RU2223395C1 - Process of development of oil bed - Google Patents

Abstract

FIELD: oil production. SUBSTANCE: process relates to extraction of oil from nonuniform oil bed by injection of agents reacting with mineralized water, for example, microorganisms, water soluble polymers of acryl series, cellulose ester, into oil bed. Process involves injection of water fringes of agents into bed. Study for determination of dependence of volume and composition of fringes on mineralization of water is conducted in correspondence with invention prior to injection of agent into bed. Such volume of fringe, its composition and such mineralization of water with which period of gel formation of water fringe of agent is not less than time of running by this fringe in flooded interlayer are determined. In this case water fringes with same mineralization are injected before and after injection of water fringe of agent as well as between them. EFFECT: increased efficiency of process thanks to preliminary selection of optimal mineralization, volume and composition of fringes of agents. 3 cl, 2 tbl

Description

The invention relates to the oil industry, in particular to methods for producing oil from a heterogeneous oil formation by pumping into the formation of water rims agents that respond to water mineralization, for example microorganisms, water-soluble acrylic polymers, cellulose ethers, etc.

A known method of processing an oil reservoir by pumping into it a culture of microorganisms represented by methanotrophs. The metabolic products of methanotrophs have oil-displacing properties (1).

The disadvantage of this method is that in mineralized water methanotrophs die. And as you know, formation water, even with prolonged injection of fresh water into the formation, remains quite mineralized. In addition, the development of oil fields is carried out mainly by pumping into the reservoirs not fresh, but wastewater with a salt content of up to 100 g / l.

The closest method (prototype) is a method of oil production from a heterogeneous oil reservoir, which involves the injection into the reservoir of an aqueous solution of a water-soluble anionic polymer of an acrylic series with a crosslinker, which is used as chromium acetate (2). The use of a crosslinker makes it possible to obtain a much more viscous and stable crosslinked polymer composition (ATP) compared to using a single polymer.

However, the known method does not take into account that polyacrylamide (PAA) samples with different anionicity react differently to the mineralization of the water in which they are dissolved. And this, as shown by laboratory studies conducted by the authors, significantly affects the crosslinking time (the induction period of gelation) and the concentrations of the starting reagents, i.e. ultimately on the effectiveness of their use.

Another close to the proposed technical essence (prototype) is a method of increasing the production of flooded layered-heterogeneous formations (3). The essence of the method lies in the fact that an aqueous solution of methylcellulose is pumped into the formation, which under formation conditions - when the temperature rises to the formation - passes into a sedentary gel, thus redistributing the flows of the rims of the displacing agent and increasing the coverage of the formation by displacement.

However, methyl cellulose has the property that increasing the mineralization of water leads to a decrease in its gelation temperature. When moving deeper into the formation, the methylcellulose rim mixes with mineralized formation water, as a result of which the gel is formed not in the desired section of the formation, but much closer to the well, where the temperature is lower than the calculated one. In addition, the viscosity of methyl cellulose solutions strongly depends on the mineralization of water, so an unexpected change in mineralization leads to unexpected technological effects.

Thus, as can be seen from the above examples, the water rims of agents used in the oil industry, for the most part, react to the mineralization of the water in which they are dissolved and with which they are in contact under reservoir conditions, which leads to unpredictable effects.

The aim of the proposed method is to increase the efficiency of the method of developing a heterogeneous oil reservoir due to preliminary selection of optimal mineralization, volumes and compositions of agent rims.

This goal is achieved by the fact that in the method of developing an oil reservoir, including the injection of water rims of agents into the reservoir, before pumping the water rim of the agent into the reservoir, studies are carried out to determine the dependence of the volume and composition of this rim on the mineralization of water and determine such a volume of the rim, its composition and such mineralization of water, in which the induction period of gelation of the water rim of the agent is not less than the time that the rim reaches the flooded layer, and before and after the water rim of the agent, as well as waiting for them, rims of water are pumped with the same mineralization.

Other differences of the method are as follows:

chemicals or microorganisms are pumped into the formation as agents of the water rim;

when using, for example, a solution of a water-soluble anionic polymer of acrylic series - polyacrylamide with a crosslinker, PAA solutions with anionicity higher than 20% are prepared in wastewater by mineralization up to 100 g / l, and preliminary tests are carried out to select the mineralization of PAA solutions with anionicity lower than 20% with waters of different salinity at different ratios of reagents, after which a system with an induction period that is not less than the time it reaches the flooded layer at the optimal concentration x reagents;

when using cellulose ethers as a reagent, for example methyl cellulose, the volume and composition of the rims are selected depending on the salinity and temperature of the formation.

The essence of the proposed method is as follows. It is known that the mineralization of formation water of oil reservoirs varies over a wide range (from 60 to 300 g / l) both in deposits and within a single reservoir as a result of injection of surface water. Due to the fact that the majority of agents used in oil extraction of water rims change their properties depending on the mineralization of the water in which they are dissolved, each of the agents used in water rims should be tested before injection into the reservoir to determine how its characteristics used change in or other technology, depending on the salinity of the water. According to the results of such testing, the mineralization of water should be chosen in such a way as to surely obtain the expected effect. At the same time, in order to avoid mixing the agent rims with the selected mineralization of water by produced water, it is proposed, before and after the agent rims, and also between the rims (if there are several of them), to inject water rims with a mineralization equal to that selected in the agent rims.

Specifically, the application of the proposed method can be illustrated by the following examples.

1. Download PAA with a stapler.

In the proposed method, a regularity found as a result of laboratory studies is used - PAA samples of various anionicity react differently to the mineralization of water. This is manifested both in a change in the concentration range of the starting reagents (mainly chromium acetate) and in a change in the duration of the induction period. If the anionicity of PAA is higher than 20%, it is possible to definitely recommend wastewater with a mineralization of up to 100 g / l; for samples of PAA with anionicity below 20%, preliminary testing is required to select such water and such concentrations of PAA and chromium acetate at which the induction period of crosslinking is equal to or slightly longer time to reach the water rim of the reagents of the flooded layer. If the induction period is less, then the ATP is formed earlier than the water rim of the reagents reaches the desired location.

The creation of buffer rims by injecting water of a certain mineralization before, between and after the rims of an aqueous polymer solution and chromium acetate contributes to the reliable preservation of the selected optimal mineralization in reservoir conditions.

In field conditions, the method is as follows.

A complex of hydrodynamic and geochemical studies is carried out on the site of an inhomogeneous oil reservoir, according to the results of which the presence of highly permeable zones, the injectivity profile and the salinity of the produced water are determined, based on this, experimentally select the concentrations of the water rim of the reagents in the water rim and the salinity of the water so that the induction period of formation ATP was no less than their achievement of the desired layer.

At the same time, it is assumed that in the test areas characterized by a high degree of heterogeneity, for the most highly permeable and waterlogged (worked out) interlayers, an aqueous rim of the composition containing the polymer of higher concentrations (up to 0.5 wt.%) Should be injected to create a waterproofing screen with increased strength characteristics.

In surface conditions, using a mobile or stationary unit, an aqueous rim of the polymer composition is prepared, while for an aqueous rim of PAA with anionicity above 20%, a rim of wastewater with a salinity of up to 100 g / l in volume not less than the volume of feather space at a distance of 3-5 m from the borehole wall (the volume of the expressed depression funnel), and for the water rim of polymers with anionicity below 20%, for which, based on preliminary testing, the degree of mineralization of water with estimated times m crosslinking induction period, rim water is pumped to the same extent with the mineralization selected.

Then, a rim of the polymer composition with enhanced insulating properties is pumped to shut off waterlogged (worked out) layers in a volume of at least 10 m ³ per 1 m of the opened perforation interval, which is pressed into the reservoir with a rim of water in a volume of not less than the volume of pore space at a distance of 3-5 m from well walls (volume of expressed depression funnel) with the same estimated mineralization. After that, a technological stop of the injection is carried out during gelation (crosslinking).

After that, a PAA rim with a lower content of PAA and a crosslinker (movable rim) is pumped into the matrix of the reservoir with a low degree of development to regulate water filtration and reduce viscous instability at the displacement front (eliminating the possibility of the formation of "tongues" of water breakthrough into production wells). At the same time, they create a rim of water with selected mineralization in the amount of not less than the volume of feather space at a distance of 3-5 m from the well wall (the volume of the expressed depression funnel) before and after injection of the PAA rim with a crosslinker. Then carry out a technological stop of the injection at the time of gelation (crosslinking) for a given concentration of the PAA rim and crosslinker. At the end of this cycle of work, the well is transferred for water injection in accordance with the development regime of this section.

The proposed method was tested in laboratory conditions. The following reagents were used:

1. As PAA - samples of grades Alcoflood-935, Alcoflood-2548, DP-9-8177, Flopaam-25308, Flopaam-35308, DK8-ORT-TA-2, CHP-1, RDA-1004, FP-9120 and FP-9210. Water of various salinity was used to dissolve PAA samples.

2. As a crosslinker - chromium acetate manufactured by Allied Colloids Gmbh (Great Britain). For the preparation of crosslinker solutions, only fresh water was used.

3. As water - fresh water of the river. Kama and natural wastewater, the salt content of which was 0.3-0.5 g / l and 96.4-114.4 g / l, respectively. In some cases, produced water was used, the salt content of which was 230 g / l, as well as relatively weakly saline water (57.2 g / l). Such water was obtained by mixing wastewater with distilled.

Studies of the possibility of obtaining ATP were carried out by standard methods. The passage of the crosslinking process (the formation of a three-dimensional structure in the entire volume of a polymer solution with viscoelastic properties) was visually controlled by the appearance of the jet formed when the tube was turned over. If the polymer system did not pour out of the test tube or pour out in the form of a single inextricable stream, then this indicated the formation of ATP.

In the table. 1 summarizes the results of the studies. From the summarized results of table 1 it can be seen that the mineralization of water affects the efficiency of the formation of ATP. Thus, PAA samples with anionicity of more than 20% form PCA only in mineralized water. For PAA samples with a lower degree of anionicity, this effect affects the change in the concentration range in which gel formation occurs. Moreover, for some of the samples studied (FP-9120, FP-9210, Alcoflood-935), the use of fresh water is most preferable from this point of view, and for others (Alcoflood-2548, RDA-1004, TA-2, TA-1 , DP9-8177) - mineralized.

1. Injection of methylcellulose rims.

As mentioned above, an increase in the mineralization of water leads to a decrease in the gelation temperature of methyl cellulose solutions. In laboratory conditions, a sample of a water-soluble cellulose ether - methyl cellulose of the MMC-BTR brand (TU 39-08-047-74) was investigated. In the table. 2 shows the results of a gelation study of methyl cellulose solutions depending on the salinity and water temperature.

As can be seen from the table. 2 data, the gelation of methyl cellulose solutions depends on temperature, water salinity and reagent concentration. At a constant concentration, the gelation temperature decreases with increasing salinity of the water. This defines the technology for applying methyl cellulose rims.

Before pumping methyl cellulose fringes into the formation, as in the case of the PAA rim, a complex of hydrodynamic and geochemical studies is carried out, according to the results of which the presence of highly permeable zones, the injectivity profile and the salinity of the produced water are determined, based on this, experimentally select the concentrations of the water rims of the reagents and the salinity of the water so that under these specific conditions gelation occurs in the desired area of the reservoir. Before and after the rim of methyl cellulose, rims of water with selected mineralization are pumped into the formation. This embodiment of the method provides reliable receipt of the expected technological effect from the use of an aqueous rim of methyl cellulose.

The advantage of the proposed method in comparison with the known is a more efficient use of water rims agents in the development of oil reservoirs.

Claims (4)

1. A method of developing an oil reservoir, including the injection of water rims of agents into the reservoir, characterized in that prior to the injection of the water rim of the agent into the reservoir, studies are carried out to determine the dependence of the volume and composition of this rim on the salinity of the water and determine such a volume of the rim, its composition and such mineralization water, in which the induction period of gelation of the water rim of the agent is not less than the time that the rim reaches the flooded layer, and before and after the water rim of the agent, rims of water with the same mineralization. 2. The method according to claim 1, characterized in that chemicals or microorganisms are pumped into the formation as agents of the water rim. 3. The method according to claim 1 or 2, characterized in that when using, for example, a solution of a water-soluble anionic polymer of an acrylic series - polyacrylamide with a crosslinker, solutions of polyacrylamide with anionicity above 20% are prepared in wastewater by mineralization up to 100 g / l, and to select the mineralization of polyacrylamide solutions with anionicity below 20%, preliminary testing is carried out with waters of different mineralization at different ratios of reagents, after which a system with an induction period of at least time up to tizheniya it watered seam at optimal concentrations of the reagents. 4. The method according to claim 1 or 2, characterized in that when using cellulose ethers, for example methyl cellulose, as the reagent, the volume and composition of the rims are selected depending on the salinity and temperature of the formation.