RU2785044C1 - Method for developing oil ultra-low-permeability deposits - Google Patents

Abstract

FIELD: oil industry.

SUBSTANCE: invention relates to a method for the development of ultra-low permeability oil deposits. Horizontal wells are drilled with in-line placement of horizontal shafts in the direction of the initial minimum horizontal formation stresses. Cementing of liners is carried out to isolate the behind-the-casing intervals. The optimal number of hydraulic fractures is determined based on the length of the horizontal section of the wellbore, the geological and geomechanical features of the object, and the hydraulic fracturing technology. The trajectories of hydraulic fracture development are calculated taking into account the rotation of the hydraulic fracture trajectory based on the calculation of the stress-strain state in the area of horizontal wells. Cross-directional multi-stage hydraulic fracturing is performed in all wells. In horizontal wells, packer installations are installed to isolate alternating production and injection hydraulic fractures from each other. Fluid production and fluid injection are carried out simultaneously in each well through separated ports along two independent channels. An electric centrifugal pump is located in the first channel for fluid production, and fluid is injected through the second channel at a bottomhole pressure not exceeding the formation fracturing pressure.

EFFECT: increasing the oil recovery factor and reducing the time to reach its maximum value.

1 cl, 7 dwg

Description

The invention relates to the oil industry and can be used in the development of oil deposits with ultra-low permeability highly dissected reservoirs.

A known method for the development of oil deposits, based on the presentation of areal symmetrical layouts of production and injection directional wells (NNS) in the form of in-line systems, taking into account the presence of hydraulic fractures (HF) and auto-HF, their size and direction of development [Technical and economic analysis of development systems formed by hydraulic fractured wells / M.M. Khasanov, V.A. Krasnov, T.R. Musabirov, R.K. Mukhamedshin // Oil industry. - 2009. - No. 2. - S. 92-96]. The limitation of the application of this development method is that it does not take into account the geological features of low-permeability reservoirs, in particular, the dissection and disconnection of the reservoirs.

A known method for the development of low-permeability reservoirs, based on a linear in-line placement of HNS with hydraulic fracturing, taking into account the direction of the regional stress of the field and the effect of auto-fracturing, while the rows of injection and production wells are placed alternating through one in the direction of maximum horizontal stresses of the reservoir [Choice of the optimal development system for deposits with low-permeability reservoirs / V.A. Baykov, R.M. Zhdanov, T.I. Mullagaliev, T.S. Usmanov // Oil and gas business. - 2011. - No. 1].

The disadvantage of these technical solutions is the use of NNS, the use of which in reservoirs with ultra-low permeability is unprofitable due to the low efficiency of the reservoir pressure maintenance system (RPM) and rapid drops in production rates.

In low-permeability reservoirs with high stratification and low connectivity of sand bodies, the use of horizontal wells with multi-stage hydraulic fracturing (MSHF) is relevant. This is due to the fact that horizontal wells, in contrast to HNS, are in contact with a larger area of the reservoir; due to multistage hydraulic fracturing, the connectivity of sand bodies and well productivity increase.

A known method of developing oil deposits using producing horizontal wells drilled in the direction of the minimum horizontal stresses of the formation with transverse directional MHF [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, 7-9 December 2009] (analogue 1) .

The disadvantage of this 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 factor due to the lack of a GSHD system and oil displacement.

Closest to the proposed technical solution is a method of developing an oil deposit with in-line placement of production horizontal wells in the direction of the minimum horizontal stresses of the reservoir and performing transverse directional multi-stage hydraulic fracturing on them, taken as a prototype. The method includes drilling rows of injection pumping stations parallel to rows of producing wells with alternation through the row [RF patent No. 2515628, IPC E21V4 3/18, 43/30, published 05/20/2014]. At the same time, on injection pumping stations located opposite the midpoints of the lengths of producing horizontal wells, hydraulic fracturing and start-up are carried out at the stage when the nearest wells are already put into operation in order to develop hydraulic fracturing and auto-fracturing fractures in the direction perpendicular to the initial direction of maximum horizontal formation stresses.

The disadvantage of this method is that there is a risk of fracture breakthrough auto-fracturing injection wells placed opposite the middle of the lengths of horizontal wellbores of production wells, production horizontal wells (HW). This method was chosen as a prototype.

The objective of the invention is to create a method for the development of ultra-low-permeability oil deposits, which eliminates the disadvantages of analogues and prototype.

The technical result of the invention is to increase the oil recovery factor (ORF) and reduce the time to reach the maximum ORF.

The technical result is achieved by the fact that in a method for developing oil ultra-low-permeability deposits, including drilling horizontal wells with in-line placement of horizontal wellbores in the direction of the initial minimum horizontal stresses of the formation, cementing liners to isolate behind-the-casing intervals, determining the optimal number of hydraulic fractures based on the length of the horizontal section of the wellbore, geological and geomechanical features of the object, hydraulic fracturing technology, calculation of hydraulic fracture development trajectories taking into account the rotation of the hydraulic fracture trajectory based on the calculation of the stress-strain state in the area of horizontal wells and the implementation of transverse multi-stage hydraulic fracturing in all wells, according to the present invention, in horizontal wells, packer units are installed to isolate alternating production and injection fractures from each other. Hydraulic fracturing is carried out simultaneously in each well. at the fluid and injection of liquid through disconnected ports through two independent channels, wherein the first channel is equipped with an electric centrifugal pump for fluid production, the second channel is used to inject fluid at a bottomhole pressure not exceeding the formation fracturing pressure.

Thus, the achievement of the technical result is due to the convergence of the extraction and injection zones without increasing the density of the well grid, taking into account the rotation of the hydraulic fracture trajectory and the associated risks of crossing adjacent production and injection hydraulic fractures in the reservoir and obtaining premature water cut in the well production.

The implementation of the proposed method is illustrated by the following materials.

Fig. 1, 2 - schemes for the development of oil deposits with alternating production and injection hydraulic fractures, where 1 - wells that are drilled in the direction of the minimum horizontal stresses of the reservoir; 2 - isolated production hydraulic fractures; 3 - hydraulic fracturing injection cracks; σ _min - the direction of the minimum horizontal stress of the formation; σ _max - direction of the maximum horizontal stress of the formation.

Fig. 3 - development scheme similar to 1, where there is no reservoir pressure maintenance system, the deposit is operating in depletion mode.

Fig. 4 - scheme of development according to the prototype, where 1 - wells that are drilled in the direction of the minimum horizontal stresses of the formation; 2 - injection wells, the hydraulic fractures of which are directed in the direction of the maximum horizontal stresses of the formation σ _max ; 3 - injection wells, hydraulic fractures of which are directed in the direction of the initial minimum horizontal stresses of the formation σ _min .

Fig. 5, 6 - calculated graphs of the change in oil recovery factor, where option 1 is a variant of development systems similar to 1, option 2 is a variant of development systems based on a prototype, options 3-8 are options for development systems according to the invention, in which the number of hydraulic fractures varied.

Fig. 7 - calculated values of oil recovery factor and the time to achieve it depending on the distance between the production and injection fractures of hydraulic fracturing, where option 1 is the option of development systems according to analog 1, option 2 is the option of development systems according to the prototype, options 3-8 are options for development systems according to the invention , in which the number of hydraulic fractures varied.

The method is carried out as follows.

1. At the field, rows of horizontal wells 1 are drilled in the direction of the minimum horizontal stresses of the formation (Fig. 1, 2). The initial regional directions of the minimum and maximum horizontal stresses of the formation can be determined from the results of cross-dipole broadband acoustic logging after hydraulic fracturing, in the direction of artificial fracturing, determined by an electric microimager [Latypov I.D., Borisov G.A., Khaidar A.M., Gorin A. N., Nikitin A.N., Kardymon D.V. Reorientation of the fracture azimuth of repeated hydraulic fracturing at the fields of OOO RN-Yuganskneftegaz // Neftyanoe khozyaystvo. - 2011. - No. 6. - With. 34-38], based on the results of monitoring the development of hydraulic fractures during previous work using microseismic monitoring or microdeformation monitoring [J.N. 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". SPE Hydraulic Fracturing Technology Conference, College Station, Texas. Extended abstract, SPE 106159. - 2007].

2. On all wells, liner cementing is carried out to isolate the behind-the-casing intervals.

3. Determine the optimal number of hydraulic fractures, which depends on the length of the horizontal section of the wellbore, geological and geomechanical features of the object (including the features of the profile of mechanical properties along the section), hydraulic fracturing technology, and the influence of local changes in the stress-strain state in the well area on the trajectory of transverse hydraulic fractures.

4. Evaluation (calculation) of the trajectories of hydraulic fracturing for the optimal arrangement of the position of hydraulic fractures along the length of the horizontal wellbore in order to reduce the risks of crossing hydraulic fracturing fractures, minimizing premature water cut in the well production and obtaining strictly perpendicular hydraulic fractures relative to the horizontal wellbore is carried out based on the calculation of stressed -deformed state in the area of horizontal wells in the geomechanical simulator.

5. Next, transverse multi-stage hydraulic fracturing is carried out on the wells. Two-pipe systems with packers are installed in the liners, which serve to isolate hydraulic fractures, and the number of hydraulic fractures depends on the length of the horizontal section of the wellbore and the geological features of the object.

6. After the multi-stage hydraulic fracturing, all wells are launched into fluid production and fluid injection, while production and injection are carried out simultaneously through two independent channels through alternating isolated production 2 and injection 3 hydraulic fractures. The bottomhole pressure in the injection line should not exceed the formation fracture pressure. In FIG. Figure 2 shows a diagram of the implementation of the method when hydraulic fractures in wells in the central vertical row are inverted.

An example of a specific implementation of the method.

An oil deposit with an ultra-low-permeability reservoir is considered as an object of development, characterized by the following geological and geophysical parameters: occurrence depth - 2600 m, effective oil-saturated thickness - 10 m, permeability coefficient - 0.0003 µm ² , porosity coefficient - 0.17, oil saturation coefficient - 0.5, initial reservoir pressure - 260 atm, oil viscosity in reservoir conditions - 1.5 cP, oil density in reservoir conditions - 870 kg/m ³ .

According to the scheme of the proposed development system (Fig. 1, 2), rows of horizontal wells with a bore length of 600 m are drilled in the direction of the minimum horizontal stresses of the formation, arranging the wells in three rows, three wells in a row with distances between horizontal wells in a row of 100 m and between rows 300 m wells. In these wells, transverse multi-stage hydraulic fracturing is performed with fracture half-lengths of 140 m with alternating production and injection fractures, which simultaneously start fluid 2 production and fluid 3 injection. In the geomechanical simulator, based on the calculation of the stress-strain state in the area of horizontal wells the required distance is estimated for arranging the position of hydraulic fractures along the length of the horizontal wellbore to reduce the risks of crossing adjacent hydraulic fractures, minimizing premature water cut in the well production and obtaining strictly perpendicular hydraulic fractures relative to the horizontal wellbore. The growth of hydraulic fractures in these wells will occur in the direction of the initial maximum horizontal stresses of the formation.

For comparison, 2 variants of development systems according to analogue 1 and prototype and 6 variants of development systems according to the invention, in which the number of hydraulic fractures varied, were calculated.

With a non-inverted fracture order in the central vertical row of wells: option 3 with 13 fractures every 50 m, option 4 with 9 fractures every 75 m, option 5 with 7 fractures every 100 m (Fig. 1). With inverted hydraulic fracture order in the central vertical row of wells: option 6 with 13 fractures every 50 m, option 7 with 9 fractures every 75 m, option 8 with 7 fractures every 100 m (Fig. 2). Bottom hole pressure in the first channel (production fractures of hydraulic fracturing) is 70 atm, in the second channel (injection fractures of hydraulic fracturing) - 450 atm.

According to option 1, according to analogue 1 (Fig. 3), horizontal production wells 600 m long were drilled in three rows, three wells in a row in the direction of the initial minimum horizontal stresses of the formation, performing transverse multi-stage hydraulic fracturing with 7 hydraulic fractures every 100 m from the floor 140 m long. The distance between the rows of producing horizontal wells is 300 m, between the wells in the rows is 100 m, the density of the well grid is 21 ha/well.

According to option 2, according to the prototype (Fig. 4), in addition to option 1, 28 injection pumping stations with auto-fracturing fractures with a floor length of 300 m in 4 rows of 7 wells in a row are placed in the development system, alternating with rows of horizontal wells, 3 wells in a row . The distance between rows of wells is 300 m, between horizontal wells in rows is 400 m, between injection wells in rows is 500 m, the density of the well grid is 20 ha/well. Hydraulic fracturing and commissioning are carried out on horizontal production 1 and injection pumps 2, located in the corners of the development scheme. The development of hydraulic fractures and auto-fracturing in these wells will occur in the direction of the initial maximum horizontal stresses of the formation. Hydraulic fracturing and commissioning of injection HPS 3, located opposite the middle of horizontal production wells, is carried out after the remaining wells are put into operation, while the development of auto-HF fractures in these wells will occur in the direction of two adjacent previously launched injection HPS in the same in a row - parallel to the initial directions of the minimum horizontal stresses of the formation.

In FIG. 5 and 6 shows the results of calculations showing the dynamics of changes in oil recovery factor over 10 years according to the invention for options 3, 4, 5 and 6, 7, 8, respectively, in comparison with option 1 according to analogue 1 and option 2 according to the prototype. According to the invention, the largest ORF=0.37 is achieved for option 8, the smallest ORF=0.34 for option 3, both of which exceed the values of ORF=0.05 for option 1 according to analogue 1 and ORF=0.29 for option 2 to the prototype.

From FIG. 5 and 6, it can be seen that the terms of effective operation of horizontal wells for all options, according to the invention, exceed the period of effective operation of production wells according to option 1, which indicates a decrease in the rate of decline in oil production. The maximum well performance indicators, according to the invention, for all options are achieved in a much shorter period than for option 2: for 2 years for option 3 with ORF=0.34 and for 6.5 years for option 8 with ORF=0.37. For option 2, recovery factor = 0.11 after 2 years, recovery factor = 0.24 after 6.5 years, and the maximum value of recovery factor = 0.38 is reached only 40 years after the wells are put into operation.

A significant reduction in the time to reach the maximum oil recovery factor and cumulative oil production leads to a quick payback of costs. In FIG. 7 shows the calculated maximum recovery factor and the time to achieve it for all options according to the invention in comparison with option 2. With the same number of cracks and distances between them, the recovery factor values are greater for options with inverted order of cracks. At the same time, the smaller the distance between the fractures, the shorter the time to reach the maximum recovery factor, and the recovery factor values change insignificantly and amount to ~ 0.36-0.37. Increasing the distance between the injection and production fractures by more than 100 m is not advisable, since in this case the time to reach the maximum oil recovery factor increases exponentially.

Thus, the application of the invention will make it possible to achieve high oil recovery factors and reduce the time to reach its maximum value.

Claims (1)

A method for developing oil ultra-low-permeability deposits, including drilling horizontal wells with in-line placement of horizontal wellbores in the direction of the initial minimum horizontal stresses of the formation, cementing liners to isolate behind-the-casing intervals, determining the optimal number of hydraulic fractures based on the length of the horizontal section of the wellbore, geological and geomechanical features of the object, technology hydraulic fracturing, calculation of the trajectories of hydraulic fracturing development taking into account the rotation of the trajectory of hydraulic fracturing fractures based on the calculation of the stress-strain state in the area of horizontal wells and the implementation of transverse multi-stage hydraulic fracturing on all wells, characterized in that packer systems are installed in horizontal wells to isolate each other from other alternating production and injection hydraulic fractures and carry out simultaneously in each well fluid production and fluid injection through separated ports in two independent channels, and in the first channel there is an electric centrifugal pump for fluid production, through the second channel fluid is injected at a bottomhole pressure not exceeding the formation fracturing pressure.

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