FR3102482A1 - Process for treating aqueous fluid containing polymers using zirconium salts and alkali carboxylates - Google Patents

Abstract

The invention relates to a method of treating an aqueous fluid comprising at least one water-soluble polymer carrying carboxylate or sulphonate functions in the aqueous phase, said method comprising a step of bringing said aqueous fluid into contact with at least one tetravalent zirconium salt and at least one alkaline carboxylate chosen from alkali citrates or alkali propionates; making it possible to reduce the viscosity of said aqueous fluid, in order to produce an aqueous fluid having a lowered viscosity, preferably close to that of water. The invention also relates to a process for the enhanced recovery of crude oil contained in a geological reservoir in which the produced water obtained by means of said process for treating an aqueous fluid is treated.

Description

Process for treating aqueous fluid containing polymers using zirconium salts and alkali carboxylates

The present invention relates to the field of exploration and exploitation of an underground formation. The invention relates more particularly to the treatment of an aqueous fluid recovered from the underground formation. By "aqueous fluid" is meant in the remainder of the description any fluid comprising a continuous aqueous phase.

The invention relates in particular to the field of Enhanced Oil Recovery (EOR) and the field of treatment of produced water.

For the exploration and exploitation of an underground formation, it is common to inject a fluid into the underground formation in order to increase the efficiency of the processes (Han D. K. & al, Recent Development of Enhanced oil Recovery in China, J. Petrol. Sci. Eng. 22(1-3):181-188;1999). To optimize these processes, it is customary to include at least one additive in the injected fluid. This additive can take the form of a formulation of organic molecules, such as polymers, copolymers and/or surfactants, etc. This formulation may also contain inorganic molecules such as minerals (clays, barite, etc.), oxide particles (titanium oxides, iron oxides, etc.) etc. The addition of additive(s) poses certain problems related in particular to the presence of the additive or of molecules constituting it in the water produced.

For enhanced oil recovery, when the injected fluid, also called sweeping fluid, is supplemented with compounds such as polymers, surfactants, alkaline compounds, or mixtures of these compounds, we speak of tertiary enhanced recovery. Compared to a simple injection of water or brine, the advantage of the presence of a polymer is to increase the viscosity of the flushing fluid and consequently to improve the mobility ratio between the injected fluid and the hydrocarbons. in place in the underground formation.

The hydrocarbon recovery yield is increased with the help of better formation sweeping efficiency (Han D. K. & al, Recent Development of Enhanced oil Recovery in China, J. Petrol. Sci. Eng. 22(1-3 ): 181-188; 1999). The polymers used in this method are generally high molecular mass polymers chosen for their viscosifying properties at moderate concentrations.

During oil production operations, water is frequently co-produced with crude oil, a ratio of three barrels of aqueous effluent to one barrel of crude oil is commonly advertised.

Crude oil and water must be separated. The oil is transported to its place of refining and the water is treated to remove undesirable compounds and comply with discharge standards.

Various techniques are applied to treat production water, in particular to eliminate the dispersed drops of crude oil: sedimentation by gravity separation, centrifugation, flotation with or without gas injection and filtration.

The use of polymers in tertiary enhanced recovery nevertheless poses practical problems. At the level of the producing wells, a production effluent comprising a mixture of aqueous fluid and hydrocarbons is recovered in the form of an emulsion whose water/hydrocarbon ratio changes according to the duration of production. The presence of polymer in the production effluent, due to its viscosifying effect, makes it more difficult to separate the different fluids (oil/gas/water) and, in particular, the secondary water treatments. (Zhang Y.Q & al. Treatment of produced water from polymer flooding in oil production by the combined method of hydrolysis acidification dynamic membrane bioreactor-coagulation process, J. Petrol. Sci. Eng., 74 (1-2): 14-19, 2010). When the production effluent reaches the surface, it is treated in a surface unit. This unit makes it possible to separate the different fluids, gas, oil and water. At the end of the surface treatment, the hydrocarbons are ready to be refined. The water is treated and depolluted in order to minimize the discharge of toxic products into the environment, the thresholds of which are subject to standards. The presence of the polymer in the produced fluids, as reported in SPE 65390 (2001) "Emulsification and stabilization of ASP Flooding Produced liquid", can lead to the stabilization of emulsions in the produced fluids and pose process problems. surface treatment, at the level of water/oil/gas separation and in particular, at the level of secondary water treatment processes.

If the interest of the presence of a polymer is to increase the viscosity of the sweeping water to improve the extraction of the hydrocarbons in place in the underground formation, the viscosity of the water in the production effluent becomes an obstacle to the separation between water and hydrocarbons.

This problem has led operators in the field to consider means of reducing the viscosity of the water produced, that is to say of the aqueous phase in the production effluent, in order to improve the separation between the water and hydrocarbons. Among these means, the degradation of the viscosifying polymer(s) in the water produced is envisaged and is described in the prior art.

The conventional polymers used in EOR are high molecular weight polymers which generally belong to the family of polyacrylamides (PAM) or partially hydrolyzed polyacrylamides (HPAM). They may optionally contain monomer units of the N-vinylpyrrolidone or acrylamido-tertiobutylsulfonate (ATBS) type.

Polyacrylamides are obtained by radical polymerization of acrylamide according to the following general scheme.

Partially hydrolyzed polyacrylamides are copolymers of acrylamide with either acrylic acid or an acrylate, for example an acrylate of an alkaline element such as sodium. They can be represented for example by the following general formula in which the alkaline element is sodium. The acrylamide monomer unit is generally predominant.

Partially hydrolyzed polyacrylamides can be obtained, for example, by copolymerization of acrylamide with acrylic acid, the carboxylic acid function of which can optionally be neutralized into the carboxylate function of an alkaline element such as, for example, sodium. Partially hydrolyzed polyacrylamides can also be obtained by copolymerization of acrylamide with an acrylate of an alkaline element such for example sodium acrylate. Partially hydrolyzed polyacrylamides can also be obtained by polymerization of acrylamide into polyacrylamide followed by partial hydrolysis of the amide functions into carboxylic acid functions or into carboxylate functions of alkaline salts.

The HPAMs can be random or block copolymers.

The degradation of these polymers in order to attenuate or eliminate their viscosifying effect is described in particular in the document "SPE-163751 Chemical degradation of HPAM by oxidization in produced water, (2013)" in which HPAMs are degraded by the action of oxidizing agents such as hydrogen peroxide or sodium persulfate or by photodegradation in the presence of titanium dioxide.

The document SPE-169719-MS "Treating back produced polymer to enable use of conventional water treatment technologies, (2014)" describes, in order to reduce the viscosity of produced water, the degradation of HPAM polymers by the action of different oxidants such as potassium persulfate, potassium percarbonate, hydrogen peroxide, sodium hypochlorite, Fenton's reagent or potassium permanganate.

The document "SPE-179776-MS Management of viscosity of the back produced viscosified water, (2016)" describes, in order to reduce the viscosity of produced water, the degradation of HPAM polymers by mechanochemical, thermal and chemical, in particular by means of chlorinated derivatives.

It is also possible not to degrade the polymer in order to eliminate its effects, but to separate it from the medium, that is to say to reduce the concentration of polymer in the aqueous medium.

It is known that aqueous solutions of certain polymers exhibit increased viscosities and sometimes form gels following treatment with zirconium salts. Such a treatment can have applications when one seeks to viscosify a fluid. Document SPE-27720-MS and document US 6,737,386 B1 describe the use of zirconium derivatives in order to crosslink polymers belonging to the guar family in order to increase the viscosity of their aqueous solutions with a view to their application as a fluid for hydraulic fracturing.

This type of treatment can be carried out with in particular zirconium tetrachloride. However, this compound has a major drawback. It reacts spontaneously or even violently with water to produce oxydichlorozirconium of formula ZrOCl ₂ and hydrochloric acid at the rate of two moles of hydrochloric acid per mole of zirconium tetrachloride. Consequently, this results in risks, in particular of corrosion in the event of industrial application.

Surprisingly, the Applicant has discovered that it is possible to reduce, even eliminate or cancel out the viscosifying effect provided by the polymers used in the fluids formulated to improve enhanced oil recovery, in particular polymers of the partially hydrolyzed polyacrylamide type of HPAM under the successive or simultaneous action of two families of reagents, the objective being to reach or approach the viscosity of the aqueous matrix or simply the viscosity of water.

The invention relates to a process for treating an aqueous fluid comprising at least one water-soluble polymer carrying carboxylate or sulphonate functions in the aqueous phase, said process comprising a step of bringing said aqueous fluid into contact with at least one tetravalent zirconium salt and at least one alkaline carboxylate selected from alkaline citrates or alkaline propionates; for reducing the viscosity of said aqueous fluid, in order to produce an aqueous fluid having a lowered viscosity, preferably close to that of water.

Said water-soluble polymer can be chosen from: partially hydrolyzed polyacrylamides (HPAM), or partially hydrolyzed polymers comprising units of the N-vinylpyrrolidone or acrylamido-tertiobutylsulfonate (ATBS) type.

Preferably, said zirconium salt is chosen from zirconium sulphate, nitrate, carbonate, phosphate and carboxylate.

Very preferably, said salt is a zirconium sulphate.

Advantageously, said tetravalent zirconium salt is introduced at a content of between 0.3 and 100, preferably between 0.5 and 50 millimoles per gram of polymer present in said aqueous fluid and said alkaline carboxylate is introduced at a content of between 3 and 300, preferably between 5 and 100 millimoles per gram of polymer present in said aqueous fluid.

In one embodiment, said aqueous fluid is brought into contact with said at least one tetravalent zirconium salt, then with said alkaline carboxylate.

In another embodiment, said aqueous fluid is brought into contact with said alkaline carboxylate, then with said at least one tetravalent zirconium salt.

In a third embodiment, said aqueous fluid is brought into contact with said at least one tetravalent zirconium salt and with said alkaline carboxylate simultaneously.

Can be introduced and dissolved simultaneously in the aqueous fluid containing the polymer said tetravalent zirconium salt and said alkaline carboxylate.

It is also possible to introduce and solubilize simultaneously in the aqueous fluid containing the polymer a previously prepared mixture, optionally in aqueous solution, of said tetravalent zirconium salt and of said alkaline carboxylate.

Advantageously, the temperature of the contacting step is between 5° C. and 90° C., preferably between 10° C. and 80° C., very preferably the temperature is room temperature.

Advantageously, the contact time corresponding to the duration of the contacting step between said aqueous fluid, said zirconium salt and said alkaline carboxylate is between 15 seconds and 1 hour, preferably between 30 seconds and 10 minutes.

Said aqueous fluid may be produced water from enhanced oil recovery, said produced water comprising a continuous aqueous phase containing said water-soluble polymer and an organic phase dispersed in said continuous aqueous phase.

The concentration of said polymer in said produced water can be between 1 ppm and 1000 ppm.

The dispersed organic phase may be crude oil, with a concentration of said crude oil in said produced water preferably between 1 and 900 ppm.

The invention also relates to a method for enhanced recovery of crude oil contained in a geological reservoir, in which:
- Injecting into said reservoir a flushing fluid comprising at least one water-soluble polymer so as to displace said crude oil towards at least one producing well, said water-soluble polymer carrying carboxylate or sulphonate functions in the aqueous phase;
- an effluent comprising the major part of the crude oil is collected by said producing well;
- an aqueous fluid called produced water comprising a continuous aqueous phase comprising traces of said polymer and an organic phase consisting of droplets of crude oil dispersed in said aqueous phase is recovered at the surface of the producing well;
- Said produced water is treated by means of the treatment method according to any one of the variants described.

The Applicant has discovered that it is possible to reduce or eliminate or cancel the viscosifying effect provided by the polymers used in the fluids formulated to improve enhanced oil recovery, in particular polymers of the HPAM type under the successive or simultaneous action of two reagent families.

The first family of reagents corresponds to the family of tetravalent zirconium salts.

The second family of reagents corresponds to certain alkaline carboxylates, in particular alkaline citrates or alkaline propionates.

The Applicant has surprisingly discovered that said polymer becomes insoluble in aqueous fluid by reaction with the tetravalent zirconium salt and is in the form of a gel or a precipitate, then by reaction with certain alkaline carboxylates, the gel or the precipitate is dissolved in the medium. The medium obtained then has a reduced viscosity or equal to or close to that of the aqueous fluid without the presence of the viscosifying polymer, which indicates that the viscosifying effect of said polymer has been reduced, even eliminated or canceled although it is still present. and soluble in the medium.

The Applicant has discovered, surprisingly, that said polymer in solution with certain alkaline carboxylates becomes, by reaction with the tetravalent zirconium salt, temporarily insoluble in the aqueous fluid and is in the form of a gel or a precipitate which is rapidly dissolved in the medium, and that the medium obtained then has a reduced viscosity or equal to/or close to that of the aqueous fluid without the presence of the viscosifying polymer, which indicates that the viscosifying effect of the said polymer has been reduced or eliminated/cancelled although it is always present and soluble in the medium.

The Applicant has discovered, surprisingly, that said polymer in solution can also be treated with a mixture of a tetravalent zirconium salt and certain alkaline carboxylates and that the medium obtained then has a reduced viscosity or equal to or close to that of the fluid aqueous without the presence of the viscosifying polymer, which indicates that the viscosifying effect of said polymer has been reduced or eliminated/cancelled although it is still present and soluble in the medium.

The method according to the invention consists in reducing, even eliminating, or canceling the effect of a viscosifying polymer of the HPAM type, dissolved in an aqueous solution: by bringing said aqueous solution into contact with a tetravalent zirconium salt, which causes the insolubilization of the polymer, then by introducing into the medium in a second step (and preferably in the same equipment, without having to transfer the medium from one equipment to another) certain alkaline carboxylates, in particular alkaline citrates or alkaline propionates, which resolubilizes the polymer.

At the end of the succession of the two steps, a solution is obtained whose viscosity is reduced or equal to or close to that of the aqueous fluid without the presence of the viscosifying polymer, which indicates that the viscosifying effect of the polymer has been reduced, even suppressed or canceled although it is still present and soluble in the medium.

When performing only the first step mentioned, i.e. the reaction between the polymer solution and the zirconium salt, the polymer precipitates. It may then be difficult to separate it from the aqueous solution.

The successive combination of the two steps makes it possible to reduce or eliminate or cancel the effect of a viscosifying polymer of the HPAM type, dissolved in an aqueous solution. The invention can be applied to all polymers containing functions allowing the creation of bonds between the zirconium salts and the polymer, in particular the carboxylate functions or the sulphonate functions.

The Applicant has also discovered that the order of the previous steps can be reversed, that is to say that the second step described above can be carried out followed by the first step described above. In this case, the method according to the invention consists in reducing or eliminating or canceling the effect of a viscosifying polymer of the HPAM type, dissolved in an aqueous solution by introducing and dissolving in the aqueous solution containing the polymer certain alkaline carboxylates , in particular alkaline citrates or alkaline propionates, then introducing into the medium in a second stage (and preferably in the same equipment, without having to transfer the medium from one equipment to another) a salt of tetravalent zirconium.

At the end of the succession of these two steps, a solution is obtained whose viscosity is reduced or equal to or close to that of the aqueous fluid without the presence of the viscosifying polymer, which indicates that the viscosifying effect of the polymer has been reduced. or suppressed or canceled although still present and soluble in the medium.

The Applicant has also discovered that it is possible to bring the two reagents into contact in a single step by combining the two steps previously described. In this case, the method according to the invention consists in reducing or eliminating or canceling the effect of a viscosifying polymer of the HPAM type, dissolved in an aqueous solution:

-Either by introducing and dissolving simultaneously in the aqueous solution containing the polymer a salt of tetravalent zirconium as well as certain alkaline carboxylates, in particular alkaline citrates or alkaline propionates.

-Either by introducing and dissolving simultaneously in the aqueous solution containing the polymer a previously prepared mixture, optionally in an aqueous solution, of a salt of tetravalent zirconium and of certain alkaline carboxylates, in particular alkaline citrates or alkaline propionates.

At the end of the simultaneous contact with the two reagents, a solution is obtained whose viscosity is reduced or equal to or close to that of the aqueous fluid without the presence of the viscosifying polymer, which indicates that the viscosifying effect of the polymer has been reduced or suppressed or canceled although it is still present and soluble in the medium.

Throughout the specification, salts or complexes of zirconium will be referred to as "zirconium salts".

The zirconium salt can be chosen from zirconium sulphate, zirconium nitrate, zirconium carbonate, zirconium phosphate, certain carboxylates such as zirconium lactate. Preferably, the zirconium salt will be zirconium sulphate.

The content of said zirconium salt in aqueous solution is advantageously between 50 and 5000 ppm, and preferably between 50 and 1000 ppm.

The alkaline carboxylates are chosen from alkaline citrates and alkaline propionates, preferably from sodium citrate (also called trisodium citrate) and sodium propionate.

Said tetravalent zirconium salt is advantageously introduced at a content comprised between 0.3 to 100, preferably 0.5 to 50 millimoles per gram of polymer present in solution in said aqueous fluid and said alkaline carboxylate is advantageously introduced at a content comprised between 3 and 300 millimoles, preferably between 5 and 100 millimoles per gram of polymer present in solution in said aqueous fluid.

The temperature of the contacting step is generally between 5° C. and 90° C., preferably between 10° C. and 80° C., very preferably the temperature is room temperature. The contact time corresponding to the duration of the contacting step between said aqueous fluid, said zirconium salt and said alkaline carboxylate is advantageously between 15 seconds and 1 hour, preferably between 30 seconds and 10 minutes.

An example of application of the treatment process is the treatment of aqueous fluids from enhanced oil recovery, said fluids frequently containing water-soluble polymers carrying carboxylate or sulphonate functions, of the partially hydrolyzed HPAM polyacrylamide type.

In one embodiment, said aqueous fluid is produced water from enhanced oil recovery, said produced water comprising a continuous aqueous phase containing said water-soluble polymer and an organic phase dispersed in said continuous aqueous phase.

Generally, the concentration of said polymer in said produced water is between 1 ppm and 1000 ppm.

Advantageously, the dispersed organic phase is crude oil, with a concentration of said crude oil in said produced water preferably between 1 and 900 ppm.

Example 1

In 50.00 g of an aqueous solution containing 500 ppm of a viscosifying polymer, of partially hydrolyzed acrylamide copolymer type, also called HPAM, with a molar mass of 6 MDa, 25 mg of sulphate are introduced with stirring and at ambient temperature. of zirconium Zr(SO ₄ ) _{2 .4} H ₂ O. The immediate appearance of a white gel is observed which is the product of the reaction between the polymer and the zirconium salt. 131 mg of trisodium citrate of molecular formula C ₆ H ₅ O ₇ Na _{3 .2} H ₂ O are then introduced into the medium, with stirring and at room temperature. The medium becomes clear and colorless after 3 minutes.

Example 2

Into 50.00 g of an aqueous solution containing 500 ppm of a viscosifying polymer, of the HPAM copolymer type, with a molar mass of 6 MDa, 50 mg of zirconium sulphate Zr(SO ₄ ) ₂ are introduced with stirring and at room temperature, ₄ H ₂ O. The immediate appearance of a white gel is observed, which is the product of the reaction between the polymer and the zirconium salt. 186 mg of trisodium citrate of molecular formula C ₆ H ₅ O ₇ Na _{3 .2} H ₂ O are then introduced into the medium, with stirring and at room temperature. The medium becomes clear and colorless after 3 minutes.

Example 3

300 mg of a solution of zirconium sulphate Zr( SO ₄ ) _{2 .4} H ₂ O at 5.0% by mass. The immediate appearance of a white gel is observed, which is the product of the reaction between the polymer and the zirconium salt. 251 mg of sodium propionate are then introduced into the medium with stirring and at ambient temperature. The medium becomes clear colorless after 8 minutes.

Example 4

100 mg of trisodium citrate of molecular formula C₆H₅O₇N / A₃,₂H₂O. 300 mg of an aqueous solution of zirconium sulphate Zr(SO₄)₂,₄H₂O at 2.5% by mass. A slight white haze appears which disappears after a few minutes.

Example 5

Into 20.00 g of an aqueous solution containing 500 ppm of a viscosifying polymer, of the HPAM copolymer type, with a molar mass of 6 MDa, a solution previously prepared by mixing 20 mg of zirconium sulphate Zr( SO ₄ ) _2.4 H ₂ O and 85 mg of trisodium citrate _of molecular formula C ₆ H ₅ O ₇ Na _3.2 H ₂ O in 2.00 g _of water. No presence of gel or precipitate is observed.

Example 6 (comparative)

In 20.00 g of an aqueous solution containing 500 ppm of a viscosifying polymer, of the HPAM copolymer type, with a molar mass of 6 MDa, 20 mg of zirconium sulphate Zr(SO ₄ ) ₂ are introduced with stirring and at room temperature, ₄ H ₂ O. The presence of a white gel is observed.

On each of the samples from Examples 1 to 6, as well as on a reference sample composed of an aqueous solution containing 500 ppm of the same viscosifying polymer, a viscosity measurement was carried out using a rotational rheometer (DHR3 of TA Instruments). A double cylinder type geometry is used. A logarithmic sweep in flow is performed between 1 and 200s ^-1 . The values are measured at 10s ^-1 . The measured values are given in the following table 1. On the sample from Example 6, no viscosity measurement could be made.

Sample taken from the example Viscosity (m.Pa.s) 1 1.3 2 1.7 3 1.8 4 1.9 5 3.8 6 n/a Reference 51.0

These results illustrate the effectiveness of the treatment method according to the invention.

Examples 1 and 2 illustrate the effectiveness of the treatment involving successively tetravalent zirconium salt and trisodium citrate.

Example 3 illustrates the effectiveness of the treatment involving successively tetravalent zirconium salt and sodium propionate.

Example 4 illustrates the effectiveness of the treatment involving successively trisodium citrate and tetravalent zirconium salt.

Example 5 illustrates the effectiveness of the treatment involving the simultaneous use of trisodium citrate and tetravalent zirconium salt.

Comparative example 6 shows that the addition of zirconium sulphate to a polymer solution not followed by the addition of trisodium citrate does not make it possible to obtain a clear single-phase solution.

It is therefore the addition of the two families of reagents whatever the order of addition that causes the best reduction in the effect of the viscosifying polymer.

The reduction in the viscosity of the solution thus allows, in a context of enhanced oil recovery, a better separation between water and crude oil with which water is frequently co-produced.

Claims (16)

Process for treating an aqueous fluid comprising at least one water-soluble polymer bearing carboxylate or sulphonate functions in the aqueous phase, said process comprising a step of bringing said aqueous fluid into contact with at least one tetravalent zirconium salt and at least one alkaline carboxylate selected from alkali citrates or alkali propionates; for reducing the viscosity of said aqueous fluid, in order to produce an aqueous fluid having a lowered viscosity, preferably close to that of water. Treatment process according to Claim 1, in which the said water-soluble polymer is chosen from: partially hydrolyzed polyacrylamides (HPAM), or partially hydrolyzed polymers comprising units of the N-vinylpyrrolidone or acrylamido-tertiobutylsulfonate (ATBS) type. Treatment process according to one of Claims 1 to 2, in which the said zirconium salt is chosen from zirconium sulphate, nitrate, carbonate, phosphate and carboxylate. A method of treatment according to claim 3 wherein said salt is zirconium sulphate. Treatment process according to one of Claims 1 to 4, in which the said tetravalent zirconium salt is introduced at a content of between 0.3 and 100 millimoles, preferably 0.5 and 50 millimoles, per gram of polymer present in the said aqueous fluid. and said alkaline carboxylate is introduced at a content of between 3 and 300 millimoles, preferably between 5 and 100 millimoles per gram of polymer present in said aqueous fluid. Treatment process according to one of Claims 1 to 5, in which the said aqueous fluid is brought into contact with the said at least one tetravalent zirconium salt, then with the said alkaline carboxylate. Treatment method according to one of Claims 1 to 5, in which the said aqueous fluid is brought into contact with the said alkaline carboxylate, then with the said at least one salt of tetravalent zirconium. Treatment method according to one of Claims 1 to 5, in which the said aqueous fluid is brought into contact with the said at least one tetravalent zirconium salt and with the said alkaline carboxylate simultaneously. Treatment process according to Claim 8, in which the said tetravalent zirconium salt and the said alkaline carboxylate are introduced and dissolved simultaneously in the aqueous fluid containing the polymer. Treatment process according to Claim 8, in which a previously prepared mixture, optionally in aqueous solution, of said tetravalent zirconium salt and of said alkaline carboxylate is introduced and dissolved simultaneously in the aqueous fluid containing the polymer. Treatment process according to one of the preceding claims, in which the temperature of the contacting step is between 5°C and 90°C, preferably between 10°C and 80°C, very preferably the temperature is the ambient temperature. Treatment process according to one of the preceding claims, in which the contact time corresponding to the duration of the step of bringing said aqueous fluid, said zirconium salt and said alkaline carboxylate into contact is between 15 seconds and 1 hour, preferably between 30 seconds and 10 minutes. Treatment process according to one of the preceding claims, in which the said aqueous fluid is produced water resulting from enhanced oil recovery, the said produced water comprising a continuous aqueous phase containing the said water-soluble polymer and an organic phase dispersed in the said aqueous phase. keep on going. A treatment method according to claim 13 wherein the concentration of said polymer in said produced water is between 1 ppm and 1000 ppm. Treatment process according to one of Claims 13 or 14, in which the dispersed organic phase is crude oil, with a concentration of said crude oil in said produced water preferably between 1 and 900 ppm. Process for the enhanced recovery of crude oil contained in a geological reservoir in which:
- Injecting into said reservoir a flushing fluid comprising at least one water-soluble polymer so as to displace said crude oil towards at least one producing well, said water-soluble polymer carrying carboxylate or sulphonate functions in the aqueous phase;
- an effluent comprising the major part of the crude oil is collected by said producing well;
- an aqueous fluid called produced water comprising a continuous aqueous phase comprising traces of said polymer and an organic phase consisting of droplets of crude oil dispersed in said aqueous phase is recovered at the surface of the producing well;
- said produced water is treated by means of the treatment method according to one of claims 1 to 15.