RU2515628C1 - Method for development of low-permeable oil deposits using horizontal wells with transversal cracks in hydraulic fracturing - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: method includes drilling of horizontal producers with in-line placement and orientation of horizontal boreholes towards the minimum horizontal stress in the formation, performing multistage hydraulic fracturing and, according to the invention, drilling rows of directional injectors with performance of hydraulic fracturing at all wells in parallel to the lines of horizontal producers with alternation in one row. At that at all injectors located opposite the middle of the producer horizontal boreholes hydraulic fracturing and start-up of operations is made at the stage when operations are started for all other neighbouring wells: production for the nearest horizontal producers in the neighbouring rows and injection for the nearest injectors in the neighbouring rows. Injection to directional injectors is made under the bottomhole pressure that exceeds the fracturing pressure.

EFFECT: reducing oil production decline rate by producers and increasing oil recovery factor.

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Description

The invention relates to the oil industry and may find application in the development of purely oil deposits with low permeability reservoirs.

There is a method of developing low permeability reservoirs based on areal five-, seven-, nine-point systems for the placement of production and injection wells [Fazlyev R.T. Area flooding of oil fields. -M.: Nedra, 1979, pp. 7.47-49]. The disadvantage of this technical solution is the use of directional wells, the use of which on low-permeability reservoirs is unprofitable due to the low production rates of production wells and the low oil recovery coefficient.

Closest to the proposed invention is a method according to which, on horizontal production wells drilled in the direction of minimum horizontal formation stresses, multi-stage hydraulic fracturing (Fracturing) is performed - several hydraulic fracturing performed in different sections of the horizontal wellbore [E. Sayapov, I.R. Diyashev and A.V. Brovchuk "Application of Horizontal Wells with Multiple Hydraulic Fractures for the Development of Low Permeability Oil Reservoir in Western Siberia", paper IPTC 13395 presented at the International Petroleum Technology Conference held in Doha, Qatar, December 7-9, 2009].

A disadvantage of the known technical solution is the low technical and economic efficiency, which is associated with a high rate of decline in oil production and a low value of the final oil recovery coefficient due to the lack of maintaining reservoir pressure and oil displacement.

The solved problem of the presented development method is the cost-effective development of low-permeability oil deposits. The technical result is a decrease in the rate of decline in oil production and an increase in the final coefficient of oil recovery.

The problem is solved in that in the method of developing low-permeability oil deposits using horizontal wells with transversely directed hydraulic fractures, including drilling horizontal production wells, in-line placement of wells and orienting horizontal shafts in the direction of minimum horizontal formation stresses, and performing multi-stage hydraulic fracturing at the indicated horizontal production wells, according to the invention, parallel to the rows of horizontal production wells, alternating through one n series, drill rows of directional injection wells with completion in all hydraulic fracturing wells, while injection wells located opposite the middle of the horizontal length of the production wellbore, hydraulic fracturing and commissioning are carried out at the stage when all neighboring wells have already been put into operation: horizontal producing wells in adjacent rows - into production, the nearest injection wells in a row - into the injection, and the liquid is injected in directionally directed injection wells at bottomhole pressure, exceeds an pressure fracturing. The method is as follows.

1. Drill injection directional and production horizontal wells in a straight-line system, alternating rows of injection and production wells. The rows of wells and the direction of the horizontal wellbore of the producing wells are arranged taking into account the direction of horizontal stresses - in the direction of the minimum horizontal stress of the formation.

2. At production and boundary injection wells located at a distance from the middle of the horizontal well of production wells, hydraulic fracturing is immediately carried out after drilling and the wells are put into operation.

3. In injection wells located opposite the middle of the horizontal wellbore of the producing wells, hydraulic fracturing and commissioning are carried out at the stage when all neighboring wells are put into operation: the closest producing horizontal wells in adjacent rows are in production, the closest injection wells in a row are in download.

4. In this case, the fluid is injected in directionally directed injection wells at bottomhole pressure exceeding the fracture pressure.

Example

An oil reservoir with a low permeability reservoir is considered as an object of development. The reservoir is characterized by the following geological and geophysical parameters: occurrence depth - 2600 m, effective oil saturated thickness - 10 m, permeability coefficient - 0.001 μm, porosity coefficient - 0.16, oil saturation coefficient - 0.52, initial reservoir pressure - 25 MPa., Oil viscosity in reservoir conditions - 1.6 cP, oil density in reservoir conditions - 870 kg / m ³ , gas saturation pressure - 11.6 MPa, gas factor - 70 m ³ / t.

For this oil reservoir, the initial regional directions of the minimum and maximum horizontal formation stresses are determined. They can be determined in various ways: according to the results of cross-dipole broadband acoustic logging after hydraulic fracturing, in the direction of artificial fracturing, determined by the electric microimager [Latypov ID, Borisov GA, Khaidar AM, Gorin AN, Nikitin A .N., Kardymon D.V. Reorientation of the azimuth of the re-fracturing fracture in the fields of RN-Yuganskneftegaz LLC. // Oil industry. - 2011.-№6. - p. 34-38], according to the results of monitoring the development of hydraulic fractures during previous work using microseismic monitoring or microdeformation monitoring, etc. [J. H. Le Calvez, R.C. Klem, L. Bennett, A. Erwemi, M. Craven, J.C. Palacio "Real-Time Microseismic Monitoring of Hydraulic Fracture treatment: A Tool To Improve Completion and Reservoir Management"; B.C. Mironov, I.R. Diyashev, A.V. Brovchuk, B.M. Davidson “Mapping of hydraulic fractures with surface tilt gauges at the Palnikovsky field in Western Siberia”, article SPE 117097 was presented at the Russian Oil and Gas Technical Conference and Exhibition in Moscow on October 28-30, 2008]. Knowing the direction of these stresses, the oil deposit is drilled according to the proposed development system, the scheme of which is presented in figure 1. Figure 1 presents a diagram of the proposed development system, in which the horizontal trunk of the producing horizontal well (1) and the rows of injection directional wells (2) are placed in the direction of the minimum horizontal stress of the formation.

Rows of horizontal production wells with a barrel length of 1000 m are drilled in the direction of minimum horizontal stresses, with a distance between horizontal wells in the row of 400 m.Multi-stage transverse hydraulic fracturing is performed on these wells, therefore, the appropriate type of completion is chosen for them. In this case, an uncemented liner descends with the placement of several external packers. Packers are used to separate the stages of hydraulic fracturing, and their number depends on the number of hydraulic fracturing stages, the length of the horizontal section of the wellbore and the geological features of the object. There are special ports in the liner layout, with the aim of creating a connection between the downhole space and the formation and in the transport position are in the closed position. The ports are opened by dropping special balls, which at the same time isolate the previous stage of hydraulic fracturing from the current stage [E. Sayapov, I.R. Diyashev and A.V. Brovchuk "Application of Horizontal Wells with Multiple Hydraulic Fractures for the Development of Low Permeability Oil Reservoir in Western Siberia", paper IPTC 13395 presented at the International Petroleum Technology Conference held in Doha, Qatar, December 7-9, 2009]. Perform eight transverse hydraulic fracturing. After hydraulic fracturing and development, horizontal wells are put into production.

In addition to horizontal wells, directional injection wells are drilled with hydraulic fracturing. The rows of injection wells are located 300 m parallel to the rows of producing horizontal wells, alternating through one row. The distance between the injection wells in the row is 700 m. Not all injection wells are put into operation immediately after drilling. Injection wells located opposite the middle of the horizontal wellbore of a production well are put into operation with hydraulic fracturing only after all neighboring wells have been put into operation: the closest producing horizontal wells in adjacent rows are put into production, and the closest injection wells in a row are injected. The following is a detailed description of the implementation of this scheme.

Figure 2 presents an element of the development system, consisting of two horizontal production wells (1) and nine directionally directed injection wells (2) with hydraulic fractures (3) and auto-hydraulic fracturing (4). Auto-fracturing cracks are spontaneously developed cracks resulting from fluid injection at injection wells at bottomhole pressures above the fracture pressure [Maltsev V.V., Asmandiyarov R.N., Baykov V.A., Usmanov T. S., Davletbaev A. Ya. Research on the development of auto-fracturing cracks in the experimental section of the Priobskoye field with a linear development system. / Oil industry. - 2012. - No. 5. -S.70-73].

Consider the plot of the presented element of the development system, highlighted by a dashed rectangle in figure 2, which includes two horizontal production wells and three directional injection wells. Initially, hydraulic fracturing and commissioning are carried out from the edge wells of this section, represented by a dashed rectangle, i.e. from two horizontal production wells and two regional directional directional injection wells. The development of hydraulic fracturing and auto-hydraulic fracturing in these wells will occur in the direction of the initial maximum horizontal formation stresses. After these four boundary wells are put into operation, hydraulic fracturing and commissioning are performed on the injection well located in the center of the area marked by a dashed rectangle opposite the middle of the horizontal wellbore of the horizontal well. If the bottomhole injection pressure, fracturing pressure is exceeded, auto-hydraulic fracturing will develop. The development of hydraulic fracturing and auto-hydraulic fracturing will occur in the direction of two adjacent injection wells in a row - perpendicular to the initial directions of the maximum horizontal formation stresses, as shown in Fig.2.

In a similar manner, all such injection wells located opposite the middle of the horizontal shaft length of the producing horizontal wells are put into operation. The operation of neighboring injection wells in a row and production wells in adjacent rows will allow you to change the initial orientation of the minimum and maximum stresses in the environment of the injection wells under consideration, which will lead to a change in the azimuth of the hydraulic fracture and auto-hydraulic fracturing in the direction of neighboring injection wells in a row.

A hydrodynamic model has been created for the site of the considered reservoir with the layout of wells according to the prototype: nine horizontal production wells with a horizontal section of the wellbore of 1000 m with eight transversely directed fractures with a half length of 100 m are located in three rows of three wells each, with a distance between the wells in 400 m. Three variants of a development system with bottomhole pressure at producing horizontal wells of 8 MPa were calculated:

1. Option 1 - the prototype. Figure 3 presents the layout of the wells according to the prototype. The distance between the rows of producing horizontal wells is 300 m.

2. Option 2 - according to the invention. Figure 4 presents the layout of the wells according to the invention, with the placement in addition to Option 1 (according to the prototype), 28 directionally directed injection wells with a half-length of auto-hydraulic fracturing fractures - 350 m. Bottom-hole pressure at the injection wells - 45 MPa.

3. Option 3 - according to the invention. Figure 5 presents another arrangement of wells according to the invention, with the placement in addition to Option 1 (according to the prototype), 16 directional injection wells with half-length auto-fracturing fractures - 350 m. Bottom-hole pressure at the injection wells of 45 MPa.

Figure 6 and 7 presents the calculation results of the three options. In Fig.6 shows the dynamics of changes in cumulative oil production per unit area of the element, Fig.7 is the dynamics of changes in the coefficient of oil recovery. Figure 6 shows that the period of effective operation of production wells in Options 2 and 3 significantly exceeds the period of effective operation of production wells in Option 1, which indicates a decrease in the rate of decline in oil production at production wells in Options 2 and 3 (according to the invention) according to Compared with Option 1 (prototype). From Fig.7 it is seen that the oil recovery ratio increased to 0.345 for Option 2 and to 0.32 for Option 3 compared with 0.056 for Option 1.

Claims (1)

A method for developing low-permeability oil reservoirs using horizontal wells with transversely directed hydraulic fractures, including drilling horizontal production wells, in-line placement of wells and orienting horizontal shafts in the direction of minimum horizontal hydraulic stresses, and performing multi-stage hydraulic fracturing (hydraulic fracturing) at said horizontal producing wells wells, characterized in that parallel to the rows of producing horizontal wells, alternating through one poison, drill rows of injection directional wells with hydraulic fracturing at all wells, while on injection wells located opposite the middle of the horizontal length of the production well, hydraulic fracturing and commissioning are carried out at the stage when all neighboring wells are already put into operation: horizontal producing wells in adjacent rows - into production, the nearest injection wells in a row - into injection, and the liquid is injected in directional injection wells at bottomhole pressure, etc. higher fracture pressure.

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