RU2546704C1 - Less explored oil deposit development method - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: according to the method a deposit is drilled out by wells as per the wide well spacing pattern. Deposits are surveyed with the determination of their hypsometric depths. New wells are constructed and offshoots or horizontal offshoots are drilled from the existing wells towards the maximum oil saturation of the deposit. At that a seismic survey is performed with the determination of several oil-saturated zones in the deposit with advanced permeability and porosity both in the square area and altitude of the reservoir. Availability and position of fault lines is defined additionally. New horizontal or inclined wells are constructed as per an irregular pattern so that horizontal or inclined section of these wells passes through the selected oil-saturated zone with the maximum filtering area. Construction of offshoots or horizontal offshoots from the existing wells is made towards the closest oil-saturated zone so that they pass the maximum filtering area upon drowning of the wells or reduction of the oil flow rate below the profitable value. The offshoots or horizontal offshoots pass through the zone with the effective oil-saturated thickness of at least 10 m when water-bearing reservoirs are available in the stratum foot, or at least 4 m when the water-bearing reservoirs are not available in the stratum foot. The inclined offshoots or horizontal offshoots pass through the oil-saturated zone perpendicular or at an acute angle towards the deposit fault line at the distance that allows the prevention of fast drowning of the extracted product.

EFFECT: higher efficiency of development for a less explored oil deposit.

2 cl, 1 ex, 1 dwg

Description

The proposed method relates to the oil industry, in particular to the field of development of oil little explored deposits.

A known method of developing small unproductive oil fields (patent RU No. 2342521, IPC E21B 43/20, publ. 12/27/2008, bull. No. 36), including drilling production wells, oil selection from production wells and individual injection of water into the injection to maintain pressure in oil reservoirs, oil displacement towards production wells. According to the invention, before drilling production wells, a basic uniform square grid of well placement is superimposed on a map of oil fields with drilled exploratory wells. After that, wells are drilled along the base grid near existing exploratory wells. Hydrodynamic studies of drilled wells are carried out and, if the productivity of oil reservoirs is confirmed, rational pooling of reservoirs into production facilities is carried out, given the increase in average well production. The following wells are also drilled along a basic uniform square grid until autonomous working well cells are formed from drilled and hydrodynamically investigated wells with injection wells highlighted in them. The productivity of individual water injection into injection wells in these cells is determined by the productivity of the surrounding production wells.

The disadvantage of this method is that when drilling small deposits on a uniform grid without additional use of data from various modifications of seismic surveys, it is likely that wells will open aquifers. The known method does not allow to determine the location of the faults.

The closest in technical essence to the proposed one is a method of developing an underexplored oil reservoir (patent RU No. 2447270, IPC E21B 43/16, publ. 04/10/2012, bull. No. 10), including drilling a deposit with a rare grid of design wells, product selection through production wells and injecting a working agent through injection wells. In a drilled well, detailed seismic surveys are carried out using the vertical seismic profiling method in the direction of elevated hypsometric marks of the structure in three directions diverging by no more than 60 ° and a length of no more than 600 m, the forecast structural plan of the productive formation is refined, and areas for increasing the hypsometric marks are identified. When confirming the forecast structural plan according to the research results, the project well is drilled in the direction of seismic profiles to the zone of elevated hypsometric marks at a distance of 300-400 m from the drilled one. If the forecast structural plan is not confirmed, the project well is moved to the zone of elevated hypsometric marks according to the new structural plan and drilled in a new location, adjusted according to the results of vertical seismic profiling and the presence of a cost-effective oil-saturated thickness of at least 2 m, cased in the well and mastered as production in the consolidated and / or the near-water parts of the structures that control the oil deposit and / or the injection in the lower parts of the structures, in the marginal area and at least 70 m from the circuit oil content. According to the results of drilling, the placement of the project well stock is adjusted.

The disadvantage of this method is that the radius of the research using the vertical seismic profiling method does not exceed 600 m, therefore this method does not guarantee the correct determination of the structural surface of productive deposits in areas distant more than 600 m from the well in which the vertical seismic profiling studies were conducted. The known method does not provide information about the filtration-capacitive properties of rocks along the section, does not allow to determine the location of faults.

The technical task of the proposed method is the determination of several oil-saturated zones with improved filtration and capacitive properties both in area and in height, location of faults for a more rational placement of production wells in order to increase oil production and the efficiency of development of an undeveloped oil field.

This problem is solved by a development method, including drilling a reservoir with wells on a sparse grid, exploring a reservoir with determining the hypsometric marks of the reservoir, constructing new wells and horizontal or lateral or lateral boreholes from existing wells towards the maximum oil saturation of the reservoir.

What is new is that seismic surveys are carried out to determine several oil-saturated zones of the reservoir with improved filtration and reservoir properties both in area and in height, and further determine the presence and location of fault lines, the construction of new horizontal or directional wells is carried out on an uneven grid so that a horizontal or inclined direction of these wells passes through the selected oil-saturated zone with the maximum possible filtration area II, the construction of sidetracks and horizontal sidetracks from existing wells is carried out in the direction of the nearby oil-saturated zone with the passage of the maximum possible filtration area after flooding the latter or reducing the oil flow rate in them below the cost-effective; lateral trunks or lateral horizontal trunks pass through an area with an effective oil-saturated thickness of at least 10 m in the presence of aquifers in the bottom of the formation or at least 4 m in the absence of aquifers in the bottom of the formation; directional lateral and lateral horizontal wells pass along the oil-saturated zone perpendicularly or at an acute angle to the fault line of the reservoir, without crossing the fault line and at such a distance to avoid rapid flooding of the produced products.

Also new is the fact that when finding nearby oil-saturated zones belonging to different objects with similar filtration-capacitive properties, wells are built so that they cross several such zones with subsequent equipment with their devices for simultaneous and separate operation of these objects.

The drawing shows a diagram of the implementation of the proposed method for the development of oil little explored deposits.

The inventive method is carried out in the following sequence.

Oil reservoir 1 is drilled with wells 2, 3 on a rare grid. According to the results of seismic surveys covering the area and height of reservoir 1 (3D method), the geological structure of reservoir 1 is refined, several zones 4, 5 are distinguished with improved filtration and reservoir properties of reservoirs both in area and in height. Hypsometric marks of the deposit are determined.

The task of increasing oil recovery is solved by rational placement of wells in the reservoir, for which the boundaries of oil-saturated zones 4, 5 with improved filtration and capacity properties are highlighted on the map of effective oil-saturated thicknesses of reservoir 1, fault lines 6 are plotted.

In wells 2 and 3, laboratory core studies, hydrodynamic studies with the determination of reservoir permeability are carried out. Then conduct an analysis of the operation of wells 2 and 3.

Well 2, drilled in an oil-saturated zone with improved filtration-capacitive properties, has a higher oil production rate compared to well 3 drilled in compacted carbonate reservoirs of reservoir 1. The increased permeability of carbonate rocks contributes to a more intensive flow of fluid to the perforation intervals.

Directional wells 7–9 are drilled along an uneven grid with penetration into oil-saturated zone 4 with improved filtration-capacitive properties and an effective oil-saturated thickness of 10 more than 2 m. Directional wells 7–9 should not cross fault line 6 to avoid rapid flooding of the produced products from the deposit.

From the well 3, a sidetrack 11 is drilled into a zone with improved reservoir properties 4 without crossing a fault line. The lateral barrel 11 extends as far as possible along the selected zone with improved filtration-capacitive properties 4 with an effective oil-saturated thickness of more than 4 m.

From a well 2 after its flooding or a decrease in oil production below a cost-effective one, a lateral horizontal wellbore 12 is drilled, passing through zone 5 with improved filtration and reservoir properties, with an effective oil-saturated thickness of at least 10 m in the presence of aquifers in the bottom of the formation. If there are no aquifers in the bottom of the reservoir, the lateral horizontal barrel 12 can be drawn in an area with an oil saturated thickness of 4 m. The horizontal part of the trunk is placed in a selected oil saturated zone with coverage of the maximum possible filtration area.

The horizontal well 13 is placed on an uneven grid so that the horizontal wellbore of this well passes through the selected oil-saturated zone with improved filtration-capacitive properties 5, covering the maximum possible filtration area without crossing the fault line, perpendicular or at an acute angle to fault line 6 of reservoir 1. In the selected zone, oil-saturated thicknesses of 10 should be more than 10 m in the presence of aquifers in the bottom of the reservoir 1. If there are no aquifers in the bottom of the reservoir 1, horizontal well 13 can be drawn in zone 5 with an oil-saturated thickness of at least 4 m.

The horizontal well 13 should not cross the fault line 6 in order to avoid rapid flooding of produced products with formation water.

When conducting trajectories of horizontal wells 13, it is necessary to take into account the presence of cost-effective specific oil reserves per horizontal well 13, which leads to a reduction in the payback period for the construction of a horizontal well 13 and the production of each ton of oil.

When finding nearby oil-saturated zones 5 that belong to another object with similar filtration-capacitive properties, wells 7, 8, 11 are built so that they cross several such zones 5 with subsequent equipment with their devices for simultaneous and separate operation of these objects.

An example of a specific implementation.

The implementation of this method, consider the example of deposits characteristic of the Tournaisian stage.

Oil reservoir 1 with carbonate reservoirs is drilled with wells 2 and 3 along a sparse grid of 700 × 700 m. The geological structure of reservoir 1 is specified, structural plan. According to the results of 3D seismic surveys, it is determined that the reservoir crosses a tectonic fault in the northwest direction. On the map of effective oil-saturated thicknesses of the deposit, fault line 6 and oil-saturated zones 4, 5 with improved filtration-capacitive properties are plotted.

Laboratory core studies are carried out and reservoir properties of the reservoir are determined: porosity is 12.1%, oil saturation is 82.2%. Then conduct hydrodynamic studies in wells 2 and 3, determine the permeability, which is respectively 0.158 and 0.054 μm ² . Select zone 4 in reservoir 1 with effective oil-saturated thicknesses from 2 to 15 m.

Well 2, drilled in oil saturated zone 4 with improved filtration and reservoir properties, has a higher oil production rate (9.1 t / day) compared to production well 3, which opened up compacted carbonate reservoirs. The initial oil production rate of well 3 was 4.8 tons / day.

Directional wells 7-9 are placed on an uneven grid in the oil saturated zone 4 with improved filtration and capacitive properties.

From well 3 drilled in compacted carbonate reservoirs of reservoir 1, a 280 m lateral well 11 is drilled in a northeast direction, passing through zone 4 with improved filtration-capacitive properties with an effective oil-saturated thickness of 6.0-8.8 m.

From the well 2, after two years of operation, after lowering the oil production rate to 4.1 t / day, a horizontal lateral bore 12 is drilled in the south-west direction, carried out in zone 4 with improved filtration and reservoir properties with an effective oil-saturated thickness of 10.6 m. horizontal well is 340 m. The bottom hole of the lateral horizontal well 12 is at a distance of 185 m from the fault line.

The horizontal well 13 is placed on an uneven grid in zone 4 with improved filtration and capacity properties subperpendicular to the fault line 6. The effective oil-saturated thickness of the reservoir is 12.4 m. The bottom of the well is 230 m from the fault line 6. The length of the horizontal well 13 is 400 m. During the month of operation of the horizontal well 13, the total oil production amounted to 304 tons.

In a horizontal well drilled on a similar deposit along a uniform triangular grid of 300 × 300 m, without taking into account the results of 3D seismic surveys, the total oil production per month was 242 tons.

A comparative analysis of the operation of two horizontal wells showed that the total oil production of horizontal well 13 for one month of operation increased by 20.4% compared to a horizontal well drilled on a similar field using a uniform triangular grid of 300 × 300 m, without taking into account the results of seismic exploration by 3D

In the area of well 3 below the section at a distance of 32 m, there is an oil reservoir. According to the results of 3D seismic surveys, oil-saturated zones 5 with improved filtration-capacitive properties are distinguished in it. The effective oil-saturated thickness of the deposit is more than 2 m. In this case, directional wells 7–9 are constructed so that they intersect zones 4, 5 with improved filtration-capacitive properties in two deposits. Then wells 7-9 are equipped with devices for simultaneous and separate operation of these objects.

The proposed method for developing low-drilled oil deposits allows to increase the coverage of oil reserves in the deposits, to increase oil production rates of producing wells by an average of 20-30%.

Claims (2)

1. A method of developing an underexplored oil reservoir, including drilling a reservoir using wells on a sparse grid, exploring the reservoir with determining the hypsometric marks of the reservoir, constructing new wells and horizontal or lateral or lateral boreholes from existing wells in the direction of maximum oil saturation of the reservoir, characterized in that they carry out seismic exploration with the determination of several oil-saturated zones of the reservoir with improved filtration-capacitive properties both in area and in height, and additionally determine the presence and location of fault lines, the construction of new horizontal or directional wells is carried out on an uneven grid so that the horizontal or directional section of these wells passes through the selected oil-saturated zone with the maximum possible filtration area, construction of sidetracks and sidetracks from existing wells carried out in the direction of the nearby oil-saturated zone with the passage of the maximum possible filtering area after e flooding of the latter or lowering the oil production rate below the profitable one, sidetracks or lateral horizontal trunks pass through an area with an effective oil-saturated thickness of at least 10 m if there are aquifers in the bottom of the formation or at least 4 m if there are no aquifers in the bottom of the formation , deviated directional lateral and lateral horizontal wells pass along the oil-saturated zone perpendicularly or at an acute angle to the fault line of the reservoir without crossing the fault line and at such a distance and to avoid rapid flooding of the products. 2. The method according to p. 1, characterized in that when finding nearby oil-saturated zones belonging to different objects with similar reservoir properties, the wells are built so that they cross several such zones with subsequent equipment with their devices for simultaneous and separate operation of these objects .

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