RU2059062C1 - Method for developing oil deposits - Google Patents

Abstract

FIELD: oil production, particularly developing of oil deposits with collectors of low permeability. SUBSTANCE: method provides use of area or block-type developing system, injection of displacing agent into injection wells, discharge of fluid through producing wells and hydraulic rupture of the stratum after commence of drilling out the deposit. Wells of the given producing stratum or wells of upper (after making deeper) and lower horizons located along the line where producing wells of productive stratum are positioned. Fractures being initiated are directed from these wells to producing wells of the productive stratum. In this case when wells of upper or lower fracture horizons are used for hydraulic rupture, these wells are interconnected to producing wells of the productive stratum. EFFECT: high productivity. 4 dwg, 2 tbl

Description

 The invention relates to the oil industry, in particular to methods for developing oil deposits.

 Especially effective is its use in reservoirs with low permeability of the reservoir. The invention can be used on deposits with both low and high viscosity of oil, with carbonate and terrigenous reservoirs, on new ones being put into development and in the fields being developed at an early stage of operation.

With the traditional technology of developing oil deposits in production and injection wells, hydraulic fracturing is carried out, resulting in the formation of randomly (randomly) located fractures, sometimes of considerable length [1]
At the same time, the flow rates of wells increase, but unfavorable conditions are created for the process of oil displacement by water, which leads to premature breakthrough of the injected water through the resulting cracks and, as a result, to a decrease in the oil recovery coefficient.

 This disadvantage can be eliminated if, during hydraulic fracturing, cracks of a given direction are formed.

 There is a method of developing oil deposits [2] in which, in order to limit water inflow through hydraulic fractures using hydraulic fracturing, two adjacent producing wells are connected with a fracture using a composition to limit water inflow as a fracturing fluid.

 That is, directional cracks are created in order to form a screen that prevents water from entering.

 However, directional cracks can also be used as an element of the development system.

 The aim of the invention is to provide a method for developing oil deposits using directed hydraulic fractures, suitable for deposits where production drilling has already begun or production and injection wells have already been drilled, for deposits with any waterflooding system, both block and all types of areal water flooding systems.

 The goal is achieved by a method of developing oil fields, which provides for the injection of a displacing agent in injection wells, the selection of fluid from production wells and the intensification of the reservoir development process by hydraulic fracturing, while hydraulic fracturing is performed in wells of a given reservoir or in wells of overlying and underlying horizons located along the lines the location of the producing wells of the productive formation (this line should not cross the inside of the cell of the well mesh m).

 Fractures formed during hydraulic fracturing are directed from wells in which hydraulic fracturing is carried out to production wells of a productive formation. When using overlying and underlying horizons for hydraulic fracturing, formed cracks connect these wells with producing wells of the reservoir.

 When hydraulic fracturing is carried out in the producing well of a given reservoir, the length of the fracture may be less than the distance between the producing wells, i.e. these wells are not necessarily fissured.

 Due to the fact that cracks (increased permeability zone) are connected to production wells, fluid selection from the reservoir is intensified, and the direction of the cracks along the location of the production wells provides a more favorable picture of fluid filtration flows, contributing to an increase in oil recovery coefficient.

 Figure 1-4 shows a diagram of the implementation of the proposed method.

 PRI me R 1. Application of the method on a multilayer field.

The oil reservoir of the B1 carbonate layer of the Tournaisian stage of the Krasnogorodetsky deposit of the Samara region, characterized by low reservoir permeability (0.004 μm ² ) and high oil viscosity (35.8 MPa · s in reservoir conditions), was designed to be developed with a seven-point areal flooding system.

 Wells are currently being drilled at formation B1 and overlying formation B2. All wells of formation B2 are drilled with opening of formation B1.

 For the formation of cracks in each production well of the formation B1, the well that is closer to this line is selected from the wells of the overlying horizon located along the production line of the production wells of the formation B1.

 So near the location line of production wells 155 and 153 choose well formation B2 110.

 In the same way, for producing wells of formation B1 155, 156, 150, 151, 152 and 153, wells of overlying formation B2 are selected, respectively 110, 116, 115, 106, 102 and 103.

 In the planned wells, hydraulic fracturing is performed (for example, well 110), and in the corresponding production wells of the formation B1, fluid sampling is forced (respectively, in well 155).

 Using hydraulic fracturing in wells 110, 116, 115, 106, 102 and 103, it is planned to form cracks that connect these wells with production wells, respectively 155, 156, 150, 151, 152 and 153, i.e. connect the wells 110 and 155, 116 and 156, 115 and 150, 106 and 151, 102 and 152, 103 and 153 (Fig. 1).

 The distance between the wells that need to be connected by cracks is 50-100 m.

 After hydraulic fracturing in the above wells, artificial slaughter is installed in them above the top of formation B1 and these wells are used for their intended purpose in formation B2.

 Wells of underlying horizons are also used for hydraulic fracturing. These are wells that are planned to be transferred from the lower layers in connection with their watering or for technical reasons. In this case, after hydraulic fracturing, the wells are transferred to overlying horizons or used as producers to this horizon.

 When choosing wells of other horizons for hydraulic fracturing, the following factors are taken into account: proximity of the location of wells to the production line of production wells; the distance over which it is planned to draw a crack (based on technical capabilities or technological necessity); for new wells of overlying horizons, the distance between these horizons and the reservoir (i.e. how far should the wells be deepened); for old wells, their technical condition (the possibility of hydraulic fracturing in them).

 In addition, consider the possibility of further use of the wells of the upper horizons for their intended purpose (as production, injection, control, etc.) after hydraulic fracturing and installation of artificial face above the roof of the considered reservoir.

 When conducting hydraulic fracturing, one should not allow the direction of the generated cracks from the producing wells towards the injection well or the connection of the producing and injection wells with a crack, since in this case the efficiency of the process of oil displacement by water will sharply worsen, which leads to a decrease in oil recovery.

 PRI me R 2. The application of the method on deposits of highly viscous oil, developed with an area seven-point water flooding system.

 The A4 reservoir of the Bashkir layer of the Borovskoye field in the Samara Region is characterized by high oil viscosity (70 MPa · s) and low well productivity.

 Currently, the reservoir is being developed in a natural depletion mode. It is planned to continue drilling the reservoir and develop it with a seven-point areal flooding system. An analysis of the development (1993) provides for the use of development technology using hydraulic fracturing with the direction of the resulting fractures along the production line of the production wells. The length of the cracks is less than the distance between the producing wells.

 The sequence of operations when using the method for the areal seven-point development system is given in table 1 (figure 2).

 PRI me R 3. The application of the method on deposits with low viscosity oil, which is scheduled block development system.

The reservoir BS18 of the Kogalym field of the Tyumen region is characterized by low reservoir permeability and low oil viscosity (permeability of 0.008 μm ² , oil viscosity of 0.92 MPa · s).

 In the technological scheme, it was planned to develop a reservoir with a three-row block flooding system.

 Due to the low productivity of wells in the development analysis (1993), it is planned to switch to a more intensive single-row block flooding system and the use of reservoir development technology using directional hydraulic fracturing is envisaged.

 Fracturing is planned to be carried out in production wells with the direction of cracks along the line of location of production wells.

 The sequence of operations during the implementation of the method for a single-row block development system is given in table 2 (figure 3).

 As a result, cracks are created from the well 1300 towards the well 1301 and from the well 1303 to the well 1302 (FIG. 3).

 The sequence of operations was described above during the implementation of the method on deposits that have not yet entered development.

 The sequence of operations is the same as described above for deposits that have begun development: in the well to which the fracture is directed, fluid sampling is increased and injection of the displaced agent is increased in the injection well, after which hydraulic fracturing is carried out in the corresponding well (production well of this productive formation or well with an overlying or underlying horizon).

 The influence of directed cracks on the amount of fluid withdrawal and the oil recovery coefficient are estimated using mathematical modeling of the oil reservoir development process, using a three-dimensional mathematical model.

 To determine the effectiveness of the proposed method, two options for the development of a deposit site are considered (the site is located in the oil-water zone of the reservoir): 1 development option using traditional technology; Option 2 development when conducting directional deep-penetrating hydraulic fracturing.

 When modeling hydraulic fracturing, it was assumed that in the wells located in the oil-water zone, the upper (oil-saturated) part of the reservoir is opened and vertical cracks are formed only in oil-saturated interlayers, which have a rather poor connection with the underlying water-saturated layers (i.e., a high value of the anisotropy coefficient formation vertical).

In FIG. Figure 4 presents the simulation results in the form of characteristics of oil displacement by water, i.e. as a function of oil recovery (CIF) and the proportion of oil in the produced products (f _n ) from the relative fluid withdrawal (τ) for an element of a single-row waterflooding system (curve 1, development indicators with traditional technology, 2 with technology with directional deep penetrating hydraulic fracturing).

 As the calculations showed, the initial production rates of wells with the technology of developing a reservoir with hydraulic fracturing are 2 times higher, while the characteristic of oil displacement by water is significantly improved (Fig. 4), i.e. when developing to achieve the same oil content in the produced products (to the same water cut) in the variant with hydraulic fracturing, a higher oil recovery is achieved.

 Implementation of the technology using hydraulic fracturing allows to increase the development rate of the deposit by 2 times and increase the oil recovery coefficient.

Claims (1)

 METHOD FOR DEVELOPMENT OF OIL DEPOSITS, including injection of a displacing agent into injection wells, selection of fluid through production wells and hydraulic fracturing, characterized in that hydraulic fracturing is carried out in the wells of the reservoir or higher and lower horizons along the production line of the producing reservoir, moreover cracks direct from these wells to production wells.

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