Title of Invention

"METHOD AND SYSTEM FOR THE TREATMENT OF LIQUID EFFLUENTS CONTAINING ESPECIALLY POLLUTANTS IN A SUSPENSION"

Abstract Method for the purification and filtration of fluids, especially liquid effluents such as untreated water containing organic pollutants in solution and employing gravity separation means such as in particular a settling tank and a flotation separator, and as well as membrane separation means, in a finishing step, according to which a coagulant is injected at a point on the untreated water supply conduit, a powdery reagent is introduced upstream of the membrane separation, this powdery reagent being recycled from the membrane separation means to the upstream side of the gravity separation means, this method being characterised: in that a first powdery reagent is introduced downstream of the coagulant injection point and upstream of the gravity separator, in that this first powdery reagent and the second powdery reagent that is introduced upstream of the membrane separation have different characteristics, especially particle size and absorption capacity adapted to the pollutants to be eliminated, and in that the residence time of the first powdery, reagent in its contact reactor is between 5 and 60 hours.
Full Text The present invention relates to method and system for the treatment of liquid effluents containing especially pollutants in a suspension.
The present invention relates to a process and to an installation for the treatment of liquid effluents, containing especially pollutants in solution, for example natural organic matter, micropollutants, etc.
Such processes ' and installations employ gravity separation means that include known systems of the settling tank type or flotation separator type, these being optionally followed by a granular filtration unit. It is known that, during the treatment of a liquid effluent, it may be necessary to use pulverulent reactants such as adsorbents (for example active carbon, bentonites or ion exchangers of the gel or macroporous type, with a standard or magnetic backbone). The addition of these reactants into the liquid effluent treatment line usually takes place at the same time as another reactant for promoting the coagulation, flocculation and gravity separation of the particulate impurities contained in the solution. Such an operation therefore makes it possible to remove the particulate, colloidal and dissolved impurities from the stream of liquid effluent to be treated. However, it is recognized that, to improve the effectiveness of this type of process, it is necessary to add the adsorbent reactant before the coagulant, since these suspended reactants behave as colloids and it is necessary to take account of their presence when adjusting the doses of reactants needed for the clarification.
The advent of membrane separation techniques, especially applications of ultrafiltration to the treatment of liquid effluents, makes it possible to improve the overall efficiency of clarification and


filtration means installed upstream of the membrane separation means, the membranes having a separation efficiency of 100% in the case of particles that are larger than the separating power of the membranes used. In this context, it is desirable to inject the coagulant upstream of the adsorbent reactants - the metal hydroxide formed during the coagulation and flocculation is used to adsorb most of the organic matter (organic molecules of high molecular weight), thereby increasing the efficiency of adsorption of the residual organic matter and of the micropollutants by the pulverulent adsorbent.
Since it turns out that the organic matter and the micropollutants are in competition for the same adsorption sites, the efficiency of this type of system can be improved by increasing the number of points of injection and the types of adsorbent. For example, in a system that includes a settling tank followed by membranes, a first adsorbent will be added before the settling tank and a second before the membranes, each of the reactors being optimized according to the characteristics specific to the materials to be removed and to the adsorbents. It is to this type of installation that the present invention relates.
FR-A-2 628 337 in particular discloses installations for the purification of fluids by means of membranes, into which installations an adsorbent, for example pulverulent and/or granular active carbon, is introduced, this adsorbent being introduced before the filtration membranes into the stream of fluid to be purified.
Also disclosed, especially by US-A-4 610 792, are installations for the treatment of polluted water that include clarification means and membrane separation means as finishing treatment. In this known type of installation, a pulverulent reactant, for example

active carbon, is introduced into the raw water treatment line between the conventional clarification means and the membrane separation means, the pulverulent reactant being recirculated into the membrane filtration loop between the clarification means and the membrane separation means.
Also known are older systems for the addition of
pulverulent reactants, in which the reactant is
injected into the treatment line directly upstream of
the gravity separation unit (flotation separator or
settling tank).
Finally, installations are known (FR-A-2 696 440) for the purification of fluids that include gravity separation means and membrane separation means, in which the pulverulent reactant is introduced upstream of the membranes and the water for backwashing these membranes containing this pulverulent reactant is recirculated upstream of the gravity separation means.
Starting from this prior art, the present invention proposes improvements, for improving the efficiency of removing the dissolved pollution, while reducing the operating costs.
As a consequence, the subject of this invention is, firstly, a process for the purification and filtration of fluids, especially liquid effluents such as raw water containing organic pollutants in solution and employing gravity separation means such as in particular a settling tank and a flotation separator, and also membrane separation means, in a finishing step, in which process a first pulverulent reactant is introduced into the stream of the fluid to be treated, upstream of the gravity separation unit, and a second pulverulent reactant, upstream of the membrane separation unit, this process being characterized in that the coagulant needed for the separation is

injected before the first pulverulent reactant, in that said first and second pulverulent reactants have different characteristics, especially particle size and adsorptivity suitable for the pollutants to be removed, and in that said second pulverulent reactant is recycled from the membrane separation means toward the upstream end of the gravity separation means.
According to the invention, the fact of adding the coagulant before the first pulverulent reactant into a reactor whose contacting time can moreover be adapted to the characteristics of the raw water (temperature, turbidity, organic matter, etc.) makes it possible to obtain an adsorbent residence time of generally between 5 and 20 hours, but never more than 60 hours, beyond which it has been observed that the efficiency of the first adsorption step is substantially reduced, in particular as regards the removal of miscropollutants.
According to one method of implementing the process as defined above, each of the pulverulent reactants is formed by adsorbents, especially active carbon, bentonites or ion exchangers of the gel or macroporous type, with a standard or magnetic backbone.
The invention also relates to an installation for implementing the process as defined above.
This installation comprises a treatment line including especially gravity separation means, membrane separation means, as finishing step, and means for the respective introduction of coagulant, of a first pulverulent reactant upstream of the gravity separation unit and of a second pulverulent reactant upstream of the membrane separation means, this installation being characterized in that it furthermore includes a loop for recycling the second pulverulent reactant from the purge of the membrane separation means back to the line in which the liquid effluent to be treated flows,
upstream of the gravity separation means and in that the means for injecting the coagulant needed for the separation are located upstream of the means for injecting the first pulverulent reactant.
According to one embodiment of this installation, the gravity separation means are produced in the form of a clarifier, which may consist of a sludge bed settling tank or a sludge recirculator, optionally supplemented with a lamellar separator system and preceded either by a contacting zone, for the injection of the coagulant, or by a complete coagulation/flocculation step, the choice between the various combinations being guided by the time needed for the coagulant to form its first adsorption and by the residence time needed for the first: pulverulent reactant to achieve an optimum adsorption efficiency.
According to another method of implementing the invent ion, the gravity separation means exre produced in the form of a clarifier such as a flotation separator, optionally preceded either by a contacting zone for injecting the coagulant or by a complete coagulation/flocculation step.
According to the invention, the membrane separation means are formed by microfiltration, ultrafi1tration, nanofiltration or even reverse osmosis systems that are equipped with plate-and-frame, tubular, spiral or hollow-fiber (external skin or internal skin) membranes. The gravity separation means may comprise a granular filter with ascending or descending current.
Other features and advantages of the present invention will become apparent from the description given below with reference to the appended drawings which illustrate (exemplary embodiments of the invention, these being devoid of any limiting character. In the drawings, figures 1 and 2 are schematic representations
of two embodiments of a treatment installation for implementing the process according to the invention.
Figure 1 shows that the installation according to the present invention comprises, as is known, a gravity separation means denoted in its entirety by the reference 10, which may consist of a clarifier 11 followed by a granular filter 12 and a membrane separation means 13, produced for example in the form of microfiltration, ultrafiltration, nanofiltration or even reverse osmosis systems. It will be noted that the clarifier 11 may consist of a sludge bed settling tank or a sludge recirculator or a flotation separator, or a settling tank, optionally supplemented with a lamellar separation system.
According to the invention, the installation provides for a coagulating reactant to be introduced at a point 18 into the raw water feed line, said line being followed by a mixing/contacting reactor 14, by means for introducing the first pulverulent reactant (adsorbent 1), upstream of the gravity separator 10 and downstream of the point of injection 18 of the coagulating reactant, and by a means for introducing the second pulverulent reactant (adsorbent 2) upstream of the membrane separator 13. A mixing/contacting reactor 15 is also provided between the means of introducing the adsorbent 2 and the membrane separation means 13.
According to the present invention, the installation also includes the recycling of the second pulverulent reactant (adsorbent 2), from the purge of the membrane separator 13, by means of a loop 16 that takes the second pulverulent reactant thus recycled back to a point 17 located on the raw water feed line, upstream of the gravity separator 10 but downstream of the point of introduction 18 of the coagulant.
As mentioned above, the pulverulent reactants (adsorbents I and 2) have different characteristics (materials, particle size, adsorptivity matched to the
pollutants to be removed).
Referring now to figure 2, this illustrates an alternative embodiment of the installation according to the invention. In this embodiment it may be seen that the gravity separation means 10' includes no clarifier and it may consist of a granular filter 12' (with ascending or descending filtration), optionally preceded either by a contacting zone for injection of the coagulant or by a complete coagulation/flocculation step. The membrane separation means 13 may for example be produced in the form of ultrafiltration devices. This installation is particularly advantageous for the clarification of water in which the amount of colloidal matter and the amount of suspended matter are low.
According to the invention, and as previously, in this embodiment a means is provided for the introduction of a coagulating reactant at a point 18 on the raw water feed line, upstream of the point of injection of the first pulverulent reactant, said means being followed by a mixing/contacting reactor 14, by a means of injecting the first pulverulent reactant (adsorbent 1) at a point located upstream of the granular filters 12' and by a means of injecting the second pulverulent reactant (adsorbent 2) upstream of the membrane separator 13. Recycling of the second pulverulent reactant (adsorbent 2) is also provided, coming from the purge for the membrane separator 13, by means of a loop 16 that takes the pulverulent reactant thus recycled back to a point 17 located on the raw water feed line, upstream of the gravity separator 10' but downstream of the point 18 of injection of the coagulant.
Thus, compared with the known technique, as defined
especially in the abovementioned publications, the invention differs by the fact that it employs two pulverulent reactants having different characteristics, these being added at different points on the treatment line, and by the fact that the coagulant is injected upstream of the first pulverulent reactant. Thanks to this arrangement, the efficiency of the adsorption of the various organic pollutants is optimized (since the effects of the coagulant and of the adsorbent do not counteract each other), while the operating costs of the system are reduced.
The results of trials for implementation of the process according to the invention, which indicate the increases in efficiency of the adsorption of organic matter (OM) and pesticides, are given below. These results are set out in Tables I and 2.
Table 1: Comparison of the percentage removal of
organic matter (TOG) for adsorbent injection (i)
simultaneously with and (ii) subsequently to coagulant
injection.
(Table Removed)

In both cases, a coagulant dose of 60 mg/1 of ferric chloride and an adsorbent dose of 15 mg/1 of powdered active carbon (Norit W 35) were used on the same water containing 10 mg/1 of TOC (Total Organic Carbon) . The

removal efficiency was greatly improved in the case of delayed injection.
Table 2: TOG adsorption efficiencies for various
systems.
(Table Removed)
PACi = powdered active carbon (Norit W 35) , not screened (particle size: 50-100 /-tm) ;
PAC2 = powdered active carbon (Norit S.A.U.F.), screened (particle size: 10 fj.m) ;
(1): knowing the contacting time in the sludge bed is 12 to 48 hours and that in the membranes is about 60 minutes, the high specific surface area of PAC2 nevertheless makes it possible to obtain an equivalent result on TOC and a better result on miscropollutants;
(2): recirculation makes it possible to optimize the use of the total capacity of PAC;
(3): improved performance with cost reduction, since PAC! is substantially cheaper than PAC2. The low

dose of PAC2 would even allow dead-end filtration, with no recirculation;
(4) : PAC2 is more effective on pesticides (miscropollutants) when the TOG has been reduced beforehand on PACi.
Compared with the other known processes employing the combination of gravity separation means with filtration plus membrane separation means, the invention in particular provides the following advantages:
the order of injection of the reactants
(addition of a first pulverulent adsorbent reactant into a raw water that has been pre-coagulated) optimizes the overall removal of organic compounds
(total organic carbon or TOC) with a high concentration
(a few mg/1);
- the addition of a second pulverulent adsorbent upstream of the membranes constitutes a double barrier for adsorption of miscropollutants (pesticides and compounds responsible for taste and odor) with a low concentration (a few //g/1) . This second adsorbent is much more effective for the adsorption of miscropollutants, this resulting from the reduction, upstream, in the concentration of natural organic matter (TOC) by coagulation and adsorption;
the recycling of the second pulverulent adsorbent reactant from the membrane separation means to a point upstream of the gravity separation means
(with a long residence time) makes it possible to saturate this pulverulent reactant and to increase the overall adsorption efficiency in the gravity separation means; and
the discharge from the membrane separation means, containing the second pulverulent reactant, is sent back into the sludge coming from the gravity separator, which contains the first adsorbent. This simplifies the problem of treating the sludge of the treatment line and minimizes the amount of water "lost" owing to the extractions.
Of course, it remains to be stated that the present invention is in no way limited to the exemplary embodiments and methods of implementation described and/or mentioned above, rather it encompasses all variants thereof.















We Claim
1. Method for the purification and filtration of fluids, especially liquid
effluents such as untreated water containing organic pollutants in
solution and employing gravity separation means such as in particular a
settling tank and a flotation separator, and as well as membrane
separation means, in a finishing step, according to which a coagulant is
injected at a point on the untreated water supply conduit, a powdery
reagent such as herein described is introduced upstream of the
membrane separation, this powdery reagent being recycled from the
membrane separation means to the upstream side of the gravity
separation means, this method being characterised:
in that a first powdery reagent is introduced downstream of the coagulant injection point and upstream of the gravity separator, in that this first powdery reagent and the second powdery reagent that is introduced upstream of the membrane separation have different characteristics, especially particle size and absorption capacity adapted to the pollutants to be eliminated, and in that the residence time of the first powdery reagent in its contact reactor is between 5 and 60 hours.
2. Method as claimed in claim 1, wherein the residence time of the first powdery reagent in its contact reactor is between 5 and 20 hours.
3. Method as claimed in claim 1, wherein the powdery reagents are formed by absorbents, such as especially activated carbon, bentonites or iron exchangers of the gel or macroporous type, with a standard or magnetic frame work.
4. A system for implementing the method as claimed in claim 1, which comprises a treatment line including particularly gravity separation means (10), membrane separation means, as a finishing step, means for

respectively introducing a coagulant and a powdery reagent upstream of the membrane separation means, this device also comprising a loop (16) for recycling the powdery reagent from the purge of the membrane separation means (13) as far as the conduit in which the liquid effluent to be treated is flowing, upstream of the gravity separation means (10), wherein it comprises means for introducing a first powdery reagent upstream of the gravity separation, the powdery reagent injected upstream of the membrane separation means being a second powdery reagent having different characteristics,
and in that the means of injecting the coagulant necessary for the separation are situated upstream of the means of injecting the first powdery reagent.
A system as claimed in claim 4, wherein the gravity separation means (10) are produced in the form of a clarifier, such as a sludge bed settling tank, optionally supplemented by a lamellar separator system and preceded either by a contact zone for the injection of the coagulant, or by a complete coagulation/flocculation step.
A system as claimed in claim 4, wherein the gravity separation means (10) are produced in the form of a clarifier such as a flotation separator, optionally preceded either by a contact zone for injecting the coagulant or by a complete coagulation/flocculation step.
A system as claimed in claim 4, wherein the gravity separation means (10) are provided in the form of a clarifier, such as a sludge recirculator, supplemented by a lamellar separator system and preceded either by a contact zone for the injection of the coagulant or by a complete coagulation/flocculation step.
A system as claimed in claim 4, wherein the gravity separation means (10) are produced in the form of a granular filter (12) with ascending or

descending flow, optionally preceded either by a contact zone for injecting the coagulant or by a complete coagulation/flocculation step.
9. A system as claimed in any one of claims 4 to 7, wherein the membrane separation means (13) are formed by microfiltration, unfiltration, nanofilteration or even reverse osmosis systems.

Documents:

3697-DELNP-2005-Abstract-(25-03-2009).pdf

3697-delnp-2005-abstract.pdf

3697-DELNP-2005-Claims-(15-04-2009).pdf

3697-DELNP-2005-Claims-(25-03-2009).pdf

3697-delnp-2005-claims.pdf

3697-delnp-2005-complete specification (granted).pdf

3697-DELNP-2005-Correspondence-Others-(25-03-2009).pdf

3697-delnp-2005-correspondence-others.pdf

3697-DELNP-2005-Description (Complete)-(25-03-2009).pdf

3697-delnp-2005-description (complete).pdf

3697-delnp-2005-drawings.pdf

3697-delnp-2005-form-1.pdf

3697-delnp-2005-form-18.pdf

3697-delnp-2005-form-2.pdf

3697-DELNP-2005-Form-3-(25-03-2009).pdf

3697-delnp-2005-form-3.pdf

3697-delnp-2005-form-5.pdf

3697-DELNP-2005-GPA-(25-03-2009).pdf

3697-delnp-2005-gpa.pdf

3697-delnp-2005-pct-210.pdf

3697-delnp-2005-pct-409.pdf

3697-DELNP-2005-Petition-137-(25-03-2009).pdf

3697-DELNP-2005-Petition-138-(25-03-2009).pdf

abstract.jpg


Patent Number 233895
Indian Patent Application Number 3697/DELNP/2005
PG Journal Number 20/2009
Publication Date 15-May-2009
Grant Date 17-Apr-2009
Date of Filing 22-Aug-2005
Name of Patentee DEGREMONT
Applicant Address 183,AVENUE DU 18 JUIN 1940,F-92508 RUEIL MALMAISON,FRANCE.
Inventors:
# Inventor's Name Inventor's Address
1 CARLOS COMPOS 5 QUAI VOLTAIRE,F-78230 LE PECQ,FRANCE
2 FRANCOIS BERNAZEAU 82,RUE JEAN JACQUES ROUSSEAU,F-92500 RUEIL MALMAISON,FRANCE,
3 JACQUES MOLES 25,RUE DES CHATEAUPIEDS,F-92500 RUEIL MALMAISON,FRANCE
4 WILLIAM LEVASSEUR LE FOURNEAU DES TUILERIES, F-27290 APPEVILLE DIT ANNEBAULT,FRANCE,
PCT International Classification Number C02F 9/00
PCT International Application Number PCT/FR2003/000627
PCT International Filing date 2003-02-26
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 NA