CROSS-REFERENCE TO RELATED APPLICATION

[0001] The present document is based on and claims priority to US Provisional

Application Serial No.: 62/442,240, filed January 4, 2017, which is incorporated herein by reference in its entirety.

BACKGROUND

[0002] In various well applications, the subterranean formation is stimulated to enhance recovery of hydrocarbon fluids such as oil and gas. One form of well stimulation is hydraulic fracturing which may be conducted in a wellbore following a drilling operation and an optional casing operation. Hydraulic fracturing operations initially were performed in single stage vertical or near vertical wells. To further improve productivity, however, hydraulic fracturing operations have trended toward use in generally horizontal wells. Although horizontal fracturing operations have improved productivity, current methods have limitations with respect to productivity and efficiency in certain types of subterranean environments and operations.

SUMMARY

[0003] In general, the present disclosure provides a methodology and system for enhancing hydrocarbon fluid production. A well is formed in a subterranean region by drilling a borehole, e.g. a generally vertical wellbore. At least one tunnel, e.g. two tunnels, may be formed and oriented to extend outwardly from the borehole at least 10 feet into a formation surrounding the borehole. The orientation of the tunnels is selected such that the tunnels extend at a desired azimuthal orientation and/or deviation. For example, the orientation of the tunnels may be selected with respect to a direction of maximum horizontal stress in the formation. A fracture stimulation of the tunnels is performed to create a network of fractures. The orientation of the tunnels ensures that the network of fractures extends through a target zone in a hydrocarbon bearing region of the formation.

BRIEF DESCRIPTION OF THE DRAWINGS

[0004] Certain embodiments will hereafter be described with reference to the accompanying drawings, wherein like reference numerals denote like elements. It should be understood, however, that the accompanying figures illustrate various

implementations described herein and are not meant to limit the scope of various technologies described herein, and:

[0005] Figure 1 is a schematic illustration of an example of a well system having a generally vertical borehole and a plurality of tunnels extending from the borehole, according to an embodiment of the disclosure;

[0006] Figure 2 is another schematic illustration of an example of a well system with a borehole and a plurality of tunnels, according to an embodiment of the disclosure;

[0007] Figure 3 is a graphical illustration showing a fracture geometry created from a vertical borehole, according to an embodiment of the disclosure;

[0008] Figure 4 is a graphical illustration showing a fracture geometry created from a plurality of tunnels extending laterally from a vertical borehole, according to an embodiment of the disclosure; and [0009] Figure 5 is a graphical illustration comparing predicted barrels of oil produced from a fractured vertical borehole versus fractured lateral tunnels extending from a vertical borehole, according to an embodiment of the disclosure.

DETAILED DESCRIPTION

[0010] In the following description, numerous details are set forth to provide an understanding of some illustrative embodiments of the present disclosure. However, it will be understood by those of ordinary skill in the art that the system and/or

methodology may be practiced without these details and that numerous variations or modifications from the described embodiments may be possible.

[0011] The disclosure herein generally relates to a methodology and system for enhancing hydrocarbon fluid production. A well is formed in a subterranean region by drilling a borehole, e.g. a generally vertical wellbore. At least one tunnel, e.g. at least two tunnels, may be formed and oriented to extend outwardly from the borehole at least 10 feet into a formation surrounding the borehole. In some operations, the tunnels may be formed to extend outwardly from the borehole at least 15 feet and in other operations at least 20 feet. For example, some applications may utilize tunnels substantially longer than 20 feet. In various formations, the borehole is oriented generally vertically and the tunnels extend outwardly generally horizontally. However, some applications may utilize a deviated, e.g. horizontal, borehole with tunnels extending outwardly from the deviated borehole. Depending on the application and characteristics of the subterranean region, the tunnels may be oriented generally horizontally, generally vertically, or at desired orientations therebetween.

[0012] The orientation of the tunnels may be selected such that each tunnel extends at a desired angle with respect to a direction of principal stresses in the formation. For example, the tunnel azimuths may be oriented in a direction of maximum horizontal stress, minimum horizontal stress, or at a desired other angle with respect to the maximum horizontal stress. Additionally, the tunnel azimuths (as well as the borehole azimuth) may be constant but they may also vary in some applications, e.g. to achieve a desired positioning with respect to a hydrocarbon bearing target zone in a formation.

[0013] Once the tunnels are formed, a fracture stimulation of the tunnels may be performed to create a network of fractures. For example, a hydraulic fracturing fluid may be pumped downhole and out through the tunnel or tunnels to create fracture networks extending from each tunnel. The fracture networks may be formed to extend laterally from each tunnel but they also may be formed parallel with the tunnels and/or at other desired orientations. The orientation of the tunnels ensures that the network of fractures extends through a target zone in a hydrocarbon bearing region of the formation.

[0014] The diameter of the tunnels may vary according to the formation and/or other parameters of a given operation. By way of example, the tunnels are generally smaller in diameter than casing used along the borehole from which they extend. In some operations, the tunnel diameters may be 2 inches or less and in other operations the tunnel diameters may be 1.5 inches or less. However, some embodiments may utilize tunnels equal to or larger in diameter than the borehole. The diameter of the tunnels may be selected according to parameters of the formation and/or types of equipment used for forming the tunnels. Also, the resultant diameter of the tunnels may vary depending on the technique used to form the tunnels, e.g. drilling, jetting, or other suitable technique.

[0015] In some embodiments, the borehole may be drilled at least in part in a non-productive zone of the subterranean formation. The non-productive zone may be a zone which contains limited amounts of hydrocarbon fluid or is less desirable with respect to production of hydrocarbon fluid. Depending on the characteristics of the subterranean region, the borehole may be drilled in nonproductive rock and/or in a region with petrophysical and geo-mechanical properties different from the properties of the target zone. For example, the borehole may be drilled in a region of the formation having a substantially higher minimum in situ stress relative to that of the target zone. It should be noted the tunnels may be used in many types of formations, e.g. laminated formations, to facilitate flow of fluid to the tunnels through fracture networks even in the presence of pinch points between formation layers.

[0016] To facilitate production, at least one tunnel is formed which intersects the borehole and extends into a target zone, e.g. a productive zone containing hydrocarbon fluid. Often, a plurality of tunnels, e.g. at least two tunnels, may be formed to extend from the borehole outwardly into the target zone to serve as extended treatment passages. The target zone may be a single region or separate distinct regions of the formation. In some applications, the borehole may be entirely outside of the target zone and a plurality of tunnels may be formed in desired directions to reach the target zone. For example, the tunnels may be formed generally horizontally, generally vertically, generally along desired angles between horizontal and vertical, in generally opposed directions with respect to each other, or at other orientations with respect to each other. In other applications, however, the borehole may extend into or through the target zone.

[0017] As described above, the well stimulation may comprise a hydraulic fracturing of the stimulation zone or zones. During hydraulic fracturing, a fracturing fluid may be pumped down through the borehole and out through the plurality of tunnels. The fracturing fluid is forced under pressure from the tunnels out into the surrounding subterranean formation, e.g. into the surrounding hydrocarbon bearing target zone, to fracture the surrounding subterranean formation. For example, the surrounding subterranean formation may be fractured at a plurality of stimulation zones within the overall target zone.

[0018] It should be noted the fracturing fluid also may comprise propping agent for providing fracture conductivity after fracture closure. In certain embodiments, the fracturing fluid may comprise acid such as hydrochloric acid, acetic acid, citric acid, hydrofluoric acid, other acids, or mixtures thereof. The fracturing of the stimulation zones within the target zone enhances production of hydrocarbon fluid from the target zone to the wellbore and ultimately to the surface. The target zone may be a productive zone of the subterranean region containing desired hydrocarbon fluid, e.g. oil and/or gas. [0019] Referring generally to Figure 1, an embodiment of a well system 20 is illustrated as extending into a subterranean formation 22. The well system 20 enables a methodology for enhancing recovery of hydrocarbon fluid, e.g. oil and/or gas, from a well. In this embodiment, a borehole 24, e.g. a generally vertical wellbore, is drilled down into the subterranean formation 22. The borehole 24 may be drilled into or may be drilled outside of a target zone 26 (or target zones 26) containing, for example, a hydrocarbon fluid 28.

[0020] In the example illustrated, the borehole 24 is a generally vertical wellbore extending downwardly from a surface 30. However, some operations may form deviations in the borehole 24, e.g. a lateral section of the borehole 24, to facilitate hydrocarbon recovery. In some embodiments, the borehole 24 may be formed in nonproductive rock of formation 22 and/or in a zone with petrophysical and geo- mechanical properties different from the properties found in the target zone or zones 26.

[0021] At least one tunnel 32, e.g. a plurality of tunnels 32, may be formed to intersect the borehole 24. In the example illustrated, at least two tunnels 32 are formed to intersect the borehole 24 and to extend outwardly from the borehole 24. For example, the tunnels 32 may be formed and oriented laterally, e.g. generally horizontally, with respect to the borehole 24. Additionally, the tunnels 32 may be oriented to extend from borehole 24 in different directions, e.g. opposite directions, so as to extend into the desired target zone or zones 26.

[0022] The tunnels 32 provide fluid communication with an interior of the borehole/wellbore 24 to facilitate flow of the desired hydrocarbon fluid 28 from tunnels 32, into borehole 24, and up through borehole 24 to, for example, a collection location at surface 30. Furthermore, the tunnels 32 may be oriented in selected directions based on the material forming subterranean formation 22 and on the location of desired target zones 26. [0023] Depending on the characteristics of the subterranean formation 22 and target zones 26, the tunnels 32 may be formed along various azimuths. For example, the tunnels 32 may be formed in alignment with a direction of maximum horizontal stress, represented by arrow 34, in formation 22. However, the tunnels may be formed along other azimuths such as in alignment with a direction of minimum horizontal stress in the formation, as represented by arrow 36.

[0024] In some embodiments, the tunnels 32 may be formed at a desired angle or angles with respect to principal stresses when selecting azimuthal directions. According to an example, the tunnel or tunnels 32 may be oriented at a desired angle with respect to the maximum horizontal stress in formation 22. It should be noted the azimuth and/or deviation of an individual tunnel 32 may be constant but the azimuth and/or deviation also may vary along the individual tunnel 32 to, for example, enable formation of the tunnel through a desired zone to facilitate recovery of hydrocarbon fluids 28.

[0025] Additionally, at least one of the tunnels 32 may be formed and oriented to take advantage of a natural fracture 38 or multiple natural fractures 38 which occur in formation 22. The natural fracture 38 may be used as a flow conduit which facilitates flow of the hydrocarbon fluid 28 into the tunnel or tunnels 32. Once the hydrocarbon fluid 28 enters the tunnels 32, the fluid is able to readily flow into wellbore 24 for production to the surface or other collection location.

[0026] Depending on the parameters of a given formation 22 and hydrocarbon recovery operation, the diameter and length of tunnels 32 also may vary. The tunnels 32 are generally longer than the lengths of perforations formed in a conventional perforation operation. According to an embodiment, the tunnels 32 extend from the borehole 24 at least 10 feet into the formation 22 surrounding the borehole 24. However, some embodiments of the methodology utilize tunnels 32 which extend from the borehole 24 at least 15 feet into the formation 22. Other embodiments of the methodology utilize tunnels 32 which extend from the borehole 24 at least 20 feet into the formation 22. For example, some embodiments may utilize tunnels substantially longer than 20 feet. [0027] Each tunnel 32 also has a diameter generally smaller than the diameter of borehole 24, e.g. smaller than the diameter of casing which may be used to line borehole 24. With respect to diameter, various embodiments utilize tunnels 32 having a diameter of 2 inches or less. However, some embodiments of the methodology utilize tunnels 32 having a diameter of 1.5 inches or less. The actual lengths, diameters, and orientations of tunnels 32 may be adjusted according to the parameters of the formation 22, target zones 26, and objectives of the hydrocarbon recovery operation.

[0028] With additional reference to Figure 2, a stimulation operation may be performed via tunnels 32 to deliver stimulating fluid to stimulation zones 40 which are distributed through the target zone(s) 26. Distributing the stimulating fluid under pressure to the stimulation zones 40 creates fracture networks 42. The fracture networks 42 facilitate flow of fluid into the corresponding tunnels 32. By way of example, the stimulation operation may comprise hydraulic fracturing performed to fracture the subterranean formation 22, e.g. oil or gas bearing target zone 26, so as to facilitate flow of the desired fluid along the resulting fracture networks 42 and into the corresponding tunnels 32.

[0029] If the stimulation operation is a hydraulic fracturing operation, fracturing fluid may be pumped from the surface under pressure, down through wellbore 24, into tunnels 32, and then into the stimulation zones 40 surrounding the corresponding tunnels 32 as indicated by arrows 44. The pressurized fracturing fluid 44 causes formation 22 to fracture in a manner which creates the fracture networks 42 in stimulation zones 40. According to an embodiment, the tunnels 32/zones 40 may be fractured sequentially. For example, the fracturing operation may be performed through sequential tunnels 32 and/or sequentially through individual tunnels 32 to cause sequential fracturing of the stimulation zones 40 and creation of the resultant fracture networks 42.

[0030] The tunnels 32 may be formed via a variety of techniques, such as various drilling techniques or jetting techniques. For example, drilling equipment may be deployed down into wellbore 24 and used to form the desired number of tunnels 32 in appropriate orientations for a given subterranean environment and production operation. However, the tunnels 32 also may be formed by other suitable techniques, such as jetting techniques, laser techniques, injection of reactive fluid techniques, electrical

decomposition techniques, or other tunnel formation techniques. In a specific example, the tunnels 32 may be jetted using hydraulic jetting technology similar to hydraulic jetting technologies available from Radial Drilling Services Ltd, Viper Drill of Houston Texas, Jett-Drill Well Services Ltd, or Fishbones AS of Stavanger Norway.

[0031] The use of tunnels 32 during the stimulation operation enables creation of fracture networks 42. The fracture networks 42 provide fractures with an increased density, thus increasing the size of the contact area with respect to each target zone 26 containing hydrocarbon fluid 28. This, in turn, leads to an increase in well productivity compared to wells completed without utilizing tunnels 32.

[0032] As illustrated graphically in Figures 3 and 4, for example, the fracture geometry of a vertical well perforated and fractured without tunnels 32 (see Figure 3) is substantially smaller and less dense than the fracture geometry of a vertical well with opposed tunnels 32 which was hydraulically fractured via the tunnels 32 to create the fracture networks 42 (see Figure 4). According to modeled fracture geometry and well production computations (including orientation of extended tunnels 32), the fracture networks 42 resulting from fracturing via tunnels 32 substantially improves productivity. According to one example, performing hydraulic fracturing via extended tunnels 32 initiates fractures in transverse directions and increases the well productivity

substantially, e.g. by 33% or more, compared to a well which is fracture stimulated without use of the tunnels 32.

[0033] The projected oil production from such wells is illustrated graphically in

Figure 5. In Figure 5, graph line 46 corresponds to projected production resulting from a fracturing operation without tunnels 32 and graph line 48 corresponds to projected production resulting from a fracturing operation utilizing tunnels 32 to create the fracture networks 42 in stimulation zones 40. The projections are based on a comparison of flow resulting from different test applications combined with modeling of the stimulation techniques.

[0034] In an operational example, the orientation of tunnels 32 may be

determined based on various well productivity considerations prior to creating the tunnels 32. For example, the tunnels 32 may be created in the direction of maximum horizontal stress to enable formation of fractures which are aligned with the direction of such tunnels 32. In other embodiments, the extended tunnels 32 may be created in a direction perpendicular to a direction of maximum horizontal stress information 22 to enable creation of fractures oriented perpendicular to the direction of tunnels 32.

[0035] The tunnels 32 also may be placed at an angle to the principal horizontal stresses such that the created fractures are oblique with respect to the tunnels 32. As described above, individual tunnels 32 also may be oriented to intersect natural fractures 38 within the formation 22 which may be further activated during subsequent stimulation. In some embodiments, the tunnels 32 may be formed at a desired angle with respect to a horizontal plane.

[0036] It should be noted production levels corresponding to various orientations of the tunnels 32 can be forecast by employing various well production modeling techniques using software products such as Kinetix™ available from Schlumberger Corporation, Gohfer® available from Barree & Associates, or other suitable software products. Depending on the parameters of a given operation, the wellbore 24 may be an open hole, a cased hole with packers and port collars, or a wellbore with a cased and cemented completion. The tunnels 32 may be formed as extended treatment passages and may be created prior to or subsequent to casing the wellbore 24.

[0037] Use of tunnels 32 and the stimulation techniques described herein also may be employed to reduce the amount of sand and material delivered downhole in a variety of fracturing operations while still enhancing production of the desired hydrocarbon fluids. Although the tunnels 32 effectively increase production via vertical wellbore 24, the tunnels 32 and stimulation techniques described herein may be used in vertical wells and deviated wells, e.g. horizontal wells, in unconventional or conventional formations.

[0038] Depending on the parameters of a given application, the wellbore geometries described herein may be adjusted according to the type, size, orientation, and other features of the target zone or zones 26. Additionally, the location of the borehole 24 as well as the tunnels 32 may be affected by the type of non-productive zones adjacent the target zone(s) 26 containing desired hydrocarbon fluids 28. Similarly, many different types of equipment, e.g. packers, valves, sleeves, sand screens, and/or other types of equipment may be used in completing the wellbore 24. Various sections of the wellbore 24 may be cased or open-hole depending on the parameters of the specific application.

[0039] Although a few embodiments of the system and methodology have been described in detail above, those of ordinary skill in the art will readily appreciate that many modifications are possible without materially departing from the teachings of this disclosure. Accordingly, such modifications are intended to be included within the scope of this disclosure as defined in the claims.