RU2774455C1 - Method for completing a well with a horizontal completion using a production column of one diameter from head to bottomhouse and subsequent carrying out large-volume, speed and multi-stage hydraulic fracturing - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention relates to the oil and gas industry, in particular to methods for completing horizontal wells. A method is proposed for completing a well with a horizontal completion using a production string of the same diameter from the wellhead to the bottom and subsequent high-volume with a volume of 150-200 tons, high-speed at a rate of 12 to 22 m³/min and multi-stage hydraulic fracturing (HF). At the same time, a production string is lowered into a horizontal section drilled in a hydrocarbon solution to the planned depth, both with the possibility of rotation during descent and cementing, and without rotation, consisting from bottom to top of: a drilling shoe of the string, a check valve, a landing sleeve for a cementing plug, a hydraulic fracturing sleeve , casing pipe with pipe centralizers, when choosing a two-stage cementing technology, a stage cementing sleeve (SCS) is used. The design of the previous casing strings is represented by a direction and a conductor or a direction, a conductor and an intermediate string. Next, one-stage or two-stage continuous cementing of the production casing is carried out, if necessary, during the cementing process, the production casing is rotated in order to obtain high-quality cement stone behind the casing. After the stage of waiting for cement hardening (WCH), measures are taken to check the production casing for tightness. To perform perforation for the technological stage of hydraulic fracturing in order to create injectivity, the hydraulic fracturing sleeve is activated by creating a pressure of up to 60 MPa in the production string, after activating the hydraulic fracturing sleeve, communication with the formation and injectivity appear through the circulation windows in the horizontal section of the well. In the absence of a hydraulic fracturing sleeve in the assembly, perforation for the technical stage of hydraulic fracturing is carried out using a coiled tubing fleet by lowering the assembly on a coiled tubing (CT) consisting of: a cumulative perforator and a sleeve locator, activation of the perforator is carried out hydraulically or electrically. After activating the hydraulic fracturing sleeve or after perforating and lifting the assembly on the coiled tubing, a technological stage of hydraulic fracturing is performed through the production string and perforations in order to increase the injectivity for further work. Further, for perforation for the first large-volume with a volume of 150-200 tons, high-speed with a speed of 12 to 22 m³/min stage of hydraulic fracturing with cluster perforation, an assembly is lowered into the production string on a cable or coiled tubing to the required depth, consisting from the bottom up of: the first section of the cumulative perforator, selective perforation sub, the second section of the cumulative perforator, the collar locator and the cable lug when the assembly is lowered on the cable. The perforators are activated hydraulically or electrically. Then the assembly is lifted and inspected for the operation of perforators. Further, through the perforations, which are part of one cluster, a large-volume hydraulic fracturing stage with a volume of 150-200 tons, a high-speed hydraulic fracturing stage with a speed of 12 to 22 m³/min, is performed. To carry out measures to separate the previous stages of hydraulic fracturing and cluster perforation, before the second and subsequent stages, an assembly is lowered into the production string on a cable or coiled tubing to the required depth, consisting of the following from the bottom up: thru-drillable or thru-soluble packer plug, landing tool, compensator, first section of the cumulative perforator, selective perforation sub, the second section of the cumulative perforator, collar locator and cable lug when running the assembly on the cable. The packer plug and perforators are activated hydraulically or electrically. Then the assembly is lifted and inspected for the installation of a packer plug and the operation of perforators, thereby ensuring the separation in the horizontal section of the production casing of the previous stage of hydraulic fracturing and cluster perforation, consisting of two intervals of perforations. Further, through the perforations, which are part of one cluster, a large-volume hydraulic fracturing stage with a volume of 150-200 tons, a high-speed hydraulic fracturing stage with a speed of 12 to 22 m³/min, is performed. To carry out subsequent stages of hydraulic fracturing and cluster perforation, operations to run the assembly with a plug packer and cumulative perforators are repeated up to the required number of stages, depending on the length of the horizontal section. After all stages of hydraulic fracturing, using a coiled tubing fleet, the liner is normalized by milling separating plugs using insoluble packer plugs or flushing the horizontal section of the well using soluble packer plugs, then the well is discharged or equipment is lowered into the production string on the tubing for operation.

EFFECT: development of a horizontal well design and technology for large-volume, high-speed and multi-stage hydraulic fracturing with cluster perforation and stage separation.

1 cl, 19 dwg

Description

The invention relates to the oil and gas industry, and more specifically to optimize the design of the well, increase the flow rate for the implementation of interval, high-volume, high-speed and multi-stage hydraulic fracturing (hereinafter hydraulic fracturing) in wells with a horizontal ending, as well as simplifying geological and technical measures during the operation of the well.

At present, hydraulic fracturing technology remains the most effective method for stimulating the inflow of hydrocarbons and increasing oil recovery of productive formations in wells, in particular with a horizontal completion. In many regions, according to some domestic and foreign researchers, this is the only technology to involve in the development of fields with hard-to-recover hydrocarbon reserves confined to low-permeability, poorly drained, heterogeneous and dissected reservoirs, which can significantly increase hydrocarbon production and make wells economically viable.

Known well design for multi-stage hydraulic fracturing [PM No. 175464], including non-cementing liner for multi-stage hydraulic fracturing, characterized in that it is made with the possibility of placement in the productive formation, fixing in the production string and separation of casing packers into sections containing a section of filter pipes , a section of continuous pipes and controlled circulation sleeves with the possibility of opening and closing, while the width of the slot in the filter pipe is determined by the ratio:

t ≤ (0.65÷0.80)D10,

where t is the slot width in the filter tube, mm;

D10 is the diameter of the proppant particles for hydraulic fracturing, corresponding to the size of the meshes of the sieve through which 10% of the total mass of the proppant sample passes, mm.

This design, which includes a filter pipe with a filter gap width determined according to the stated ratio, is aimed at preventing the removal of proppant (proppant) from hydraulic fractures into the well.

The disadvantage of this design is that hydraulic fracturing requires a tubing string equipped with a double packer, which implies the appearance of additional flow resistance, this will lead to a decrease in proppant concentration and, accordingly, the hydraulic fracture will not be effective enough. Also, there is no possibility to control the fixation of the upper packer, and the lower packer cannot be pressurized properly, i.e. it is highly likely that the packer will leak during hydraulic fracturing, which will lead to proppant spillage into the string.

The closest in technical essence and the achieved result is a method for completing the construction of a horizontal production well with interval hydraulic fracturing [RF Patent No. of the wellbore into zones that differ by the porosity and porosity characteristics of the formation by 1.5-1.6 times, selection of the throughput capacity of the filter holes separately for each zone and the number of holes depending on the porosity and porosity characteristics, lowering the production string into the bored horizontal wellbore with filter and annular oil-swellable packers, placement of packers at the boundaries of zones with different porosity and porosity characteristics, fastening of the production string, running a pipe string with a pump into a horizontal well and launching horizontal oh wells in operation. According to the invention, a water-swellable packer is installed on the outer surface of each filter, made in the form of an elastic sleeve with holes and stretched over the filter, moreover, the holes in the filters are coaxial with the holes made in the elastic sleeves, and the diameters of the holes in the elastic sleeve are made twice as large as the diameters of the holes in filters and in contact with water, the holes in the elastic hose are pulled together and hermetically sealed from the outside of the holes in the filters, the process pipe string is disconnected from the bottom-plugged retrievable liner by operating the downhole disconnector, after which the process pipe string is pulled to the surface, the pipe string is lowered into the horizontal well with pump and put the horizontal well into operation.

The disadvantages of this method are:

- swellable packers and sleeves require a certain dwell time for their activation or deactivation (in the case of sleeves), the reliability of which in reservoir conditions is questionable and it is almost impossible to control the result;

- the length of zones separated by casing packers for selective hydraulic fracturing is very limited, since, for example, at a 100 m zone it will be impossible to isolate some sleeves (close holes) and leave others, in addition, the sleeves will have to withstand the pressure created during hydraulic fracturing;

- low efficiency due to the fact that this method does not implement measures to prevent proppant carryover during well operation.

The objective of the claimed invention is the selection of the optimal option for completing a well with a horizontal completion, followed by a large-volume (for example: 150-200 tons), high-speed (for example: from 12 to 22 m3/min) and multi-stage (for example: from 15 to 50 stages ) Hydraulic fracturing with cluster perforation and separation between stages, which will increase the productivity of the well after the work.

The technical result consists in the development of a horizontal well design and technology for conducting large-volume, high-speed and multi-stage hydraulic fracturing with cluster perforation and stage separation.

The set task and the technical result are achieved by the fact that the method of completing a well with a horizontal completion using a production string of the same diameter from the wellhead to the bottom and subsequent large-volume, high-speed and multi-stage hydraulic fracturing, includes running into a horizontal production section drilled on a hydrocarbon solution (for example: diameter 139.7 mm) both with the possibility of rotation during running and cementing, and without the possibility of rotation, consisting of (from bottom to top): drilling shoe of the string (for example: shoe without check valve or shoe with check valve), check valve ( it is possible to use two check valves, a double check valve, or not include a check valve in the layout at all), a landing sleeve for a cementing plug (may not be included in the layout), hydraulic fracturing coupling or its analogues (may not be included in the layout), casing pipe (for example: 139.7 mm with cut lateral connection type TMK UP PF or VAM TOP HT), pipe centralizers (for example: spring or rigid), when choosing a two-stage cementing technology, it is possible to use a stage cementing sleeve (hereinafter MSC); in this case, the design of the previous columns can be presented in the following version:

Execution No. 1: Direction (for example: with a nominal outer diameter of 323.9 mm, GOST 632-80, vertical installation interval of the column: 0-60 meters, OTTMA connection type), conductor (for example: with a nominal outer diameter of 244.5 mm , GOST 632-80, vertical spacing of the column: 0-1800 (+/- 400) meters, type of connection OTTMA), production string (for example, with a nominal outer diameter of 139.7 mm, API Spec 5CT / ISO 11960:2004 , vertical installation interval of the column: 0-2400 (+/- 500) meters, connection type TMK UP PF or VAM TOP HT).

Execution No. 2: Direction (for example: with a nominal outer diameter of 426 mm, GOST 632-80, vertical installation interval of the column: 0-60 meters, type of connection NORMKB), conductor (for example: with a nominal outer diameter of 323.9 mm, GOST 632-80, vertical installation interval of the column: 0-1000 (+/- 400) meters, type of connection OTTMA), intermediate column (for example: nominal outer diameter 244.5 mm, GOST 632-80, vertical installation interval of the column : 0-1850 (+/- 400) meter, OTTMA connection type), production string (e.g. 139.7mm nominal OD, API Spec 5CT / ISO 11960:2004, vertical spacing: 0-2400 ( +/- 500) by meter, connection type TMK UP PF or VAM TOP HT).

* Next, we will consider the design of the previous columns in version No. 1.

One-stage, continuous cementing of the production string is carried out (it is possible to carry out two-stage cementing if there is an MSC in the composition of the layout), and if necessary, during the cementing process, the production string can be rotated in order to obtain high-quality cement stone behind the string.

Further, after waiting for cement hardening (WSC), measures are taken to ensure the tightness of the production casing.

Further, for perforation (communication with the formation) for the technological stage of hydraulic fracturing in order to create injectivity and the possibility of further pumping equipment, there are 2 options:

Option No. 1: If the hydraulic fracturing clutch (or its analogues) is included in the layout, it is activated by creating pressure in the production string (for example: up to 60 MPa (600 atm)), after activating the hydraulic fracturing clutch (or its analogues) through the circulation windows in the horizontal section of the well, communication with the formation and injectivity appear.

Option No. 2: If there is no hydraulic fracturing coupling (or its analogues) in the assembly, perforation for the technical stage of hydraulic fracturing is carried out by the coiled tubing fleet using the following methods:

The electric method consists in the fact that an assembly consisting of a cumulative electrical action perforator and a collar locator (may not be part of the assembly) is lowered into the production string on a coiled tubing (hereinafter coiled tubing) with a cable stored in it to a predetermined depth. Next, an electrical impulse is applied and the cumulative perforator is activated, after which the perforations in the production string will be delighted.

The hydraulic method consists in the fact that an assembly consisting of a cumulative hydraulic perforator and a collar locator (may not be part of the assembly) is lowered to a predetermined depth into the production string on coiled tubing. Next, the cumulative hydraulic perforator is activated by creating pressure in the coiled tubing (for example: 12 MPa (120 atm)), after which the perforations are filled in the production string.

After activating the hydraulic fracturing sleeve (or its analogues) or after perforating and lifting the assembly on the coiled tubing, the technological stage of hydraulic fracturing is performed through the production string and perforations (for example: 5-10 tons) in order to increase the injectivity for further work.

There are 2 options for perforation (communication with the formation) for the first, large-volume, high-speed stage of hydraulic fracturing with cluster perforation:

Option No. 1: A assembly is lowered into the production string on coiled tubing to the required depth (the assembly can be used both hydraulically and powered by an electrical impulse by means of a cable stored in the coiled tubing) consisting of (from bottom to top): the first section of the cumulative perforator, selective sub perforations, the second section of the cumulative perforator (sections with a shaped charge can be from 1 to 5), the clutch locator.

There are 2 methods for activating the layout: hydraulic and electrical .

The hydraulic method consists in the fact that when a certain pressure is created (for example: 12.5 MPa (125 atm)) the first section of the cumulative perforator is activated and perforations are formed in the production string, then pressure is created (for example: 15 MPa (150 atm) )) the second section of the cumulative perforator is activated and perforations are formed in the production string.

The electric method consists in the fact that an electrical impulse is applied through the stored cable located in the coiled tubing and the first section of the cumulative perforator is activated and perforations are formed in the production string, followed by the next electrical impulse and the second section of the cumulative perforator is activated and perforations are formed in the production string .

Option No. 2: A layout consisting of (from bottom to top) is lowered into the production string on a cable to the required depth: the first section of the shaped charge gun, the selective perforation sub, the second section of the shaped charge gun (sections with a shaped charge can be from 1 to 5), sleeve locator and cable lug.

The layout is activated electrically and consists in the fact that an electrical impulse is applied through the cable, as a result, the first section of the cumulative perforator is activated and perforations are formed in the production string, then the next electrical impulse is applied and the second section of the cumulative perforator is activated and perforations.

Next, the assembly of option No. 1 or option No. 2 is lifted and inspected for the operation of perforators. In the horizontal section of the production string, a cluster perforation is formed, consisting of two intervals of perforations (it is possible to use from 1 to 5 sections with shaped charges). Further, through the perforations included in one cluster, a large-volume (for example: 150-200 tons), high-speed (for example: from 12 to 22 m3/min) hydraulic fracturing stage is performed.

2** It is possible not to perforate and not to carry out the technological stage of hydraulic fracturing to create injectivity, but to carry out activities according to option No. 1 of perforating (communication with the formation) for the first, large-volume, high-speed stage of hydraulic fracturing with cluster perforation.

There are 2 options for carrying out activities for the separation of stages (upcoming from the previous one) and cluster perforation before the second and subsequent large-volume, high-speed and multi-stage hydraulic fracturing stages:

Option No. 1: A assembly is lowered into the production string on coiled tubing to the required depth (the assembly can be used both hydraulically and powered by an electrical impulse by means of a cable stored in the coiled tubing) consisting of (from bottom to top): packer plug (for example: blind (drillable), continuous (drillable) or continuous (soluble)) allowing to separate hydraulic fracturing stages, landing tool, compensator, first section of the shaped charge perforator, selective perforation sub, second section of the shaped charge perforator (sections with a shaped charge can be from 1 to 5), clutch locator.

There are 2 methods for activating the layout: hydraulic and electrical .

The hydraulic method consists in the fact that when a certain pressure is created (for example: 10 MPa (100 atm)) in the coiled tubing, the packer plug is activated (set), which contributes to the separation of the upcoming stage from the previous hydraulic fracturing stage, then pressure is created (for example: 12, 5 MPa (125 atm)) the first section of the cumulative perforator is activated and perforations are formed in the production string, then pressure is created (for example: 15 MPa (150 atm)) the second section of the cumulative perforator is activated and perforations are formed in the production string.

The electrical method consists in the fact that an electrical impulse is applied through the stored cable located in the coiled tubing and the packer plug is activated (set), which contributes to the separation of the upcoming stage from the previous hydraulic fracturing stage, then the next electrical impulse is applied and the first section of the cumulative perforator is activated in the production string perforations are formed, then the next electrical impulse is applied and the second section of the cumulative perforator is activated, and perforations are formed in the production string.

Option No. 2: An assembly consisting of (from bottom to top) is lowered into the production string on a cable to the required depth: packer-plug (for example: blind (drillable), through-hole (drillable) or through-hole (soluble)) allowing to separate hydraulic fracturing stages, tool landing, compensator, the first section of the shaped charge gun, selective perforation sub, the second section of the shaped charge gun (there can be from 1 to 5 sections with a shaped charge), a sleeve locator and a cable lug.

The assembly is activated electrically and consists in the fact that an electrical impulse is applied through the cable, as a result, the packer plug is activated (set), which contributes to the separation of the upcoming stage from the previous hydraulic fracturing stage, then the next electrical impulse is applied and the first section of the cumulative perforator is activated, and in perforations are formed in the production string, then the next electrical impulse is applied and the second section of the cumulative perforator is activated, and perforations are formed in the production string.

Next, the assembly of option No. 1 or option No. 2 is lifted and inspected for the installation of a packer plug and the operation of perforators.

A plug packer was installed in the horizontal section of the production casing separating the upcoming stage from the previous stage of hydraulic fracturing and a cluster perforation consisting of two intervals of perforations (it is possible to use from 1 to 5 sections with shaped charges). Further, through the perforations included in one cluster, a large-volume (for example: 150-200 tons), high-speed (for example: from 12 to 22 m3/min) hydraulic fracturing stage is performed.

To carry out the subsequent stages of hydraulic fracturing, operations to run the assembly (packer plugs, sections of cumulative perforators, etc.) are repeated until the required number of stages (for example: 20-50 stages) depending on the length of the horizontal section.

After all stages of hydraulic fracturing, the coiled tubing fleet normalizes the liner by milling plugs using insoluble packer plugs or flushing the horizontal section of the well using soluble packer plugs. At the end, the well goes into development (discharging) or equipment is lowered into the production string on the tubing for operation.

The method is carried out as follows (Fig. 1-19).

A production string 2 (example: 139.7 mm in diameter) is lowered into the horizontal section 1 drilled in hydrocarbon mud to the planned depth (for example: vertical depth: 2400 (+/- 500) meters) both with the possibility of rotation during descent and cementing , and without the possibility of rotation, consisting of (from bottom to top): working shoe of the column 3 (for example: shoe without check valve 3.1 or shoe with check valve 3.2), check valve 4 (it is possible to use two check valves, a double check valve or do not include a check valve in the assembly at all), landing sleeve for cement plug 5 (may not be included in the assembly), hydraulic fracturing sleeve 6 or its analogues (may not be included in the assembly), casing pipe 7 (for example: diameter 139 .7 mm with threaded connection type TMK UP PF or VAM TOP HT), pipe centralizers 8 (for example: spring 8.1 or rigid 8.2), when choosing a two-stage cementing technology, it is possible It is important to use a staged cementing sleeve 9 (hereinafter referred to as MSC). In this case, the design of the previous columns can be presented in the following version:

Execution No. 1

Direction 10 (for example: with a nominal outer diameter of 323.9 mm, GOST 632-80, vertical installation interval of the column: 0-60 meters, OTTMA connection type), conductor 11 (for example: with a nominal outer diameter of 244.5 mm, GOST 632-80, vertical spacing of the string: 0-1800 (+/- 400) meters, OTTMA connection type), production string 2 (for example, 139.7 mm nominal outside diameter, API Spec 5CT / ISO 11960:2004, vertical installation interval of the column: 0-2400 (+/- 500) meters, connection type TMK UP PF or VAM TOP HT) (Fig. 1).

Execution No. 2

Direction 13 (for example: with a nominal outer diameter of 426 mm, GOST 632-80, vertical installation interval of the column: 0-60 meters, NORMKB connection type), conductor 14 (for example: with a nominal outer diameter of 323.9 mm, GOST 632- 80, vertical installation interval of the column: 0-1000 (+/- 400) meters, type of connection OTTMA), intermediate column 15 (for example: nominal outer diameter 244.5 mm, GOST 632-80, vertical installation interval of the column: 0-1850 (+/- 400) meter, OTTMA connection type), production string 2 (for example, 139.7 mm nominal outside diameter, API Spec 5CT / ISO 11960:2004, vertical spacing of the string: 0-2400 ( +/- 500) meter, connection type TMK UP PF or VAM TOP HT) (Fig. 2).

* Next, we will consider the design of the previous columns in version No. 1 (Fig. 1).

One-stage, continuous cementing of the production casing 2 is carried out (it is possible to carry out two-stage cementing if MSC 9 is included in the assembly), and, if necessary, during the cementing process, the production casing 2 can be rotated (not shown) in order to obtain high-quality cement stone behind the casing.

Further, after waiting for cement hardening (WSC) 12, there are measures for the tightness of the production casing 2 (not shown) (Fig. 3).

Further, for perforation (communication with the formation) for the technological stage of hydraulic fracturing in order to create injectivity and the possibility of further pumping equipment, there are 2 options:

Option #1:

If the hydraulic clutch 6 (or its analogues) is present in the assembly, it is activated by creating pressure in the production string 2 (for example: up to 60 MPa (600 atm)), after activating the hydraulic clutch 6 hydraulic fracturing (or its analogues) through circulating windows 16 in the horizontal section of the well, communication with the formation 17 and injectivity appear (Fig. 4).

Option #2:

If hydraulic fracturing coupling 6 (or its analogues) is not included in the assembly, perforation 17 for the technical stage of hydraulic fracturing is carried out by the coiled tubing fleet using the following methods:

The electric method consists in the fact that in the production string 2 on a coiled tubing (hereinafter coiled tubing) 18 with a cable 19 stored in it, an assembly 20 is lowered to a predetermined depth, consisting of a cumulative electric action perforator 21 and a sleeve locator 22 (may not be included in layout composition). Next, an electrical impulse is applied and the cumulative perforator 21 is activated, after which perforations 17 will be formed in the production string 2 (Fig. 5).

The hydraulic method consists in the fact that in the production string 2 on the coiled tubing 18, the layout 23 is lowered to a predetermined depth, consisting of a cumulative hydraulic action perforator 24 and a collar locator 22 (may not be included in the layout). Next, the cumulative hydraulic perforator 24 is activated by creating pressure in the coiled tubing 18 (for example: 12 MPa (120 atm)), after which perforations 17 will be filled in the production string 2 (Fig. 6).

After activating the hydraulic fracturing sleeve 6 (or its analogues) or after perforating 17 and lifting the assembly 20 or 23 on the coiled tubing, the technological stage of hydraulic fracturing (for example: 5-10 tons) 25 is performed through the production string 2 and perforations 17 (for example: 5-10 tons) 25 in order to increase the injectivity for further work (Fig. 7).

There are 2 options for perforation (communication with the formation) for the first, large-volume, high-speed stage of hydraulic fracturing with cluster perforation:

Option #1:

The assembly 26 is lowered into the production string 2 on the coiled tubing 18 to the required depth (the assembly can be used both hydraulically and powered by an electrical impulse by means of the cable 19 stored in the coiled tubing 18) consisting of (from bottom to top): the first section of the cumulative perforator 27, selective perforation sub 28, the second section of the cumulative perforator 29 (sections with a shaped charge can be from 1 to 5), the sleeve locator 22 (Fig. 8).

There are 2 methods for activating layout 26: hydraulic and electrical.

The hydraulic method consists in the fact that when a certain pressure is created (for example: 12.5 MPa (125 atm)) the first section of the cumulative perforator 27 is activated and perforations 30 are formed in the production string 2, followed by pressure (for example: 15 MPa (150 atm)) the second section of the cumulative perforator 29 is activated and perforations 31 are formed in the production string 2 (Fig. 9).

The electrical method consists in the fact that an electrical impulse is applied through the stored cable 19 located in the coiled tubing 18 and the first section of the cumulative perforator 27 is activated and perforations 30 are formed in the production string 2, followed by the next electrical impulse and the second section of the cumulative perforator 29 is activated and perforations 31 are formed in the production string 2 (Fig. 10).

Option #2:

The assembly 33 is lowered into the production string 2 on the cable 32 to the required depth, consisting of (from bottom to top): the first section of the shaped charge perforator 27, the selective perforation sub 28, the second section of the shaped charge perforator 29 (sections with a shaped charge can be from 1 to 5), sleeve locator 22 and cable lug 34 (FIG. 11).

The activation of the assembly 33 occurs electrically and consists in the fact that an electrical impulse is applied through the cable 32, as a result, the first section of the cumulative perforator 27 is activated and perforations 30 are formed in the production string 2, followed by the next electrical impulse and the second section of the cumulative perforator is activated. 29 and perforations 31 are formed in the production string 2 (FIG. 12).

Next, the assembly 26 (for option No. 1) or 33 (for option No. 2) is lifted and inspected for the operation of perforators 27 and 29. In the horizontal section of the production casing 2, a cluster perforation 35 is formed, consisting of two intervals of perforations 30 and 31 ( it is possible to use from 1 to 5 sections with shaped charges). Further, through the perforations 30 and 31, which are part of one cluster 35, a large-volume (for example: 150-200 tons), high-speed (for example: from 12 to 22 m ³ /min) hydraulic fracturing stage 36 is performed (Fig. 13).

2** It is possible not to perforate and not to carry out the technological stage of hydraulic fracturing to create injectivity described and shown in figures 4 to 7 (inclusive), but to perform measures according to option No. 1 described and shown in figures 8 to 10.

There are 2 options for carrying out activities for the separation of stages (upcoming from the previous one) and cluster perforation before the second and subsequent large-volume, high-speed and multi-stage hydraulic fracturing stages:

Option #1:

The assembly 37 is lowered into the production string 2 on the coiled tubing 18 to the required depth (the assembly can be used both hydraulically and powered by an electrical impulse by means of the cable 19 stored in the coiled tubing 18) consisting of (bottom-up): packer-plug 38 (for example : blind (drillable) 38.1, through-hole (drillable) 38.2 or through-hole (soluble) 38.3) allowing to separate hydraulic fracturing stages, landing tool 39, compensator 40, the first section of the cumulative perforator 27, selective perforation sub 28, the second section of the cumulative perforator 29 (sections with cumulative charge can be from 1 to 5), clutch locator 22 (Fig. 14).

There are 2 methods for activating layout 37: hydraulic and electrical .

The hydraulic method consists in the fact that when a certain pressure is created (for example: 10 MPa (100 atm)) in the coiled tubing 18, the packer plug 38 is activated (planted), which contributes to the separation of the upcoming stage from the previous hydraulic fracturing stage 36, then pressure is created (for example : 12.5 MPa (125 atm)) the first section of the cumulative perforator 27 is activated and perforations 41 are formed in the production string 2, followed by pressure (for example: 15 MPa (150 atm)) the second section of the cumulative perforator 29 is activated and in production string 2 formed perforations 42 (Fig. 15).

The electrical method consists in the fact that an electrical impulse is applied through the stored cable 19 located in the coiled tubing 18 and the packer plug 38 is activated (landing), which contributes to the separation of the upcoming stage from the previous hydraulic fracturing stage 36, then the next electrical impulse is applied and the first section of the cumulative perforator is activated 27 and perforations 41 are formed in the production string 2, then the next electrical impulse is applied and the second section of the cumulative perforator 29 is activated, and perforations 42 are formed in the production string 2. (Fig. 16).

Option #2:

In the production string 2 on the cable 32 to the required depth, the layout 43 is lowered, consisting of (bottom-up): packer plug 38 (for example: blind (drilled) 38.1, through (drilled) 38.2 or through (soluble) 38.3) allowing to separate the stages Hydraulic fracturing, landing tool 39, compensator 40, first section of cumulative perforator 27, selective perforation sub 28, second section of cumulative perforator 29 (sections with a shaped charge can be from 1 to 5), sleeve locator 22 and cable lug 34 (Fig. 17) .

The activation of the assembly 43 occurs electrically and consists in the fact that an electrical impulse is applied through the cable 32, as a result, the packer plug 38 is activated (landing), which contributes to the separation of the upcoming stage from the previous hydraulic fracturing stage 36, then the next electrical impulse is applied and the first section is activated cumulative perforator 27 and in the production string 2 perforations 41 are formed, then the next electrical impulse is applied and the second section of the cumulative perforator 29 is activated and perforations 42 are formed in the production string 2 (Fig. 18).

Next, the assembly 37 (for option No. 1) or 43 (for option No. 2) is lifted and inspected to install the packer plug 38 and trigger the perforators 27 and 29.

In the horizontal section of the production string 2, a packer plug 38 is installed separating the upcoming stage from the previous hydraulic fracturing stage 36 and cluster perforation 44, consisting of two intervals of perforations 41 and 42 (it is possible to use from 1 to 5 sections with shaped charges). Further, through the perforations 41 and 42, which are part of one cluster 44, a large-volume (for example: 150-200 tons), high-speed (for example: from 12 to 22 m ³ /min) hydraulic fracturing stage 45 is performed (Fig. 19).

To carry out the subsequent stages of hydraulic fracturing, operations to run the assembly (packer plug 38, sections of cumulative perforators 27 and 29, etc.) are repeated up to the required number of stages (for example: up to 50 stages) depending on the length of the horizontal section.

After all stages of hydraulic fracturing, the coiled tubing fleet normalizes the liner by milling plugs using insoluble packer plugs or flushing the horizontal section of the well using soluble packer plugs. At the end, the well goes into development (discharging) or equipment is lowered into the production string on the tubing for operation.

Explanations for the drawings:

1 - Horizontal section drilled in hydrocarbon solution;

2 - Production string;

3 - Working through the shoe of the column;

3.1 - Shoe without check valve;

3.2 - Shoe with check valve;

4 - Check valve;

5 - Landing sleeve for cementing plug;

6 - Hydraulic fracturing clutch;

7 - Casing pipe of the production string;

8 - Pipe centralizers;

8.1 - Spring centralizers;

8.2 - Rigid centralizers;

9 - Staged cementing sleeve (MSC);

10 - Direction;

11 - Conductor;

12 - Cement;

13 - Direction;

14 - Conductor;

15 - Intermediate column;

16 - Circulation windows of the hydraulic fracturing clutch (6);

17 - Perforations (communication with the reservoir);

18 - Flexible tubing (CT);

19 - Cable stored in coiled tubing;

20 - Layout;

21 - Cumulative perforator of electric action;

22 - Coupling locator;

23 - Layout;

24 - cumulative hydraulic perforator;

25 - Technological stage of hydraulic fracturing;

26 - Layout;

27 - Section of the cumulative perforator;

28 - Selective perforation sub;

29 - Section of the cumulative perforator;

30 - Perforations;

31 - Perforations;

32 - Cable;

33 - Layout;

34 - Cable lug;

35 - Perforation cluster;

36 - Large-volume, high-speed stage of hydraulic fracturing;

37 - Layout;

38 - Packer plug;

38.1 - Blind (drillable) packer plug;

38.2 - Through (drillable) packer plug;

38.3 - Through (soluble) packer plug;

39 - Landing tool;

40 - Compensator;

41 - Perforations;

42 - Perforations;

43 - Layout;

44 - Perforation cluster;

45 - Large-volume, high-speed stage of hydraulic fracturing.

Claims (1)

A method for completing a well with a horizontal completion using a production string of the same diameter from the wellhead to the bottom and then carrying out a large-volume one with a volume of 150-200 tons, a high-speed one with a speed of 12 to 22 m ³ /min and a multi-stage hydraulic fracturing (HF), characterized in that a production string is lowered into a horizontal section drilled in a hydrocarbon solution to the planned depth, both with the possibility of rotation during descent and cementing, and without rotation, consisting from the bottom up of: a drilling shoe of the string, a check valve, a landing sleeve for a cementing plug, a hydraulic fracturing sleeve, a casing pipes with pipe centralizers, when choosing a two-stage cementing technology, a staged cementing sleeve (MSC) is used; at the same time, the design of the previous casing strings is represented by a direction and a conductor or a direction, a conductor and an intermediate string; then one-stage or two-stage continuous cementing of the production casing is carried out, if necessary, during the cementing process, the production casing is rotated in order to obtain high-quality cement stone behind the casing; then, after waiting for cement hardening (WSC), measures are taken to check the production casing for tightness; further, to perform perforation for the technological stage of hydraulic fracturing in order to create injectivity, the hydraulic fracturing sleeve is activated by creating a pressure of up to 60 MPa in the production string, after activating the hydraulic fracturing sleeve, communication with the formation and injectivity appear through the circulation windows in the horizontal section of the well, in the absence of hydraulic fracturing sleeve assembly perforation for the technical stage of hydraulic fracturing is carried out using a coiled tubing fleet by running on a coiled tubing (coiled tubing) assembly, consisting from bottom to top of: a cumulative perforator and a sleeve locator; the perforator is activated hydraulically or electrically; after activating the hydraulic fracturing sleeve or after perforating and lifting the assembly on the coiled tubing through the production string and perforations, the technological stage of hydraulic fracturing is performed in order to increase the injectivity for further work; further, to perform perforation for the first large-volume with a volume of 150-200 tons, high-speed with a speed of 12 to 22 m ³ /min, the stage of hydraulic fracturing with cluster perforation, an assembly is lowered into the production string on a cable or coiled tubing to the required depth, consisting from the bottom up of: the first section of the cumulative perforator, the selective perforation sub, the second section of the cumulative perforator, the locator of the sleeves and the cable lug when the layout is lowered on the cable; perforators are activated hydraulically or electrically; then, the assembly is lifted and inspected for the operation of perforators; then, through the perforations that are part of one cluster, a large-volume hydraulic fracturing stage with a volume of 150-200 tons is produced, with a speed of 12 to 22 m ³ /min; in order to carry out measures to separate the previous stages of hydraulic fracturing and cluster perforation, before the second and subsequent stages, an assembly is lowered into the production string on a cable or on coiled tubing to the required depth, consisting of the following from the bottom up: a through-drillable or through-soluble packer-plug, a landing tool, a compensator , the first section of the cumulative perforator, the selective perforation sub, the second section of the cumulative perforator, the sleeve locator and the cable lug when the assembly is lowered on the cable; packer plug and perforators are activated hydraulically or electrically; then, the assembly is lifted and inspected for the installation of a packer plug and the operation of perforators, thereby ensuring the separation in the horizontal section of the production casing of the previous stage of hydraulic fracturing and cluster perforation, consisting of two intervals of perforations; then, through the perforations that are part of one cluster, a large-volume hydraulic fracturing stage with a volume of 150-200 tons is produced, with a speed of 12 to 22 m ³ /min; for subsequent stages of hydraulic fracturing and cluster perforation, operations to run the assembly with a plug packer and cumulative perforators are repeated up to the required number of stages, depending on the length of the horizontal section; after all stages of hydraulic fracturing, using a coiled tubing fleet, the liner is normalized by milling separating plugs using insoluble packer plugs or flushing the horizontal section of the well using soluble packer plugs, then the well is discharged or equipment is lowered into the production string on the tubing for operation.

Images