RU2519093C1 - Method of oil formation treatment - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: method involves a stage of vibroseis formation stimulation using an elastic wave generator. Prior to the stage of vibroseis stimulation, multicycle treatment of formation with an inflating agent is performed, which ensures CO₂ bleeding. Each of the cycles includes injection in formation of 10-15% water solution of inflating agent and subsequent displacement of it and produced gas deep into formation with water flow till decrease of design concentration of produced gas in water solution to 10^-4-10^-2 wt %. After the sate of vibroseis stimulation, formation undergoes mud acid treatment.

EFFECT: improving treatment efficiency.

Description

The invention relates to the oil industry and can be used to intensify oil production and increase oil recovery.

A known method of processing an oil reservoir, including the stage of vibroseismic stimulation of the reservoir using an elastic wave generator (RU 2272896 C1 - prototype). The essence of the method consists in the cyclical, pulsating effect of depression and repression on the wellbore, as a result of which the flow rate of the well increases from 1 to 5 m ³ / day.

The disadvantage of this method is its low efficiency associated with a small depth of conversion of the reservoir in the vicinity of the well.

Also known are methods of treating an oil reservoir, including treating the reservoir with a gas generating agent (RU 2337125 C1, RU 2272897 C1, RU 2373385 C1, RU 2260687 C1, RU 2178067 C1, etc.). The treatment of the formation with various gas-forming agents (the so-called rheogasochemical technology) is traditionally used to restore the filtration characteristics of long-operating wells, to recover the remaining oil reserves.

However, these known methods have low efficiency, especially in low permeability reservoirs.

A known method of treating an oil reservoir by clay-acid treatment, including injecting clay clay and technological exposure, moreover, before carrying out clay-clay treatment in a well, a clay-acid bath is arranged (RU 2425971 C1). Clay acid is a mixture of hydrochloric (10-15% wt.) And hydrofluoric (2-5% wt.) Acids, usually used both to remove carbonate cementitious substances and to dissolve clay material.

The disadvantage of this method is its low efficiency, due to the fact that only the near-borehole formation zone is subjected to treatment. When opening a reservoir, in the section of which there are intervals with different permeabilities, a one-time acid treatment of the entire interval always positively affects the most permeable interlayer, while other interlayers with poor hydraulic conductivity actually remain untreated.

Closest to the proposed invention in technical essence and the achieved result is a known method of processing an oil reservoir, including the stage of vibroseismic treatment of the reservoir using an elastic wave generator (RU 2291956 C2). Vibroseismic impact on the formation is carried out by vibrations created by ground sources, which are a group of two or more generators of elastic waves, in two stages. At the first stage, the generators are operated synchronously with a frequency equal to the dominant one; at the second stage, the group of generators is divided into two parts equal or close in the number of generators; each part is tuned to a specific frequency based on the condition that the average frequency of the generators of the whole group is equal to the dominant frequency of the reservoir , and the difference between the frequencies of each part of the generators is determined in accordance with the linear size of the processed geological body from the experimentally found condition, while the exposure to seismic vibrations in the productive stratum is increased by a decrease in the beat frequency of these vibrations. As a result of this processing method, a complex effect on the oil reservoir is provided, the result of which is the appearance in the reservoir of elastic and inelastic deformations of the selected rock formations.

However, in practice, a decrease in the friction forces cannot be achieved without a directed change in the nature of the interaction between the reservoir rock and the fluid. In this regard, the prototype method has low efficiency: after exposure in the runout mode for several days, the flow rates of wells increased by an average of only 15%.

The technical task is to create a method of processing an oil reservoir devoid of this drawback.

The technical result of the proposed method consists in increasing the processing efficiency.

The specified technical result is achieved by the fact that in the method of treating an oil reservoir, which includes the stage of vibroseismic treatment of the reservoir using an elastic wave generator, in addition to the stage of vibroseismic treatment, a multi-cycle treatment of the reservoir with a gas generating agent is carried out, which ensures the release of CO ₂ in the reservoir, and each of the cycles includes injection into the formation of a 10-15% aqueous solution of a gas-forming agent and subsequent forcing it and the resulting gas into the depth of the formation by a stream of water until the calculated concentration of the formed gas in the aqueous solution decreases to 10 ^-4 -10 ^-2 wt.%, and after the stage of vibroseismic exposure, clay-acid treatment is carried out.

The essence of the proposed method consists in creating a zone around the well in the formation, characterized by superfluidity of the formation fluid. The proposed method can be used for processing any low-permeable, clayey layers, however, the effectiveness of the proposed method is most fully manifested in cases where the reservoir rock has mechanical emission (see, for example, V. S. Zamakhaev, M. A. Kolobov. “Emission phenomena during the mechanical destruction of sedimentary rocks of deep occurrence. "Abstracts of the All-Union Symposium on Mechanochemistry and Mechanoemission of Solids, September 11-14, 1990, Chernigov; Formation Damage due to Mass Transfer in the Layers under a Dynamic Impact, Victor Zamakhaev, Journal of Petroleum science re search, 2013, Volume 2, Issue 1; Zamakhaev B.C., Martynov VG Blasting operations in wells. Textbook for universities. M: Nedra, 2010).

To implement the invention, a block of deposits is determined (part of a reservoir that is structurally distinguished by geological characteristics; in the framework of this method, a system of perturbing and potentially responsive wells) and a well is selected through which the impact will be made. The perturbing well can be selected from both injection and production wells.

In order to prepare for the subsequent vibroseismic action, a concentrated (10-15%) aqueous solution of a gas-generating agent generating CO ₂ is injected into the formation through a selected disturbing well and the gas formed is forced into the depth of the formation by a stream of water. The choice of gas-forming agents generating CO ₂ in the formation is due to the fact that CO ₂ is an inert gas in the formation and is capable of emitting electromagnetic waves during seismic action. In any commercially available agents reogazohimicheskogo stimulation generating mainly of CO _2, including ammonium salts and alkali metal, for example consisting of ammonium bicarbonate, and mixtures of ammonium sulfate and sodium nitrite can be used as a blowing agent. In addition to gas generating agents generating CO ₂ , in order to enhance the technical result, agents generating NO ₂ can also be injected into the formation. The choice of a specific agent that forms CO ₂ in the formation depends on the nature of the formation (carbonate, terrigenous) and is limited mainly by economic considerations: for example, when treating carbonate formations, more expensive gas-forming agents based on ammonium salts and alkali metals can be used, but limit the use of cheaper acid gas generating agents generating CO ₂ in the formation. The injection of a solution of a gas-forming agent and the subsequent forcing of the generated gases into the depth of the formation by a stream of water is carried out in cycles, the amount of which depends on the filtration characteristics of the treated formation and should be sufficient to advance the treatment front to a depth of at least 100 m.Mostly, the number of cycles is from 2 to 6. Each treatment cycle includes the injection of a 10-15% aqueous solution of a gas-forming agent in an amount determined by the filtration characteristics of the processed about the reservoir, preferably 10-20 m ³ , and the subsequent continuous pushing by a stream of water from the reservoir pressure maintenance system until the calculated concentration of the formed gas in the aqueous solution decreases to 10 ^-4 -10 ^{-2 -2} wt.%. It was experimentally proved that at a given, technologically determined concentration of the initial solution of the gas-forming agent (10-15 wt.%), Dilution of the aqueous solution of the gases formed in the formation to their calculated concentration of 10 ^-4 -10 ^-2 wt.% Allows achieving “smearing” of the released gases, their penetration into the formation to the required depth, which provides a directed change in the adsorption situation in the formation. Greater dilution (estimated gas concentration of less than 10 ^-4 wt.%) Does not allow to increase the efficiency of the subsequent vibroseismic exposure, smaller dilution (calculated gas concentration of more than 10 ^-2 wt.%) Does not allow gas to penetrate to a sufficient depth.

Vibroseismic effects on the prepared in the first stage of processing the block of deposits are carried out through a selected disturbing well using any suitable generators, either installed at the wellhead or lowered into the well by cable or pipe, using any known technology (for example, known from RU 2277633 C1 ; Buryan Yu.A. and Sorokin VN Vibroseismic impact on oil and gas reservoirs - technology of the 21st century, J. “National Priorities of Russia”, 2009, No. 1; RU 2272896 C1, etc.). The frequency with which the vibroseismic effect is carried out depends on the state of the formation being treated and, preferably, is from 0.1 to 100 Hz. The time during which the vibroseismic effect is carried out depends on the state of the treated formation and can be from 5 to 10 minutes. As a result of vibroseismic action in the interwell space, the phenomenon of superfluidity of the fluid is observed. It was experimentally proved that the preliminary treatment of the deposit block with a solution of a gas-forming agent according to the technology described above allows, in comparison with the prototype, to increase the depth of the effective vibroseismic effect due to preliminary directional changes in the adsorption situation in the formation.

At the same time, it was experimentally proved that the result of the vibroseismic effect is not only superfluidity of the fluid in the interwell space, but also a simultaneous decrease in its mobility in the near-well zone of the disturbing well formation, which limits the efficiency of the entire processing process. In order to eliminate this drawback after the stage of vibroseismic exposure, according to the invention, clay formation is performed in a disturbing well using a known technology (see, for example, Ibragimov L.Kh. et al. Production Intensification. M .: Nauka, 2000, p. 55-57). Clay acid treatment is carried out by pumping clay clay to restore fluid mobility in the near-wellbore zone of the disturbing well formation.

According to the tests carried out according to the invention, it is possible to achieve superfluidity of the fluid in the zone of the formation that underwent the transformation by changing the nature of the interaction between the reservoir rock and the fluid, as well as maintaining the state responsible for the superfluidity of the fluid in the memory for a long time. The result of the occurrence and preservation of superfluidity is a multiple increase in the productivity of producing wells (compared with no more than 15% of the prototype) and the injectivity of injection wells, and this increase remains for many months.

Claims (1)

A method of treating an oil reservoir, including a stage of vibroseismic stimulation of the reservoir using an elastic wave generator, characterized in that, in addition to the stage of vibroseismic stimulation, a multi-cycle treatment of the reservoir is carried out with a gas generating agent, which ensures the release of CO ₂ in the reservoir, each of which includes pumping 10- 15% aqueous solution of a gas-forming agent and the subsequent forcing it and the resulting gas into the depth of the reservoir with a stream of water to reduce the estimated concentration and the formed gas in an aqueous solution up to 10 ^-4 -10 ^-2 wt.%, and after the stage of vibroseismic exposure carry out clay acid treatment.