RU2374435C2 - Method of multi-layered oil field development with presents of highly permeable interlayer using hydraulic fracturing - Google Patents

Abstract

FIELD: oil-and-gas production.

SUBSTANCE: invention related to multi layered oil fields development and can be used in oil-and-gas industry. Essence of the invention in method of hydraulic fracturing execution, performed selectively in area of low permeability layers, not all the interlayer at one time. Pick up highly permeable layer with permeability three times greater then average one, called "super collector". And do not execute its perforation on that stage. After planned oil reserves developed perform highly permeable layer perforation and execute its production. Execute a hole with vertical entering into production facility to create maximum perforation pressure gradient and to create optimal hydraulic fracturing crack. At the same time execute hydraulic perforation in interval with low permeability in injection area of well.To create a vertical filtration between highly permeable interlayer-non perforated and low permeable create side horizontal hole in low permeable area with the following gradual hydraulic fracturing.

EFFECT: decrease in unevenness of multi layered field development and maximal fluid withdrawal.

2 cl, 4 dwg

Description

The invention relates to the field of development of multilayer oil fields and can be used in the oil and gas industry.

If there are several interlayers in the section of the reservoir, one of which has a permeability significantly higher than the others, the selection of oil is mainly from a highly permeable interlayer. In the case of water injection to maintain reservoir pressure, there is an accelerated breakthrough of water in a highly permeable layer and a decrease in well productivity and, as a result, a decrease in the rate of selection of reserves.

A known method of developing a multilayer oil reservoir [1], which includes the separation of formations into two groups: the first group includes formations with higher permeability (the so-called supercollector), the second group consists of less permeable formations, oil is taken from the formations through production wells, and the worker is injected agent through injection wells drilled into formations of the second group, which are then stopped, drill injection wells directly into the super reservoir and / or use injection wells drilled in uperkollektor, thus eliminate the hydrodynamic connection directly from production wells superkollektorom, additional production wells drilled over superkollektorom, the working agent is injected through injection wells in superkollektor is withdrawn through oil production wells over superkollektorom. In this case, producing wells are horizontal.

The disadvantage of this method is the low oil production efficiency of horizontal wells in intermittent multilayer formations, i.e. they do not provide sufficient coverage of the interlayers, which is confirmed by many studies conducted by specialists of various enterprises [2, 3, 4].

Secondly, when the working agent is injected into the supercollector, a leading breakthrough of the working agent in neighboring wells is possible. If the vertical gradient of pressure on the cement ring is exceeded, there will be overflow through the annulus to previously drilled production wells [5], the efficiency of oil displacement and the effect of pressure on production in horizontal wells will be reduced.

Thirdly, hydraulic fracturing is not used in this situation, which is a highly effective way to increase permeability in a low permeability reservoir. In discontinuous formations in the presence of a large number of clay sections (bridges) without hydraulic fracturing, it is impossible to create vertical filtration and increase the efficiency of the development of this type of reservoir.

A technical solution is known for “A method for developing a multilayer oil reservoir using hydraulic fracturing” (6), which includes injecting a displacing agent through injection wells, selecting fluids through production wells and performing hydraulic fracturing, which is carried out comprehensively on the entire set of injection and production wells, the direction of hydraulic fractures is determined by the selection of anti-aircraft and azimuthal angles of the injection and production wells from the calculation elimination of heterogeneity of filtration flows, while it is proposed to process hydraulic fractures to increase their effective work.

The invention allows to increase the oil recovery coefficient by reducing the residual oil saturation.

However, hydraulic fracturing is carried out comprehensively across all layers, which entails uneven production.

The disadvantage is that with an increase in the zenith angle, the pressure gradient of the hydraulic fracturing decreases, which affects the quality (size) of the fracture.

The entry of a wellbore with a zenith angle in directional wells reduces the quality of cementing in the intervals between the production site and the aquifer.

Thus, the entry of an inclined wellbore into a production facility does not allow creating a high-quality cement ring in the annulus and an optimal fracture after hydraulic fracturing.

The objective of the invention is to reduce the uneven production of multilayer reservoirs, to ensure high-quality selection by isolating a highly permeable layer, eliminating its initial perforation and hydraulic fracturing in adjacent areas with a vertical wellbore in the reservoir to improve cementing quality and create an optimal hydraulic fracture.

The problem is solved in that in the method of developing a multilayer oil reservoir in the presence of a highly permeable layer using hydraulic fracturing, with the injection of a displacing agent through injection wells, the selection of formation fluids through production wells, hydraulic fracturing to produce an effective hydraulic fracture, hydraulic fracturing is not carried out immediately across all layers and selectively in the zone of low permeability formations, excluding perforation of a highly permeable stratum with a permeability of three or more times higher than more common in the reservoirs, then after the projected selection of oil reserves, a highly permeable formation is perforated with the subsequent operation of the latter, a trunk is used for vertical entry into the production facility with a maximum fracture pressure gradient to create the optimal hydraulic fracture, while at the same time hydraulic fracturing is performed in the injection well stock at intervals of low permeability; to obtain vertical filtration between the high permeability layer (non-perforated) and low permeability, a lateral horizontal wellbore is carried out in a low permeability interval with subsequent interval fracturing.

The result of the application of the invention is to increase the efficiency of the development of a multilayer oil reservoir in the presence of a highly permeable interlayer that exceeds the average permeability in the reservoir by three or more times.

The best results of high-quality cementing of the production facility interval were obtained with vertical entry of the wellbore into the formation [7]. Field analysis determined the effect of the zenith angle on the fracture pressure gradient [8], found the inverse relationship between these parameters: with increasing zenith angle, the fracture pressure gradient decreases and, therefore, the fracture pressure will be minimal and insufficient for the crack to develop. It is possible to achieve a fracture in wells with a minimum zenith angle at a higher pressure, which will not only allow for a fracture, but also to create a high-quality fracture due to the pressure spent on the development of the fracture.

The conducted model studies revealed a satisfactory relationship between the conductivity of the fracture and the magnitude of the zenith angle, and an analysis of the effect of the zenith angle of the wellbore in the production facility on the productivity of the well also confirmed that wells with vertical entry of the wellbore into the formation have better productivity than wells with a maximum zenith angle. Thus, the vertical entry of the wellbore into the reservoir eliminates the issue of selecting the zenith and azimuthal angle when drilling wells [9]. When designing wells at cluster sites, the choice of the zenith angle and azimuthal direction is not realistic.

To justify the technical solution, a field analysis of the effectiveness of hydraulic fracturing in the Talinskaya area of the Krasnoleninsky field was carried out. The operational facility SK ₁₀ has an average of four layers, one of which has a high permeability that exceeds the average reservoir by three or more times and is a super collector.

Figure 1 shows the relationship between the initial flow rate of the fluid and the maximum permeability of the supercollector in the UK ₁₀ reservoir.

Figure 2 shows the relationship between the specific flow rate of liquid per ton of proppant and the maximum permeability of the supercollector in the UK ₁₀ formation.

Figure 3 is an example of a two-stage development of a layer of UK _{10 of the} Talinsky deposit of the Krasnoleninsky area of well 2720.

Figure 4 is an example of the creation of vertical filtration at well 2720 of the Talinsky field of Krasnoleninsky Square.

The relationship (Fig. 1) between the initial fluid flow rate and the maximum permeability of the supercollector of the UK ₁₀ reservoir is obtained. The analysis involved more than 300 wells built on the UK ₁₀ formation. Fishing materials are processed according to (9). As can be seen, between the fluid flow rate and the maximum permeability of the supercollector, there is an inverse relationship with a correlation ratio of 0.6.

The relationship between the initial specific fluid flow rate per ton of proppant and the maximum permeability is considered (figure 2). An inverse relationship is obtained with a correlation ratio of 0.7.

This conclusion about the presence of an inverse dependence of the fluid flow rate on the maximum permeability of the supercollector is associated with the peculiarity of crack formation in the presence of a highly permeable interlayer in the reservoir.

The relationship between the initial specific fluid flow rate per ton of proppant and the average permeability in the section is considered. There is practically no connection between these parameters (correlation ratio of 0.13). This situation is probably due to the fact that the priority when creating a hydraulic fracture is the interval of a highly permeable layer, and not the reservoir matrix.

This conclusion allows us to justify the technical solution for the development of a multilayer reservoir having a high permeability layer and exceeding the average permeability of the formation by three or more times.

Thus, it is proposed that in a multilayer reservoir having a high permeability interlayer, hydraulic fracturing is performed in the low permeability interval separated by a clay section. To improve the quality of cementing and create the optimal fracture, the hydraulic fracturing of the wellbore in the zone of the productive (production reservoir) is carried out vertically. After selecting the design volume of oil from the low permeability interval, a high permeability interlayer is opened by perforation. To create vertical filtration into a highly permeable interlayer, a lateral horizontal well is drilled in the low-permeability interval, followed by interval fracturing with preliminary cutting of slotted channels.

This technological solution will allow to extract additional oil from the low permeability interval of the reservoir and increase the oil recovery coefficient in general by 5-7%, which can be seen from the diagram where there is an active involvement in the development of a low permeability section with a permeability of 41 mD by using the proposed method, creating a vertical filtration from a supercollector into a low-permeability section of the reservoir

Thus, the invention allows to reduce the unevenness of the formation of multilayer reservoirs and to ensure maximum selection of fluids.

Information sources:

1. The method of developing a multilayer oil reservoir. No. 2170344 ЕВВ 43/20. publ. 2001.07.10 - an analogue.

2.Saunin V.I. The choice of the design of the face and technology of completion in the oil fields of Western Siberia. Oil industry, No. 12, 2004, p.64-67.

3. The development project of the Koshilskoye field. LLC TNNC, 2006

4. Kanevskaya R.D., Diyashev I.R., Nekipelov Yu.V. (OAO Sibneft, NIIPP INPETRO) The use of hydraulic fracturing to intensify production and enhance oil recovery, Oil Industry N5, 2002, p.96-100.

5. Technological regulations on the technology of hydraulic fracturing to intensify the influx of reservoir fluid. RD 00158758-212-2000, Tyumen, 2001, p. 68.

6. A method of developing an oil and gas reservoir using hydraulic fracturing. No. 2135750 Е21В 43/20, 43/26. Publ. 08/27/1999 - a prototype.

7. Development and implementation of requirements for uncoupling of productive formations with bottom water when completing wells in Western Siberia. The dissertation for the degree of candidate of technical sciences, Tyumen, 1984, p.162.

8. Saunin V.I., Yagafarov A.K. CJSC TNNC Assessment of the tension of the geological environment and its impact on the efficiency of well construction. Problems of geology and development of oil and gas fields. (Collection of scientific works of ZAO Tyumen Oil Research Center, dedicated to the 5th anniversary of the Center). - Tyumen, 2006. - 412 p.

9. Schigolev B.M. Mathematical processing of observations, M., Science, 1969, p. 344.

Claims (2)

1. A method of developing a multilayer oil reservoir in the presence of a highly permeable interlayer using hydraulic fracturing, injecting a displacing agent through injection wells, selecting reservoir fluids through production wells, performing hydraulic fracturing to produce an effective hydraulic fracturing, characterized in that the hydraulic fracturing is carried out not immediately across all layers, but selectively, in the zone of low permeability layers, excluding perforation of a highly permeable layer with a permeability of three or more times higher than the average in the reservoirs, then after the projected selection of oil reserves, a highly permeable reservoir is perforated with the subsequent exploitation of the latter, a barrel with vertical entry into the production facility is performed to provide the maximum fracture pressure gradient and to create the optimal hydraulic fracture, at the same time, hydraulic fracturing is performed in the injection well stock at low permeability intervals. 2. The method according to claim 1, characterized in that to create a vertical filtration between a highly permeable interlayer, non-perforated, and low permeability, a lateral horizontal wellbore is carried out in a low permeability interval followed by interval hydraulic fracturing.

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