RU2672292C1 - Method for oil deposit development with horizontal wells with multi-stage fracing - Google Patents

Abstract

FIELD: oil and gas industry.SUBSTANCE: invention relates to oil industry and can be applied to development of multi-layer oil deposits, represented by heterogeneous permeability pods. Method comprises steps of drilling an extracting horizontal well with a multifrac, after which geophysical studies are carried out according to the logging-impact-logging scheme. Actual geometry of the created cracks is calculated. Based on the obtained results of geophysical studies, a region of well drainage with multifrac is calculated and a preliminary grid is chosen for drilling subsequent two horizontal wells. Drilling of two parallel-located production wells relatively to the first one on a pre-selected grid, with analysis of interference of horizontal wells with multifrac during their simultaneous operation and evaluation of the optimality of the selected grid are carried out. Entire oil reservoir according to the well + multifrac technology for an optimal grid density of wells is designed and drilled.EFFECT: technical result is higher efficiency of oil deposit development.6 cl, 1 dwg

Description

 The invention relates to the oil industry and may find application in the development of multilayer oil deposits represented by reservoirs heterogeneous in permeability.

A known method of developing an oil reservoir by multiple fracturing (MHF) of a low-permeable oil reservoir, including designing and drilling horizontal wells (HS) in a reservoir previously exposed by vertical and / or directional wells, conducting multiple hydraulic fracturing in horizontal wells and subsequent product selection. According to the invention, according to geophysical studies in vertical and / or directional wells, an oil-saturated formation is heterogeneous in permeability, the permeability of which varies in thickness by at least 10 times, while the average permeability of the formation in volume does not exceed 2 mD. Next, in a most permeable interlayer with a thickness of at least 1 m, a horizontal well is designed and drilled, while the horizontal well is drilled using the over-bit module and the geophysical parameters are measured during drilling, by which the well’s trajectory is adjusted to guide it through the most permeable section. The layout of the horizontal trunk is performed with the possibility of multiple hydraulic fracturing with the number of stages from 5 to 30 and the distance between the stages from 10 to 50 m (patent RU No. 2549942, IPC ЕВВ 43/26, published on 05/10/2015).

A known method of developing low-permeability oil deposits, including drilling production and injection wells in a straight-line development system, with hydraulic fracturing (Fracturing) in all wells, placing rows of injection and production wells in parallel and alternating through one in the direction of the maximum horizontal stress of the formation. With this method of development, production and injection wells are drilled with horizontal shafts in the direction of maximum horizontal stresses with multistage hydraulic fracturing. (patent RU No. 2547848, IPC ЕВВ 43/263, ЕВВ 43/30, publ. 04/10/2015).

The closest in technical essence to the proposed method and adopted as a prototype is a method of developing a low-permeability oil field by horizontal wells in natural mode, including drilling parallel parallel production horizontal wells with subsequent multiple hydraulic fracturing and selection of products, and in formations with no permeability more than 2 mD drill a producing horizontal well with an angle β between the maximum main stress of the formation and is directed it horizontal wellbore from 30 ° to 60 °. After that, multiple hydraulic fracturing is carried out on it with the subsequent launch of the well into operation. The development of the reservoir is carried out in a natural mode without drilling injection wells in a regime in which the reservoir pressure during development is reduced by no more than 3% per year. The remaining producing horizontal wells are drilled parallel to the first in quantity, so that the specific initial geological oil reserves per horizontal well are at least 50 thousand tons and the distance between horizontal shafts is at least 100 m, multiple hydraulic fracturing is also performed at all wells (patent RU No. 2528757, IPC ЕВВ 43/26, ЕВВ 43/16, publ. 09/20/2014).

The disadvantages of the presented methods is that in these cases, the optimal density of the grid for drilling the reservoir using the GS + multi-fracturing technology is not calculated taking into account the increase in the drainage area of the wells due to the creation of hydraulic fractures, which can lead to interference between the two wells. When developing deposits by known methods, premature reduction in oil flow or water flooding occurs.

In the proposed method for the development of a multilayer reservoir by the optimal grid of horizontal wells with multistage hydraulic fracturing, the problem of low profitability of the development of low-permeability oil deposits is solved.

The technical result, which the proposed method aims to achieve, is achieved by the fact that before designing and completely drilling the oil reservoir, the optimal grid of horizontal wells is determined, which excludes interference between them after a multi-stage hydraulic fracturing, which increases drainage coverage and the final oil recovery factor (CIN), as well as reduced capital costs for construction by reducing the density of the grid of wells. According to the proposed method, horizontal wells are drilled in the formation with the best reservoir properties (according to the results of geophysical studies in drilled wells in the area, but not previously operating this productive horizon) according to the calculated grid density. The technology and the intervals of the hydraulic fracturing stages are selected based on the results of the success of various types of hydraulic fracturing in drilled directional wells, taking into account the maximum involvement of all productive layers of the horizon in the work. In order to maintain reservoir pressure, the reservoirs transfer horizontal wells below the absolute elevations for water injection, as well as drilled directional wells, spent oil reserves of the underlying horizons.

SUMMARY OF THE INVENTION

Multilayer oil deposits, represented by reservoirs that are heterogeneous in permeability, are characterized by uneven production of reserves, and some of them remain completely unused in the development process. The use of horizontal production wells with multiple hydraulic fracturing across several layers of the horizon increases the likelihood of involving all oil-saturated layers in operation, increases the coverage and rate of oil recovery. However, the drilling and exploitation of a reservoir using this technology using a traditional grid of wells reduces the technical and economic efficiency of the project, which is associated with an increased density of the grid of wells with an increased drainage zone due to the creation of hydraulic fractures. Developing a multilayer reservoir with the choice of the optimal grid of horizontal wells with multistage hydraulic fracturing by the proposed method increases the profitability of developing low-permeability oil deposits.

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 is illustrated in the figure "Method for the development of oil deposits by horizontal wells with multi-stage hydraulic fracturing." Accepted designations: 1 - hydraulic fracture, 2 - drainage area of horizontal well reserves with hydraulic fracturing, 3 - reserve reserve area, S - required distance between wells, excluding interference of drainage areas, L1 and L2 - fracture length, r1 and r2 - drainage zone radius .

A method for developing an oil reservoir by horizontal wells with multi-stage fracturing comprises the following steps.

Determine the most effective fracturing technology. At this stage, hydraulic fracturing of various modifications (proppant, marked, acid, etc.) is carried out on a drilled pool of directional wells of the designed area. The control of the production process is carried out using geophysical studies to determine the geometry of cracks 1, according to the logging - impact - logging scheme (such as microseismic and acoustic studies). At the end of the work, a comparison of the actual design of the crack 1 is carried out according to the results of the interpretation of geophysical studies. As a result of hydraulic fracturing on different layers of the productive horizon, the most effective technology is assessed, which allows to involve the maximum number of productive layers in the work.

Drilling the first horizontal well No. 1 with multistage fracturing. According to the results of the 1st stage, the horizontal well No. 1 is designed and drilled for the selected layer of the productive horizon, followed by multistage acid fracturing. The design design of the multistage hydraulic fracturing is being updated taking into account the results of work performed on drilled wells. After putting well No. 1 into operation, the operational characteristics of the well and forecast indicators are estimated based on the results of constructing a hydrodynamic model of the site.

The preliminary grid is calculated and the additional two horizontal wells No. 2 and No. 3 are drilled to the productive horizon. At this stage, determine the location of two horizontal shafts on the production horizon relative to the drilled well No. 1. The distance between wells S is determined by calculating the length of the crack development L1 and L2 according to the results of geophysical studies, taking into account the drainage area 2 and the reserve area of reserves 3 according to the formula: S = r1 + r2 = (L1 + 50) + (L2 + 50).

Well No. 2 is placed on the middle, and Well No. 3 on the edge of the structure is parallel to Well No. 1. Hydraulic fracturing designs for wells are calculated taking into account the information obtained according to the results of work when drilling an experimental horizontal well No. 1.

An analysis of the interference of horizontal wells with multistage fracturing is carried out, that is, the optimality of the selected grid is evaluated. The stage provides an analysis of the joint work of three horizontal wells with hydraulic fracturing after putting them into operation. Conduct regular sampling for water cut of produced products, measure bottomhole pressures, take dynamograms, etc. Next, evaluate the interference of wells relative to control well No. 2 (middle). If:

1) Qн (well 1)> Qн (well 2), t / day and Qн (well 1) = Qн (well 3), t / day, then there is interference between the wells, the grid is not optimal;

2) Qн (well 1) = Qн (well 2) = Qн (well 3), t / day, then there is no interference, the optimal mesh is selected.

Designing and drilling of the entire oil reservoir is carried out using the GS + multi-fracturing technology according to the selected grid according to the calculations above. Wells located in areas with the lowest absolute elevations of the roof of the productive horizon, after being worked out for oil, are transferred under injection of water in order to replenish reservoir pressure reserves. They also provide for the option of pumping water through drilled directional wells located below the absolute elevations of the reservoir and the spent oil reserves of the underlying horizons.

This method of developing an oil reservoir by horizontal wells with multi-stage hydraulic fracturing has technical application in the NGDU “Elkhovneft”.

An example of a specific implementation of the method

The Verey horizon deposit is represented by the carbonate type of the reservoir and a purely oil zone of 4 m thick. The deposit consists of five productive interlayers that have been sustained over the area and are discovered by 35 directional wells that exploit the Lower Carboniferous deposits. Based on the results of the final logs of the drilled wells and taking into account additional information about the geological structure of the reservoir, the geological model of the site is constructed using the general depth point (MOGT) 3D seismic survey. Carry out proppant and acid fracturing on drilled directional wells in different layers of the Verey horizon. According to the results of geophysical studies carried out before and after hydraulic fracturing, the geometry of the hydraulic fractures created is determined, the target formation for drilling a horizontal wellbore and the most effective type of hydraulic fracturing is chosen based on the oil production rate - acidic. The first horizontal well is drilled along the selected (second) layer of the Verey horizon with five stages of acid fracturing. Using the obtained information on geophysical studies on the geometry of fractures actually created, the area of well drainage is calculated, the diameter of which is 300 m. Taking into account the reserve reserves of 50 m, a well network of 400 m × 400 m is chosen. Then, two more wells are drilled parallel to the first well horizontal well 200 m, with five stages of acid fracturing in different layers of the Verey horizon, including on the site before reaching the horizontal plane of the well. Based on the results of evaluating the interference between the wells during their operation, the effectiveness of the selected grid of wells is determined, taking into account the design of drilling the entire reservoir.

Using the presented method allows to solve the problem of low profitability of the development of oil low-permeability deposits and to obtain the effect by increasing the coverage of the horizon by drainage with the involvement of all productive layers in the development with the exception of interference between producing horizontal wells, the method also allows to increase the recovery factor and reduce capital construction costs for by reducing the density of the grid of wells.

Claims (14)

1. A method of developing an oil field by horizontal wells with multi-stage hydraulic fracturing containing the following steps: - Drilling a producing horizontal well with multi-stage hydraulic fracturing; - conduct geophysical research according to the logging scheme - impact - logging, calculate the actual geometry of the created fractures; - according to the results of geophysical studies, the area of hydraulic well drainage with hydraulic fracturing is calculated and a preliminary grid is selected for drilling the next two horizontal wells; - make drilling of two parallel located production HS relative to the first on a pre-selected grid; - analyze the interference of horizontal wells with multistage fracturing during their simultaneous operation and assess the optimality of the selected grid; - design and drill the entire oil reservoir using the GS + multistage fracturing technology according to the optimal density of the grid of wells. 2. The method according to claim 1, in which the calculation of the actual geometry and design of the created cracks is performed using a computer program. 3. The method according to claim 1, in which the location of the wells is determined by the results of constructing a geological and hydrodynamic model of the site, taking into account the data of seismic surveys. 4. The method according to claim 1, in which the placement of two subsequent drilled wells is carried out on the middle and edge of the structure parallel to the first well. 5. The method according to claim 1, in which the interference of the wells is estimated relative to the control well located in the middle part of the structure according to the relations: - Qn (well 1)> Qn (well 2), t / day and Qn (well 1) = Qn (well 3), t / day, then there is interference between the wells, the grid is not optimal; - Qн (well 1) = Qн (well 2) = Qн (well 3), t / day, then there is no interference, the optimal mesh is selected. 6. The method according to claim 1, which provides for the option of pumping water through drilled directional wells located below the absolute elevations of the reservoir and the spent oil reserves of the underlying horizons.

Images