RU2377390C1 - Method of insulating flow of water into well - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to exploitation of oil-gas fields, combined with thick mass of fractured and fissured-cavernous water-saturated carbonate formations, particularly to methods of limiting water flow in producing wells and regulating input profile of a well. The method involves preparation and pumping into a layer an inert emulsion based on hydrocarbon dispersion medium and a dispersed phase in form of chemically modified dispersed silica. Additionally, a gel forming composition can be used as a dispersed phase, where the said gel forming composition used is a solution of carbamide in aluminium-containing industrial wastes. The modified dispersed silica used has specific weight ranging from 40 to 160 g/dm³ and specific surface area ranging from 140 to 380 m²/g in amount of 0.25-2.5 wt % of the entire mass of the emulsion, and the gel forming composition is taken in amount of 50-80% of the entire volume of the emulsion.

EFFECT: more efficient insulation of water inflow.

5 cl, 4 tbl

Description

The proposal relates to the development of oil and gas fields, composed of a thick stratum of fractured and fractured-cavernous water-saturated carbonate formations, in particular, to methods of limiting water inflow in producing wells and regulating the injectivity profile of injection wells.

A known method of developing an oil field, including the injection into the formation of a gel-forming composition (US Pat. RF No. 2120544, IPC ЕВВ 43/22, publ. BI No. 29 from 10/20/98). The gelling composition includes urea and an aqueous solution of aluminum salts. Before injection, urea is dissolved in liquid aluminum-containing industrial waste with an aluminum salt content of 8.0 to 25.0 wt.% In the following proportions, wt.%: Liquid aluminum-containing waste - 20.0-75.0; carbamide - 15.0-50.0; water is the rest.

The advantage of this method is that by increasing the coverage of the formation by the impact, the oil recovery of the field increases.

The disadvantage of this method is the low efficiency of water insulation due to the low technological and operational properties of the gelling composition, the lack of selectivity of the composition especially at elevated temperatures, low stability and deterioration of structural and mechanical properties over time. Another disadvantage of this method is the so-called "aging of the gel", which is accompanied by a noticeable separation of water (the phenomenon of syneresis) and leads to a decrease in the efficiency of the obtained water-insulating screens. In addition, the gel-forming composition reacts with the carbonate rock of the reservoir, thereby leading to an increase in its filtration properties. To increase the effect of isolation of water inflows in the water supply channels of the fractured zone of the carbonate formation, an increase in the injected composition is required.

The closest in technical essence and the problem to be solved is a method for selectively restricting water inflows in production wells, including preparing and pumping invert emulsion based on the dispersed phase and hydrocarbon dispersion medium with the addition of an emulsifier and stabilizer (US Pat. RF No. 2184836, IPC ЕВВ 33/138 , publ. BI No. 19 of 07/10/02). An aqueous solution of the required density and a hydrocarbon phase with the required amount of a powder emulsifier and stabilizer are preliminarily prepared. Next, both phases are thoroughly mixed until a homogeneous emulsion is obtained and pumped into the reservoir. To facilitate the injection and increase the phase permeability, a small amount of oil or its lighter fraction is pumped before the emulsion. As a squeezing liquid, oil or produced water is used. As an emulsifier and stabilizer, chemically modified highly dispersed silica is used, which has the properties of solid nonionic surfactants, with discrete particles 2–4 orders of magnitude smaller than the average size of the pore channels, which allows the reverse emulsion to penetrate deep into the reservoir under pressure. As a hydrocarbon dispersion medium, oil or products of its processing are used. The ratio of the dispersed phase / dispersion medium in the emulsion varies from 1/1 to 6/1.

The disadvantage of this method is the lack of insulation efficiency of water in the well due to the high filtering ability and low stability of the emulsion, especially at elevated temperatures.

The technical task of the proposal is to increase the efficiency of the method of isolating water inflows in washed high-permeability fractured zones of an oil and gas formation while maintaining the permeability of low-permeability layers by increasing the stability of the insulating composition, operational properties, increasing the coverage of the formation by exposure and, as a result, increasing oil and gas production. Also, the method allows to expand the technological capabilities of the method of isolation of water inflows in the well.

The technical problem is solved by a method of isolating water inflows in a well, including the preparation and injection into the formation of an invert emulsion based on a hydrocarbon dispersion medium and a dispersed phase, which is used as chemically modified dispersed silica.

New is that in addition, a gel-forming composition is used as the dispersed phase, as a solution of urea in aluminum-containing industrial wastes, and modified dispersed silica is used with a specific gravity of 40 to 160 g / dm ³ and a specific surface area of 140 to 380 m ² / g, in an amount of 0.25-2.5 wt.% To the entire weight of the emulsion, and the gelling composition is used in an amount of 50-80% of the total volume of the emulsion.

It is also new that oil or products of its processing are used as a hydrocarbon dispersion medium.

It is also new that sequentially modified disperse silica and a gelling composition are introduced into the hydrocarbon liquid with constant stirring.

Also new is that the gelling composition is introduced in portions into the hydrocarbon liquid.

Also new is the fact that modified disperse silica is used with a discrete particle size of 0.0005-0.1 μm, with an emulsifying ability of at least 350%.

The essence of the method of isolation of water inflows in the well is as follows.

When developing a high-temperature oil or gas reservoir represented by a fractured-porous reservoir of a carbonate reservoir, as well as washed by high-permeability zones of an oil or gas reservoir, geophysical and hydrogeological studies are carried out, the distribution of productive thicknesses of the reservoir over the area of the reservoir is determined, well injectivity, allowable pressure on the well are determined . The volume of the injected invert emulsion is determined based on the hydrocarbon dispersion medium and the dispersed phase, which is used as a chemically modified dispersed silica depending on the volume of the pore space. The invert emulsion based on the hydrocarbon dispersion medium and the dispersed phase is injected in a volume equal to the volume of cracks and washed highly permeable zones.

An invert emulsion is preliminarily prepared.

With constant stirring, modified dispersed silica is successively introduced into the hydrocarbon liquid and the gel-forming composition is added in uniform portions. Modified dispersed silica is used with a specific gravity of from 40 to 160 g / dm ³ and a specific surface area of 140 to 380 m ² / g, in an amount of 0.25-2.5 wt.% Of the total weight of the emulsion. The content of the gelling composition is used from 50 to 80% of the total volume of the emulsion. Modified dispersed silica is used with a discrete particle size of 0.0005-0.1 μm, with an emulsifying ability of at least 350%. The ratio of the hydrocarbon phase to the gel-forming composition is varied in the range from 1/4 to 1/1. To prepare the gelling composition, carbamide, liquid aluminum-containing industrial wastes with aluminum salts from 8.0 to 25 wt.% And water are used. Urea is previously dissolved in these wastes in the following proportions, wt.%: Liquid aluminum-containing wastes 20.0-75.0; carbamide 15.0-50.0; water is the rest. As the hydrocarbon phase for the preparation of the emulsion using oil viscosity from 5 to 50 MPa · s or its products. Portions of the gel-forming composition and modified disperse silica (MDC) in the injected emulsion form closed volumes of a dispersible gel with a distribution of the MDK over the interface between the gel and the emulsion. The injected composition is an emulsion - dispersion - gel system. The gel-forming composition and MDK in the emulsion injected into the reservoir perform the function of the dispersed phase, stabilizer and emulsifier. Due to the temperature of the formation, which reaches 70-120 ° C, in the gel-forming composition, the process of hydrolysis of urea begins, due to which the aqueous solution of aluminum salts from the liquid state turns into a gel state. After injection of the emulsion, the well is stopped for technological exposure for 1-5 days to form a water-proof screen under excessive pressure. Changing the concentration of components, controlling the supply of components during cooking and the content of the dispersed phase and dispersion medium can improve the quality and stability of the rheological, thixotropic, plugging and filtration properties. The proposed method allows to expand the technological capabilities of the preparation and injection of the emulsion under various geological and physical conditions of the reservoir. And, as a result, the method leads to an increase in the efficiency and durability of water insulation works, provides an increase in the production of heterogeneous permeability productive formations by increasing the coverage of the formation by water flooding, which is achieved by preliminary complete or partial blocking of highly permeable, fractured zones of the formation and subsequent change of direction and redistribution of filtration flows involving in the development of previously unexplored low-permeability productive zones of plas a.

The analysis of patent and scientific and technical literature allowed us to conclude that there are no technical solutions containing essential features of the proposed method that perform a similar task, therefore, the proposed method meets the criteria of "novelty" and "inventive step".

To prepare the emulsion using modified disperse silica, for example, MDC "Quartz" according to TU 245810-001-50618596-2000, manufactured by LLC "Quartz", Aznakayevo, RT, which has a developed specific surface area (up to 380 m ² / g), or hydrophobic dispersed powder "Polysil", produced according to TU 2169-005-13303015-03. MDC “Quartz” and “Polysil” are chemically modified silica - a highly dispersed white powder, the feedstock of which is amorphous silica of various dispersion with a specific gravity of 40 to 160 g / dm ³ and a specific surface area of 140 to 380 m ² / g s emulsifying ability of at least 350%.

As a gel-forming composition, for example, RV-3P-1 reagent according to TU 2458-001-14702906-08 produced by LLC NPP Impulse or LLC NPP Spektr, a gel-forming composition based on liquid glass, hydrochloric acid and PAA, with the following ratios of components, wt.%: liquid glass - 6-8, hydrochloric acid - 0.8-1.2, PAA - 0.05-0.07, the rest is water, as well as gel-forming compositions based on acid solutions of synthetic aluminosilicates (zeolite). The composition of the zeolite compositions: zeolite - 6-8 wt.%, Hydrochloric acid 8-12%, the rest is water.

As the hydrocarbon phase, oil or its fractions is used - diesel fuel, a wide fraction of light hydrocarbons (BFLH), kerosene, hexane and others.

As aluminum-containing wastes of industrial production, solutions of aluminum salts are used, for example, aluminum chloride solution, aluminum sulfate solution or aluminum nitrate solution with a mass fraction of aluminum salts of 8-25%, etc.

The stability of the insulating compositions is characterized by the volume of the separated aqueous and hydrocarbon phases (UV) in the case of emulsion systems (prototype) and the aqueous phase (WF) due to syneresis in the case of a gelling composition (analogue). Studies were carried out at a temperature of 95 ° C. The results of comparative studies are shown in table 1.

The results of the studies show that the proposed method for the preparation and injection of the emulsion has better stability (has a synergistic effect) compared with the prototype and analogue.

In the case of waterproofing works in a fractured-porous carbonate reservoir, their effectiveness is primarily determined by the plugging properties of the insulating compositions. In this regard, modeling of the fractured bottomhole formation zone was carried out using tubes. The plugging properties of the systems under study were evaluated by the pressure drop at the ends of the tubes during their displacement by water.

Filtration studies characterizing the effectiveness of isolation of water inflows were carried out using the filtering apparatus UIPK-1M Kern at a constant flow rate corresponding to the hydrodynamic conditions of the bottom-hole formation zone, using steel tubes 20 cm long and an inner diameter of 8 mm, equipped at the ends with fittings with a cross-section 4 mm.

Filtration tubes were filled with the studied compositions and compositions, and they were displaced from the tubes with water. During the displacement process, the pressure drop and the volume of the displaced fluid were recorded. Upon reaching a constant pressure drop, the tubes were disassembled, and the amount of water and the amount of emulsion remaining after displacement were determined. Then the filtration tube was again filled with the same emulsion being studied and placed in an oven with a temperature of 95 ° C for 1 day for the gelation process to proceed. After gelation from the filter tubes with the studied emulsions, they were also displaced by water with registration of the displacement parameters. Upon reaching a constant pressure drop, the tubes were disassembled, and the amount of water and the amount of remaining emulsion were determined. A comparative assessment was carried out by the pressure drop during the displacement of the studied systems.

Comparative studies were carried out with the closest prototype and gel-forming composition - working solution of the reagent RV-3P-1 by analogy and solutions of aluminum sulfate and nitrate after gelation. The formulations of the studied systems and the results of experimental studies are shown in Tables 2 and 3. As an emulsifier and stabilizer, modified quartz and polysil grades of modified silica were used in the studies.

An analysis of the results of filtration studies showed that the concentration of the MDK and the ratio of the dispersed phase and the dispersion medium influence the parameters of the displacement process of the emulsion under study. When the emulsion is displaced by water, the maximum pressure drop varies from 0.01 to 0.075 at. The final pressure drop, i.e. the pressure drop after displacement varies in a very narrow range from 0.01 to 0.035 bar, and almost does not depend on the formulation of the investigated emulsions. At the same concentration of MDK, the maximum pressure drop during displacement increases with increasing content of gelling composition. And with the same ratio of the gel-forming composition and the hydrocarbon phase, the maximum pressure drop increases with an increase in the concentration of MDK in the system.

As can be seen from tables 2 and 3, according to the proposed method for isolating water inflows in a well, the maximum and final pressure drop is 2-15 times higher than in the prototype.

Comparative filtration studies with gel-forming compositions:

Composition 1 - RV-3P-1 - 40%; carbamide - 32%; water - 8%; diesel fuel 18%; MDK Quartz - 2%.

Composition 2 - liquid glass - 4.8%; hydrochloric acid - 0.8%; PAA - 0.05%; water - 74.35%; diesel fuel 47.5%; MDK Quartz - 2.5%.

Composition 3 - zeolite - 6.4%; hydrochloric acid - 6.4%; water - 67.2%; diesel fuel 19%; MDC Quartz - 1%, are shown in table 4.

Table 4 No. p / p Downloadable composition Maximum pressure drop, at Final pressure drop, at one. Composition 1 0.65 0.35 2. Composition 2 0.32 0.19 3. Composition 3 0.43 0.29

As can be seen from table 4, according to the proposed method for isolating water inflows in a well, the maximum pressure drop is higher than that of emulsions and gels of the same composition, the final pressure drop is 5-30 times higher compared to the prototype.

Thus, the proposed method for isolating water inflows in a well allows increasing oil and gas recovery in heterogeneous fractured-cavernous water-saturated carbonate formations while preserving the permeability of low-permeability interlayers by increasing the stability of the insulating composition, operational properties, and increasing the coverage of the formation by exposure. Also, the method allows to expand the technological capabilities of the method of isolation of water inflows in the well.

Claims (5)

1. A method of isolating water inflows in a well, including the preparation and injection into the formation of an invert emulsion based on a hydrocarbon dispersion medium and a dispersed phase, which is used as a chemically modified dispersed silica, characterized in that a gel-forming composition is additionally used as the dispersed phase, which urea solution used in the aluminum-containing industrial wastes, wherein the modified particulate silica is used with a specific weight of 40 to 160 g / dm ³ a specific surface area of 140 to 380 m ² / g, in an amount of 0.25-2.5 wt.% to the entire weight of the emulsion, and gelling composition is used in an amount of 50-80% of the total emulsion. 2. The method according to claim 1, characterized in that oil or products of its processing are used as the hydrocarbon dispersion medium. 3. The method according to claim 1, characterized in that sequentially modified dispersed silica and a gelling composition are introduced into the hydrocarbon liquid with constant stirring. 4. The method according to claim 1, characterized in that the gelling composition is introduced in portions into the hydrocarbon liquid. 5. The method according to claim 1, characterized in that the modified dispersed silica is used with a discrete particle size of 0.0005-0.1 μm, with an emulsifying ability of at least 350%.