RU2200831C1 - Bottomhole formation zone treatment composition - Google Patents

Abstract

FIELD: oil and gas production. SUBSTANCE: composition with increased structural viscosity, increased thermal stability, and better wetting capacity, enhancing waterproofness of formation rock and increasing adhesion of composition to rock, contains 2.0-10.0 wt.% mixture of water- and oil-soluble surfactants, 0.5-5.0 wt.% oil emulsion of anionic-type polymer, and water, the balance, and can additionally contain hydrocarbon in amounts between 5.0-20.0 wt.%. EFFECT: engaged low-drainable or nondrainaible oil-saturated part of formation due to that composition with increased rheological properties reduces permeability of formations and prevents water inflow in wells thereby increasing oil recovery and reducing water content in produced oil. 2 cl, 4 tbl, 4 ex

Description

 The invention relates to the oil industry, in particular to compositions for treating a bottomhole formation zone.

 It is known to use a surfactant composition containing, in wt.%: Hydrolyzed polyacrylamide (PAA) 0.0016-0.30, nonionic surfactant (nonionic surfactant) 0.033-0.0, water the rest (as.with. 1544958, 5 E 21B 43/22, publ. 23.02.90. Bull. 7).

 According to the known composition, in the interaction of PAA with hydroxyethylated alkyl phenol, a complex of several PAA molecules is formed, crosslinked by the interaction of the amide group of PAA with a lone pair of oxygen electron of the polyoxyethylene group of nonionic surfactants.

 However, the resulting complex has a low molecular weight, since the measured relaxation time is one of the rheological properties of aqueous polymer solutions, which makes it possible to evaluate, in particular, the interaction of polymer molecules with hydroxyethylated alkyl phenol molecules, has a low value that does not exceed 1.85-2.0 .

 It is known to use a surfactant composition containing, in wt.%: A mixture of surfactants 0.25-2.0: PAA 0.012-0.10 and 6-19% hydrochloric acid (as.with. 1641984, 5, E 21 B 43/22, publ. 15.04.91. Bull. 4).

 It is known that upon dissolution of ACAS, nonionic surfactants and PAA in hydrochloric acid, sulfonic acid, an oxonium compound and PAA containing units of acrylic acid are formed. As a result of their interaction with each other due to hydrogen bonding, high molecular weight polyacrylamide complexes are formed.

 However, the composition, due to the low concentration of PAA and surfactant, creates insufficient resistance to the injection of both the composition itself and the subsequent water due to the low oil-displacing properties of the composition.

 Closest to the proposed is a composition containing, wt.%: Anionic oil-soluble surfactant 2.0-10.0; non-ionic surface-active surfactants 0.1-2.5 and water (a positive decision to grant a patent according to the application 96123262/03/029846 dated 04/01/98, "Composition for processing the bottom-hole formation zone", the authors A. Ryskin, Lysenko T.M.).

 This composition is a reverse emulsion, which has good oil-displacing properties, has a high structural viscosity, but low thermal stability at a high temperature of the reservoir. The prototype data on the thermal stability of the emulsion is not, and our studies have shown that the emulsion of the prototype is destroyed within 1-2 days.

 The aim of the invention is to increase the structural viscosity and increase the thermal stability of the composition, as well as a change in the wettability, namely, hydrophobization of the formation rock and improvement of the composition adhesion to the rock, which will ensure the inclusion of a slightly drained or non-drained oil-saturated part of the formation, since possessing enhanced rheological non-Newtonian properties, the composition will create effective resistance to injection of both the composition itself and, subsequently, water in a highly permeable well-drained part of the bottom-hole formation zone.

The problem is solved in that the composition for processing the bottom-hole zone of the formation containing a mixture of surfactants surfactants and water, characterized in that it contains as surfactants water-, oil-, water-oil-soluble surfactants and, in addition, an anionic type polymer emulsion in oil at the following ratio of components, wt.%:
a mixture of these surfactants - 2.0 - 10.0
the specified emulsion is 0.5 to 5.0
water - the rest
2. The composition according to p. 1, characterized in that it additionally contains hydrocarbon in an amount of 5.0 -20.0% wt.

 Mixtures of surface-active surfactants are used as a surfactant: first of all, mixtures of oil-soluble and non-ionic surfactants in the form of ready-made compositions produced by different companies, for example emulsifier Sinol EM, manufactured by ZAO Bursintez in accordance with TU 2413-048-48482528- 98, NZN neftenol emulsifier manufactured at Khimeko-Gang CJSC in accordance with TU 2483-012-17197708-93, as well as Vikor 1 reagents (TU 39-13-13 88 rev. 102), and VIKOR 2, manufactured according to TU 6-01-0203314-110-90 at CJSC Experimental Neftekhim Plant Ufa and other finished mixed compositions.

 In the absence of a ready-made (manufactured) composition, the mixture is prepared on the basis of oil-soluble surfactants, for example, petrochemicals of the petrochemicals 1.3 brands produced in accordance with TU 2415-001-00151816-94 at the Ufa Experimental Plant Neftekhim CJSC; Neftenol NZ, produced by AOZT "HIMEKO-GANG" according to TU 2483-007-17197708-93, emulsified by TU 6-14-1035-79, oil-soluble petroleum sulfonates with MM = 600-700; synthetic alkylaryl sulfonates, for example, alkylnaphthalene sulfonic acid and other oil-soluble surfactants, and nonionic surfactants.

As nonionic surfactants, an oil-soluble nonionic surfactant is used, for example nonylphenol, ethoxylated with six moles of ethylene oxide (AF ₉ -6), as well as a water-soluble nonionic surfactant, for example, nonylphenol, ethoxylated with 12 moles of ethylene oxide (AF ₉ -12), or its commercial form -3,4 or water-soluble surfactants, for example ML-80, containing nonionic surfactants - 12% or ML-81B (winter version of ML-80).

 In addition, as a surfactant for the treatment of bottom-hole zones, mixtures of water-oil-soluble surfactants are used in the form of ready-made compositions, for example, detergents ML-80 or ML-81B (winter version of ML-80) containing a mixture of a water-soluble anionic surfactant (23-28% ) and non-ionic oil-soluble surfactants (12 wt.%) produced in accordance with TU 2481-007-48482528-99 at ZAO NPF Bursintez, neftenol B - a composition of water-soluble and water-oil-soluble surfactants: sulfoethoxylates, nonionic surfactants and high molecular weight oil sulfonates, "X MEKO-GANG "Neftenol-001.V - products co-processing sour petroleum tars (waste products of sulfuric acid and oleum purification mineral oil) and ethoxylated alkylphenol grade OP-10.

As an anionic type polymer emulsion in oil, polyacrylamide emulsions (PAA) with MM = 0.5-18 • 10 ⁶ and a degree of hydrolysis of 5-20%, carboxymethyl cellulose emulsions (CMC) with a degree of polymerization of SP = 350-1200 and degree of substitution according to carboxyl groups C3 = 80-90, ethers of hydroxyethyl cellulose (OEC) and other cellulose ethers, emulsions of polymethacrylic acid (PMAA), as well as emulsions of other anionic type polymers in oil.

 Emulsions of polymers in oil are produced by some companies, for example, Allied Colloids (England) or Rhone-Pouleng (France), as well as other companies.

 The emulsion of the polymer in oil has a concentration of 30-50 wt.% And form with water, with water-soluble surfactants, with water-oil-soluble surfactants emulsions.

 Comparative analysis with the prototype allows us to conclude that the proposed composition is different from the known introduction of an additional component - an anionic type polymer emulsion in oil.

 In the proposed compositions, the structural viscosity and thermal stability of the emulsions increases due to the introduction of the polymer emulsion in the oil.

 It is known that for the formation and stabilization of highly stable emulsions it is necessary that the adsorption layers and the solvate shells associated with them have a sufficiently high structural viscosity. The high structural viscosity of the emulsions is ensured by introducing the polymer into the oil, which has a sufficiently high viscosity and forms gel-like adsorption layers at the phase boundary.

 Due to the formation of colloidal adsorption layers, the introduced polymer plays the role of a strong stabilizer of the stability of emulsions, as well as the viscosity in the resulting emulsions. Obtaining stable emulsions is due to the formation of a highly viscous film on the interface, the existence of this film is manifested in the increased viscosity of the surface layer of the dispersed phase.

 The introduction of a polymer emulsion in oil in small concentrations does not noticeably change the viscosity in the bulk of the medium, but in the adsorption layers its concentration is much higher and therefore such layers have an increased structural viscosity, and hence strength.

 Since the introduction of a polymer emulsion in oil increases the strength of structurally viscous (gel-like) adsorption layers, when the particles of the dispersed phase approach each other (collide), for example, with stirring or under high temperature conditions, the highly viscous medium layer does not have time to squeeze out. Adsorption layers with elasticity and mechanical strength resist significant destructive forces.

With an increase in the concentration of polymer introduced into the composition, its stabilizing effect increases, which makes it possible to obtain stable emulsions of high viscosity and thermal stability under conditions of high formation temperature (100 ^° C).

 In addition, the surfactant contained in the proposed composition gives it surface-active properties; when it is injected into water-logged oil wells, the surface of the formation rock changes its wettability, namely, it is hydrophobized due to the hydrophobic chains of PAA or surfactant. When hydrophobizing the surface of the rock, the adhesion of the composition to the rock improves, which contributes to its better retention in the formation.

 The proposed composition containing a surfactant, an emulsion of the polymer in oil and water, due to the improvement of its rheological properties and thermal stability, will allow its effective use in highly flooded oil reservoirs in contact with highly mineralized waters to reduce the permeability of highly permeable reservoir layers.

 The inventive composition may contain a hydrocarbon (usually oil) to control the viscosity of the prepared compositions. In addition, the oil contains a number of natural emulsifying additives (emulsifiers), which further stabilize the proposed emulsion.

 The study of the structural viscosity of the proposed and claimed compositions was carried out both in the presence of oil, and without it.

 The structural viscosity of the compositions is determined using a RPE-1 M polymer viscometer, an immersion-type viscometer at various temperatures with cylinder-to-cylinder sensing elements, and the viscous and rheological properties are evaluated by torque in terms of viscosity.

 The following examples illustrate the properties of known and claimed compositions.

 Example 1. For the preparation of the claimed compositions as a surfactant, a mixture of an oil-soluble surfactant and a nonionic surfactant is used in the form of a finished composition manufactured by ZAO Bursintez in accordance with TU 2413-048-48482528-98, for example, Sinol EM emulsifier.

To prepare the inventive composition, a PAA emulsion with MM = 15 • 10 ⁶ and a degree of hydrolysis of 15% (under the code P-1), or an emulsion with MM = 5 • 10 ⁶ and a degree of hydrolysis of 5% (under the code P- 2) or an emulsion of carboxymethyl cellulose of the KMTs-600 brand (under the code P-3), then slightly mineralized water with a salt content of 15.9 g / l is metered in portions with stirring.

 The prototype compositions are prepared by mixing an emulsifier Sinola EM with slightly mineralized water 15.9, g / l.

 The results of measurements of the structural viscosity of the claimed compositions and compositions of the prototypes are presented in table. 1.

 The results of viscosity measurements show that with the introduction of the polymer emulsion in oil, the viscosity of the emulsions increases 1.5-3 times or more (compare the claimed compounds with the prototype compositions in table 1), and the thermal stability of the emulsions increases many times in comparison with the compositions- prototypes (the claimed compositions and prototype compositions are presented in table 1).

 From the data table. 1 it can be seen that the optimal concentrations of Sinol EM are 2.0-10.0 wt.%, The emulsion of the polymer 0.5-5.0 wt.%, Since when the content of Sinol EM is less than 2 wt.% And the emulsion of the polymer is less than 0, 5 wt.% Emulsions exfoliate, and with an increase in the concentration of Sinol EM more than 10 wt. % and polymer emulsion more than 5.0 wt.% decreases the viscosity of the composition.

 The results of viscosity and thermal stability measurements show that with the introduction of a polymer emulsion in oil into the composition, not only the viscosity of the emulsion increases, but also the thermal stability of the composition increases sharply.

Example 2. In the absence of ready-made (manufactured) mixed compositions of an oil-soluble surfactant with a non-ionic surfactant, surface-active mixtures (based on the prototype) are prepared on the basis of an oil-soluble surfactant, for example, a petrochemical-3 composition and a non-ionic oil-soluble surfactant, for example nonylphenol, ethoxylated with six moles of oxide ethylene (AF ₉ -6) or nonylphenol, ethoxylated with 12 moles of ethylene oxide (AF ₉ -12).

To prepare the claimed composition in the prepared above prototype above-mentioned surface-active mixture, an PAA emulsion in oil with MM = 15 • 10 ⁶ and a degree of hydrolysis of 15% (under code P-1) or PAA emulsion in oil with MM = 5 • 10 ⁶ are additionally introduced and a degree of hydrolysis of 5% (under the code P-2), or an emulsion of carboxymethyl cellulose in KMC-600 brand oil (under the code P-3), then slightly mineralized water with a salt content of 15.9 g / l is metered in portions with stirring.

Prototype compositions are prepared by mixing the petrochemical-3 with nonionic surfactants AF ₉ -6 or AF ₉ -12, and then low-mineralized water with a salt content of 15.9 g / l is dosed in portions.

 The results of measurements of the structural viscosity of the claimed compositions and compositions of the prototypes are presented in table.2.

 The results of viscosity measurements show that when a polymer emulsion is introduced into the composition, the viscosity of the emulsions increases 1.5-3 times or more (compare the claimed compositions with the prototype compositions in Table 2), and the thermal stability of the emulsions increases many times in comparison with the compositions- prototypes (the claimed compositions and compositions of the prototypes are presented in table 2).

 From the data of table 2 it is seen that the optimal concentrations of oil-soluble surfactants are 1.9-7.5 wt.%, 0.1-2.5 wt.% Non-ionic surfactants, polymer emulsions 0.5-5.0 wt.%, since when the content of the components is less than the specified limits, the emulsions are quickly stratified, and with an increase in the concentration above the specified limits of the components, the viscosity of the composition decreases.

 The results of table 2 show that with the introduction of a polymer emulsion in oil into the composition, not only the viscosity of the emulsion increases, but also the thermal stability of the composition increases (compare the viscosity and thermal stability of the claimed compositions and prototype compositions).

Example 3. For the preparation of compositions as a water-oil-soluble surfactant, a ML-80 brand detergent is used, as a polymer emulsion, a PAA emulsion in oil with MM = 15 • 10 ⁶ and a degree of hydrolysis of 15% (under code P-1) or PAA emulsion in oil with MM = 5 • 10 ⁶ and a degree of hydrolysis of 5% (under code P-2), or an emulsion of carboxymethyl cellulose in oil grade KMTS-600 (under code P-3).

 ML-80 brand detergent is mixed with the polymer emulsion in oil, then fresh water with a salt content of 0.32 g / l is dosed in portions.

 Fresh water is used to completely dissolve water-soluble surfactants and improve the conditions for their interaction with the components of the mixture.

 The prototype compositions are prepared by mixing a water-soluble surfactant brand ML-80 with fresh water with a salt content of 0.32 g / l.

 The results of viscosity measurements show that when a polymer is introduced into the emulsion, the viscosity of the emulsions increases tens of thousands of times compared with the prototype compositions (compare the claimed compositions with the prototype compositions in Table 3) and 3-5 times as compared with the comparison compositions, and the thermal stability of emulsions increases many times in comparison with the compositions of the prototypes and compositions of comparison (the claimed compositions, compositions of the prototypes and compositions of comparison are presented in table 3).

 From the data of table 3 it is seen that the optimal concentrations of water-oil-soluble surfactants are 2.0-10.0 wt.%, The emulsion of the polymer in oil 0.5-5.0 wt. %, since when the content of the components is less than the specified limits, the emulsions are quickly delaminated, and with an increase in the concentration above the specified limits of the components, the viscosity of the composition decreases.

 The results of table 3 show that with the introduction of the polymer emulsion in oil into the composition, not only the viscosity of the emulsion increases, but also the thermal stability of the composition increases (compare the viscosity and thermal stability of the claimed compositions and prototype compositions).

 Example 4. The inventive compositions may additionally contain hydrocarbon in an amount of 5.0-20 wt. % As a hydrocarbon, oil, stable gasoline, nefras and other hydrocarbons are most often used.

 Hydrocarbon is introduced to regulate the viscosity of emulsions, as well as to increase its thermal stability.

 The research data are summarized in table 4. The research results show that when a hydrocarbon is introduced into the composition, its viscosity decreases without decreasing the thermal stability of the composition.

 The use of the proposed composition for oil production will allow, by improving the rheological properties, hydrophobization of the surface in waterlogged oil reservoirs and increasing the thermal stability of the composition, to reduce the permeability of the formations and to isolate the influx of water into the wells, increase oil production and reduce the water content in the produced oil.

 The technology for using the proposed compositions is simple and consists in pumping them into the formation to reduce well injectivity by 30-50%, selling the composition from the wellbore to the formation with water or oil, holding in the formation for 12-24 hours and putting the well into operation for oil wells or injection of water for injection wells.

Claims (1)

1. The composition for processing the bottom-hole zone of the formation, containing a mixture of surfactants surfactants and water, characterized in that it contains as surfactants water-, oil-, water-oil-soluble surfactants and, in addition, an anionic type polymer emulsion in oil in the following ratio of components, wt. %:
A mixture of these surfactants - 2.0 - 10.0
The specified emulsion is 0.5 to 5.0
Water - Else
2. The composition according to p. 1, characterized in that it further comprises a hydrocarbon in an amount of 5.0-20.0 wt. %

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