RU2208140C1 - A method of development of oil pool with low-permeability reservoirs - Google Patents

Abstract

FIELD: development of oil deposits, particularly, development of oil pools with low- permeability reservoirs. SUBSTANCE: method includes drilling of producing and injection wells, injection of water into formation for displacement of oil to producing wells and performance of hydraulic fracturing of formation. Producing and injection wells are drilled with horizontal wellbores parallel to one another in plan by intersecting of all low-permeability formations from roof to bottom of oil pool. Drilled in structure crest are vertical wells along revealed or supposed occurrence of natural fractures with location of bottomholes of these wells on extensions of extrapolated straight lines with respect to horizontal wellbores of injection wells. After that, hydraulic fracturing of formation is accomplished from these wells. Water is injected into vertical wells in which hydraulic fracturing of formation is effected, and into horizontal injection wells. Injected water contains chemical reagents preventing swelling of argillaceous particles and interlayers, and reagents for equalizing of injectivity profile. Which are introduced into injected water after 50-80% water cutting of recovered products. EFFECT: higher efficiency of method in case of layer heterogeneity of formations. 3 cl, 2 dwg

Description

 The present invention relates to the field of oil field development and helps to increase the efficiency of oil production from productive sediments with hard-to-recover oil reserves.

 The subject of the invention is an oil reservoir with low permeability reservoirs.

A known method of developing low-permeability reservoirs based on areal five-, seven-, nine-point systems for locating production and injection wells (see Fazlyev R.T. ) The disadvantages of the known technical solutions, due to the use of vertical wells, are
low initial and current oil production rates,
low coverage factor
low oil recovery rates.

Closest to the proposed one is a method of developing oil fields based on the use of horizontal wells (see Erokhin V.P. et al. Experience and problems of building horizontal wells. // Oil industry, 9, 1997, p. 32-35). The disadvantages of this development method are as follows
the desire to transfer the idea of five-point and other on-site development systems to systems with horizontal wells leads to ignoring the real geological situation in the reservoir, which is accompanied by a decrease in the efficiency of the oil production process;
mutually perpendicular placement of horizontal wells in the case of stratified heterogeneity of the formation causes a decrease in the production rate of at least a couple of wells for oil, as well as premature flooding of produced products;
These shortcomings predetermine a decrease in the final oil recovery coefficient (CIN).

The present invention is based on the task of creating an effective method for the development of low permeability reservoirs, taking into account their layered heterogeneity. This goal is achieved through
combining the advantages of horizontal wells (hydraulic wells) and hydraulic fracturing (hydraulic fracturing);
adequate consideration of the real layered heterogeneity of the low permeability reservoir;
chemical treatment of water injected into the reservoir.

 The achievement of this task is achieved by the fact that in the method of developing a reservoir with low permeability reservoirs, including drilling production and injection wells, pumping water into the formation in order to displace oil to production wells and conducting hydraulic fracturing, production and injection wells are drilled with horizontal shafts parallel to each other to a friend in plan, with the intersection of all low-permeability formations from the roof to the bottom of the reservoir, while vertical wells are drilled along the identified silt in the arch of the structure supposed tracing of natural fracturing with the location of the faces of these wells along the extrapolation lines relative to the horizontal wells of injection wells, after which hydraulic fracturing is performed in these wells, and water is injected into vertical wells in which hydraulic fracturing has been performed, and into horizontal injection wells while the injection of water is carried out with chemical reagents that prevent the swelling of clay particles and layers, and the reagent to align the injectivity profile, the latter being introduced into the injected water after flooding the produced products by 50-80%.

The proposed method is based on the fact that
- when crossing low-permeability reservoirs from the roof to the bottom with horizontal trunks of production and injection wells and pumping water into hydraulic fractures, a coverage factor close to unity is reached;
- involvement in the drainage process of all low-permeability formations ensures the highest oil production rate of producing wells and the highest water injection rate of injection wells;
- water injection into hydraulic fractures contributes to the intensification of the process of oil development and production, and also prevents the possibility of negative movement of injected water to the bottom of production wells through natural fracture systems;
- in the presence of clay minerals, treatment of the injected water with chemicals (for example, various salts) prevents clay swelling, which means a decrease in the injectivity of injection wells and a decrease in the vertical sweep coefficient;
- alignment of the injectivity profile in injection wells (for example, using polymers) provides an increase in the vertical coverage coefficient and, consequently, the value of the final oil recovery coefficient.

 The method is as follows.

 According to modern practice of designing the development of oil and gas fields, the optimal technological parameters of the development system are found as a result of multivariate hydro-gas-dynamic and technical and economic calculations using three-dimensional (3D) geological and technological models of reservoirs and the corresponding software package. This is due to the fact that there are many optimized parameters and they depend in a complex way on the parameters of the productive formation and the formation fluids saturating it. Therefore, a statement of the implementation of the proposed development method is given in relation to a reasonable optimal development option.

 The oil deposit is drilled by systems of horizontal production and injection wells as shown in Fig. 1, where a) shows a profile section, and b) is a top view in which 1 is an injection well, 2, 3 are horizontal production wells, 4 - vertical well, 5 - hydraulic fracturing. The trunks of production and injection wells are arranged parallel to each other (to the greatest extent parallel to the geometrical features of the reservoir, restrictive conditions on the surface). The length of the horizontal trunks is such that they intersect all low-permeability interlayers from the roof to the bottom of the formation. Hereinafter, horizontal trunks, as usual, are understood to be strictly horizontal trunks, as well as slightly tilted towards the external water-oil contact (BHC) or trunks with some ascension in relation to the BHC outer contour.

 The distance between the horizontal trunks, as well as the degree of exceeding the marks of the horizontal trunks from the surface of the OWC, are determined, as noted, based on calculations using a 3D hydrodynamic model of the formation.

 In the arch of the structure, where the fracture of the reservoirs or the predisposition to crack formation is usually most pronounced, a system of vertical wells is drilled so that their bottom faces extend along the trajectory of the injection wells.

 In all vertical wells, hydraulic fracturing is carried out. However, their main purpose is not to increase the productivity or injectivity of vertical wells, but to increase the coverage factor and oil recovery rates.

 Oil is taken from the production well system, and water is injected both into horizontal injection wells and into vertical wells stimulated by hydraulic fracturing.

 In the proposed method, injection wells and wells with hydraulic fracturing provide the creation of extensive displacement fronts, which contributes to an increase in the area coverage factor by displacement, and hence, oil recovery factor, and also leads to an increase in production wells, which is important for the type of reservoir under consideration.

 In the case of significant areal sizes, drilling is carried out at different vertical elevations of several systems of horizontal production and injection wells, as well as systems of vertical wells (see figure 2). Similarly, if the reservoir is waterflooding, then the elements of development under consideration are “replicated” over the area of the reservoir above the surface of the oil and gas complex.

 Due to the prevailing presence of a sharp layered heterogeneity of the reservoir according to reservoir properties, there will always be a process of uneven flooding of individual layers and, consequently, production wells. Therefore, when the specified degree of water cut (50-80%) of the produced products is reached, reagents are added to the injected water, which help to equalize the injectivity profile, and therefore, increase the vertical sweep rate of the oil displacement process. For these purposes, in recent years, the biopolymer BP-92, Temposkrin, solutions of sodium silicate with hydrochloric and other acids, RITIN and others have become widespread.

 In the case of clay particles and clay interlayers in the reservoir, the need arises for the chemical treatment of the injected water in order to prevent their swelling with corresponding negative consequences. Such water treatment using potassium chloride, cationic surfactants, brine mineralized water are common in oil production practice and they are included as an integral element in the proposed development method.

 Example.

 An oil reservoir with low permeability reservoirs with developed layered reservoir heterogeneity (Western Siberia) is considered as an object of development. Geological oil reserves are estimated at 20 million tons.

 The traditional approach to the development of this reservoir provides a final recovery factor of 20%, therefore, recoverable oil reserves amount to 4 million tons.

 The preferred distance between the wells in the traditional approach is 450 m, in the case of the proposed technology, the optimal distance between horizontal shafts increases to 630 m.

 Due to the increase in the initial and current oil production rates of the producing horizontal wells, the total required number of wells for the development of the reservoir is 1.5 times less. Given the costs of hydraulic fracturing, the capital costs of developing the proposed and traditional technologies become almost the same.

 Then the implementation of the proposed technology with chemical treatment of the injected water provides a final recovery factor of 39%, i.e. recoverable oil reserves are equal to 7.8 million tons, or 3.8 million tons more than with the traditional approach.

 Such additional oil production makes the process of developing the reservoir under consideration cost-effective at any oil price above $ 11 per barrel.

 Thus, the above research results confirm the validity of the proposed approach to the development of oil deposits from the considered type of reservoirs with hard-to-recover oil reserves.

Claims (3)

 1. The method of developing deposits with low permeability reservoirs, including drilling production and injection wells, pumping water into the reservoir, displacing oil to production wells and conducting hydraulic fracturing, characterized in that the production and injection wells are drilled with horizontal shafts parallel to each other in plan with the intersection of all low-permeability formations from the roof to the bottom of the reservoir, while vertical wells are drilled along the identified or proposed trace in the arch of the structure fracture with the location of the faces of these wells along the extrapolation lines with respect to the horizontal wells of injection wells, after which hydraulic fracturing is performed in these wells, and water is injected into vertical wells in which hydraulic fracturing has been performed, and into horizontal injection wells, water is injected with chemicals that prevent the swelling of clay particles and layers, and reagents for alignment of the profile ti, the latter being introduced into the injection water after the water cut by 50-80%.  2. The method according to claim 1, characterized in that in the case of the significant areal dimensions of the oil reservoir, the systems of the horizontal and vertical wells under consideration are constructed at different elevations of the reservoir.  3. The method according to claim 1, characterized in that in the case of a floating reservoir, the considered development elements are relatively evenly distributed over the area of the reservoir above the surface of the oil-water contact.

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