminated waste water, using aeration before decanting. The objective sought in this publication is to avoid an anaerobic disease which inevitably prevails in enclosures containing large quantities of sludge. US-A-5 268 094 also relates to a separation of the sludge by decantation, preceded by an aeration step in order to avoid the sludge flotation. The commissioning of the aeration step here ensures correct biological functioning of the equipment using activated sludge, to ensure oxygenation proper, with or without anoxic denitrification phases and above all by avoiding sludge flotation, frequent in the case of waters with a high nitrogen pollution content.

DE-A-39 00153 describes a stirring and flocculation system in a purification of waste water using steps of aeration, aerated flocculation and decantation.

In these devices according to the prior art, the final clarifier is a simple device, which consumes little energy (it requires raising the water of the order of a few centimeters) but whose reliability is limited since a biological dysfunction can induce an exaggerated development of the volume of sludge present in the works (activated sludge tank and clarifier). We are aware of the problems posed by the dysfunction of biological purification plants which can result in a sudden drop in the quality of purified water, in particular by an abundance due to the development of filamentous bacteria, settling very slowly and thickening poorly or by foaming resulting in the development of a more or less thick foam on the surface of the aeration tank. These malfunctions can lead to an overflow of the clarifier sludge, when the devices for taking up the settled sludge are insufficient to take up the volume flow of the sludge. Part of the activated sludge is then entrained with the decanted water coming from the clarifier, which means that the water treatment installation rejects particulate and biological pollution in the natural environment (a few hundred mg / l of matter in suspension with high oxygen demand, against 10 to 20 mg / l in normal operation). We understand from the reading of the considerations made above that the conventional purification process: "activated sludge + clarifier" has the advantage of a low energy cost of raising the water to be treated (a few centimeters) but that it has the drawback of not making it possible to achieve a high and permanent level of the quality of the treated water since the final clarifier cannot satisfactorily resolve the problems arising from biological dysfunctions.

To limit the drawbacks specified above, the so-called “tertiary filtration” technique is sometimes used, which consists in using a battery of sand filters placed downstream of the clarifier. This known technique makes it possible to carry out effective filtration with regard to the reduction of peaks in the concentration of suspended solids, but this advantage is obtained at the cost of high energy consumption due to an increase in the water to be treated of the order of the meter. In addition, this technique requires periodic washing of the filters, which induces constraints which can be very significant during periods of biological dysfunction.

Another known solution to the above problems has been provided by the Membrane Bioreactors known under the name "BRM". In installations using this technique, separation membranes are used by micro-filtration or ultrafiltration (ceramic or organic membranes) which are located outside the biological basin, or in the latter, in order to carry out the separation. These installations are complex, highly energy-consuming (they require a rise in water of a few meters - in the case of organic membranes - to a few tens of meters - in the case of mineral membranes), but they have the advantage of producing treated water of excellent quality with high reliability: the concentration of suspended solids in the treated water is well below 5 mg / l and this permanently. Thus, this BRM sector (activated sludge + separation membrane by micro-filtration or ultra-filtration) has the advantage of achieving a high and permanent level of the quality of the treated water but the disadvantage of an energy cost Student. We know (FR-A-2 764 818) another biological process for treating waste water using a pool of activated sludge and a separator comprising filtration plates with textile support, such as in particular textile membranes. This technique is generally known under the name of "Textile Bioreactor" or BRT. The filtration medium used in the implementation of this technique is a commercially available textile medium, having mesh openings of the order of a few microns to a few tens of microns, which generally provides:

- a good stop of the bacterial flocs, therefore a good quality of the treated water, in terms of suspended matter;

- a low resistance to the passage of water, therefore low pressure losses (the raising of the water is limited to a few millimeters).

However, for reasons that are still poorly understood (probably variation in the size of the bacterial flocs, creation or disappearance of a filter cake on the surface of the textile), the concentration of suspended matter in the treated water (or filtrate) may vary and exceed the values required by administrative regulations (generally 30 mg / l in Europe).

This drawback can be limited by adopting smaller mesh sizes of the filter membranes, but this leads to the use of textile membranes which are not usually produced, which are therefore expensive, clog up quickly and which require higher energy consumption. Therefore, we find the disadvantages of the BRM sector, micro-filtration.

In conclusion, the BRT sector (activated sludge + textile separation membranes) has the advantage of an energy cost of raising the water to be treated limited to a few centimeters, but it does not make it possible to reach a high level and quality of the treated water, due to fluctuating concentrations of suspended matter and sometimes higher than the values currently required by administrative regulations, this disadvantage being able to become even more important in the event that the administrative standards in this area could evolve towards increased requirements.

The article "Short term effects of dissolved oxygen concentration on the turbidity of the supernatant of activated sludge" published by Britt-Marie Wilen and Peter Balmer in the journal "Water science and technology" Vol. 38, N ° 3, pp. 25-33, 1998 deals with the influence of dissolved oxygen on the turbidity, after settling, of the effluent from an activated sludge treatment. This article refers to a decanted effluent, that is to say in an unstirred regime, which constitutes a conventional option for those skilled in the art, in order to protect the flocs and stabilize the colloids which are adsorbed there. The lessons that a person skilled in the art can draw from this article is that it is necessary to ensure a minimum of oxygen content in the effluent during settling.

Given the drawbacks of the previous solutions mentioned above, the technical problem solved by the invention lies in obtaining qualities of filtrate (treated water) conforming to the values resulting from increased requirements from the environmental authorities and a limitation raising the water to be treated to a few centimeters, in order to limit energy consumption to its lowest level.

The solution provided to this problem by the present invention resides in a process for the purification of waste water by activated sludge using a stage of treatment by activated sludge followed by a stage of separation by filtration of suspended solids, characterized in that the activated sludge, before it passes through the separation stage by filtration, is subjected to aeration for a period of the order of a few minutes to a few tens of minutes.

According to the invention, the residence time of the activated sludge in the aeration step is greater than ten minutes, preferably greater than 30 minutes and generally less than 3 hours. A subject of the present invention is also a device for implementing the method as specified above, this device comprising an activated sludge reactor and a separator, of the textile separator or membrane type, characterized in that it further comprises aeration means through which pass the activated sludge during the transfer from said reactor to said separator. According to the invention, said aeration means can be internal or external to said reactor, they can for example be installed in the separator.

Thus, the present holder has highlighted an unexpected phenomenon: prior aeration of the activated sludge, during a period of the order of a few minutes to a few tens of minutes, induces a significant reduction in the concentration of suspended solids of the filtrates obtained during of the separation step, by filtration through textile membranes.

In this process which is the subject of the invention, the characteristic that an aeration is carried out before a filtration step, on a textile separator or with membranes, has the aim of increasing the redox potential of the liquor during treatment, which results in a variation of the Zeta potential making it possible to obtain a cohesion of the sludge much more favorable to filtration, a much more gradual clogging of the membranes and a significant increase in the specific flow rate (expressed in lm ^"2 , h ^{′ 1} ) of the textile membrane.

In order to implement this phenomenon, we used the device which is shown very schematically in Figure 1 of the accompanying drawings. This device includes:

- a 40 m ³ activated sludge reactor 1 supplied with urban waste water;

- a textile separator 2 comprising filtration plates 3 of 0.135 m ² , produced according to the provisions claimed in French patent application No. 98 03 197 filed on March 16, 1998 by the present owner and entitled "Improvements to separation equipment solid-liquid, in particular for the biological purification of waste water ", equipped with a fabric having a mesh size of 20 microns, which separate the activated sludge into a filtrate (treated water) and a concentrate which is returned to reactor 1;

a means 4 for pumping activated sludge supplying the textile separator 2 from the activated sludge reactor 1, the time for the sludge to pass between this reactor and the textile separator 2 being of the order of 5 minutes;

- a REDOX 5 probe to continuously record the redox potential of the activated sludge contained in reactor 1 and,

- a turbidimeter 6 which continuously records the turbidity of the treated water.

During a first experiment, the activated sludge reactor 1 operated in alternating aeration:

- for a period of 90 minutes, the reactor 1 was aerated (nitrification period);

- for a second period of 90 minutes, the reactor 1 was no longer ventilated (denitrification period);

- the reactor was re-aerated for 90 minutes and so on.

In FIG. 2 of the appended drawings, one can see the recording of the measurements of turbidity and REDOX potential of the treated water, carried out during these periods of alternating aeration. In this same FIG. 2, the periods of aeration and anoxia (absence of aeration) of reactor 1 have been indicated (slots arranged on the left side of FIG. 2). In this figure 2, the time axis is oriented from bottom to top. Examination of this figure shows that the turbidity of the treated water oscillates over time, with a periodicity identical to that of aeration. It is also noted that the turbidity decreases during periods of aeration and that it increases during periods of anoxia. There is a slight difference of a few minutes between the turbidity oscillations and the aeration / anoxia phases, corresponding to the transit time of the activated sludge between the reactor 1 and the textile separator 2.

In parallel with this test, samples of the treated water were taken during the periods of minimum turbidity (end of the aeration cycles) and maximum turbidity (end of the anoxia cycles), in order to measure the concentrations of matter in suspension in treated water. These concentrations were respectively 60 and 95 mg / l, ie a “peak to hollow” factor of 1.6.

A second test was then carried out, on the same device as that illustrated in FIG. 1, but equipped with filtration plates 3 comprising a fabric with a mesh of 15 microns. Figure 3 of the accompanying drawings is a representation similar to that of Figure 2, that is to say a recording of the turbidity and the REDOX potential made during this second test. We see that the turbidity of the treated water oscillates over time, with a periodicity identical to that of aeration: the periods of aeration correspond to the periods of decrease in turbidity of the treated water. In this particular case, the concentrations of suspended matter in the treated water varied from 20 to 30 mg / l, i.e. a crest-to-trough factor of 1.5.

Examination of the two records illustrated in Figures 2 and 3 shows that the turbidities did not reach a minimum level at the end of the aeration periods and that an extension of the aeration period would have led to a reduction complementary to the turbidity of the treated water.

In order to clarify this point, a third test was carried out, on sludges having slightly different characteristics, during which the activated sludge reactor 1 also operated in alternating aeration, but with an extension of the duration of certain periods of aeration or anoxia. The textile separator 2 was equipped with 15 micron mesh fabrics.

FIG. 4 of the appended drawings is a recording of the turbidity and REDOX potential measurements of the treated water carried out during a test during which an aeration period was extended for nine hours. We see that the turbidity decreased during this period from 20 to 13 mg / l, a crest-to-trough factor of 1.5.

FIG. 5 of the appended drawings is a recording of the measurements of turbidity and REDOX potential of the treated water carried out during a test during which an anoxia period was prolonged for 4 hours. It can be seen that the turbidity increased during this period from 10 to 19 mg / l, ie a crest-to-trough factor of 1.9.

The pressure losses (on the filtrate circuit) observed during these tests were less than 1 cm of water column, that is to say in accordance with the objectives.

It will be noted that these various tests were carried out on different dates; the characteristics of the activated sludge varying from one day to another, it is not necessary to compare the suspended solids of the treated water from one test to the other but only the peak-to-hollow ratios observed during the same experience.

The results of the tests reported above show an improvement, according to an important factor, in the concentration of suspended matter in the treated water, obtained by feeding the separator 2 with activated sludge sampled after a sufficient aeration phase. This is an unexpected effect, brought about by the implementation of the invention, that is to say an increase in the quality of the filtered water obtained thanks to this prior aeration of the activated sludges before their separation. This unexpected effect is also particularly advantageous since it makes it possible to resolve the problem posed, namely obtaining qualities of filtrates (treated water) conforming to the values required by administrative regulations, while limiting to a few centimeters, raising the water to be treated, thereby reducing energy expenditure.

Other characteristics and advantages of the present invention will emerge from the description given below with reference to the accompanying drawings which illustrate various embodiments thereof which are in no way limiting. In these drawings: Figures 1 to 5 refer to the tests described above and Figures 6 to 9 are schematic representations of different embodiments of devices implementing the present invention.

Firstly, reference is made to FIG. 6 which illustrates an embodiment of the invention in which the activated sludge basin has been arranged so that it comprises an aerated zone in which the residence time of the activated sludge is greater 10 minutes, preferably more than 30 minutes (or a time such that the REDOX potential is greater than a minimum value). In this figure, we find the activated sludge pool 1 as well as the textile separator 2 of FIG. 1. The textile separator 2 consists of filtration plates equipped with a fabric with pass-through mesh of 0.2 to 100 microns, of preferably 10 to 30 microns. The reference 7 designates the continuous aeration zone of the activated sludges before their transfer to the textile separator 2. In this FIG. 6, the reference 8 designates the inlet of the raw water and the reference 9 the return of the concentrated sludges at the top of the activated sludge tank 1.

In the variant illustrated in FIG. 7, the same arrangement is found as in the embodiment described above with reference to FIG. 6, the only difference being that the return 9 'of the concentrated sludge takes place towards the zone d ventilation 7.

The embodiment illustrated in FIG. 8 applies to the case of an activated sludge pool 1 operating in alternating aeration (case of the first test described above). In this FIG. 8, the same references have been used as in FIG. 6 to identify the similar elements. The activated sludge can be removed during the final phase of the aeration periods so as to obtain filtrates which always have a turbidity corresponding to the minimum of the curve in FIG. 2. According to a variant, the separator 2 can be put into service from a minimum threshold of REDOX potential.

As seen above, the invention can be implemented by providing an intermediate ventilation between the activated sludge tank 1 and the separator 2. In the embodiment illustrated in FIG. 9, this middle ventilation is obtained by a separate aerated tank 13 to which the activated sludge from the tank 1 is delivered, the residence time of this sludge in the aerated tank being of the order of 10 minutes to 3 hours.

Other variants of the invention can be provided: thus, the intermediate ventilation can be obtained by the use of oxygen dissolution means, for example of the hydro-ejector, static mixer or liquid gas contactor type. It is also possible to size the separator so as to obtain the minimum residence time for this intermediate ventilation.

It remains to be understood that the present invention is not limited to the embodiments described and / or mentioned above but that it encompasses all variants thereof, within the limits of the appended claims.

Claims

1 - Process for the purification of waste water by activated sludge using a stage of treatment by activated sludge followed by a stage of separation by filtration of the suspended solids, characterized in that the activated sludge, before it passes through the 'filtration separation step are subjected to aeration for a period of the order of a few minutes to a few tens of minutes. 2 - Process according to claim 1, characterized in that the residence time of the activated sludge in the aeration step is greater than ten minutes, preferably greater than 30 minutes. 3 - Method according to one of claims 1 and 2, characterized in that the residence time of the activated sludge in the aeration step is less than three hours. 4 - Device for implementing a process as specified in any one of the preceding claims comprising an activated sludge reactor (1) and a separator (2) of the textile separator or membrane type, characterized in that 'it further comprises aeration means through which pass the activated sludge during their transfer from said reactor (1) to said separator (2). 5 - Device according to claim 4, characterized in that the separator (2) is a textile separator comprising filtration plates provided with a fabric with pass-through mesh, having a mesh size of 0.2 to 100 microns, preferably from 10 to 30 microns. 6 - Device according to one of claims 4 or 5, characterized in that said aeration means are produced in the form of an aeration zone (7) formed in the activated sludge reactor (1). 7 - Device according to one of claims 4 or 5, characterized in that the ventilation means are located in the separator. 8 - Device according to claim 4, characterized in that said aeration means are obtained by operating in alternating aeration said reactor (1), the activated sludge feeding the separator (2) being sampled during the final phase of said periods d 'aeration. 9 - Device according to claim 4, characterized in that said aeration means are made in the form of an aeration tank (13) interposed between said reactor (1) and said separator (2). 10 - Device according to claim 4, characterized in that said aeration means are made in the form of oxygen dissolution systems of the hydro-ejector, static mixer, gas-liquid contactor type.