RU2547892C1 - Multiple hydraulic fracturing of formation in well horizontal shaft - Google Patents

Abstract

FIELD: oil-and-gas industry.SUBSTANCE: proposed method comprises drilling the well horizontal shaft in oil-saturate section of production bed, cementing of annulus between casing and bed rock. Casing pipe is perforated in said well shaft oriented in azimuth by intervals with the help of slot perforator lowered in the well on string in a single trip. String with packer is lowered in the well to fit the packer in place. Fracturing fluid is injected via said string for hydrofracturing in said horizontal well shaft. Well shaft us drilled in the bed parallel with direction of minimum main strain. Plug is fitted at string lower end and two packers are arranged at flexing pipe string. Note here that through holes are made at the latter. Said flexing pipe string with packers is lowered into well shaft for hydraulic fracturing via perforated intervals by cutting of every interval of perforation on both sides. Bed fracturing is started from horizontal well interval nearby the bottom and fluid is forced via flexible pipe string via through holes at flow rate of 2 m/min to produce transverse fractures from perforation interval relative to well shaft. Note here that fracturing fluid is composed of hydrocarbon-based cross-linked gel. Made fractures are secured by injection of proppant of 12/18 mesh fraction with cross-linked gel, a carrier fluid. Packers are removed to displace flexible pipe string for hydraulic fracturing of the bed in the next perforation interval. Then, above jobs are reiterated. Then, flexible piper string with packers is withdrawn from the well to lower pipe string therein. Packer is fixed at well vertical part for hydraulic fracturing by injection of fluid via horizontal well shaft to produce lengthwise fractures at flow rate of 8 m/min. Linear gel is used as fracturing fluid. Said lengthwise fractures are secured by injection of ground quartz with linear gel as carrier fluid.EFFECT: higher efficiency of fracturing.2 dwg

Description

The invention relates to the oil industry and can be used in the development of oil fields, in particular fields having productive formations with low reservoir reservoir properties by hydraulic fracturing.

A known method of multiple hydraulic fracturing in a horizontal wellbore (patent RU No. 2472926, IPC E21B 43/267 publ. 01/20/2013, bull. No. 2), including the descent of the packer into the well on a pipe string with its subsequent landing in the well, the formation of cracks opposite the filters, sequentially at different intervals of the reservoir, opened by a horizontal wellbore, by supplying hydraulic fracturing fluid through a filter installed in each of the parts of the horizontal wellbore corresponding to each of these intervals with isolation of the remaining parts In this case, the direction of the horizontal trunk relative to the direction of the minimum principal stress is determined, then the interval to be hydraulically fractured is isolated from the remaining sections of the horizontal trunk by planting twin packers, then the valve located inside the pipe string between the twin packers opposite the filter is opened if the direction of the horizontal trunk parallel to the direction of the minimum principal stress, the hydraulic fracturing is carried out by injection of a fracturing fluid the formation of transverse cracks relative to the horizontal wellbore and subsequent fastening of transverse cracks by injecting a fluid with aluminosilicate proppant, gradually increasing its fractions from 20/40 mesh to 16/30 mesh, if the direction of the horizontal trunk is perpendicular to the direction of the minimum principal stress, then hydraulic fracturing is carried out by pumping a fracturing fluid with the formation of horizontal cracks relative to the horizontal trunk and subsequent fastening of horizontal cracks by pumping fluid with with a proppant with a 20/40 mesh fraction, at the end of the hydraulic fracturing, the well is closed for a technological pause for 0.5 h, after which an adjustable nozzle is installed on the wellhead at the wellhead and the spent proppant fluid is poured out of the formation along the wellhead pipe string wells before closing the valve, while during the spout by adjusting the nozzle, they ensure that the pressure in the pipe string is 2-3 MPa less than the pressure when opening the well after a technological pause, after which releasing the packer and moving the pipe string into the horizontal bore other part, and the above process for the hydraulic fracturing in a horizontal wellbore is repeated depending on the number of horizontal barrel slots filters equipped in its various parts.

The disadvantages of the method are:

- firstly, the low efficiency of the implementation of the method in a reservoir with low reservoir filtration and reservoir properties, which is due to the weak attachment of proppant in longitudinal and transverse fractures formed from a horizontal wellbore, therefore, during subsequent production from transverse and especially longitudinal fractures formed in in a productive formation with low reservoir-filtration-reservoir properties, proppant grains will enter the horizontal wellbore, which will lead to the closure of cracks and p viscous reduce the bandwidth of the formation of cracks in the near-wellbore zone;

- secondly, the high duration of the hydraulic fracturing associated with conducting hydromechanical slotted perforation of the casing string (liner) by lowering the perforator on the pipe string;

- thirdly, the high material and financial costs of implementing the method associated with casing a horizontal shaft with a casing or liner and its subsequent cementing.

The closest in technical essence is the method of hydraulic fracturing in a horizontal wellbore (patent RU No. 2401942, IPC E21B 43/26, publ. 10/20/2010, bull. No. 29), including drilling a horizontal wellbore in the oil-saturated part of the reservoir with cementing the annular space between the casing and rock of the productive formation of the horizontal wellbore, perforating the casing, lowering the pipe string with the packer into the well, perforating and forming hydraulic fractures of the injection formation fracturing fluid in the horizontal wellbore sequentially, starting from the end farthest from the axis of the vertical wellbore communicating the horizontal wellbore with the reservoir, while during the next hydraulic fracturing, each perforated section through which hydraulic fracturing is performed is isolated from the rest columns with packers, while drilling the horizontal wellbore is carried out in the oil-saturated part of the reservoir with cementing the annular space the holes between the casing and the rock of the horizontal wellbore, and the perforation of the horizontal wellbore, azimuthally oriented by the intervals, is performed using a hydromechanical slotted perforator, lowered into the well on the pipe string in one round trip, after which the packers are lowered, cutting off each interval, equal to the length of the formed gap from the rest of the column, and hydraulic fracturing in the horizontal part of the wellbore is performed sequentially, starting from the furthest from the axis the borehole of the perforated section of the horizontal borehole, and the hydromechanical slotted perforation is performed bilaterally to form slots that are located relative to each other at an angle of 180 ° in a vertical plane opposite each other, relative to the axis of the horizontal wellbore in one interval, or perform one-sided hydromechanical slotted perforation rotated 180 ° in a vertical plane relative to the axis of the horizontal wellbore, alternately through each pos the next interval - in a checkerboard pattern, equal to the length of the formed gap, or with a small thickness of the reservoir and in the presence of active bottom water produce one-way hydromechanical slotted perforation in the direction of the roof of the formation.

The disadvantages of this method:

- firstly, the low efficiency of the implementation of the method in a reservoir with low reservoir filtration and reservoir properties, due to the lack of crack attachment, which leads to the closure of the cracks and a sharp decrease in the throughput of the formation cracks in the near-wellbore zone;

- secondly, the low reliability of hydraulic fracturing, due to the fact that the perforation interval to be hydraulically fractured is cut off only on one side, therefore, the proppant flow into the horizontal wellbore is increased;

- thirdly, the high duration of hydraulic fracturing associated with the entire cycle of the process of conducting interval hydraulic fracturing in a horizontal wellbore using a pipe string.

The technical objectives of the proposal are to increase the efficiency of hydraulic fracturing by creating a branched network of fixed cracks in a productive reservoir with low reservoir and filtration-reservoir properties, as well as increasing reliability by minimizing proppant removal into a horizontal wellbore and shortening the duration of hydraulic fracturing during due to the acceleration of the process.

The stated technical problems are solved by the method of hydraulic fracturing in a horizontal wellbore, including drilling a horizontal wellbore in the oil-saturated part of the reservoir with cementing the annular space between the casing and rock of the productive formation of the horizontal wellbore, perforating the casing in the horizontal wellbore, azimuthally oriented using a hydromechanical slotted puncher lowered into the borehole on a stake it doesn’t include pipes in one round-trip operation, lowering a pipe string with a packer into a well, packing a packer, pumping a fracturing fluid along a pipe string and forming hydraulic fractures in the horizontal wellbore.

What is new is that the horizontal wellbore in the oil-saturated part of the productive formation is drilled in the formation parallel to the direction of the minimum principal stress, the casing is lowered into the well and cemented, then the hydromechanical slotted perforator is lowered on the string of flexible pipes and the perforation is performed in the horizontal wellbore, the string is removed flexible pipes with a hydromechanical slotted punch from the well, dismantle the hydromechanical slotted punch, on the lower end of the column of flexible a plug is installed and two packers are mounted on the string of flexible pipes, through holes are made between the packers in the string of flexible pipes, then the string of packers with packers is lowered into the horizontal wellbore and hydraulic fracturing is performed at perforated intervals in the horizontal wellbore by cutting off each perforation interval on both sides, and the interval hydraulic fracturing begins from the horizontal well interval closest to the bottom of the hole and produces they drive injection fluid through a string of flexible pipes through holes with a flow rate of 2 m ³ / min with the formation of transverse cracks from the perforation interval relative to the horizontal wellbore, and as a fracture fluid, a cross-linked gel is used on a hydrocarbon basis, after the formation of transverse cracks, they are fixed by injection along the column of proppant tubes of fraction 12/18 mesh with a carrier fluid — crosslinked gel, packers are unpacked and the string of flexible pipes is moved to carry out hydraulic fracturing in the next perforation interval, then the above-described technological operations are repeated, starting with the packers landing and ending with the movement of the string of flexible pipes to the next interval of perforation depending on the number of perforation intervals of the horizontal wellbore, then the string of flexible pipes with packers is removed from the well and the pipe string with the packer is lowered into the well, put the packer in the vertical part of the well and produce hydraulic fracturing by pumping the fracture fluid along the pipe string through a horizontal well with Vazhiny to form longitudinal cracks fracturing a rate of 8 m ³ / min, and as a fracturing fluid using a linear gel, whereupon fastening longitudinal cracks injection silica flour with a liquid carrier - linear gel.

The essence of the proposal is that after the creation of interval-wise transverse fractures relative to the horizontal wellbore, the fracture perimeter is blocked by a large fraction proppant (12/18 mesh), therefore, with further hydraulic fracturing by a “common filter” by increasing the injection rate, “bloating” occurs cracks and an increase in its width, which leads to bending of the surface of transverse cracks in the direction of the main stress, namely, the development of longitudinal cracks and, as a result, the formation of a network of branched cracks in a reservoir with low reservoir reservoir properties by hydraulic fracturing.

1 and 2 schematically and sequentially depicted the proposed method.

The method is implemented as follows.

The horizontal wellbore 1 (see Fig. 1) of the well 2 is drilled in the oil-saturated part of the reservoir 3 parallel to the direction of the minimum principal stress - σ _min .

Lower the casing 4 into the well 2 and cement the annular space 5 between the casing 4 and the rock of the producing formation 3 of the horizontal wellbore 1 of the well 2.

Then, on the string of flexible pipes 6, a hydromechanical slotted punch (not shown in FIGS. 1 and 2) is lowered into the horizontal bore 1 of the casing 4 of the well 2 and interval perforation is performed in the horizontal bore 1 (see FIG. 1) of the well 2. For example, hydromechanical perforation in four intervals 7 ′, 7 ″, 7 ″ ″, 7 ″ ″ (see FIGS. 1 and 2) of the horizontal wellbore 1 of well 2, using any known slotted hydromechanical perforator, for example, manufactured by LLC "Complex" (Ekaterinburg, Russia).

The column of flexible pipes 6 with the hydromechanical slotted punch is removed from the well 2, the hydromechanical slotted punch is dismantled. A plug 8 is installed on the lower end of the flexible pipe string 6 and two packers 9 and 10 are mounted on the flexible pipe string 6, through holes 11 are made between the packers 9 and 10 in the flexible pipe string 6.

Packers 9 and 10 have the ability to tightly cut off each of the four intervals 7 ′, 7 ″, 7 ″ ″, 7 ″ ″ (see FIGS. 1 and 2) of the horizontal wellbore 1 of the well 2. In order to eliminate an error in the fit and, as a result, leaky cutoff, the distance L (see Fig. 1) between the packers 9 and 10 on the string of flexible pipes 6 should be 5 m longer than the maximum length - l of any of the four intervals 7 ′, 7 ″, 7 ″ ′, 7 ′ ′ ′ ′.

As the string of flexible pipes 6 (see FIGS. 1 and 2), for example, a string of flexible pipes with a diameter of 60 mm is used. As packers 9 and 10, continuous packers with an anchor of the mechanical axial and rotary installations PRO-YaM2-YaG1 (F) or PRO-YaM3-YaG2 (F) (100 MPa) manufactured by the Packer research and production company (Oktyabrsky) are used , Republic of Bashkortostan, Russian Federation).

A column of flexible pipes 6 is lowered into the horizontal wellbore 1 of the well 2, plugged from below and equipped with packers 9 and 10. Interval hydraulic fracturing of the formation is made through the perforated intervals 7 ′, 7 ′ ′, 7 ′ ′ ′, 7 ′ ′ ′ ′ in the horizontal wellbore 1 wells 2. To do this, first packers 9 and 10 are planted and the perforation interval 7 ′ of the horizontal well 1 of the well 1 closest to the bottom is cut off. Hydraulic fracturing of the formation is carried out in this interval by pumping a fracture fluid, which uses a cross-linked gel for hydrocarbon th basis.

A cross-linked hydrocarbon-based gel with a flow rate of 2 m ³ / min along the string of flexible pipes 6 through its through holes 11 falls into the perforation interval 7 ′ of the horizontal wellbore 1 of the well 2 with the formation of a transverse crack 12 ′ relative to the horizontal wellbore 1 of the well 2. On the formation of a transverse crack 12 ′ indicate a drop in injection pressure and an increase in injectivity of formation 1. For example, when the crosslinked gel was injected into the formation 3, a pressure of 30 MPa was reached, due to the formation of a transverse crack 12 ′ in the formation 3, the injection pressure dropped crosslinked gel by 25%, i.e. up to 22.5 MPa, while the injectivity of the formation 3 increased by 50%, for example, with a flow rate of up to 4.5 m ³ / min.

The use of a flexible pipe string 6 accelerates the process of carrying out tripping operations and reduces the duration of hydraulic fracturing, and the use of twin packers allows you to cut the perforation interval to be hydraulic fractured from two sides, which minimizes proppant removal during subsequent hydraulic fractures formation perforation intervals in a horizontal wellbore 1 of a well 2.

A transverse crack 12 ′ is fastened by pumping through a string of flexible pipes 6 proppant fractions 12/18 mesh with a grain size of 0.8-1.0 mm with a carrier fluid (crosslinked gel).

The proppant fraction 12/18 mesh with a grain size of 0.8-1.0 mm is made in accordance with GOST R 51761-2005 - "Aluminosilicate proppants. Specifications ”and is produced by the Borovichi Refractories Plant (Borovichi, Republic of Belarus).

A cross-linked hydrocarbon-based gel has a high viscosity in the formation, which, when injected into the formation with a flow rate of 2 m ³ / min, provides the creation of wide, deeply penetrating cracks with good filling of the proppant material. When destruction does not form a sediment, does not damage the formation and proppant packing.

Unpack the packers 9 and 10 and move the string of flexible pipes 6 towards the wellhead 2 for hydraulic fracturing in the next interval 7 ″, where all technological operations are repeated in the same way, starting from cutting off the perforation interval 7 ″ by the packers 9 and 10 and ending with the movement columns of flexible pipes 6 in the next interval 7 ″ ″. Thus, an interval hydraulic fracturing is performed with the formation of transverse cracks 12 ′, 12 ″, 12 ″, 12 ″ ″ in all perforation intervals 7 ′, 7 ″, 7 ″, 7 ″ ″ in the horizontal wellbore 1 of the well 2.

To create transverse cracks 12 ′, 12 ″, 12 ″ ″, 12 ″ ″ ′ (see FIG. 1), a cross-linked hydrocarbon-based gel with a dynamic viscosity of 150 (cP) is used in reservoir 3 (see chapter 3 of the monograph SA Ryabokonya “Technological fluids for completion and repair of wells (OJSC NPO Bureniye, 2006. P.153), which includes a polymer solution (MO-NT) in hydrocarbon, a crosslinking and temporary destructor (MO-NT hydrophobic modification PAA) My-T-Oil (Halliburton).

Next, the string of flexible pipes 6 with packers 9 and 10 is removed from the well 2 and the string of pipes 13 (see FIG. 2) with the packer 14 is lowered into the well 2. The packer 14 is planted in the vertical part of the well 2. According to the string of pipes 13 (see FIG. .2) pump the fracturing fluid (linear gel) into the horizontal wellbore 1 of well 2 with a flow rate of 8 m ³ / min, through transverse cracks 12 ′, 12 ′ ′, 12 ′ ′ ′, 12 ″ ″ ”form longitudinal cracks 15 ′, 15 ′ ′, 15 ′ ′ ′, 15 ′ ′ ′ ′ in the formation 3 relative to the open horizontal wellbore 1 of the well 2. The formation of longitudinal cracks 15 ′, 15 ′ ′, 15 ′ ′ ′, 15 ′ ′ ′ ′ ′ indicate a drop in injection pressure and an increase in injectivity of the formation 3.

For example, when the linear gel was injected into the formation 3, a pressure of 33 MPa was reached, due to the formation of longitudinal cracks 15 ′, 15 ″, 15 ″, and 15 ″ ″ in the formation 3, the injection pressure of the crosslinked gel dropped by 25%, t. e. up to 24.75 MPa, while the injectivity of the formation 3 increased by 30%, for example, with a flow rate of up to 10.4 m ³ / min.

Longitudinal cracks are fastened 15 ′, 15 ′ ′, 15 ″ ″, 15 ″ ″ ″ by injection of fine proppant pipes 13 with a grain size of 0.05-0.15 mm, for example, silica flour with a carrier fluid (linear gel) )

As a small proppant, quartz flour with a grain size of up to 0.1 mm is used, which is produced according to TU5717-001-16767071-99 (supplier of Quartz Trade House LLC, Ekaterinburg, Russia).

The linear gel has low friction losses in the pipes, which, at a high injection rate of 8 m ³ / min, allows penetration deep into reservoir 3 and ensures uniform deposition of fine proppant along transverse 12 ′, 12 ″, 12 ″ ″, 12 ″ ′ ′ And longitudinal 15 ′, 15 ′ ′, 15 ′ ′ ′, 15 ′ ′ ′ ′ ′ fractures.

To create longitudinal cracks 15 ′, 15 ″, 15 ″ ″, 15 ″ ″ ”from transverse cracks 12 ′, 12 ″, 12 ″, 12 ″ ″ in formation 3 relative to the open horizontal wellbore 1 2 use a linear gel with a dynamic viscosity of 30 (cP).

For example, a linear water-based gel is used, which is prepared on water-soluble polymers of various nature of any known composition (for example, see the monograph by S. A. Ryabokonya “Technological fluids for completion and repair of wells” of NPO Bureniye, 2006. - P. 118).

The efficiency of the method implementation in a reservoir with low reservoir filtration and reservoir properties is increased due to the fastening of transverse cracks with a large proppant of the 12/18 mesh fraction with a grain size of 0.8-1.0 mm, and longitudinal cracks with a small proppant with a grain size of 0.1 mm Small proppant grains bind large proppant grains in longitudinal cracks, excluding their mobility. As a result, the closure of transverse cracks and the proppant exit into the open horizontal wellbore 1 of well 2 in the formation 3 are excluded, which preserves their throughput. As a result, in the reservoir 3 with low reservoir-reservoir properties, a branched network of fixed transverse 12 ′, 12 ″, 12 ″ ″, 12 ″ ″ and longitudinal 15 ′, 15 ″, 15 ″ ’, 15 ′ ′ ′ ′ cracks, which leads to an increase in the efficiency of hydraulic fracturing.

At the end of the hydraulic fracturing of the horizontal wellbore, the pressure in the well 2 is released, the packer 14 is unpacked and the pipe string 13 with the packer 14 is removed from the well 2. Production equipment is lowered into the well 2 (not shown in FIGS. 1 and 2) and the well is put into operation.

The proposed method of hydraulic fracturing in a horizontal wellbore allows you to:

- to increase the efficiency of the method in a reservoir with low reservoir filtration and reservoir properties;

- reduce the duration of hydraulic fracturing;

- to improve the quality of hydraulic fracturing by minimizing proppant removal into the horizontal wellbore.

Claims (1)

A method of hydraulic fracturing in a horizontal wellbore, comprising drilling a horizontal wellbore in an oil-saturated part of a producing formation with cementing the annular space between the casing and rock of a productive formation of a horizontal wellbore, perforating the casing in a horizontal wellbore azimuthally oriented by intervals with a hydraulic a perforator lowered into the well on a pipe string in one round trip, the descent of the pipe string with the packer into the well, the packing of the packer, the injection of fracturing fluid along the pipe string and the formation of hydraulic fractures in the horizontal wellbore, characterized in that the horizontal wellbore in the oil-saturated part of the productive formation is drilled in the formation parallel to the direction of the minimum principal stress, casing string into the well and cemented, then hydromechanical slotted perforator is lowered on the flexible pipe string and interval perforation is performed horizontally the borehole, remove the string of flexible pipes with a hydromechanical slotted puncher from the borehole, dismantle the hydromechanical slotted puncher, a plug is installed on the lower end of the string of flexible pipes and two packers are mounted on the string of flexible pipes, through holes are made between the packers in the string of flexible pipes, then lower into the horizontal wellbore a string of flexible pipes with packers and produce interval hydraulic fracturing at perforated intervals in the horizontal wellbore pu thereby cutting off each perforation interval on both sides, and the interval of hydraulic fracturing of the formation starts from the horizontal well interval closest to the bottom of the hole and the fracture fluid is pumped through the flexible pipe string through the through holes with a flow rate of 2 m ³ / min with the formation of transverse cracks from the horizontal perforation interval a wellbore, whereby a cross-linked hydrocarbon-based gel is used as a fracturing fluid; after the formation of transverse cracks, they are injected Packers of the 12/18 mesh fraction with the carrier fluid — crosslinked gel — are unpacked and the string of flexible pipes is unpacked for hydraulic fracturing in the next perforation interval, then the above-described technological operations are repeated, starting from the packing of packers and ending with the movement of the flexible column pipes in the next perforation interval depending on the number of perforation intervals of the horizontal wellbore, then the string of flexible pipes with packers is removed from the well and the columns are lowered tubing with a packer into the wellbore, plant packer in the vertical portion of the well and produce a hydraulic fracturing pumping the fracturing fluid through the pipe string through the horizontal well bore to form longitudinal cracks fracturing a rate of 8 m ³ / min, and using a linear gel as a fracturing fluid, after which fix longitudinal cracks by injection of quartz flour with a carrier fluid - a linear gel.

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