阅读说明：本技术 压裂含烃地层的井下工具 (Downhole tool for fracturing a hydrocarbon containing formation ) 是由 萨米·伊萨·巴塔尔赛 H·A·奥斯曼 于 2018-10-09 设计创作，主要内容包括：用于压裂地层的示例工具包括具有细长形状的主体和沿所述主体布置的多个压裂装置。各压裂装置包括用以传输电磁辐射的天线和能移动以接触所述地层的一个或多个垫。各个垫包括响应于所述电磁辐射而加热以在所述地层中产生裂缝的使能器。(An example tool for fracturing a formation includes a body having an elongated shape and a plurality of fracturing devices disposed along the body. Each fracturing device includes an antenna to transmit electromagnetic radiation and one or more pads movable to contact the formation. Each pad includes an enabler that heats in response to the electromagnetic radiation to create a fracture in the formation.)

1. A tool for fracturing a hydrocarbon-bearing formation, the tool comprising:

a body having an elongated shape; and

a plurality of fracturing devices disposed along the body, each fracturing device comprising:

an antenna to transmit electromagnetic radiation; and

one or more pads movable to contact the formation, each pad comprising an enabler that heats in response to the electromagnetic radiation to create a fracture in the formation.

2. The tool of claim 1, wherein the electromagnetic radiation comprises microwave radiation.

3. The tool of claim 1, wherein the electromagnetic radiation comprises radio frequency radiation.

4. The tool of claim 1, wherein the enabler comprises activated carbon.

5. The tool of claim 4, wherein the enabler further comprises one or more of steel, iron, or aluminum.

6. The tool of claim 1, wherein each of the plurality of fracturing devices is rotatable about the body and relative to a wall of a wellbore traversing the earth formation.

7. The tool of claim 1, wherein the enabler has a composition that supports heating to 800 degrees fahrenheit or 426.7 degrees celsius.

8. The tool of claim 1, wherein the body comprises a plurality of segments, each of the plurality of segments having one of the plurality of fracturing devices; and is

Wherein the body comprises a plurality of positions at which the body is flexible.

9. The tool of claim 1, wherein the body comprises a plurality of segments, each of the plurality of segments having one of the plurality of fracturing devices; and is

Wherein the body is configured for adding or removing one or more segments.

10. The tool of claim 1, wherein the one or more pads are two pads.

11. The tool of claim 1, further comprising:

an electromagnetic radiation source to provide the electromagnetic radiation to the antenna.

12. The tool of claim 11, wherein the source is located inside a wellbore that traverses the formation.

13. The tool of claim 11, wherein the source is located on a surface above a wellbore through the formation.

14. The tool of claim 1, further comprising:

an acoustic sensor to detect a velocity of sound through the formation; and

one or more processing devices to determine a characteristic of the formation based on the detected velocity.

15. The tool of claim 14, wherein the characteristic comprises a stress level of the formation.

16. A method of fracturing a subterranean formation, the method comprising:

positioning a pad of a downhole tool against a wall of a wellbore penetrating the formation, the pad comprising an enabler that heats in response to electromagnetic radiation;

transmitting the electromagnetic radiation to the pad, thereby heating the enabler to create a fracture in the formation; and

injecting a fluid into the fracture to expand the fracture and create additional fractures in the formation.

17. The method of claim 16, further comprising:

receiving the electromagnetic radiation from a source; and

transmitting the electromagnetic radiation to the pad via an antenna.

18. The method of claim 16, further comprising:

obtaining data regarding the velocity of sound through the formation; and

processing the data to determine a characteristic of the formation based on the detected velocity.

19. The method of claim 18, wherein the characteristic comprises at least one of a strength, deformation, or resistance of a rock in the formation.

20. The method of claim 16, further comprising:

removing the downhole tool from the wellbore prior to injecting the fluid.

21. The method of claim 16, further comprising:

pumping hydrocarbons from the formation through the wellbore via the fracture and the additional fracture.

22. The method of claim 16, wherein the electromagnetic radiation comprises microwave radiation.

23. The method of claim 16, wherein the electromagnetic radiation comprises radio frequency radiation.

24. The method of claim 16, wherein the enabler comprises activated carbon.

25. The method of claim 24, wherein the enabler further comprises one or more of steel, iron, or aluminum.

26. The method of claim 16, wherein the enabler has a composition that supports heating to 800 degrees fahrenheit or 426.7 degrees celsius.

27. The method of claim 16, wherein the pad is part of at least one fracturing device on the downhole tool; and is

Wherein disposing the pad comprises moving an arm of the at least one fracturing device holding the pad.

28. The method of claim 16, wherein the pad is part of at least one fracturing device on the downhole tool; and is

Wherein positioning the pad comprises rotating the at least one fracturing device.

29. The method of claim 16, further comprising:

moving the downhole tool to a different location within the wellbore;

repositioning the pad against the wall of the wellbore;

transmitting the electromagnetic radiation to the pad, thereby heating the enabler to create fractures in the formation at the different locations; and

injecting a fluid into the fracture at the different location to expand the fracture at the different location and create additional fractures at the different location.

30. The method of claim 16, further comprising:

prior to placement, assembling the downhole tool by connecting a plurality of segments in series, each of the plurality of segments comprising:

a main body; and

a fracturing device disposed on the body, the fracturing device comprising:

an antenna to transmit the electromagnetic radiation; and

at least one of the pads.

31. A tool for fracturing a hydrocarbon-bearing formation, the tool comprising:

a body having an elongated shape; and

a plurality of fracturing devices disposed along the body, each fracturing device comprising:

one or more pads movable to contact the formation, each pad controllable to apply heat to the formation to create a fracture in the formation.

32. The tool of claim 31, wherein the one or more pads are heated using induction heating.

33. The tool of claim 31, wherein the one or more pads are heated using resistive heating.

34. The tool of claim 31, wherein the one or more pads are heated using electromagnetic radiation.

35. The tool of claim 31, wherein each pad is connectable to an arm that is extendable away from the body and retractable toward the body.

Technical Field

The present description generally relates to example downhole tools for fracturing hydrocarbon-bearing formations.

Background

Fracturing (also referred to as "hydraulic fracturing") involves the creation of fractures or fissures in a hydrocarbon containing formation to permit the flow of hydrocarbons from the formation into a wellbore (wellbore). In some fracturing processes, a fluid is injected into a formation at a pressure greater than the fracturing pressure of the formation. The force of the fluid creates fractures in the formation and expands the fractures present in the formation. Hydrocarbons in the formation then flow into the wellbore through these created fractures.

Disclosure of Invention

An example tool for fracturing a hydrocarbon containing formation includes a body having an elongated shape and a plurality of fracturing devices disposed along the body. Each fracturing device includes an antenna to transmit electromagnetic radiation and one or more pads movable to contact the formation. Each pad includes an enabler that heats in response to the electromagnetic radiation to create a fracture in the formation. The example tool may include one or more of the following features, alone or in combination.

The electromagnetic radiation may be microwave radiation or radio frequency radiation. The enabler may include activated carbon. The enabler may comprise one or more of steel, iron, or aluminum. The enabler may have a composition that supports heating to 800 degrees fahrenheit or 426.7 degrees celsius.

The plurality of fracturing devices may each rotate about the body and relative to a wall of a wellbore traversing the formation. The body may comprise a plurality of segments. Each of the segments may comprise one of the plurality of fracturing devices. The body may be configured for adding or removing one or more segments. At multiple locations, the body may be flexible. There may be two pads in each fracturing device.

An electromagnetic radiation source may provide the electromagnetic radiation to the antenna. The source may be located inside the wellbore. The source may be located on a surface.

The tool may include an acoustic sensor to detect the velocity of sound through the formation. One or more processing devices may be configured (e.g., programmed) to determine a characteristic of the formation based on the detected velocity. The characteristic may be a compressive stress of the formation.

An example method of fracturing a formation includes positioning a pad of a downhole tool against a wall of a wellbore penetrating the formation. The pad may include an enabler that heats in response to the electromagnetic radiation. The example method includes transmitting the electromagnetic radiation to the pad, thereby heating the enabler to create a fracture in the formation. A fluid may be injected into the fracture to expand the fracture and create additional fractures in the formation. The example methods may include one or more of the following features, alone or in combination.

The method may include receiving the electromagnetic radiation from a source and transmitting the electromagnetic radiation to the pad via an antenna. The method may include obtaining data regarding the velocity of sound through the formation, and processing the data to determine a characteristic of the formation based on the detected velocity. The characteristic may include at least one of a strength, deformation, or resistance of rock in the formation.

The method may include removing the downhole tool from the wellbore prior to injecting the fluid. The method may also include pumping hydrocarbons output from the formation to the surface via the fracture and the additional fracture.

The electromagnetic radiation may be microwave radiation. The electromagnetic radiation may be radio frequency radiation. The enabler may include activated carbon. The enabler may comprise one or more of steel, iron, or aluminum. The enabler may have a composition that supports heating to 800 degrees fahrenheit or 426.7 degrees celsius.

The pad may be part of at least one fracturing device on the downhole tool. Disposing the pad may comprise moving an arm of the at least one fracturing device holding the pad. Positioning the pad may include rotating the at least one fracturing device.

The method may include moving the downhole tool to a different location within the wellbore, and repositioning the pad against the wall of the wellbore. The electromagnetic radiation may be transmitted to the pad, thereby heating the enabler to create fractures in the hydrocarbon containing formation at the different locations. A fluid may be injected into the fracture at the different location to expand the fracture at the different location and create additional fractures at the different location.

The method may include assembling the downhole tool by connecting a plurality of segments in series. Each of the plurality of segments may include a body and a fracturing device disposed on the body. The fracturing device includes at least one of an antenna and the pad to transmit the electromagnetic radiation.

An example tool for fracturing a hydrocarbon containing formation includes a body having an elongated shape and a plurality of fracturing devices disposed along the body. Each fracturing device includes one or more pads movable to contact the formation. Each pad is controllable to apply heat to the formation to create fractures in the formation. The example tool may include one or more of the following features, alone or in combination.

The one or more pads may be heated using induction heating, using resistance heating, or using electromagnetic radiation. Each pad is connectable to an arm that is extendable away from the body and retractable toward the body.

Any two or more of the features described in this specification, including the features described in this summary section, may be combined to form embodiments not specifically described in this specification.

At least a portion of the tools and processes described in this specification can be controlled by executing instructions stored on one or more non-transitory machine-readable storage media on one or more processing devices. Examples of non-transitory machine-readable storage media include read-only memory (ROM), optical disk drives, memory disk drives, and Random Access Memory (RAM). At least a portion of the tools and processes described in this specification can be controlled using a data processing system that includes one or more processing devices and memory storing instructions executable by the one or more processing devices to perform various control operations.

The details of one or more embodiments are set forth in the accompanying drawings and the description below. Other features and advantages will be apparent from the description and drawings, and from the claims.

Drawings

FIG. 1 is a side view of an example downhole tool for fracturing a formation.

FIG. 2 is a side view of a downhole tool within a wellbore.

FIG. 3 is a side view of a downhole tool and a close-up cross-sectional view of a section of the downhole tool.

Fig. 4 is a cross-sectional view of an example fracturing apparatus included in a downhole tool.

Fig. 5 is a side view of another example downhole tool within a wellbore and a close-up cross-sectional view of an activated fracturing device.

FIG. 6 is a flow chart including example operations for fracturing using a downhole tool.

FIG. 7 is a cross-sectional view of the downhole tool of FIG. 5, illustrating a fracture formed in the formation by the downhole tool.

FIG. 8 is a cross-sectional view of a formation undergoing hydraulic fracturing.

FIG. 9 is a flow chart containing example operations for performing a multi-stage fracturing process using a downhole tool.

Fig. 10 is a cross-sectional view of a fluid injection conduit used during a multi-stage fracturing process.

Like reference symbols in the various drawings indicate like elements.

Detailed Description

Example downhole tools for fracturing hydrocarbon containing formations (referred to as "formations") and example methods for fracturing formations using those tools are described in this specification. An example tool includes a body assembled from a plurality of segments. The tool is modular in the sense that segments can be added to or removed from the tool to change the length of the tool. Each segment includes a fracturing device. The fracturing device includes an articulated arm (articulated arm) connected to the pad. The arms are controllable to extend outwardly from a non-extended position to an extended position to bring the pads into frictional contact with the wall surface of the wellbore. The pad is heated when the pad is in contact with the formation. Heat from the pad is transferred to the formation, which causes the formation of fractures or preexisting fractures in the formation to expand.

In some embodiments, each pad includes an enabler, e.g., activated carbon that heats in response to electromagnetic radiation, such as microwave radiation or Radio Frequency (RF) radiation. An antenna may be included in the fracturing device to transmit electromagnetic radiation to the pad to cause the enabler to heat up. In some implementations, the pad can be electrically heated.

In some cases, the tool may be moved within the wellbore to target different portions of the formation. For example, the tool may be moved uphole or downhole to create fractures in different portions of the formation. The fracturing device may also be rotated to target different locations along the circumference of the wellbore.

After the fracture is formed using the tool, the tool may be removed from the wellbore. The hydraulic fluid may then be used for fracturing. The hydraulic fluid may include water mixed with chemical additives and proppant (e.g., sand). Hydraulic fluid is injected into the wellbore to expand the fractures created using the downhole tool and create additional fractures in the formation. The additional fractures permit the flow of hydrocarbons into the wellbore. Hydrocarbons may then be removed from the wellbore by pumping.

Fracturing using hydraulic fluid may be of the multistage type. In an example multi-stage fracturing process, a hydraulic fluid is injected into a wellbore in a region near an end of the wellbore. The fluid expands the fractures created in the formation using the downhole tool and creates additional fractures in the region. A cement plug (cement plug) is then positioned in the wellbore to isolate the zone from the rest of the wellbore. Hydraulic fluid is injected into the wellbore from the isolation zone into the next zone uphole to expand the fracture created in that zone using the downhole tool and create additional fractures in that zone. A cement plug is then positioned in the wellbore to isolate the next zone from the remainder of the wellbore. This process may be repeated multiple times to create multiple fracture zones in the formation. The drill bit is then drilled through the cement plug to allow hydrocarbons to flow through the fracture to the wellbore.

FIG. 1 shows an example embodiment of a downhole tool 10 (referred to as "tool 10") for fracturing a subterranean formation. The tool 10 includes a body 11 having a plurality of segments. In this example, the tool comprises four segments 12, 13, 14 and 15. However, the tool may include any number of segments, such as one segment, two segments, three segments, five segments, six segments, or twelve segments. As mentioned, the tool is modular. Segments may be added to the tool to increase the length of the tool in order to simultaneously target other areas of the formation. The segments may be removed from the tool to reduce the length of the tool in order to target fewer areas of the formation. In some embodiments, the number of segments comprising a tool may be based on the length of a wellbore traversing a formation. The tool may be assembled in the well by connecting the segments together using a connection mechanism. For example, the segments may be screwed together or connected using clamps, bolts, screws, or other mechanical connectors. Other tools, instruments or segments may be located between or in the segments in the form of posts (string) to customize the spacing between or in the segments.

The tool is flexible to allow it to bend around deviated portions of the wellbore during insertion and removal. For example, FIG. 2 shows the tool 10 contained within the horizontal portion 16 of the wellbore 18. To reach the horizontal section, the tool is lowered into the vertical section 19 of the borehole 18 using a coiled tubing unit (coiled tubing unit)20 or wireline. The tool bends as it passes through the offset 22 between the vertical 19 and horizontal 16 portions. In some embodiments, the tool may be flexible at the connection between the two segments. In some embodiments, the tool may be flexible at the interior of the individual segments. Flexibility may be achieved by incorporating materials such as flexible metals or flexible composites at locations along the length of the tool where bending is desired.

In some embodiments, each section comprises a fracturing device. For example, the tool 10 includes four fracturing devices 23, 24, 25, and 26, one for each segment. Each of the fracturing devices may have the same structure and function. Thus, only one fracturing device is described.

Fig. 3 includes a cutaway close-up view of a portion of an example segment 15. The enlargement of the segment 15 is conceptually indicated by the arrow 28. The staging section 15 includes an example fracturing apparatus 26. Fig. 4 shows a close-up cross-sectional view of the fracturing unit 26. The fracturing device 26 includes pads 30 and 31, the pads 30 and 31 being configured to move away from the tool body toward the wellbore wall surface. In fig. 3, the pad is partially extended, while in fig. 4, the pad is fully extended.

Two pads are included in the fracturing unit 26; however, the fracturing apparatus may include less than two pads or more than two pads. For example, the fracturing device may include a single pad or three pads, four pads, five pads, or six pads. In some embodiments, each pad includes an enabler. The enabler comprises a material that increases in temperature in response to an electromagnetic signal (e.g., microwave radiation or RF radiation). Examples of electromagnetic signals that may be used for the heating enabler include electromagnetic signals in the 915 megahertz (MHz) to 2.45 gigahertz (GHz) range.

An example of an enabler that heats in response to microwave or RF radiation is activated carbon. Exemplary activated carbons have pores with diameters in the range of 2 nanometers (nm) to 50 nm. When exposed to microwave or RF radiation, the activated carbon is heated to approximately 800 degrees Fahrenheit (F.) (426.7 degrees Celsius (C.)). The activated carbon in the pad may be in the form of a powder or granules. In some embodiments, activated carbon may be combined with one or more powders or granules of steel, iron, or aluminum to strengthen the enabler. The powdery or granular structure of the mat makes the mat flexible. For example, the enabler and the material forming the pad partially or completely conform to the surface of the formation including an uneven surface. As a result, there is direct surface contact to transfer heat from the pad to the formation.

In some embodiments, the fracturing apparatus 26 also includes antennas 34 and 35. Two antennas are shown; however, the fracturing device may include less than two antennas or more than two antennas. The antenna transmits electromagnetic radiation to the pad. In some embodiments, the antenna may be rotated about the longitudinal dimension 36 of the tool to direct electromagnetic radiation uniformly to the plurality of pads. The rotation is conceptually depicted by arrow 37. In some embodiments, the rotation may be up to and including 360 °. In some embodiments, the rotation may exceed 360 °.

As mentioned, examples of electromagnetic radiation that may be used to heat the fracturing device include microwave radiation and RF radiation. One or more sources for electromagnetic radiation may be located on the surface or downhole. For example, the electromagnetic radiation source may be located in each of the subsections or in each of the fracturing devices. The source transmits electromagnetic radiation to the antenna. Each antenna receives electromagnetic radiation from one or more sources and transmits the electromagnetic radiation to the pad. As explained previously, the temperature of the pad increases in response to electromagnetic radiation.

Referring to fig. 4, the fracturing unit 26 includes arms 40 and 41 connected to the pads 30 and 31, respectively. When activated, the fracturing device moves the pad outward toward the wellbore wall surface. The pad is moved by extending the arm outwardly. For example, the arms may start at a position where the pads are fully retracted against the fracturing device. The arms may extend outward after activation. As mentioned, fig. 3 shows the case where the arm portion is extended. Figure 4 shows the arm fully extended.

Extension of the arms and thus extension of the pads connected to the arms forces the pads against the formation to be fractured. For example, the arms force the pad against the wellbore wall surface. As mentioned, the pad has sufficient flexibility to conform to the uneven surface of the wellbore wall surface to maximize surface contact thereof. The pads are pivotally mounted on their respective arms so as to be able to rotate at least partially along arrow 42. The rotation of the pad along arrow 42 also promotes maximum contact with the uneven surface of the wellbore.

Fig. 5 shows an example tool 45 of the same type as the tool 10 but including twelve stages and corresponding fracturing devices 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, and 57. In this example, the pads of the fracturing devices 46-57 are each in contact with a wall 58 of a wellbore 59. The enlarged view 60 shows how the pads 61 and 62 of the fracturing device 54 substantially conform to the uneven surface of the wellbore 59 at the location of the fracturing device 54 along the wellbore.

In some embodiments, each fracturing device can be rotated along a longitudinal dimension of the tool. This rotation is conceptually depicted by arrow 37 in fig. 4 (the same arrow depicting the antenna rotation). In some embodiments, the rotation may be up to and including 360 °. In some embodiments, the rotation may exceed 360 °. The rotation may be implemented using a motor. The fracturing device can be rotated to align the pad on the circumference of the wellbore at the location where the tool will be used to initiate fracturing. In some embodiments, repositioning the pad by rotation requires retracting the pad from the wellbore wall surface.

Referring to fig. 3, each segment may also include one or more sensors. In this example, the sensors include acoustic sensors 63 and 64. The acoustic sensor may be a fiber optic acoustic sensor. The fiber optic acoustic sensor detects the velocity of sound passing through the formation. For example, a sound source (not shown) may be located on each segment. The fiber optic acoustic sensor may detect both sound transmitted from the acoustic source and the same sound that passes through and reflects from within the formation. Data representing this acoustic information may be sent to a computing system 65 located at the surface or downhole.

The computing system may be configured (e.g., programmed) to determine a velocity of sound traversing the formation based on the transmitted sound and based on sound reflected from the formation. The velocity of sound through the formation may be used to determine the following properties of the rock contained in the formation: young's Modulus (Young's Modulus), Poisson's ratio (Poisson's ratio), shear (shear), bulk density, and compressibility. These properties correspond to the strength, deformation and resistance of the rock. Based on these characteristics, a region of the formation may be identified for fracturing. For example, if the rock in a formation is strong and under compressive stress in a region, then the region is characterized as a good candidate for fracturing because fractures in the formation under stress propagate more easily and faster than fractures in the formation not under stress. In one example, a region under stress for purposes of the present application includes rock that fractures at pressures greater than 400 kilopascals (kPa).

A computing system may be used to control the operation of the tool to create fractures in the formation. For example, a drilling engineer may input commands to the computing system to control operation of the tool based on the zones identified for fracturing. Examples of computing systems that may be used are also described in this specification.

In an example, a communication cable (e.g., an ethernet or other cable) may carry commands and data between the computing system and the tool. The commands may be generated using the computing system 65 and may control the operation of the tool. For example, the commands may include commands to selectively activate one or more fracturing devices, rotate one or more fracturing devices, move a tool, or transmit electromagnetic signals to heat a fracturing device. The segment may include a local electronic device capable of receiving and executing commands. Acoustic data may be transmitted to a computing system via a fiber optic medium. In some embodiments, a wireless protocol may be used to send commands downhole to the tool and data downhole from the tool to the computing system. For example, RF signals may be used for wireless transmission of commands and data. The dashed arrow 33 in FIG. 3 represents the exchange of commands and data between the downhole tool and the computing system.

The computing system may include circuitry or an onboard computing system to enable user control of the placement and operation of the downhole tool. The onboard circuitry or onboard computing system is "onboard" in the sense that it is located on the tool itself or downhole with the tool rather than at the surface. The circuitry or onboard computing system may communicate with the computing system on the surface to effect control of the operation and movement of the tool. Alternatively, an electronic circuit or onboard computing system may be used in place of the computing system located at the surface. For example, the circuit or on-board computing system may be configured (e.g., programmed) while on the surface to implement the control instructions in sequence while downhole.

Fig. 6 illustrates an example fracturing process 66 using a downhole tool (e.g., tool 10 or tool 45). First, the tool is lowered (72) into the wellbore into a location where fracturing is to be performed. For example, coiled tubing units or cables may be used to lower the tool into the wellbore. For example, the tool may be moved through the wellbore to reach the end of the wellbore or to another portion of the wellbore to be fractured using the tool. These locations may be predetermined based on knowledge about, for example, the length of the wellbore, the geological survey of the formation, and previous drilling in the region.

The sensors may be used to identify (74) locations of deposits of hydrocarbons within the formation. In one example, the acoustic source may generate an acoustic wave. Those acoustic waves pass through the formation and reflect from within the formation. The acoustic sensors detect the level of the generated acoustic waves and the reflected acoustic waves that pass through the formation. Data representing the levels of these sound waves is sent to the computing system 65 in real time. In this regard, real-time may not mean that the two actions are simultaneous, but may include actions that occur continuously in time or track one another in view of delays associated with data processing, data transmission, and hardware. As explained previously, the computing system uses the data to determine a characteristic of the formation, such as its strength, deformation, or resistance. These characteristics may be used to identify regions of the formation that are targets for fracturing using the tool. In this regard, in some instances, deposits of hydrocarbons may be located in isolated pockets of the formation and may be unevenly distributed throughout the formation. Acoustic data can be used to identify the location of these deposits.

If necessary, the position of the tool may be adjusted (75) based on the location determined by the acoustic sensor as a fracture target. For example, the tool may be moved uphole or downhole such that its pads are in relative positions in the wellbore to contact the portion of the formation closest to the deposit of hydrocarbons within the formation. Thus, the position of the tool may be adjusted to improve or maximize the impact of fracturing in the zone closest to the deposit of hydrocarbons.

The process 66 includes positioning a pad (76) of the tool against the wellbore wall surface. As mentioned, commands from the computing system may control the placement of the pads. Positioning may include rotating the fracturing device or pad such that the pad is at least partially aligned with a region of the formation to be fractured. For example, the pads may be aligned so that heat is directed to the area to be fractured. As previously described, the region may be identified by acoustic analysis of the formation. Other information may also be used to identify the location of the region, such as geological surveys of the formation and knowledge gained through previous drilling of the formation. Positioning further includes activating the fracturing device by extending the arms outward such that the pads are in contact with the formation. Because the pads are flexible, the pads conform to the surface of the wellbore when in contact. As a result, contact between the pad and the wellbore surface may be maximized in some cases.

Electromagnetic radiation (e.g., microwave radiation) is transmitted (77) to the pad. As explained previously, electromagnetic radiation is transmitted to the pads via, for example, antennas 34 and 35 (fig. 4). In some embodiments, the antenna is rotated during transmission of the electromagnetic radiation in order to ensure that each pad receives an equal amount of radiation. In some embodiments, the antenna is stationary during transmission of the electromagnetic radiation. In some examples, the electromagnetic radiation heats the enabler to about 800 ° f (426.7 ℃). In some embodiments, the enabler may be heated to less than 800 ° f (426.7 ℃) or to greater than 800 ° f (426.7 ℃). The amount of heat generated is based on factors such as the type of enabler used, the duration of the enabler's exposure to electromagnetic radiation, and the intensity of the electromagnetic radiation to which the enabler is exposed.

Heat from the pad is transferred to the formation. This heat causes the formation of fractures in the formation or the propagation or expansion of fractures present in the formation. The duration of the application of heat may be based on characteristics of the formation, such as the strength, deformation, or resistance of the rock in the formation. For example, the greater the strength or resistance of the rock, the longer the duration of time that heat may need to be applied. The fractures created by the tool may be referred to as microfractures because the fractures created by the tool are typically smaller or shorter than the fractures created during hydraulic fracturing. However, the fractures created by the tool need not be smaller or shorter than the fractures created during hydraulic fracturing.

FIG. 7 shows the tool 45 of FIG. 5 within the wellbore 59 creating a fracture 88 by applying heat through the pad of the tool. In this example, the cracks are primarily in three regions 81, 82, and 83. In some embodiments, the fracture zone may correspond to the location of deposits of hydrocarbons contained within the formation. Each fracture zone is separated from adjacent fracture zones by intervening zones (intersecting regions) 84 or 85 of the formation that include no fractures or fewer fractures than are visible in the fracture zone. In some cases, these intervening regions may correspond to locations of formations that contain little or no hydrocarbons.

Referring back to fig. 6, after a fracture is created in the rock, in some cases, the tool may be removed (79) from the wellbore. To remove the tool, the arms are retracted, which causes the pad to also retract. That is, the pad moves out of contact with the wellbore wall surface and toward the tool. In some embodiments, the pad is shrunk so that it is flush with the tool body.

In some embodiments, the tool may be repositioned within the wellbore in order to create fractures at different locations. The relocation and the operation after relocation are indicated by dashed line 73 in fig. 6. In one example, if the wellbore is 50m long and the tool is 25m long, the tool may fracture the last 25m of the wellbore. The tool may then be moved uphole and to the first 25m of the fractured wellbore location. Such repositioning may include moving the tool to a different location within the wellbore, repositioning the pad against a wall of the wellbore, and transmitting electromagnetic radiation to the pad to heat the enabler. In any event, the tool may be removed from the wellbore after all of the target zones within the wellbore have been treated with the tool. The tool may be removed from the wellbore using a coiled tubing unit or a wireline.

After the tool is removed, hydraulic fracturing (80) is performed to expand the microfractures in the formation created by the tool and create additional fractures in the formation. Referring to fig. 8, hydraulic fracturing involves injecting a fluid 90 into a formation 91 through a conduit introduced into the wellbore 59. The conduit may be a tube comprising perforations along its longitudinal dimension. Explosives may be launched within the tubular through the perforations to create fractures 92 in the formation and to expand fractures (including microfractures) present in the formation. Hydraulic fluid (which may include a mixture of water, proppant, and chemical additives) is pumped forcefully through the perforations and into the fracture. In some embodiments, the fluid is at 0.75 pounds per square inch (psi/ft) per foot (16,965.44 kilograms per square meter per second (kg/m)²s²) ) is pumped under force. The fluid cracks, expands, and creates branches to reach the hydrocarbons in the formation. Hydrocarbons in the formation then flow into the wellbore through these created fractures. Hydrocarbons may then be pumped from the wellbore to the surface.

In some embodiments, fracturing using hydraulic fluid may be multistage. Referring to fig. 9, in an example multi-stage fracturing process 100, hydraulic fluid is injected (101) into a wellbore in a target zone. For example, hydraulic fluid may be injected at or near the end of the wellbore. The fluid expands the fractures created in the formation using the downhole tool and creates additional fractures in the region. A cement plug is then installed (102) in the wellbore to isolate the fracture zone from the remainder of the wellbore. For example, fig. 10 shows a fluid injection conduit 110 in a wellbore 111. In the example of fig. 10, hydraulic fluid has been injected into region 113 through conduit 110 to expand gap 115. A cement plug 112 is then installed to isolate the zone 113 from the rest of the wellbore 111. The conduit 110 is then repositioned 103 in the wellbore from the isolation zone 113 to the next zone uphole. The process 100 is then repeated in this next region. That is, hydraulic fluid is injected into the wellbore in the next uphole region from the isolation zone 113 to expand the fractures created in that region using the downhole tool and create additional fractures in that region. A cement plug is then positioned in the wellbore to isolate the next zone from the remainder of the wellbore. This process may be repeated multiple times to create multiple fracture zones in the formation. The drill then drills through the plug, allowing hydrocarbons to flow from the fracture into the wellbore to reach the surface.

In some embodiments, the tool may create microfractures near the end of the wellbore. The tool may then be removed from the wellbore. Hydraulic fluid may be injected in the area where the micro-fractures are created by the tool. The fluid expands the micro-fractures in this region and creates additional fractures. A cement plug is then positioned in the wellbore to isolate the zone from the remainder of the wellbore. The tool may then be lowered into the wellbore again to create microfractures in the next zone uphole from the isolation zone. The tool can then be removed. Hydraulic fluid may be injected into the wellbore in this next zone uphole from the isolation zone to expand the microfractures in this zone and create additional fractures. A cement plug is then installed in the wellbore to isolate the next zone from the remainder of the wellbore. This process may be repeated multiple times to create multiple fracture zones in the formation. The drill drills through the plug, allowing hydrocarbons to pass from the fracture into the wellbore to the surface.

In some embodiments, an example tool may include a pad that is heated electrically rather than using an enabler and an electromagnetic signal. In an example, the wire may pass through the pad. The wire may be connected to an electrical power supply at the surface or downhole. The resistance in the wire causes the wire to heat up as current passes through the wire. This heat may be applied to the formation through contact with the pad. In another example, an induction heater heating mat may be used. For example, each pad may include a metal coil connected to an electrical power supply. The electric power supplier may output an Alternating Current (AC) through the coil. The metal structure may be placed in or near the coil. The current passing through the coil generates eddy currents within the metal structure, causing the metal structure to heat up. This heat may be transferred to the formation.

For example, the example tool may be used to create fractures in both conventional and unconventional formations. Example conventional formations include rock having a permeability of 1 millidarcy (md) or greater. An example unconventional formation includes rock having a permeability of less than 0.1 md.

All or portions of the tools and processes described herein, and various modifications thereof, may be controlled, at least in part, using a control system comprising one or more computing systems using one or more computer programs. Examples of computing systems include one or more desktop computers, laptop computers, servers, server farms, and mobile computing devices (e.g., smartphones, feature phones, and tablet computers), alone or in combination.

The computer program can be tangibly embodied in one or more information carriers, e.g., in one or more non-transitory machine-readable storage media. A computer program can be written in any form of programming language, including compiled or interpreted languages, and it can be deployed as a stand-alone program or as a module, component, subroutine, or unit suitable for use in a computing environment. A computer program can be deployed to be executed on one computer system or on multiple computer systems that are distributed across multiple sites and interconnected by a network.

Acts associated with implementing a process may be performed by one or more programmable processors executing one or more computer programs. All or portions of the tools and processes can comprise special purpose logic circuitry, e.g., a Field Programmable Gate Array (FPGA), or an ASIC Application Specific Integrated Circuit (ASIC), or both.

Processors suitable for the execution of a computer program include, by way of example, both general and special purpose microprocessors, and any one or more processors of any kind of digital computer. Generally, a processor will receive instructions and data from a read-only memory area or a random access memory area or both. Components of computers, including servers, include one or more processors for executing instructions and one or more memory area devices for storing instructions and data. Generally, a computer will also include, or be operatively coupled to receive data from, or transfer data to, one or more machine-readable storage media, or both.

A non-transitory machine-readable storage medium includes a mass storage device for storing data, such as a magnetic, magneto-optical disk, or optical disk. Non-transitory machine-readable storage media suitable for embodying computer program instructions and data include all forms of non-volatile storage. Non-transitory machine-readable storage media include, for example, semiconductor memory device (e.g., erasable programmable read-only memory (EPROM), electrically erasable programmable read-only memory (EEPROM), and flash memory device). The non-transitory machine-readable storage medium includes, for example, a magnetic disk (e.g., a built-in hard disk or a removable magnetic disk), a magneto-optical disk, and a CD (compact disc) ROM (read only memory) and a DVD (digital versatile disc) ROM.

Each computing device may include a hard disk drive for storing data and computer programs, one or more processing devices (e.g., microprocessors), and memory (e.g., RAM) for executing the computer programs.

Elements of different embodiments described may be combined to form other embodiments not specifically set forth previously. In general, elements may be excluded from the described tools and processes without adversely affecting the operation of the tools and processes or the operation of the overall system. Further, various discrete elements may be combined into one or more separate elements to perform the functions described in this specification.

Other embodiments not specifically described in the specification are also within the scope of the following claims.

The claimed embodiments are as set forth in the appended claims.