RU2496001C1 - Development method of oil-gas deposit using hydraulic fracturing of formation - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: method involves development of oil-and-gas deposit using hydraulic fracturing of formation, at that at the first stage of oil-and-gas deposit development hydraulic fracturing of formation is performed in all production wells. Simultaneously, using geophysical methods based on recording of microseisms as well as on recording of angle of formation slope occurred by hydraulic fracturing of rocks, directions of paths of hydraulic fracturing cracks by azimuth are determined. When debits of production wells are lowered below 10% from initial values, hydraulic fracturing is performed in all injection wells, at that immediately after hydraulic fracturing in injection wells there performed is treatment of formation by high pressure for increase of intake capacity. In order to set direction of hydraulic fracturing cracks parallel to rows of injection and production wells, artificially changed is stress field in well bore zone of formation around wells. For this action hydraulic fracturing of formation in wells is done in two stages, at which during initial hydraulic fracturing quartz sand and plug composition are pumped in well, and during the second one - binding agent of fractions - proppant.

EFFECT: improvement of method efficiency in various geologic and technical conditions of oil-and-gas deposit development.

7 cl

Description

The invention relates to the oil and gas industry, in particular to the field of development of oil and gas fields using hydraulic fracturing.

There is a method of developing oil fields by creating a network of production and injection wells, conducting hydraulic fracturing through them, injecting the displacing agent into the injection wells and selecting fluid through the production wells (Oil production reference book. / Ed. Sh. K. Gimatudinova. - M .: Nedra, 1974, p. 451-461).

The disadvantage of this method is that during the development of the field, the orientation of the direction of the opening of the hydraulic fracture in the reservoir is not controlled, which subsequently does not optimally implement the process of displacement in the oil-saturated reservoir of oil pumped into the reservoir by water and thereby ensure high coefficients of oil displacement from the reservoir and its coverage water flooding.

Also known is a method for the full development of productive formations of oil and gas fields (patent RU No. 2297525, IPC 6 ЕВВ 43/20, 43/26, published on 04/20/2007, Bull. No. 11), including hydraulic fracturing and formation of productive isolines, arrangement of wells with conducting grouting of their annular intervals, carrying out cycles of investigations of injectivity profiles and inflows in injection and producing wells in the initial productive contours, determining the geometric parameters of the final unproductive section when Front watering first productive interval contours till perforation zone of one of the production wells as a result of measurement of differential and integral profiles pickup and tributaries, performing grouting to form a new portion of the first contour with subsequent productive operations research and develop until complete plugging of the formation.

The disadvantage of this method is the low technical and economic efficiency due to the complexity and complexity of its implementation.

The closest in technical essence is a method of developing an oil and gas reservoir using hydraulic fracturing (patent RU No. 2135750, IPC 6 ЕВВ 43/20, 43/26, published on 08.27.1999), including the injection of water and / or gas through injection wells, and / or other displacing agent, hydraulic fracturing by artificial contouring on the development object, hydraulic fracturing comprehensively on the whole set of injection and production wells, formation fluid selection through production wells, design the development and implementation of hydraulic fracturing based on continuous information on the mechanical properties of the rocks of the sections of injection and production wells, the coordination of this information with geophysical studies, the determination of the direction of hydraulic fractures by selecting anti-aircraft and azimuthal angles of injection and production wells from the calculation of eliminating heterogeneity of filtration flows, increasing the period of effective operation fracturing fractures by pumping into them compositions of physicochemical substances dissolving clay and other ineralnye substance filling the hydraulic fracture.

The disadvantages of this method are:

- firstly, the inability to control the orientation of the fracture by specifying the anti-aircraft and azimuthal angles of the wellbore;

- secondly, the lack of effectiveness of the method in various oil and gas deposits, characterized by filtration and reservoir properties of the rocks.

The technical objectives of the claimed invention are:

- improving the efficiency of the development of oil and gas deposits by simplifying the method;

- the creation of hydraulic fractures in a given azimuthal direction;

- improving the efficiency of the method in various oil and gas deposits, characterized by reservoir properties of the rocks.

The stated technical problem is solved by the method of developing an oil and gas reservoir using hydraulic fracturing - hydraulic fracturing, including artificial contouring of the development object by injection of water and / or gas and / or another displacing agent through injection wells, selection of formation fluids through production wells, design and hydraulic fracturing is integrated in production and injection wells based on information on the geomechanical properties of rocks that make up oil call pool.

New is that hydraulic fracturing is carried out in all producing wells, and at the same time, using geophysical methods based on the registration of microseismic vibrations, as well as on registration of borehole dipsticks, changes in the dip angle that occur during hydraulic fracturing of rocks, determine the direction of fracture development hydraulic fracture in azimuth, and with a decrease in production wells by 10% of the initial values, hydraulic fracturing is carried out on all pump wells, and immediately after hydraulic fracturing in injection wells, the formation is treated with high pressure to increase injectivity.

Also new is that when the direction of the rows of production and injection wells coincides with the direction of minimum stresses in the formation that composes the oil and gas reservoir, hydraulic fracturing in the wells is carried out in two stages, in which, at the initial hydraulic fracturing, quartz sand and the plugging composition are pumped into the well, and when repeated, the crack fixer is proppant, in order to artificially change the stress field in the bottomhole formation zone around the wells to specify the direction of hydraulic fractures yva parallel rows of injection and production wells.

Also new is the fact that when the production rates of production wells fall by more than 50% of the initial values, they perform repeated hydraulic fracturing.

It is also new that in oil and gas deposits with a permeability of less than 10 mD, hydraulic fracturing is carried out with the injection of a fracture buffer fluid in the amount of 10-20% of the total volume of the fracture fluid and with a constant flow rate of the fracture fluid to produce narrow and long fractures in the reservoir, and in oil and gas deposits with a permeability of more than 100 mD, hydraulic fracturing is carried out with the injection of a fracture buffer fluid in the amount of 7-10% of the total volume of the fracture fluid and with a decrease in the flow rate of the fracture fluid to obtain wide and short cracks in the reservoir.

The proposed method is as follows.

An oil and gas reservoir is developed by artificially contouring the development object by injecting water and / or gas and / or another displacing agent through injection wells (for example, a surfactant). Produce formation fluids through production wells.

In the case when the efficiency of developing oil and gas deposits with different reservoir properties is not efficient enough, they design and carry out hydraulic fracturing in production and injection wells based on information about the geomechanical properties of the rocks that make up the oil and gas reservoir.

To do this, choose a production facility or a separate part of the oil and gas reservoir, the technical and economic development indicators of which (which) require improvement.

At the first stage of the development of an oil and gas reservoir using hydraulic fracturing, hydraulic fracturing is carried out in all producing wells located at this production facility or in a separate part of the oil and gas reservoir. Moreover, simultaneously with hydraulic fracturing, using geophysical methods based on the registration of microseismic vibrations, as well as on registration of borehole dipsticks, changes in the angle of formation that occur during hydraulic fracturing of rocks, determine the direction of development of hydraulic fractures in azimuth, i.e. actually determine the direction of minimum stress in the reservoir.

For example, if the rows of production and injection wells are located in the direction from north to south, and the direction of minimum stresses in the reservoir, determined using the geophysical methods described above, also passes from north to south, then according to the latest theoretical and practical studies in the field of hydraulic fracturing reservoirs (see, for example: monograph - MJEconomides, KGNolte, Reservoir stimulation: Schlumberger Educational Services, 3 ^rd edition, 1998) the initial hydraulic fractures will develop in a plane perpendicular to the direction of minimum stresses in the rocks composing the oil and gas reservoir, i.e. mainly from west to east, respectively. To reorient hydraulic fractures parallel to the rows of production and injection wells in the north-south direction, hydraulic fracturing is carried out in two stages.

At the first stage, the stress field in the near-wellbore zone of the formation is artificially changed - the bottom-hole formation, for which a primary hydraulic fracturing is carried out with the injection of a crack reinforcement (for example, quartz sand according to GOST 22551-77) followed by plugging (for example, cement portland cement according to GOST 1581-96).

During the initial hydraulic fracturing, a hydraulic fracture is formed, the plane of which will be perpendicular to the direction of minimum stresses in the rocks composing the oil and gas reservoir, i.e. mainly from west to east, respectively.

As a result of the initial hydraulic fracturing, the rock constituting the PPP deforms and moves apart in the west-east direction, thereby changing the stress field in the region of the crack development. Those. the rock composing the oil and gas layer in the area of the development of the hydraulic fracture will be compressed in the west-east direction, as a result of which the minimum stress in the direction from west to east will become greater than the value of the minimum stress from north to south.

Fixation of the created hydraulic fracture with quartz sand followed by plugging with Portland cement will lead to a reorientation of the stress field in the region of the hydraulic fracture development. The direction of the minimum stresses in the PPP will become perpendicular to the initial one, i.e. reoriented from north-south to west-east.

In practice, this will mean that subsequent hydraulic fracturing carried out at a given well will initiate the formation of a hydraulic fracture in the direction perpendicular to the initial hydraulic fracture, i.e. in the direction from north to south.

At the second stage, hydraulic fracturing is carried out with injection of a crack fixer (for example, the proppant of the following fractions 12/18, 16/30, 20/40 mesh according to GOST R 51761-2005) with the formation of a hydraulic fracture parallel to the direction of the production and injection rows.

When production wells are reduced by 10% from the initial values, hydraulic fracturing is carried out in all injection wells, and immediately after hydraulic fracturing in injection wells, the formation is treated with high pressure to increase injectivity (see, for example: patents RU No. 2128770, SU No. 1309645).

In the case when the formations that make up the reservoir of oil and gas deposits are low permeability (permeability less than 10 mD), hydraulic fractures create narrow in width and lengthwise. In the case when the strata that make up the reservoir of oil and gas deposits are highly permeable (permeability of more than 100 mD), hydraulic fractures create wide in width and short in length.

For example, for formations with a permeability of less than 10 mD, it is necessary to create hydraulic fractures with a half-length of more than 60 m and a width in the productive part of up to 2-3 mm, and for formations with a permeability of more than 100 mD it is necessary to create hydraulic fractures with a half-length of up to 30 m and a width in the productive parts from 5 to 10 mm.

To create hydraulic fractures with a half-length of more than 60 m and a width in the productive part of up to 2–3 mm in reservoirs with a permeability of less than 10 mD, hydraulic fracturing is carried out according to the usual technology with the injection of a fracturing buffer fluid in a volume equal to 10–20% of the total fracturing fluid volume and at a constant flow rate of fracturing fluid (see, for example: monograph - Konstantinov S.V., Gusev V.I. Technique and technology of hydraulic fracturing abroad: - Overview, M., VNIIOENG, 1985, - 61 p. )

To create hydraulic fractures with a half-length of up to 30 m and a productive width of 5 to 20 mm in reservoirs with a permeability of more than 100 mD, hydraulic fracturing is carried out using end shielding technologies (for example, such as TSO or Frac-Pack - brand names of technologies) with the injection of buffer fluid rupture in a volume equal to 7-10% of the total volume of the fluid rupture and with a stepwise decrease in the flow rate of the fluid rupture (see, for example: US patents No. 6837309 and US No. 6938693).

When the initial stage of the development of the oil and gas field is carried out and when the production rates of production wells fall by more than 50% of the initial values, they carry out repeated hydraulic fracturing.

The use of hydraulic fracturing in the development of oil and gas deposits affects the efficiency of reserves development in the whole site. In a formation that is homogeneous in permeability, the maximum oil recovery factor is achieved during hydraulic fracturing in a stagnant region of the formation.

As a result of the application of the proposed development method, additional oil production in the area amounted to 25 thousand tons.

The use of this method of developing oil and gas deposits allows to increase technical and economic efficiency by simplifying the method, creating rupture cracks with the desired azimuthal direction, and also increasing the efficiency of the method in various geological and technical conditions for the development of oil and gas deposits.

Claims (7)

1. A method of developing an oil and gas reservoir using hydraulic fracturing, including artificial contouring on the development object by injecting water and / or gas and / or another displacing agent through injection wells, selecting reservoir fluids through production wells, the design and implementation of hydraulic fracturing is carried out comprehensively in production and injection wells based on information on the geomechanical properties of the rocks that make up the oil and gas reservoir, characterized the fact that initially hydraulic fracturing is carried out in all producing wells, and at the same time, using geophysical methods based on the registration of microseismic vibrations, as well as on registration of borehole dipsticks, changes in the dip angle that occur during hydraulic fracturing of rocks, determine the direction of development of hydraulic fractures azimuthal fracture, moreover, with a decrease in production wells below 10% of the initial values, hydraulic fracturing is carried out in all the heels production wells, and immediately after hydraulic fracturing in injection wells, the formation is treated with high pressure to increase injectivity. 2. The method according to claim 1, characterized in that when the direction of the rows of production and injection wells coincides with the direction of minimum stresses in the formation that composes the oil and gas reservoir, hydraulic fracturing in the wells is carried out in two stages, in which they are pumped into the well at the initial hydraulic fracture quartz sand and tampon composition, and, if repeated, the crack fixer is proppant, in order to artificially change the stress field in the bottomhole formation zone around the wells to specify the direction of hydra fractures fracture parallel to the rows of injection and production wells. 3. The method according to claim 1 or 2, characterized in that when the production rates of the production wells fall by more than 50% from the initial values, a repeated hydraulic fracturing is carried out in them. 4. The method according to claim 1 or 2, characterized in that in oil and gas deposits with a permeability of less than 10 mD, hydraulic fracturing is carried out with the injection of a buffer fracturing fluid in the amount of 10-20% of the total volume of the fracturing fluid and with a constant flow rate of the fracturing fluid narrow and long cracks in the reservoir. 5. The method according to claim 3, characterized in that in the oil and gas deposits with a permeability of less than 10 mD, hydraulic fracturing is carried out with the injection of a buffer fracture fluid in the amount of 10-20% of the total volume of the fracture fluid and with a constant flow rate of the fracture fluid to obtain narrow and long cracks in the reservoir. 6. The method according to claim 1 or 2, characterized in that in oil and gas deposits with a permeability of more than 100 mD, hydraulic fracturing is carried out with the injection of a buffer fracture fluid in the amount of 7-10% of the total volume of the fracture fluid and with a stepwise decrease in the flow rate of the fracture fluid for receiving wide and short cracks in the reservoir. 7. The method according to claim 3, characterized in that in the oil and gas deposits with a permeability of more than 100 mD, hydraulic fracturing is carried out with the injection of a buffer fracturing fluid in the amount of 7-10% of the total volume of the fracturing fluid and with a stepwise reduction in the flow rate of the fracturing fluid to obtain wide and short cracks in the reservoir.