RU2737630C1 - Method for repeated multi-stage hydraulic fracturing of formation in horizontal well - Google Patents

Abstract

FIELD: oil, gas and coke-chemical industries.

SUBSTANCE: invention relates to oil and gas industry and can be used as a method for increasing production capacity or injectivity of injection wells, specifically as a method for repeated hydraulic fracturing of oil or gas formation in horizontal well. To implement the method, a tubing string with a packer is lowered into the well. Annular space between casing string and tubing string is sealed. First, the number of hydraulic crack fracturing initiation points is determined in a horizontal wellbore by combining and mutual exchange of data obtained during geophysical survey in horizontal shaft with results of calculations based on geological and hydrodynamic and geomechanical modelling. Depending on the number of defined points of hydraulic fracturing cracks initiation, repeated hydraulic fracturing is performed in several steps, but at least two stages. At each stage, proppant is pumped in amount not less than total weight of injected proppant at first hydraulic fracture, proportionally divided by number of stages. Immediately prior to performing the stages of repeated hydraulic fracturing, calculations are performed to determine number of hydraulic fracturing initiation points by performing diagnostic injections (mini HF).

EFFECT: technical result is improved reliability and speed of repeated hydraulic fracturing in wells equipped with unbalanced shanks.

1 cl, 1 dwg

Description

The invention relates to the oil and gas industry and can be used as a method for increasing the productivity of producing or injectivity of injection wells, namely as a method for re-hydraulic fracturing of an oil or gas reservoir in a horizontal well.

There is a method of improving the hydrodynamic connection with the formation, including carrying out acid hydraulic fracturing (HF) by installing a packer above the top of a perforated productive formation, injecting hydraulic fracturing fluid into the sub-packer zone, creating a hydraulic fracturing pressure in the sub-packer zone and pushing the hydraulic fracturing fluid into the formed fracture. According to the invention, after acid fracturing, a repeated hydraulic fracturing is performed in two stages, and at the first stage, the fracture formed as a result of acid fracturing is fixed by pumping a fracturing fluid with a proppant in a calculated amount sufficient to change the horizontal stresses in the carbonate reservoir and perpendicular to the direction of the second fracture formed during carrying out the second stage of acid hydraulic fracturing relative to the first fracture, and after the first stage of re-fracturing, the well is tested for pouring through the chokes in an increasing sequence of their diameters, while at the first stage of hydraulic fracturing, a gel is used as a hydraulic fracturing fluid, and at the second, an acid composition (patent RU 2462590, IPC Е21В 43/26 publ. 09/27/2012, bulletin No. 27).

The disadvantages of this method are the complexity and laboriousness of implementation, due to the need to use various acid compositions, as well as the long duration of time associated with the need to run the well for pouring through the chokes in an increasing sequence of their diameters.

There is also known a method of performing re-fracturing using borated galactomannan gum, including performing hydraulic fracturing of the productive zone inside the underground formation, isolating the productive zone subjected to hydraulic fracturing from the second zone in the well by injecting unhydrated borated galactomannan gum and a crosslinking agent into the well, and before the transition into a crosslinked state, unhydrated borated galactomannan gum contains borate ions, and the formation of a thickened temporary seal through the interaction of unhydrated borated galactomannan gum and a crosslinking agent, thereby isolating the productive zone subjected to hydraulic fracture from the second zone, the destruction of the productive zone between thickened times fractured and the second zone by injecting a viscosity-lowering agent into the well and reducing the viscosity of the thickened temporary sealing with a viscosity-lowering agent, wherein the viscosity-lowering agent is pumped into the well under pressure insufficient to create or expand a fracture in the subterranean formation, re-fracturing an isolated hydraulically fractured pay zone after the destruction of the thickened temporary seal by injecting fluid into the well medium for hydraulic fracturing under pressure sufficient to create or expand a fracture in an isolated productive zone subjected to hydraulic fracturing (patent RU 2682833, IPC Е21В 43/26, C09K 8/514, publ. 21.03.2019, bul. No. 9).

The disadvantage of this method is the low efficiency of implementation of the method due to clogging of the bottomhole zone, due to the need to isolate the productive zone subjected to hydraulic fracturing from the second zone in the well by injecting unhydrated borated galactomannan gum and a crosslinking agent into the well.

Is also known to re-fracturing comprising pumping fracturing fluid technology and modes according to the first fracturing, in which it the step of adding crosslinker is added in an amount of 1-2 liters per 1 m ³ of the fracturing fluid mixture comprising about. %: 10-27% hydrochloric acid 15-25, methylene phosphoric acid 55-65, water 15-25 (patent RU 2579093, IPC E21B 43/267, publ. 03/27/2016, bull. No. 9).

The disadvantage of this method is the high risk of complications (up to an emergency stop - STOP) during injection, due to a drop in the sand-carrying capacity of the fracturing fluid due to the addition of various acids to it.

The closest in technical essence is a system and method for re-fracturing in multi-zone horizontal wells, including hydraulic isolation of the first region from a section of a multi-zone horizontal well extending from this first region to the wellhead, and in the first region at least one fracturing was previously performed, re-fracing in the first area, placing the first diverting material in close proximity to the first area after re-fracing, the first diverting material hydraulically isolating the first re-fractured area from a section of a multi-zone horizontal well extending from this first areas to the wellhead, hydraulic isolation of the second area from a section of a multi-zone horizontal well extending from this second area to the wellhead, and in the second area, at least one hydraulic fracturing was previously performed, repeated hydraulic fracturing P in the second area and placing the second diverting material in close proximity to the second area after re-fracturing it, and the second diverting material hydraulically isolates the second area, in which the re-fracturing was performed, from a section of a multi-zone horizontal well extending from this second area to wellhead (patent RU 2663844 IPC E21B 43/26, 43/14, publ. 10.08.2018, bul. No. 22).

The disadvantages of this method are the impossibility of re-fracturing in wells, the horizontal wells of which are equipped with unequal liners (hydraulic fracturing couplings activated by special balls), as well as the complexity and laboriousness of execution, due to the need to run and install a cut-off packer in the horizontal wellbore.

The objective of the invention is to minimize costs and reduce the time spent on re-fracturing operations.

The technical result is the creation of a simple and reliable method of re-fracturing in wells equipped, among others, with unequal liners.

The specified technical result is achieved by the method of re-fracturing in a horizontal well, including running a tubing string with a packer into the well, sealing the annular space between the casing and the tubing string, creating a pressure in the underpacker zone sufficient to initiate a hydraulic fracture by injection of fracturing fluid into the well along the tubing string, consolidation of the created fracture by injecting proppant into it.

What is new is that the number of places of initiation of hydraulic fractures in a horizontal wellbore is preliminarily determined by integrating and interchanging data obtained during geophysical surveys in a horizontal wellbore with the results of calculations performed on geological-hydrodynamic and geomechanical models. Depending on the number of certain points of initiation of hydraulic fractures, re-fracturing is carried out in several stages, but not less than two, and at each stage proppant is injected in an amount not less than the total mass of the injected proppant at the first hydraulic fracture proportionally divided by the number of stages, and directly before performing the stages of re-fracturing, the calculations are verified to determine the number of fracture initiation sites by means of diagnostic injection.

Also new is the fact that re-fracturing is carried out using a packer set in the vertical part of the horizontal well.

FIG. 1 shows an example illustrating the result of calculations to determine the locations of initiation of hydraulic fractures, namely, the profile of the distribution of minimum horizontal stresses along a horizontal wellbore.

The proposed method is implemented as follows.

Re-fracturing in a horizontal well begins with the planning stage, at which the number of fracture initiation points in the horizontal wellbore is determined - in fact, the number of proppant injection stages during the hydraulic fracturing process is determined.

For this, a complex of geophysical studies is carried out in a horizontal wellbore aimed at determining the geomechanical parameters of rocks. At the same time, based on geological, hydrodynamic and geomechanical modeling, the profile of minimum horizontal stresses along the horizontal wellbore is calculated, taking into account the data obtained during the geophysical survey of the horizontal wellbore. Zones with low values of minimum horizontal stresses are determined by the profile of minimum horizontal stresses, i.e. places of the most probable initiation of hydraulic fractures.

Determination of the number of stages in the re-fracturing process is based on the well-known fact that hydraulic fractures predominantly develop in the zone with the lowest horizontal stress. Consequently, during hydraulic fracturing, this zone will receive the largest amount of fluid and the pressure in it will increase. During the next injection cycle, the fracture will be created in the zone with the next lowest closure stress, as a result of which the closure pressure in it will also increase. The next cycle will activate the crack in the next interval, and so on. Thus, with successive injection cycles, the fractures will develop sequentially, starting from the zone of the lowest closure stress towards the zones with sequentially increasing stress.

After determining the number of stages of proppant injection, re-fracturing is started directly on the well, while a packer installed in the vertical part of the horizontal well is used to protect the production string from high pressures.

In order to verify the calculations to determine the number of fracture initiation sites, diagnostic injection is performed immediately before performing the re-fracturing stages.

An example of a specific implementation.

A multistage hydraulic fracturing was performed on a horizontal well equipped with a non-equal-bore liner with swellable packers and five hydraulic fracturing sleeves activated by balls with a total mass of 150 tons of proppant injected. The well was in operation for one year. During this time, the oil production rate decreased from 45 to 8 tons / day. It was decided to stimulate the well by re-fracturing.

To determine the number of stages of proppant injection into the well, the locations of hydraulic fracture initiation in the horizontal wellbore were evaluated. For this, a complex of geophysical studies was carried out aimed at determining the geomechanical parameters of rocks.

On the basis of geological-hydrodynamic and geomechanical modeling, the profile of the minimum horizontal stresses along the horizontal wellbore was calculated taking into account the data obtained during the geophysical survey (see Fig. 1).

According to the profile, the values of the minimum horizontal stresses in ports were, respectively, 405 atm in port No. 1, 431 atm in port No. 2, 457 atm in port No. 3, 412 atm in port No. 4 and 423 atm in port No. 5. Horizontal well ports are numbered starting from the toe. Accordingly, zones with minimum horizontal stresses are marked in ports # 1 and # 4. The proppant mass to be injected at each stage was determined by halving the total proppant mass injected at the first hydraulic fracture.

After determining the number of fracture initiation sites in the horizontal wellbore, re-fracturing was started. For this, a packer was lowered into the well on a tubing string, and the packer was planted in the vertical part of the horizontal well.

In order to verify the preliminary calculations to determine the number of fracture initiation sites in the horizontal wellbore, we performed diagnostic injection (mini-frac) and determined the value of the minimum horizontal stress in the horizontal part of the well. Received a value equal to 402 atm. We compared the value obtained during the mini-frac with the values obtained during the preliminary calculations. It was concluded that the preliminary calculations are correct and a hydraulic fracture will initially develop in the area of Port No. 1. With this in mind, the first stage of re-fracturing was carried out, in which 75 tons of proppant were injected into the well.

After completing the first stage, mini-hydraulic fracturing was carried out and the value of the minimum horizontal stress in the horizontal part of the well was determined, which was 411 atm. We compared the value obtained during the mini-frac with the values obtained during the preliminary calculations. It was concluded that the preliminary calculations are correct and a hydraulic fracture will develop in the area of Port No. 4. Taking this into account, the second stage of re-hydraulic fracturing was carried out, where 75 tons of proppant were pumped into the well.

After completing the second stage, mini-frac was performed and the value of the minimum horizontal stress in the horizontal part of the well was determined, which was 415 atm. We compared the value obtained during the mini-frac with the values obtained during the preliminary calculations. It was concluded that a hydraulic fracture will also develop in the area of Port No. 4. Taking this into account, it was decided to terminate the re-fracturing of the formation, since when the proppant is pumped at the third and subsequent stages, hydraulic fracturing cracks will be formed mainly in the already stimulated zones.

After the repeated hydraulic fracturing, the well was put into operation with an oil flow rate of 27 t / day.

Thus, using the proposed method, a repeated hydraulic fracturing was sequentially performed through the open fracture ports of a horizontal well.

Claims (2)

1. A method for re-fracturing a formation in a horizontal well, including running a tubing string with a packer into the well, sealing the annular space between the casing and the tubing string, creating a pressure in the under-packer zone sufficient to initiate a hydraulic fracture, by pumping the fracturing fluid into the well along the tubing string, fixing the created fracture by injecting proppant into it, characterized in that the number of fracture initiation points in the horizontal wellbore is preliminarily determined by integrating and interchanging data obtained during geophysical of studies in a horizontal wellbore with the results of calculations performed on the basis of geological-hydrodynamic and geomechanical modeling, depending on the number of certain places of initiation of hydraulic fractures, repeat hydraulic fracturing of the formation in several stages, but not less than two, and at each stage, proppant is injected in an amount not less than the total mass of the injected proppant at the first hydraulic fracturing, proportionally divided by the number of stages, and immediately before performing the stages of re-hydraulic fracturing, the verification of calculations to determine the number of fracture initiation sites by means of diagnostic injection. 2. The method according to claim 1, characterized in that the repeated hydraulic fracturing of the formation is carried out using a packer set in the vertical part of the horizontal well.

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