RU2513962C1 - Oil deposit development method - Google Patents

Abstract

FIELD: oil and gas industry.SUBSTANCE: direction of reservoir-scale fractures is determined, the formation is drilled by vertical and/or inclined wells and downhole splitters as per square grid pattern and five-spot system is formed with drilling in the centre and corners of the system elements by vertical and/or inclined wells and drilling between the central and corner wells in the development pattern of downhole producing splitter with rounded borehole ending, and working fluid injection through injection wells and product recovery through producing wells. If producing wells are flooded the water-flooding interval is identified and water-flooded intervals are isolated. According to the invention, before drilling of the formation sections with total oil-filled thickness of more than 6 m are determined in carbonate reservoirs and/or sections with net oil thickness of 2 m at least in oil zone and at least 4 m in water-oil zone in terrigenous reservoirs. At these sections before drilling of downhole producing splitter direction of reservoir-scale fractures is specified. The downhole splitter is made with semi-ellipse shape which major axis is directed at angle of 30-60° to direction of reservoir-scale fractures with ratio of minor semi-axis to the major semi-axis equal to 0.1-0.8. At that boreholes of producing downhole splitters are made ascending with minimum distance in the lower part up to water-oil contact of 4 m for carbonate reservoirs and 2 m for terrigenous reservoirs and in the upper part with minimum distance of 1 m up to the roof of productive strata.EFFECT: improving coverage of the productive stratum by development and increasing its production rate.2 cl, 3 ex, 3 dwg

Description

The invention relates to the oil industry and may find application in the development of oil deposits with a reservoir having a natural fracture.

A known method of developing deposits of a multilayer oil field with water-oil zones and / or massive type, including measurements of oil, water and water injection to clarify the current conditions of development and modeling of the development of the reservoir, determining the minimum distance from the open interval to the oil-water contact at which it does not occur premature flooding of well products. In the known method, it is proposed to drill branched horizontal and / or subhorizontal wells, the main horizontal and / or subhorizontal well being located above the oil-water contact at a minimum distance, ensuring an anhydrous period of operation of the wells, and horizontal and / or subhorizontal and / or vertical branches are drilled along ascending profile with the same azimuth as the main horizontal and / or subhorizontal trunk and / or with a departure from it towards the roof of the reservoir or interlayers (RF patent No. 2282022, CL EV 43/20, publ. 08/20/2006).

The disadvantage of this method is the low oil recovery due to insufficient coverage of the reservoir by displacement over the area and high capital costs for the construction of wells in the element.

Closest to the proposed invention in technical essence is a method of developing an oil reservoir, comprising drilling a reservoir with horizontal and vertical wells on a square grid and forming elements by drilling in the center of an element of a vertical and / or directionally directed injection well, drilling multilateral wells producing horizontal wells on the sides of the elements, injecting working reagent through injection wells cyclically and product selection through production wells, production measurements n oil, water and injected fluid, conducting hydrodynamic studies and maintaining reservoir pressure in the selection zone at the initial level. In the known method, before drilling the deposits, areas with total oil-saturated thicknesses of more than 13 m in carbonate reservoirs and / or areas with effective oil-saturated thicknesses of at least 3 m in the oil zone and at least 5 m in the oil-water zone in terrigenous reservoirs are drilled, vertical and / or a directionally directed injection well in the center of each element, the sides of each element are closed with multilateral wells with a horizontal end in the form of semicircles, each of which covers half of the element, with about a bottom ascending branch in the middle of the semicircle, directed to the corner of the element for producing oil reserves in the underfloor part of the reservoir, replacing two horizontal or three vertical and / or directional wells in the element along the sides and corners of the elements, the displacing working reagent is injected through the injection well into the lower part of the productive interval cyclically, determine the optimal injection period at which the maximum pressure recovery in the selection zone and the expression of oil from the matrix (RF Patent No. 2439299, cl. ЕВВ 43/20, publ. 01/10/2012 - prototype).

The known method allows to achieve enhanced oil recovery, however, 1/4 of the reservoir remains unreached by displacement over the area. Also, in fractured reservoirs, water breakthrough occurs, which reduces final oil recovery.

The proposed invention solves the problem of increasing the coverage of the formation by exposure and, accordingly, increasing the oil recovery of the productive formation.

The problem is solved in that in a method for developing an oil reservoir, including determining the direction of fracture of the reservoir, drilling the reservoir with vertical and / or directional and multilateral wells in a square grid and forming five-point elements by drilling in the center and at the corners of the element of vertical and / or directional injection wells and drilling between central and corner wells in an element of a multilateral well with a rounded barrel end, pumping the working agent through h injection wells and product selection through production wells, according to the invention, prior to drilling the deposits, areas with total oil-saturated thicknesses of more than 6 m in carbonate reservoirs and / or areas with effective oil-saturated thicknesses of at least 2 m in the oil zone and at least 4 m in the water-oil zone are distinguished in terrigenous reservoirs, in these areas, before drilling a multilateral well, the direction of fracture of the reservoir is refined, a multilateral well is made in the form of a semi-ellipse, whose axis is directed at an angle of 30-60 ° to the direction of fracturing with the ratio of the minor axis to the major axis of the ellipse 0.1-0.8, while the trunks of multilateral wells are ascending with a minimum distance in the lower part to the oil-water contact of 4 m for carbonate collectors and 2 m for terrigenous reservoirs, in the upper part - with a minimum distance of 1 m to the roof of the reservoir.

When watering producing wells, waterlogging intervals are determined and the waterlogged intervals are isolated.

SUMMARY OF THE INVENTION

The oil recovery of an oil reservoir is significantly affected by the coverage of the reservoir by impact. Existing technical solutions do not fully allow the selection of oil from the reservoir. The proposed invention solves the problem of increasing oil recovery deposits. The problem is solved as follows.

Figure 1-3 shows the layout of wells in the reservoir with the allocation of development elements, the layout of the element in the plan and the profile of the producing well. Accepted designations: 1-9 - vertical and / or directional wells located at the corners of the development element, initially producing, able to be converted into injection wells, 10-13 - vertical and / or directional wells in the center of the development element, initially producing, capable of being converted to injection, 14-17 - multilateral wells with a half-ellipse plan in the plan, h - oil saturated thickness, S - direction of fracture of the reservoir, a / 2 - major axis, b / 2 - minor axis of the ellipse projections of the producing well in the plan, c is the distance from the multilateral wells of the producing well to the vertical injection well, L is the distance between vertical and / or directional wells in the corners of the element, x is the distance from the multilateral well bore in the lower part to the oil-water contact, y is in the upper part to the roof of the reservoir.

The method is implemented as follows.

A section of a massive deposit of carbonate deposits or a section of a reservoir-arch deposit of terrigenous reservoirs, the productive strata of which are represented by a pore-fracture type, is drilled with a rare square grid of vertical and / or directional injection wells 1-9 (Fig. 1). In the center of each element (square), vertical and / or directional wells 10-13 are also drilled. Carry out the arrangement of wells. In the process of drilling wells, the geological structure of the reservoir is specified.

Oil is produced from wells 1-13. Measure oil production, water, reservoir pressure, hydrodynamic studies. Structural maps are constructed over the roof of reservoirs of the reservoir under consideration and maps of the total oil-saturated thicknesses of the massive deposits in carbonate reservoirs and effective oil-saturated thicknesses in reservoir-type deposits of terrigenous deposits. Specify the direction of fracture of the reservoir. According to the structural map, a site with recommended thicknesses with the highest hypsometric marks of the drilled wells is distinguished. In this area in each cell, which consists of 2 wells (one in the center element and the _^fourth element of the well in the corners, Figure 2) disposed between the well 10 located at the center, and wells 1, 2, 8, 9 located in the corners of the element, a multilateral well production well 14 (FIG. 2), having a horizontal wellbore in the reservoir, which is in plan view a semi-ellipse shape (in the area, this is well 14-17, FIG. 1). The major axis of the semi-ellipse a is directed at an angle α = 30-60 ° to the fracture direction of the reservoir S, while the ratio of the minor axis b / 2 of the ellipse to its major axis a / 2 is b / a = 0.1-0.8. Moreover, the trunks of a multilateral well are ascending with a minimum distance in the lower part to the oil-water contact (WOC) x = 4 m, in the upper part with a minimum distance y = 1 m to the roof of the reservoir (Fig. 2).

All wells 1-13 of the element at the time of commissioning of the multi-hole production well 14-17 are transferred under injection of produced water. During operation of a multilateral well, a water breakthrough occurs, primarily along vertical cracks from the aquifer of the reservoir into the lower part of the ascending shafts. When water cut more than 98% of the well is stopped, geophysical surveys are carried out, the intervals of well watering are determined. Then, the waterlogged intervals are cut off with water swellable packers or waterproofing compounds and the wells are put into operation again.

The result of the implementation of this method is to increase the degree of oil recovery.

Examples of specific performance of the method.

Example 1. A section of a massive reservoir, the productive strata of which are represented by pore-crack carbonate deposits of the Tournaisian stage, is drilled with a rare square grid of vertical injection wells 1-9 (Fig. 1) with a distance between wells of L = 1200 m. Vertical injection wells are also drilled in the center of each element 10-13. Carry out the arrangement of wells. In the process of drilling wells, the geological structure of the reservoir is specified.

Carry out oil production from injection wells 1-13. Measure oil production, water, reservoir pressure, hydrodynamic studies. Structural maps are constructed on the roof of reservoirs of the reservoir under consideration and maps of the total oil-saturated thicknesses of the massive reservoir. Clarify the direction of reservoir fracture by geophysical surveys. The predominant direction of fracturing S according to the research results was found north-west (figure 1). According to the structural map, a site is identified on a massive deposit in carbonate reservoirs with total oil-saturated thicknesses of more than h = 6 m (Fig. 2) with the highest hypsometric marks of the drilled wells. In this area in each cell, which consists of 2 wells (one in the center element and the _^fourth element of the well in the corners, Figure 2) disposed between the well 10 located at the center, and wells 1, 2, 8, 9 located in the corners of the element, a multilateral well production well 14 (FIG. 2) in the form of a semi-ellipse (in the area it is well 14-17, FIG. 1), in which the major axis a is directed at an angle α = 45 ° to the directions of the cracks S, while minor axis b / 2 of the ellipse to its major axis a / 2 is equal to b / a = 0.5. The minimum distance from the multilateral wells to the vertical injection well is c = 250 m. Moreover, the multilateral wells are ascending with a minimum distance in the lower part to the oil well x = 4 m, in the upper part with a minimum distance y = 1 m to the top of the reservoir (figure 2).

All vertical wells of an element, at the time of commissioning of a multilateral well production well, are transferred under injection of produced water. During operation of a multilateral well, a water breakthrough occurs, primarily along vertical cracks from the aquifer of the reservoir into the lower part of the ascending shafts. When water cut more than 98% of the well is stopped, geophysical surveys are carried out, the intervals of well watering are determined. Then, the waterlogged intervals are cut off with water swellable packers and the wells are put into operation again.

Example 2. Perform as example 1. The major axis of the semi-ellipse is directed at an angle of 30 ° to the direction of fracture with a ratio of the minor axis to the major axis of the ellipse 0.1.

Example 3. Perform as example 1. The major axis of the semi-ellipse is directed at an angle of 60 ° to the direction of fracture with a ratio of the minor axis to the major axis of the ellipse 0.8.

As a result, according to examples 1-3, from 1 element consisting of 2 injection vertical and 1 production multilateral wells in the form of a semi-ellipse, during the development period, which was limited to 98% by watering the production well or achieving a minimum profitable oil flow rate of 0.5 t / day, 135.3 thousand tons of oil were produced, the oil recovery ratio was 0.167. According to the prototype, ceteris paribus, 97.3 thousand tons of oil was produced, oil recovery factor 0.120. The growth rate of oil recovery by the proposed method amounted to 0.047.

Thus, the proposed method provides an increase in oil recovery.

The application of the proposed method will solve the problem of increasing the coverage of the formation by exposure and, accordingly, increasing oil recovery of the productive formation.

Claims (2)

1. A method of developing an oil reservoir, including determining the direction of fracture of the reservoir, drilling the reservoir with vertical and / or directional and multilateral wells in a square grid and forming five-point elements by drilling in the center and at the corners of the element of vertical and / or directional injection wells and drilling between the central and angle wells in the element of a multilateral well with a rounded barrel end, injection of a working agent through injection wells and selection of products through production wells, when watering the latter, determining watering intervals and isolating waterlogged intervals, characterized in that before drilling the deposits, areas with total oil-saturated thicknesses of more than 6 m in carbonate reservoirs and / or areas with effective oil-saturated thicknesses of at least 2 m in the oil zone and at least 4 m in the water-oil zone in terrigenous reservoirs, in these areas, before drilling a multilateral well production well, the direction of fracture is refined the collector, the multilateral well is made in the form of a semi-ellipse, the major axis of which is directed at an angle of 30-60 ° to the direction of fracture with a ratio of the minor axis to the major axis of the ellipse 0.1-0.8, while the trunks of the multilateral wells are ascending with a minimum distance of the lower part to the oil-water contact 4 m for carbonate reservoirs and 2 m for terrigenous reservoirs, in the upper part with a minimum distance of 1 m to the top of the reservoir. 2. The method according to claim 1, characterized in that when the watering of producing wells determine the intervals of watering and isolation of waterlogged intervals.

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