RU2782712C1 - Networked wells for displacement, made with the possibility of introducing a fluid for the development of especially thick or multilayer oil and gas receipt - Google Patents

Abstract

FIELD: oil and natural gas production technologies.

SUBSTANCE: present invention relates to the field of oil and natural gas production technologies, and in particular it relates to an interlocking displacement well pattern capable of introducing fluid to develop particularly thick or multilayer oil and gas reservoirs. A grid of interlaced displacement wells capable of injecting fluid to develop multi-layer oil and gas reservoirs is obtained as follows: first, a division into cubic blocks of oil and gas reservoir development is carried out. Then, the physical parameters of said development cubes are measured, based on said physical parameters, design parameters of the well pattern are calculated, wherein said design parameters of the well pattern include the number of wells and the wellbore trajectory in relation to ERD wells, while said wellbore trajectory contains a wellbore trajectory - 1 in the length direction; and a wellbore trajectory - 2 in the width direction. Based on the specified design parameters of the grid of wells, drilling is carried out to obtain wells with extended reach. In the center of the intermediate areas of intersection of the specified trajectory 1 of the wellbore with the specified trajectory 2 of the wellbore, drilling is carried out to obtain vertical wells, while these extended reach wells serve as production wells, and these vertical wells serve as injection wells and they together form the specified grid of interlaced displacement wells.

EFFECT: present invention can improve the recovery factor when introducing fluid to develop particularly thick or multilayer oil and gas reservoirs.

6 cl, 3 dwg

Description

Technical field

The present invention relates to the field of oil and natural gas production technologies, and in particular, it relates to a grid of interlaced displacement wells capable of injecting fluid to develop particularly thick or multilayer oil and gas reservoirs.

Background of the invention

Due to the huge geological reserves, the efficient development of oil and gas reservoirs with thick reservoirs, which are difficult to apply hydraulic fracturing, such as in the case of carbonate rocks, etc., or multi-layer reservoirs, can improve the energy structure of China and fill the lack of traditional oil and gas reservoirs in terms of regional distribution. and the volume of supplies from China. Due to the rather high Young's modulus of oil and gas reservoirs, the effect of hydraulic fracturing on reservoirs is weak, and the effect of hydraulic fracturing measures on reservoir exploitation is weak. Due to the large thickness of oil deposits, it is difficult to use reservoirs in the vertical direction with high efficiency in the case of vertical wells and conventional horizontal wells, and it is also difficult to further improve the recovery factor from the well pattern.

At present, with regard to methods for improving the recovery factor from well patterns in oil reservoirs with thick reservoirs in which hydraulic fracturing is difficult to apply and multi-layer reservoirs, scientists in China and abroad have done a lot of work, generally related to the design of well patterns applied in sandstones, or designing well grids combining horizontal wells and vertical wells. However, for oil reservoirs with thick formations, which are difficult to apply hydraulic fracturing, and multi-layer reservoirs, there are currently no highly efficient production well grid designs, and there are no designs to increase the recovery factor from displacement well grids for development with excessively large retraction space. Design research on improving recovery from well patterns in oil reservoirs with thick reservoirs that are difficult to apply hydraulic fracturing and multi-layer reservoirs is still at the research stage, and no scientists have conducted design research related to increasing the recovery factor from grids intertwined in space of wells for displacement in the case of wells with excessively large deviation from the vertical.

The essence of the invention

In view of the above problems, an object of the present invention is to provide an interlocking displacement well pattern capable of injecting fluid to develop particularly thick or multi-layer oil and gas reservoirs, wherein the well pattern can effectively improve oil and gas recovery.

The technical solution according to the present invention is as follows:

A grid of interlaced displacement wells configured to introduce fluid to develop particularly thick or multi-layer oil and gas deposits, said interlocked displacement well grid being produced by the following method, wherein:

first carry out the division into cubic blocks of the development of oil and gas deposits;

then measure the physical parameters of these cubic development blocks;

then, based on said physical parameters, well pattern design parameters are calculated, wherein said well pattern design parameters include a number of wells and a wellbore trajectory with respect to extended reach wells; said wellbore trajectory comprises a wellbore trajectory 1 in the length direction and a wellbore trajectory 2 in the width direction;

finally, based on the specified design parameters of the grid of wells, drilling is carried out to obtain wells with extended reach from the vertical; in the center of the intermediate areas of intersection of the specified trajectory 1 of the wellbore with the specified trajectory 2 of the wellbore, drilling is carried out to obtain vertical wells, while said extended reach wells serve as production wells, and said vertical wells serve as injection wells, and they together form the specified grid intertwined wells for displacement.

Preferably, the particular step of said cube blocking of the development of an oil and gas reservoir is: defining the boundaries of the oil and gas reservoir based on seismic data; determination of the main developed reservoirs of an oil and gas deposit based on a geological model built on the parameters of an exploratory well; building cubes of maximum volume in said main developed formations, wherein the cubes are said cubic development blocks.

Preferably, the method for measuring said physical parameters generally consists in: measuring the length, width, and height of said development cubes; determining the porosity, permeability and saturation of said cubic blocks based on said geological model.

Preferably, the method for calculating said well pattern design parameters generally consists in:

well grid density calculation:

where: E _R - oil recovery factor, fraction; E _d - displacement ratio, fraction; e - natural background; B - well pattern index, wells/km ² ; S is the density of the grid of wells, wells/km ² ; a, b and c - match parameters, fraction; k is the permeability of the oil and gas deposit; h is the thickness of the cubic development block; μ is the viscosity of crude oil, mPa⋅s;

based on the length and width of the cubic development blocks, the flat surface area of said cubic development blocks is calculated; the specified area of the flat surface is multiplied by the specified density of the grid of wells to obtain the specified number of wells;

based on the specified number of wells, the wells are evenly and mutually perpendicularly performed in the specified cubic development blocks;

get the specified wellbore trajectory 1 and the specified wellbore trajectory 2 by the following calculations:

where x and y are the coordinates of the wellbore in the direction of the horizontal wellbore and the vertical direction of the oil deposit, respectively; n is the degree of interweaving of the grid of wells, while the value is in the range of 2-6; l _x and l _y - the length and width of the specified cubic blocks of development, respectively, km; x _i - phase angle of the initial point of the i-th crack in the direction of length; y _i - phase angle of the initial point of the i-th crack in the width direction, while the angle between x _i and y _i is 90°, and between x _i and x _i+1 and between y _i and y _i+1 , respectively, is 90° .

Preferably said oil recovery factor is determined using a digital modeling method; the specified displacement ratio is calculated using curves of relative phase permeability; these match parameters are obtained by calculating porosity and saturation. The specific method is provided in the industry standard SY/T100112006, so it will not be discussed in this document.

Preferably, if i is an odd number, then x _i =π/2 and y _i =0; if i is an even number, then x _i =0 and y _i =π/2. Similarly, the values of x _i and y _i can also be as follows: if i is an odd number, then x _i =0 and y _i =π/2; if i is an even number, then x _i =π/2 and y _i =0.

Compared with analogues known from the prior art, the present invention has the following advantages:

According to the present invention, taking into account the fact that it is difficult to develop the space of a particularly thick reservoir or a multi-layer oil and gas reservoir, coefficients are obtained for a grid of wells with a large retraction space in the reservoir, and by drilling, a grid of interlaced wells for displacement formed by extended reach wells is obtained. and vertical wells; Intertwined displacement well patterns can effectively improve recovery from a particularly thick reservoir or multi-layer oil and gas reservoir and fill the technical gaps of current methods to improve recovery rates with spatially intertwined displacement well patterns in oil reservoirs that are difficult to apply hydraulic fracturing.

Description of attached graphics

For a more understandable description of the technical solutions according to the embodiments of the present invention or analogues known from the prior art, the accompanying drawings are presented below in a simplified form, the use of which is necessary to describe the embodiments or analogues known from the prior art, while it is clear that in The attached drawings described below represent only some embodiments of the present invention, and based on these attached drawings, other drawings can also be obtained by those skilled in the art without any creative effort.

In FIG. 1 is a schematic representation of a well pattern design in a carbonate reservoir according to an embodiment of the present invention;

in fig. 2 is a graph showing the results of comparing recovery factors with water injection according to an embodiment of the present invention;

in fig. 3 is a graph showing the results of comparing recovery factors for water injection and gas injection according to an embodiment of the present invention.

Specific Implementation Methods

Below, the present invention is further described using embodiments with reference to the accompanying drawings. It should be noted that, unless otherwise indicated, in this application, embodiments and technical features in the embodiments may be combined with each other. Unless otherwise indicated, the technical terms or scientific terms used to describe the present invention should be considered in the meaning accepted in the field to which the invention pertains, and understandable to the average specialist. The words "comprise", "comprising", etc., used to disclose the present invention, mean that the elements or objects that appear before these words include the elements or objects and their equivalents that come after these words, and do not exclude other elements or objects.

Embodiment 1

As an example, they took a particularly thick oil reservoir in carbonate deposits in Brazil, while determining the boundaries of the oil and gas reservoir based on seismic data; on the basis of a geological model built on the parameters of an exploration well, the main developed reservoirs of an oil deposit are obtained; in the main reservoirs being developed, cubes of maximum volume are built, so that the cubes do not go beyond the boundaries of the main reservoirs, while the cubes are cubic blocks for the development of an oil deposit.

The results of measuring the physical parameters of the cubic blocks of oil reservoir development are as follows: length 4000 m, width 4000 m and height 100 m; based on the geological model, it is determined that the porosity of the cubic blocks of oil reservoir development is 2.0%, the permeability is 45 mD, and the oil saturation is 70%.

According to the calculation formula (1) and formula (2), it is calculated that the well grid density S is 0.625 wells/km ² ; by multiplying by the area (4 km×4 km), it is determined that 10 extended reach wells are required; these 10 extended reach wells are uniformly and mutually perpendicular to perform in the cubic block of the development of the specified oil reservoir; according to the calculation formula (3) and formula (4) calculate the trajectory of the wellbore with a large departure from the vertical, which serves as a production well; in this embodiment, the specified degree of interweaving of the grid of wells n is taken equal to 4; intermediate areas of intersection of the trajectory 1 of the wellbore and the trajectory 2 of the wellbore in the longitudinal and transverse directions serve as interlacing blocks; at the center of each weave block, drilling is performed to form vertical wells which serve as fluid injection wells; The result of designing a grid of intertwined wells for displacement is shown in FIG. one.

Based on FIG. 1, drilling is performed to obtain a grid of intertwined wells for displacement, while in the case of drilling to obtain wells with an extended reach from the vertical, the wellbore trajectory may have slight deviations, therefore it is not at all necessary that the wellbore trajectory pass completely in accordance with the design. When applied with a total injection to recovery ratio of 1:1, a recovery ratio is calculated from a grid of interlaced wells under depletion, development with liquid injection, and development with gas injection, and is compared with the recovery ratio from a grid of vertical wells. wells characterized by the same volume of capital investments; the results are shown in FIG. 2 and FIG. 3. The vertical wells shown in FIG. 2 and FIG. 3 form a conventional 5-point well pattern, which is taken as an example of comparison with the interlaced well pattern for displacement according to the present invention.

As for the target sector, the comparative vertical wells have an investment of 32,000,000 yuan/well, and a total investment of 128,000,000 yuan; the investment amount of extended reach wells is 75,000,000 yuan/well, and the total investment amount is 75,000,000 yuan, so the investment required for the present invention is much less than the investment required for vertical wells.

As can be understood from FIG. 2 and FIG. 3, over 10 years of production, the recovery factor for a grid of intertwined wells (the grid of wells formed by wellbore trajectory 1 and wellbore trajectory 2) is 23.48%, and the recovery factor for a 5-spot grid of wells with similar capital investments is 21, 84%; the recovery ratio for a grid of interlaced wells for water injection (the grid of interlaced wells for displacement according to the present invention is injected with water) is 37.21%, and the recovery ratio for a 5-spot grid of wells with similar capital investments into which gas is injected is 32 .97%; the recovery factor for a grid of interlaced wells for gas injection (the grid of interlaced wells for displacement according to the present invention is injected with gas) is 39.19%, and the recovery ratio for a 5-spot grid of wells with similar capital investments into which gas is injected is 34 .96%. From this, it can be understood that a pattern of interlaced displacement wells capable of injecting fluid to develop particularly thick or multi-layer oil and gas reservoirs, which is provided in accordance with the present invention, can markedly increase the recovery factor.

The above is merely a preferred embodiment of the present invention and does not limit the present invention in any way. Although the present invention has been disclosed above with the preferred embodiment, it is not intended to limit the present invention at all, and any person skilled in the art, without departing from the technical solution according to the present invention, based on the essence of the technology presented above, may slightly change or improve it to obtain equivalent embodiments with equivalent substitutions. However, any changes, equivalent replacements and modifications that do not deviate from the essence of the technical solution according to the present invention and are made to the above embodiment based on the technical essence of the present invention, are still included in the scope of the technical solution according to the present invention.

Claims (29)

1. A grid of interlaced wells for displacement, made with the possibility of introducing a fluid for the development of multilayer oil and gas deposits, characterized in that said grid of interlaced wells for displacement is obtained by the following method, in which: first carry out the division into cubic blocks of the development of oil and gas deposits; then, the physical parameters of said development cubic blocks are measured, wherein the measurement of the physical parameters consists in: measuring the length, width, and height of said mining cubic blocks, determining the porosity, permeability, and saturation of said cubic blocks; then, based on said physical parameters, well pattern design parameters are calculated, wherein said well pattern design parameters include a number of wells and a wellbore trajectory with respect to extended reach wells; the specified trajectory of the wellbore contains the trajectory - 1 of the wellbore in the direction of the length and the trajectory - 2 of the wellbore in the direction of the width; finally, based on the specified design parameters of the grid of wells, drilling is carried out to obtain wells with extended reach from the vertical; in the center of the intermediate areas of intersection of the specified trajectory 1 of the wellbore with the specified trajectory 2 of the wellbore, drilling is carried out to obtain vertical wells, while said extended reach wells serve as production wells, and said vertical wells serve as injection wells, and they together form the specified grid intertwined wells for displacement. 2. A grid of interlaced wells for displacement, made with the possibility of introducing a fluid for the development of multilayer oil and gas deposits, according to claim 1, characterized in that the specific stage of said division into cubic blocks of the development of an oil and gas reservoir consists in: determining the boundaries of an oil and gas reservoir based on seismic data ; determination of the main developed reservoirs of an oil and gas deposit based on a geological model built on the parameters of an exploratory well; building cubes of maximum volume in said main developed formations, wherein the cubes are said cubic development blocks. 3. A grid of interlaced wells for displacement, made with the possibility of introducing a fluid for the development of multi-layer oil and gas deposits, according to claim 2, characterized in that the method of measuring these physical parameters consists in: measuring the length, width and height of these cubic blocks of development; determining the porosity, permeability and saturation of said cubic blocks based on said geological model. 4. A grid of interlaced wells for displacement, made with the possibility of introducing a fluid medium for the development of multilayer oil and gas deposits, according to claim 3, characterized in that the method for calculating these design parameters of the grid of wells consists in: well grid density calculation:

where: E _R - oil recovery factor; E _d - displacement ratio; e - natural background; B - well pattern index, wells/km ² ; S is the density of the grid of wells, wells/km ² ; based on the length and width of the cubic development blocks, the flat surface area of said cubic development blocks is calculated; the specified area of the flat surface is multiplied by the specified density of the grid of wells to obtain the specified number of wells; based on the specified number of wells, the wells are evenly and mutually perpendicularly performed in the specified cubic development blocks; get the specified wellbore trajectory 1 and the specified wellbore trajectory 2 by the following calculations:

where: x and y are the coordinates of the wellbore in the direction of the horizontal wellbore and the vertical direction of the oil deposit, respectively; h is the thickness of the cubic development block; n is the degree of interweaving of the grid of wells, while the value is in the range of 2-6; l _x and l _y - the length and width of the specified cubic blocks of development, respectively, km; x ₁ - phase angle of the starting point of the i-th crack in the direction of length; y _i - phase angle of the initial point of the i-th crack in the width direction, wherein the angle between x _i and y _i is 90°, and between x _i and x _i +1 and between y _i and y _i +1, respectively, is 90°. 5. A grid of interlaced wells for displacement, made with the possibility of introducing a fluid for the development of multi-layer oil and gas deposits, according to claim 4, characterized in that the specified oil recovery factor is determined using a digital modeling method; the specified displacement ratio is calculated using curves of relative phase permeability; these match parameters are obtained by calculating porosity and saturation. 6. A grid of interlaced wells for displacement, made with the possibility of introducing a fluid medium for the development of multilayer oil and gas deposits, according to claim 4, characterized in that if i is an odd number, then x _i =π/2, ay _i =0; if i is an even number, then x _i =0 and y _i =π/2.

Images