RU2696690C1 - Development method of multi-object oil deposit (versions) - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention relates to oil industry and can be used in development of multi-object oil deposits. Method for development of multi-object oil deposit, containing two versions of well design, depending on geological features of object. In compliance with first version, design well bores are uniformly located at lower deposit and first drilling coordinate is fixed, location of cluster pads of drilling is determined, trajectories of wells are plotted from the bush along the minimum possible length of the borehole; then, at the level of the upper productive horizon, points of intersection of shafts of each well with the formation roof are shifted in the direction of location of the lower point to allowable values of borehole curvature, taking into account forming maximum possible uniform grid, second drilling coordinate is fixed, wells with equipment for simultaneous separate operation on upper and lower objects are started. In compliance with second version, design well bores are uniformly located at the upper production site of the deposit and the first coordinate drilling target is fixed, location of cluster pads of drilling is determined, then trajectories of wells are constructed from the bush along the minimum possible length of the borehole, after which vertical projection of the well-point is performed to the lower production site of the deposit, second target of wells falling into zones of substandard thicknesses or to allowance of drilled well is canceled, or position of second target is corrected relative to direction of well shaft in order to form uniformity of development grid, wells with equipment of simultaneous separate operation on upper and lower object are started.

EFFECT: disclosed is a method of developing a multi-object oil deposit.

3 cl, 3 dwg

Description

The invention relates to the oil industry and may find application in the development of multi-site oil fields.

A known method of developing an oil field with several deposits located one above the other. According to the invention, structural maps are constructed with the contours of the oil reservoir, drilling exploratory wells, drilling additional wells to seal the grid of wells in the field. Before drilling additional wells, additional research is carried out from exploration and production wells with the specification of the boundaries of oil saturation of the deposits. The general contour of the field and the zone with the maximum total oil saturation of the deposits of the field are determined, after which an additional well is drilled in the zone with the maximum total oil saturation of the deposits of the field, additional wells are drilled along the selected grid with the opening of the corresponding deposits so that their faces do not lie beyond the general contour of the field . In this case, additional wells located in the zones of intersection of the deposits, open the intersecting deposits and equip them with devices for simultaneous separate operation for extraction from the discovered deposits by producing additional wells or for pumping the displacing agent into the discovered deposits through additional injection wells (patent RU No. 2441145, IPC Е21В 43/20, publ. 01/27/2012).

The disadvantage of the presented method is that in the case of drilling a multi-site oil field using a cluster method, there arises the problem of densifying the location of well bores higher in the section, and the operation of overlying productive facilities with underlying horizons with the introduction of simultaneous separate production equipment for drilled wells is excluded due to the close location of the wells at upper productive horizon and the emergence of a development grid with a density higher than permissible oi.

There is a method of developing a heterogeneous multilayer oil field, including drilling a field with a system of wells with vertical and horizontal shafts with opening all the layers of a multilayer field, according to which the field is initially drilled with wells with vertical shafts along a sparse relative to the design grid. Then, production wells with horizontal shafts are drilled in each formation. The beginning and end of the horizontal trunk are placed at the same distance from the source of the displacing agent. The length of the wellbore of the producing well in the reservoir is set in direct proportion to the oil reserves and inversely proportional to their productivity. The length of the barrel in horizontal production wells in the tightening rows is set to not more than 70% of the distance along the design grid (patent RU No. 2024740, IPC ЕВВ 43/14, ЕВВ 43/20, Е21В 43/30, publ. 15.12.1994).

The disadvantage of this method is that the drilling of horizontal shafts for each layer of an oil multi-field field requires large capital expenditures, and also leads to the "burial" of oil reserves of productive horizons that were not involved in the development process in areas under horizontal shafts. Also, due to the existing curvature of the horizontal wellbore, restrictions arise in the use of equipment for the simultaneous operation (WEM) of several objects.

There is also known a method of developing an oil reservoir, including constructing a structural plan of the reservoir and determining for each production facility the rational distribution of production and injection wells, drilling and research of wells, oil production from production wells and injection of displacing agent into injection wells. (Muravyev I.M. et al. Development and operation of oil and gas fields. - M.: Nedra, 1970, p. 103).

The disadvantage of this method is that the method involves the development of each object of an oil field with its network of wells, while increasing capital costs and leading to unprofitable development of oil deposits.

The closest in technical essence to the proposed method and adopted for the prototype is a multilayer oil field method, including the uniform grid plan of wells at the base horizons and the drilling of directional wells placed by the bushes, each of which reveals the base horizon at points geometrically correct for this horizon grid. According to the invention, for each base horizon, grids for the placement of faces of directional wells are selected so that when drilling all wells of a given cluster, except for one vertical, the bit does not pass through the same point twice in plan, the type of grids for all base horizons should be the same . Depending on the geological and technical conditions, one of the existing types of profiles is selected: three-interval with a zenith angle stabilization, three-interval with a zenith angle decline after a maximum value has been set, four-interval with a zenith angle stabilization and its subsequent decline, four-interval with a zenith angle stabilization and its subsequent low-intensity kit (patent SU No. 1314758, IPC ЕВВ 43/20, publ. 11/27/1999).

The disadvantage of the presented method is that this method is not applicable for compaction drilling of wells in drilled multilayer fields where additional production of oil reserves is necessary and due to the existing grid of drilled wells, it is impossible to design the same grid of new wells at all base horizons. And also, if the base horizons are located at a great distance in depth from each other and accepting the condition of this method when designing so that the bit does not pass through the same point twice in plan, the well points on the lower object are placed at a great distance from each other friend, forming not rational grid of development.

The proposed method for the development of multi-site oil fields is applicable not only in undrilled sections of fields, but also in areas where it is necessary to compact the existing development grid in order to further develop reserves.

In the proposed method, with a cluster version of drilling, the problem of forming an irrationally dense grid of wells at the level of the upper productive horizon is solved, which allows further exploitation of wells using the technology of simultaneous production of several objects. Thus, there is an increase in the development efficiency, an increase in the rate of production, an increase in the oil recovery coefficient of all deposits and a decrease in the capital cost of oil production by reducing the drilling of additional production wells.

The technical result, which the proposed method aims to achieve, is achieved by the fact that when designing new directional wells to densify the existing development grid, depending on the geological and technological conditions, one of the proposed options for constructing trunk trajectories is selected that allows the formation of the most rational uniform grid development at all base horizons, taking into account existing wells.

SUMMARY OF THE INVENTION

Drilling of deposits with well clusters ensures an increase in efficiency and an acceleration of the return on capital investments by reducing unit costs for developing the fields. On the other hand, the inevitable increase in the angle of inclination of wells complicates the technical implementation of drilling projects and increases the number of risks caused by the likelihood of intersection of the wells. Also, when designing the trajectories of the shafts for one target development object in the presence of overlying oil deposits, a sealing arrangement of the shafts appears higher in the section of the field. Thus, zones of accumulation of wellbore points are formed at the level of the upper productive object, and most of the reservoir remains unreached by the network of wells. In the future, when planning the commissioning of overlying oil deposits, it becomes necessary to form a new well stock for this facility on a uniform grid, taking into account the possibility of switching to the operation of the upper horizons of previously drilled wells. By designing the trajectories of wellbores in the conditions of cluster drilling of a multi-site oil field using the proposed method, it is possible to commission several facilities simultaneously with the introduction of separate production equipment, eliminating the interference of wells at the level of an overlying facility. As a result, the oil recovery coefficient increases with the maximum coverage of the reservoir, the capital costs of oil production are reduced by reducing the drilling of additional production wells.

Analysis of the known technical solutions carried out according to scientific, technical and patent documentation showed that the set of essential features of the claimed technical solution is not known from the prior art, therefore, it meets the condition of patentability of the invention - "novelty", "industrial applicability" and "inventive step".

The inventive method of developing a multi-site oil field is illustrated in the figures:

FIG. 1 - “The scheme of adjusting the trajectories of wellbores during cluster drilling of the field according to the first method”.

FIG. 2 - “The scheme of adjusting the trajectories of wellbores during cluster drilling of the field according to the second method."

FIG. 3 - “The scheme for correcting well-points on the upper horizon, after designing a uniform grid on the lower object and forming a sealing cluster of points at the level of the upper object during cluster drilling of wells”.

A method for developing a multi-site oil field comprises the following steps.

An analysis is made of a drilled multi-field field in terms of residual oil reserves across all horizons. Additional studies are carried out to determine the current saturation of formations in the marginal and middle parts of the deposits with neutron generator research in drilled wells, as well as to refine the contours of the deposits and detail the geological structure by conducting studies of non-longitudinal vertical seismic profiling (NVSP) and seismic exploration using the common depth point method 3D (MOGT 3D). The geological model of the field is built with the updating of data on the geological structure of deposits and the current saturation of the reservoirs according to the results of the studies. Combine the oil contours of all the deposits along the section and determine the zones of intersection of oil deposits. Further, depending on the geological and technological conditions of the object, well trajectories are designed according to the two proposed options: Method 1, illustrated by figure 1:

The additional production well points (1) are uniformly distributed along the L1 × L1 grid with the existing grid being compacted (or on an undrilled oil deposit, an oil deposit site) within the general oil content profile on the lower productive horizon (2), thus determine the coordinates of one target. Next, they determine the location of cluster pads (3) on the ground, the coordinates of the mouths of the project wells (4) and construct the trajectories of the shafts for this purpose according to the shortest version of the segment (5). Next, analyze the passage of the wells at the highest production horizon (6) and the bore point along the trajectory (5) at the level of the upper production horizon (the point of intersection with the upper object) (7) move to the direction of the wellbore to acceptable values of curvature, determine the coordinates of the bore point (8) according to the adjusted trajectory (9) (determine the coordinates of the second target of the trajectory). After adjusting the sealing arrangement of points with the distance between the wellbore L2 at the level of the upper object (6), decompression and the formation of a uniform grid L3 × L3 on the upper horizon (6) occur. Thus, irrational development conditions, where L2 <L1 and L2 <L3, are adjusted to a uniform arrangement of wellbores, where L1 = L3.

Method 2, illustrated by figure 2.

Given the existing on the roof of the upper productive object (1), the points of passage of the shafts drilled at the lower productive object (2) of the field’s wells, place the well points (3) along a geometrically correct uniform development grid along the upper productive horizon (or design points are placed on drilled oil deposits, oil deposits), calculate the coordinates of one target. Next, determine the location of the well pads of drilling (4), the coordinates of the mouths of the project wells (5) and design the paths of the wellbores (6), for one target of the upper object (1). By vertical projection (7) of this point down to the lower base horizon, a second target (8) is formed. After that, the hit of points in the plan on the roof of the lower object is analyzed (2). If point (8) hits the location of an existing well, either correct the location of point (8) relative to the direction of the bore, taking into account the location of the drilling site (4), or cancel the second target of the well (8). Also, if point (8) falls into the zone of substandard oil-saturated thickness of the reservoir or beyond the oil profile of the lower object (2), the second drilling target (8) to the lower object (2) is canceled. The distance between the design borehole points on the roof of the lower horizon L1 is equal to the distance between the design borehole points on the roof of the upper object L2.

In this way, 2 variants of well trajectories are formed, which make it possible to most fully cover the field’s objects with the possibility of organizing the simultaneous development of all horizons with one grid of wells, without leaving the reserves of one of them in long-term conservation. The figure 3 shows a diagram of the adjustment of borehole points on the upper horizon, after designing a uniform grid on the lower object and the formation of a cluster of sealing points at the level of the upper object during cluster drilling. The figure shows that this method of designing the paths of wellbores allows you to quickly and without unnecessary laboriousness to form a uniform grid of wells (1) in terms of the allowable values of the curvature of the boreholes and the existing drilled development grid (2), eliminating the compaction of the grid (3) on the overlying object (4).

This method of developing a multi-site oil field has technical application at NGDU Elkhovneft.

An example of a specific implementation of the method.

The structural elevation of the oil field was drilled by the cluster method for deposits of the Tournaisian stage along a uniform square grid with a density of 300 × 300 m. Oil deposits were discovered in the section of the object in the Upinsky, Kizelovsky, Bobrikovsky, Tula, Vereysky horizons and the Bashkir layer. The object was previously operated only on the Lower Carboniferous deposits. Due to the significant distance in depth between the productive sediments of the middle and lower Carboniferous, at the level of the Middle Carboniferous, there is a sealing accumulation of points of intersection of the wellbores relative to the location of the drilling sites from which these wells were drilled. Thus, a significant area of Middle Carboniferous deposits is not covered by the existing development grid, and it is necessary to design a separate well stock aimed at developing their reserves. In order to increase the rate of production and increase oil recovery in productive formations of the Lower Carboniferous, with the possibility of simultaneous development of oil deposits in the upper horizons, additional wells are placed with compaction of the existing grid. To assess the need to place additional wells, studies are carried out to determine the current saturation of the strata of drilled wells in the marginal and dome parts of the structure (neutron generator, f / o and radioactive logging), and they also specify the contour of all the deposits along the elevation section by conducting MOGT 3D seismic surveys. By constructing the geological and hydrodynamic deposits of the site, taking into account additional information on the results of the studies, the residual reserves and risk zones of premature flooding are determined, after which the need and location of the design point are confirmed. According to the results of the work carried out, the southern part of the uplift has a somewhat unstable area of development of oil-saturated carbonate deposits of middle Carboniferous, relative to the northern part of the structure. And also determine the need for additional production of reserves for the lower carbon throughout the area of the deposit. Thus, in the northern part of the structure, the first target is determined from the project wells at the lower field object, the cluster drilling sites are located and trajectories are constructed with the lowest possible penetration through all wells. At the level of the Middle Carbon deposits, the design intersection points with the roof of the upper productive layer are moved from each other in the direction of placing the lower horizon point relative to the direction of the wellbore to the permissible curvature values. Thus, the second goal of the wells is determined by the roof of the middle carbon. In the southern part of the uplift, a grid of wells is designed for medium carbon, taking into account the intersection points of the previously drilled wells on the lower carbon and the geological features of the reservoir. The first goal of well drilling is determined. Next, a vertical projection of the point from the middle carbon to the lower carbon is carried out and, if necessary, the location of the lower point is corrected in the direction of the trunk wiring, or the second target is canceled if it is not necessary due to falling into the circle of an existing well or into the zone of substandard thicknesses.

Using the presented method allows, taking into account the permissible values of the curvature of the boreholes and geological features of the deposits, to form the most optimal grid of wells with a cluster method of drilling, allowing simultaneous production of objects located at a considerable distance from each other in depth, excluding the interference of wells at the level of the upper object . Also, the method allows to increase oil recovery coefficient, increase production rate and reduce capital costs for the construction of additional wells in areas not covered by the design grid of wells.

Claims (3)

1. A method of developing a multi-site oil field, including conducting uniformly planed wells at baseline horizons and drilling directional wells placed by clusters, each of which reveals a baseline horizon at points geometrically correct for a given horizon, characterized in that when designing new wells evenly place the design well points at the bottom of the field, aimed at compaction of the existing grid, and fix the first coordinate drilling target and then determine the location of the wellbore sites for drilling and construct the paths of wells from the well along the minimum possible length of the wellbore, then at the level of the highest production horizon, shift in terms of the intersection points of the boreholes of each well with the formation roof towards the location of the lower point to the permissible curvature of the wellbore taking into account the formation of the maximum possible uniform grid, after which the second coordinate drilling target is fixed and the well is planned to be launched into operation with the equipment vaniem dual completion for the top and bottom object. 2. A method of developing a multi-site oil field, including conducting uniformly planed wells at basal horizons and drilling directional wells placed by clusters, each of which reveals a baseline horizon at points geometrically correct for a given horizon, characterized in that when designing new wells evenly place the design well points at the top productive field object and fix the first coordinate drilling target, after which the location is determined drilling well sites and constructing well paths from the well along the minimum possible length of the well, then a vertical projection of the well point to the bottom productive object of the field is carried out, while the second goal of the wells that fall into the zones of sub-standard thicknesses or into the tolerance circle of the drilled well is canceled, or they also adjust the location of the second target relative to the direction of the wellbore in order to form uniformity of the development grid and plan to launch one well with one equipment Temporarily-separate operation of the upper and lower object. 3. The method of developing a multi-site oil field according to claim 1, wherein the location of the wells is determined by the results of constructing a geological and hydrodynamic model of the site, taking into account data from seismic surveys and studies to determine the nature of the current saturation of formations in drilled wells located in the boundary and dome parts of the structure.

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