RU2064571C1 - Gel-forming compound for shutoff of water inflow and increase of oil recovery - Google Patents

Abstract

FIELD: oil producing industry; shutoff of water inflow and equalization of formation permeability profile. SUBSTANCE: the invention offers gel-forming compound based on acrylic polymer for increase of oil recovery from nonuniform permeable formations. Acrylic polymer is used in form of wastes of polyacrylonitrile fibers or fabrics hydrolyzed in alkali. It also includes sodium silicate and additionally calcium chloride with the following amounts of components, mas.%: hydrolyzed in alkali wastes of fibers and fabrics of polyacrylonitrile 1.0-5.0; sodium silicate 0.3-3.0; calcium chloride 2.0-5.0; the balance, water-. EFFECT: higher efficiency. 3 tbl

Description

 The invention relates to the oil industry, in particular to sedimentary and gel-forming polymer compositions for increasing oil recovery of heterogeneous permeability reservoirs by leveling the permeability profile of injection wells, selective isolation of water inflow into production wells and increasing the coverage of the reservoirs by water flooding.

 Sedimentary and gel-forming compositions are known for the selective isolation of formation waters based on aqueous solutions of polymers of a number of acrylonitrile [1] in which polyvalent metal ions (calcium, magnesium) are used as a precipitating agent (crosslinker). As a source of calcium ions in the known compositions used highly saline formation water or a concentrated aqueous solution of calcium chloride.

 A disadvantage of the known compositions is low efficiency at elevated temperature of the reservoir, which is associated with a decrease in the volume of gel-like sediment under the influence of temperature. In addition, the disadvantage of the known compositions is the reverse removal of the formed sediment with the production of wells, which is associated with weak chemical-physical interaction of the sediment with the rock of the productive formations.

 The closest to the proposed technical essence and the achieved results is an aqueous composition based on high molecular weight polyacrylamides (PAA) and alkali metal silicates, in particular sodium silicate [2] (prototype).

A disadvantage of the known composition is the lack of effectiveness associated with thermal and thermo-oxidative degradation of PAA and in conditions of increased in-situ temperature of 70-100 ^o C. As a result of thermal and thermo-oxidative degradation of PAA, there is a significant loss in the volume of the gel formed. In addition, due to the high cost of high molecular weight polyacrylamides, the use of a known composition is economically unprofitable.

The purpose of the invention is to increase the efficiency of the composition at elevated temperatures of the reservoir 60-120 ^o C and reduce the cost while expanding the resources of polymer raw materials.

This goal is achieved in that the sedimentary and gel-forming composition for leveling the injectivity profile of injection wells and selectively isolating water inflow into production wells containing acrylic polymer and sodium silicate as an acrylic polymer contains hydrolyzed wastes of polyacrylonitrile fiber or fabrics and additionally contains calcium chloride or mineralized water in the following ratio of components, wt.
Polyacrylonitrile fiber or tissue hydrolyzed in alkali 1.0-5.0
Sodium Silicate 0.33-3.0
Calcium Chloride 2.0-5.0
Water Else
Hydrolyzed in alkali wastes of fiber or polyacrylonitrile fabrics are produced by the Ufa PA Khimprom according to TU 49560-04-02-90, under the trade name Givpan. Physico-chemical indicators for the Givpan polymer are given in table. one.

The use of Givpan polymer as a stabilizer for clay drilling fluids is recommended [3] Analysis of patent and scientific literature on sedimentary and gel-forming polymer compositions used to increase oil production and reduce associated water withdrawal by leveling the injectivity profile of injection wells and selective isolation of water inflow into production wells wells, shows that alkali-hydrolyzed wastes of polyacrylonitrile fiber or tissues in combination with sodium silicate and calcium chloride have not been previously imenyalis. Therefore, the proposed composition differs from the known combination of three components, namely, hydrolyzed in alkali waste fiber or tissue polyacrylonitrile, sodium silicates and calcium chloride. It should be emphasized that the fundamental difference between the proposed Givpan polymer and the known acrylamide polymers is that it is alkaline hydrolyzed, non-recyclable, inexpensive and affordable waste of finished fibers or polyacrylonitrile fabrics that inevitably form at textile and sewing enterprises. Wastes of finished fibers or polyacrylonitrile fabrics contain aging stabilizers and chemically stable dyes, which leads to harsh temperature conditions for their alkaline hydrolysis of at least 90 ^o C. The result of such harsh temperature exposure at the production stage is the high thermal stability of the resulting water-soluble polymer and, accordingly, precipitation and gels formed during its interaction with the components of the composition. When the partial hydrolysis of high molecular weight polyacrylamide used in the known composition according to the prototype, the temperature effect does not exceed 40 ^o C. This determines the thermal degradation in it in conditions of elevated temperature levels typical of, for example, oil fields in Western Siberia.

 The combination of Givpan polymer with calcium chloride or calcium-containing mineralized water according to the technical solution [4] partially solves the problem of thermal stability of the formed gel-like precipitate, however, this analogue has a significant drawback - the removal of the formed precipitate with well products due to its weak physicochemical interaction with the rock of the reservoir. This significantly reduces the effectiveness of the known composition. The addition of sodium silicates to the composition according to the proposed technical solution eliminates this drawback, i.e., increases the interaction of the resulting gel-like sediment with the sandstone of the reservoir. The hypothesized mechanism of this phenomenon, according to the authors and the applicant, is that during the interaction of sodium silicates with calcium chloride in the presence of an excess of alkali contained in both the Givpan polymer and sodium silicates, silicon dioxide is formed that is capable of interacting with the formation of chemical communication with both the rock (sandstone) and macromolecules of the polymer with the formation of a three-dimensional polymer-organosilicon structure.

 As a result of such a physicochemical process, in which all components of the proposed composition are involved, an acrylic polymer, sodium silicate, calcium ions and an excess of alkali (caustic sodium), a synergistic effect is observed, leading to an increase in the gel-forming and water-insulating properties of the composition, especially thermal stability.

 Thus, the combined presence of sodium silicates and calcium chloride in the Givpan polymer composition allows us to solve the set goal of increasing the efficiency of the composition at elevated formation temperatures and reducing its cost while expanding the resources of polymer raw materials. Based on the foregoing, we can conclude that the proposed technical solution satisfies the requirements of "novelty", "inventive step" and "positive effect, implemented in practice."

 To experimentally verify the advantages of the proposed technical solution over the known composition under comparable conditions, experiments were conducted to evaluate the gel-forming properties of the composition (example 1, table 2) and studied the water-insulating properties on water-saturated models of formations (example 2, table 3).

 Example 1. The gel-forming ability of the composition.

 The gel-forming ability of the composition is evaluated by the following method.

In chemical tubes with a capacity of 20 cm ³ , 2.5 cm ³ of Givpan polymer solution is poured, according to the quality of TU 49560-04-02-90, with a content of the latter 0.10; 0.50, 1.00; 3.00; 5.00; 5.50 wt. add 2.5 cm ³ sodium silicate solution, corresponding in quality to GOST 13078-87, with a content of the latter 0.10; 0.50; 0.33; 1.00; 3.00; 3.50 wt. mix thoroughly, and then add 5 cm ³ solution of calcium chloride with a density of 1.04 g / cm ³ (concentration of 5 wt.). The contents of the tube are thoroughly mixed and left in an upright position for 1 h, after which the volume of the gel formed and the total volume of the solution are measured.

 The gel-forming ability of the composition is estimated by the ratio of the volume of the gel to the total volume of the solution (D). After 24 hours, the measurements are repeated.

To assess the thermal stability of the formed gels, tubes with the composition are placed in a thermostat and incubated for 24 hours at 80 ^o C, after which they evaluate D as described above. In parallel, experiments were conducted with the prototype composition, which includes PAA and sodium silicate (with the addition of a solution of calcium chloride) and with an analogue composition consisting of hydrolyzed polyacrylonitrile (hypane) and a solution of calcium chloride with a density of 1.18 g / cm ³ (concentration 20 wt.).

 The experimental results are given in table. 2.

 From the table. 2 shows that the proposed composition in its gel-forming properties exceeds the prototype and analogue: at a polymer concentration of 1% sodium silicate 0.33%, the gel occupies almost the entire volume of the solution (D 0.94), whereas the prototype composition at the same concentrations forms a gel whose volume fraction is 0.70. The composition based on the Gipan polymer (analog) has an even lower gelling ability: at a polymer concentration of 8% and a concentration of a solution of calcium chloride of 20%, the volume fraction of gel D is 0.60.

 The advantage of the proposed structure is manifested during heat treatment.

The degree of reduction in the volume of the gel after exposure for a day at 80 ^o C for the inventive gel does not exceed 10% whereas the proportion of the prototype composition this value reaches 50%
Example 2. Water-insulating properties of the composition on water-saturated reservoir models
The waterproofing properties of the proposed composition is determined on the disintegrated core material of the BS ₁₀ layer of the Yuzhno-Balykskoye field of Yuganskneftegaz JSC. After removal of oil and drying, the core material is crushed, selecting two sand fractions with sizes of sand grains in the range of 0.04-0.05 mm and 0.25-0.5 mm. The obtained fractions are thoroughly mixed in a ratio of 1: 1 and 100 g of sand material is filled into a glass column 0.8 mm long and 0.015 m in diameter, achieving uniform compaction by tapping the column with a stick. First, water is filtered through a model and water permeability is determined K. Water is filtered at a constant pressure of 1.0 m water. Art. Then, a polymer-silicate composition in the amount of 0.3 pore volume of the model is pumped into the model. To ensure mixing of the components directly in the porous medium, the polymer-silicate mixture and the CaCl ₂ solution are injected sequentially in separate sub-points. First, 0.3-0.6 pore volumes of a calcium chloride solution with a density of 1.02-1.40 g / cm ^{3 are} pumped in, then 0.3 pore volumes of a Givpan 1.0 polymer mixture are added; 1.5; 2.0; 5.0% concentration with sodium silicate solution 0.3-3.0 concentration (in the ratio of polymer: sodium silicate volumes equal to 3-1), then, to create an excess of calcium ions, the second sub-dose of calcium chloride solution is dosed, equal to 0.33 pore model volume.

где Q объемная скорость фильтрации жидкости, м³/с;
η вязкость фильтрующей воды, Па;
l длина модели, м;
F площадь поперечного сечения модели, м²;
DP давление столба жидкости на модель при фильтрации, Па. Поскольку кроме Q все остальные параметры для данной модели при фильтрации воды постоянные, то фактор остаточного сопротивления R_ост, отношение проницаемости по воде до и после воздействия будет равен:

Аналогично проводят эксперимент с известными составами по прототипу и аналогу.After completion of the injection of the components of the composition, the column is left to react for 24 hours. Then, water filtration is resumed and the K ₂ permeability is determined after exposure. Permeability is determined by the equation:

where Q is the volumetric rate of fluid filtration, m ³ / s;
η viscosity of filtering water, Pa;
l model length, m;
F the cross-sectional area of the model, m ² ;
DP is the liquid column pressure per model during filtration, Pa. Since, in addition to Q, all other parameters for this model are constant during water filtration, the residual resistance factor R _ost , the ratio of water permeability before and after exposure will be equal to:

Similarly, conduct an experiment with known compositions of the prototype and analogue.

 The results of filtration experiments on models with different permeability and concentration of composition components are given in table. 3.

 As can be seen from the data given in table. 3, the proposed composition on the water-insulating properties exceeds the prototype and analogue: at polymer concentrations, respectively 1.0 wt. and sodium silicate 1.0 wt. the concentration of calcium chloride in the proposed composition of 2.0 wt. the residual resistance factor is 1.15 for the proposed composition against 1.07 of the prototype (experiment 2 and 8, table. 3).

When exposed to the proposed composition with a concentration of Givpan 5.0 wt. sodium silicate 3.0 wt. and calcium chloride 5.0 wt. R _ost is equal to 100.0 (experiment 6, table. 3), whereas for the same concentration of components, but the absence of sodium silicate according to the formulation of the analogue, R _ost is 9.5. The data show that the proposed composition has an advantage over the known water-insulating properties.

 From examples 1 and 2 of the table. 2 and 3 it is seen that the optimal concentration limits of the polymer are in the range of 1-5 wt. and sodium silicate 0.3-3 wt. calcium chloride in the range from 2 to 5 wt%. When the concentration of reagents is lower than the lower claimed limit, the composition is ineffective due to insufficient water insulating effect, and increasing the concentration above the claimed limit is impractical due to the fact that the residual resistance factor is very large, i.e., filtering water after exposure has a fading character.

Claims (1)

 A gelling composition for isolating water inflows and increasing oil production from heterogeneous formations, including acrylic polymer, sodium silicate and water, characterized in that it additionally contains calcium chloride, and as an acrylic polymer givpan alkali hydrolyzed in the waste fiber or polyacrylonitrile fabrics in the following ratio of components wt. Hydrolyzed in alkali waste polyacrylonitrile fiber or tissue 1.0 5.0
Sodium Silicate 0.33-3.0
Calcium Chloride 2.0-5.0
Water Else

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