US20170253792A1 - Proppant and proppant delivery system - Google Patents
Proppant and proppant delivery system Download PDFInfo
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- US20170253792A1 US20170253792A1 US15/601,416 US201715601416A US2017253792A1 US 20170253792 A1 US20170253792 A1 US 20170253792A1 US 201715601416 A US201715601416 A US 201715601416A US 2017253792 A1 US2017253792 A1 US 2017253792A1
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- expandable
- proppant
- delivery system
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Classifications
-
- C—CHEMISTRY; METALLURGY
- C09—DYES; PAINTS; POLISHES; NATURAL RESINS; ADHESIVES; COMPOSITIONS NOT OTHERWISE PROVIDED FOR; APPLICATIONS OF MATERIALS NOT OTHERWISE PROVIDED FOR
- C09K—MATERIALS FOR MISCELLANEOUS APPLICATIONS, NOT PROVIDED FOR ELSEWHERE
- C09K8/00—Compositions for drilling of boreholes or wells; Compositions for treating boreholes or wells, e.g. for completion or for remedial operations
- C09K8/60—Compositions for stimulating production by acting on the underground formation
- C09K8/80—Compositions for reinforcing fractures, e.g. compositions of proppants used to keep the fractures open
- C09K8/805—Coated proppants
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- E—FIXED CONSTRUCTIONS
- E21—EARTH OR ROCK DRILLING; MINING
- E21B—EARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B43/00—Methods or apparatus for obtaining oil, gas, water, soluble or meltable materials or a slurry of minerals from wells
- E21B43/11—Perforators; Permeators
-
- E—FIXED CONSTRUCTIONS
- E21—EARTH OR ROCK DRILLING; MINING
- E21B—EARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B43/00—Methods or apparatus for obtaining oil, gas, water, soluble or meltable materials or a slurry of minerals from wells
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- E21B43/26—Methods for stimulating production by forming crevices or fractures
- E21B43/267—Methods for stimulating production by forming crevices or fractures reinforcing fractures by propping
Definitions
- proppants are sized particles that are mixed with fracturing fluid to hold fractures open after a hydraulic fracturing treatment.
- proppants include, for example, sand grains, resin-coated sand, and high-strength ceramic materials, such as bauxite. While conventional proppants are useful in holding open relatively small fractures, because the proppants are relatively small, they do not efficiently hold open large fractures or keep near wellbore connectivity as efficiently as possible.
- a method of increasing hydrocarbon production including fracturing downhole formation and disposing an expandable proppant into the downhole formation.
- the method further includes expanding the expandable proppant into contact with the downhole formation and holding open the downhole formation with the expandable proppant.
- a proppant having an expandable outer shell layer, wherein the expandable outer shell layer is configured to expand outwardly to a size at least 10 percent greater in an open position than in a closed position.
- a proppant delivery system having a tool body, an expandable injector disposed on the side of the tool body, and an expandable proppant disposed within the tool body.
- FIG. 1 shows a side view of a proppant in an injectable position according to embodiments of the present disclosure.
- FIG. 2 shows a side view of a proppant in a partially expanded position according to embodiments of the present disclosure.
- FIG. 3 shows a side view of a proppant in an expanded position according to embodiments of the present disclosure.
- FIG. 4 shows a side view of a proppant in an injectable position according to embodiments of the present disclosure.
- FIG. 5 shows a side view of a proppant in an expanded position according to embodiments of the present disclosure.
- FIG. 6 shows a side view of a proppant in an injectable position according to embodiments of the present disclosure.
- FIG. 7 shows a side view of a proppant in an expanded position according to embodiments of the present disclosure.
- FIG. 8 shows a cross-section of a wellbore according to embodiments of the present invention.
- FIG. 9 shows a cross-section of a wellbore according to embodiments of the present invention.
- FIG. 10 shows a cross-section of a wellbore according to embodiments of the present invention.
- FIG. 11 shows a cross-section of a wellbore according to embodiments of the present invention.
- FIG. 12 shows a cross-section of a wellbore according to embodiments of the present invention.
- FIG. 13 shows a proppant delivery system according to embodiments of the present invention.
- FIG. 14 shows a proppant delivery system in a wellbore according to embodiments of the present invention.
- FIG. 15 shows a proppant delivery system in a wellbore according to embodiments of the present invention.
- FIG. 16 shows a proppant delivery system in a wellbore according to embodiments of the present invention.
- FIG. 17 shows a proppant delivery system in a wellbore according to embodiments of the present invention.
- FIG. 18 shows a proppant delivery system in a wellbore according to embodiments of the present invention.
- FIG. 19 shows a proppant delivery system in a wellbore according to embodiments of the present invention.
- FIG. 20 shows a proppant delivery system in a wellbore according to embodiments of the present invention.
- FIG. 21 shows a proppant delivery system in a wellbore according to embodiments of the present invention.
- Embodiments of the present invention are directed to apparatuses, systems, and methods for disposing proppants into downhole formation.
- proppants are sized particles that are mixed with fracturing fluid and used to hold fractures open after hydraulic fracturing.
- proppants include naturally occurring sand grains, man-made or specially engineered proppants, such as resin-coated sand or high-strength ceramic materials such as sintered bauxite, may be used.
- Proppant materials may be carefully sorted for size and sphericity to provide an efficient conduit for production of fluid from the reservoir to the wellbore.
- proppants may fail under overburden formation pressure, block production routes, provide for small increases in fracture size, and provide unreliable wellbore connectivity to stimulated formation thereby resulting in inefficient stimulation and unreliable increases in production.
- Fracturing is a stimulation treatment that is routinely performed on oil and gas wells in low-permeability reservoirs. Specially engineered fluids are pumped at high pressure and rate into the reservoir that is treated, thereby causing vertical fractures to open. The fractures extend away from the wellbore in opposing directions according to the natural stresses within the formation.
- the proppant may be pumped in after hydraulic fracturing or along with the fracturing fluid, thereby helping to keep the formed fractures open.
- Perforating refers to the process of creating holes in the casing, liner, or well formation that allows more efficient communication between the reservoir and the wellbore.
- a perforating gun having one or more shaped explosive charges is disposed in the well to a desired location. The charges are then detonated, thereby creating a perforation in the well, casing and/or liner.
- the size and shape of the perforation may vary based on the type and shape of the charges that are used. Generally, the perforation may vary in diameter closer to the wellbore, thereby providing channels for the production of fluids at a location closest to the well. While the perforation diameter may be large initially, over time, formation pinching, scaling, paraffin/asphaltene, fill, formation pressure depletion, and other sources may plug or collapse the channels, thereby restricting the flow of hydrocarbons therethrough. While hydraulic fracturing and proppant injection may hold smaller fractured channels open, it may be difficult and/or risky to perform a fracture job using proppant packed together to a size big enough to open a fracture as big as the perforation diameter near the wellbore.
- the fracture width created from a fracture job, near wellbore is 1 ⁇ 4 to 1 ⁇ 2 inch in width. Also it is difficult for proppants to hold open larger fracture channels. As such, traditional proppants are not effective in maintaining the large channels near wellbore.
- Proppants and proppant delivery systems may be used to efficiently hold open the large channels closest to the wellbore (e.g., near the wellbore), as well as hold open the smaller channels that extend into the formation.
- Various expandable proppants and proppants delivery systems are described below, which may be capable of holding open fractures in formation, thereby increasing well productivity.
- fracture refers to any cracks that are formed downhole.
- Examples of fractures may include cracks that form as a result of hydraulic fracturing, as described above, or may refer to cracks formed from perforation. Fracture may also refer to cracks in formation formed naturally, due to boring (such as drilling into the formation), or due to chemical treatment, such as acid stimulation.
- fractures in formation may be formed by any type of human or mechanical induced activity, or may be caused naturally due to seismic or other natural phenomena.
- FIG. 1 a side view of an expandable proppant according to embodiments of the present invention is shown.
- the expandable proppant 100 is illustrated in a closed or unexpanded position.
- expandable proppant 100 may be relatively small, for example, having a diameter between 0.25 and 0.5 cm, between 0.25 and 1.0 cm, between 0.75 and 1.5 cm, between 1.0 and 3.0 cm, or larger.
- the expandable proppant in the closed position may have a diameter smaller than 0.25 cm or larger than 3.0 cm.
- expandable proppant 100 may include an expandable outer shell layer 105 .
- Expandable outer shell layer 105 may be manufactured from various materials include, for example, smart memory alloys (SMA), graphene, metals, metal alloys, polymer, ceramics, KEVLAR® (a para-aramid synthetic fiber), plastics, natural materials, biodegradables, and various composites therefrom.
- SMA smart memory alloys
- KEVLAR® a para-aramid synthetic fiber
- plastics natural materials, biodegradables, and various composites therefrom.
- expandable outer shell layer 105 may be manufactured from stainless steel.
- Expandable proppant 100 may also include an internal expandable portion 110 .
- the internal expandable portion 110 may be a separate structural component from expandable outer shell layer 105 or, such as in the embodiment described and illustrated in FIG. 1 , internal expandable portion 110 may be a portion of expandable outer shell layer 105 .
- internal expandable portion 110 may be a portion of expandable outer shell layer 105 .
- the expandable outer shell layer 105 In the closed position, the expandable outer shell layer 105 is folded inwardly such that internal expandable portion 110 is substantially inside expandable outer shell layer 105 .
- apertures 115 may be formed between the structural components of expandable proppant 100 , i.e., internal expandable portion 110 and/or expandable outer shell layer 105 .
- apertures 115 may be relatively small, e.g., 0.1 cm or less, while in other embodiments apertures 115 may be relatively large, e.g., 1.0 cm or more.
- the size of apertures 115 may be a function of how expandable proppant 100 may be. Additionally, the size and/or number of apertures 115 may be a product of the configuration of the expandable outer shell layer 105 and/or the configuration of internal expandable portion 110 .
- expandable proppant 100 has a generally spherical shape while in a closed position.
- generally spherical does not refer to the expandable outer shell layer 105 as being completely smooth, rather, the generally spherical shape defines the general overall shape of expandable proppant 100 .
- expandable proppant 100 in a closed position resembles a sphere due to expandable outer shell layer 105 forming an outer boundary.
- Other examples of generally spherical shaped expandable proppants 100 may include various spherical polyhedrons, hosohedrons, and the like.
- Expandable outer shell layer 105 may be configured to expand in various directions, such as radially, latitudinally, longitudinally, and/or azimuthally.
- expandable proppant 100 In a closed. position, expandable proppant 100 may have a diameter than is at least 10 percent smaller than when expandable proppant 100 is in a closed position.
- expandable proppant 100 may have a diameter that is between 20 and 50 percent smaller than when expandable proppant 100 is in an open position.
- expandable proppant 100 in a closed position may have a diameter that is between 50 and 100 percent smaller than when expandable proppant 100 is in an open position.
- expandable proppant 100 in a closed position may have a diameter that is more than 100 percent smaller than when expandable proppant is in a closed position.
- expandable outer shell layer 105 may be configured to expand at least one of as radially, latitudinally, longitudinally, and/or azimuthally. The expandable outer shell layer 105 may thus expand until the expansion is stopped by the size of the fracture into which expandable proppant 100 is deployed. As part of the expansion of expandable proppant 100 , one or more of the internal expandable portions 110 may also expand into contact with the formation. Further explanation of the expansion of expandable proppant 100 is described below with respect to FIGS. 2 and 3 .
- expandable proppant 100 is illustrated in a partially expanded position.
- expandable proppant 100 may be relatively small, for example, having a diameter between 0.25 and 0.5 cm, between 0.25 and 1.0 cm, between 0.75 and 1.5 cm, between 1.0 and 3.0 cm, or larger.
- the expandable proppant in the partially expanded position may have a diameter smaller than 0.25 cm or larger than 3.0 cm.
- expandable proppant 100 may include an expandable outer shell layer 105 .
- Expandable proppant 100 may also include one or more internal expandable portions. 110 .
- Expandable proppant 100 may also include one or more apertures 115 that may be formed as a result of the structural configuration of expandable outer shell layer 105 and/or internal expandable portions 110 .
- expandable proppant 100 In the partially expanded position, expandable proppant 100 includes internal expandable portions 110 that are partially expanded outwardly, outside of the initial diameter of expandable outer shell layer 105 when expandable proppant 100 was in the closed position.
- the amount of expansion may vary according to the properties of expandable proppant 100 , as well as the requirements of the operation.
- expandable proppant 100 in a partially expanded position may expand to a size at least 10 percent greater in a partially expanded position than in a closed position.
- expandable proppant 100 in a partially expanded position may expand to a size between 20 and 50 percent greater in a partially expanded position than in a closed position.
- expandable proppant 100 in a partially expanded position may expand to a size between 50 and 100 percent greater in a partially expanded position than in a closed position. In another embodiment, expandable proppant 100 in a partially expanded position may expand to a size more than 100 percent greater in a partially expanded position than in a closed position.
- expandable proppant 100 may be stopped by the formation into which expandable proppant 100 is deployed. Depending on the fracture size, expandable proppant 100 may continuously expand until either expandable proppant 100 has reached its expansion limits, until the formation restricts further expansion, or until activation ceases. Thus, in some embodiments, expandable proppant 100 may expand to 100 percent of its expansion size, while in other embodiment, expandable proppant 100 may only expand into a partially expanded position, which may be anything percentage of its expansion size between zero percent, in a closed position, to 100 percent, in an open position.
- expandable proppant 100 is illustrated in a partially expanded position.
- expandable proppant 100 may have a diameter between 0.25 and 0.5 cm, between 0.25 and 1.0 cm, between 0.75 and 1.5 cm, between 1.0 and 3.0 cm, or larger.
- the expandable proppant in the partially expanded position may have a diameter smaller than 0.25 cm or larger than 3.0 cm.
- expandable proppant 100 may include an expandable outer shell layer 105 .
- Expandable proppant 100 may also include one or more internal expandable portions. 110 .
- Expandable proppant 100 may also include one or more apertures 115 that may be formed as a result of the structural configuration of expandable outer shell layer 105 and/or internal expandable portions 110 .
- expandable proppant 100 may also include secondary internal expandable portions 112 .
- Secondary expandable portions 112 may be configured to expand at the same time or after expansion of internal expandable portions 110 .
- secondary expandable portions 112 may be formed from the same or different materials as internal expandable portions 110 , and as such, may be capable of withstanding less or greater forces.
- expandable proppant 100 may further include tertiary expandable portions (not shown), quaternary expandable portions (not shown) or other numbers of expandable portions. The additional expandable portions may be configured to expand at the same time or at different intervals, depending on the requirements of the operation.
- locking mechanism 120 may include a ratchet locking mechanism.
- a ratchet locking mechanism may allow continuous linear or rotary motion in a single direction, thereby preventing motion in an opposite direction.
- the ratchet locking mechanism may include a gear and pawl system or a linear system with rows of interlocking teeth.
- expandable proppant 100 may include a spring 125 or torsion bar.
- spring 125 may bias expandable proppant 100 in an open position. In a closed position, spring 125 may be compressed, such that open release into a fracture, spring 125 may force expandable proppant open into either a partially expanded or open position.
- spring 125 may be capable of resisting compression forces, thereby allowing spring 125 to also be locking mechanism 120 .
- spring 125 may be a part of locking mechanism 120 , such that spring 125 initially causes expandable proppant 100 to expand, while locking mechanism 120 holds expandable proppant 100 in a partially expanded or open position.
- expandable proppant 100 may be actuated by external mechanical, hydraulic, explosive, SMA, magnetic, pneumatic, or chemical actuators.
- an electrical charge may be used to cause expandable proppant 100 to expand, while in another embodiment an explosive charge may cause expandable proppant 100 to expand.
- an outer coating may be disposed around expandable proppant 100 . The outer coating may dissolve when contacted by a certain chemical or chemical compound.
- expandable proppant 100 may be stored within a delivery device, which compresses expandable proppant 100 into a closed position. Upon release of expandable proppant 100 from the delivery device, expandable proppant may naturally expand or be forced open by, for example a hydraulic, explosive, mechanical, chemical reaction, SMA, or pneumatic force. Those of ordinary skill in the art will appreciate that various other ways of expanding expandable proppant 100 are within the scope of the present disclosure.
- FIG. 4 a side view of an expandable proppant according to embodiments of the present invention is shown.
- the expandable proppant 100 is illustrated in a closed or unexpanded position.
- expandable proppant 100 may be relatively small, for example, having a diameter between 0.25 and 0.5 cm, between 0.25 and 1.0 cm, between 0.75 and 1.5 cm, between 1.0 and 3.0 cm, or larger.
- the expandable proppant in the closed position may have a diameter smaller than 0.25 cm or larger than 3.0 cm.
- expandable proppant 100 may include an expandable outer shell layer 105 .
- Expandable proppant 100 may also include an internal expandable portion 110 .
- the internal expandable portion 110 may be a separate structural component from expandable outer shell layer 105 or internal expandable portion 110 may be a portion of expandable outer shell layer 105 .
- internal expandable portion 110 may be a portion of expandable outer shell layer 105 .
- the expandable outer shell layer 105 is folded inwardly such that internal expandable portion 110 is substantially inside expandable outer shell layer 105 .
- apertures 115 may be formed between the structural components of expandable proppant 100 , i.e., internal expandable portion 110 and/or expandable outer shell layer 105 .
- apertures 115 may be relatively small, e.g., 0.1 cm or less, while in other embodiments apertures 115 may be relatively large, e.g., 1.0 cm or more.
- the size of apertures 115 may be a function of how expandable proppant 100 may be. Additionally, the size and/or number of apertures 115 may be a product the configuration of expandable outer shell layer 105 and/or the configuration of internal expandable portion 110 ,
- expandable proppant 100 has a generally irregular geometry that resembles a star shape.
- the geometry of expandable proppant 100 may be generally spherical, rhombus, cubical, rectangular, triangular, hexagonal, trapezoidal, or any other general shape that allows expandable proppant 100 to expand.
- Expandable outer shell layer 105 may be configured to expand in various directions, such as radially, latitudinally, longitudinally, and/or azimuthally. In a closed position, expandable proppant 100 may have a diameter than is at least 10 percent smaller than when expandable proppant 100 is in a closed position. In another embodiment, expandable proppant 100 may have a diameter that is between 20 and 50 percent smaller than when expandable proppant 100 is in an open position.
- expandable proppant 100 in a closed position may have a diameter that is between 50 and 100 percent smaller than when expandable proppant 100 is in an open position, In still another embodiment, expandable proppant 100 in a closed position may have a diameter that is more than 100 percent smaller than when expandable proppant is in a closed position.
- expandable outer shell layer 105 may be configured to expand at least one of as radially, latitudinally, longitudinally, and/or azimuthally. The expandable outer shell layer 105 may thus expand until the expansion is stopped by the size of the fracture into which expandable proppant 100 is deployed or when activation ceases. As part of the expansion of expandable proppant 100 , one or more of the internal expandable portions 110 may also expand into contact with the formation. Further explanation of the expansion of expandable proppant 100 is described below with respect to FIG. 5 .
- expandable proppant 100 is illustrated in a partially expanded position.
- expandable proppant 100 may be relatively small, for example, having a diameter between 0.25 and 0.5 cm, between 0.25 and 1.0 cm, between 0.75 and 1.5 cm, between 1.0 and 3.0 cm, or larger.
- the expandable proppant in the partially expanded position may have a diameter smaller than 0.25 cm or larger than 3.0 cm.
- expanded proppant 100 in an open position, expanded proppant 100 have a diameter between 0.25 and 0.5 cm, between 0.25 and 1.0 cm, between 0.75 and 1.5 cm, between 1,0 and 3.0 cm, or larger.
- the expandable proppant 100 in the open position may have a diameter smaller than 0.25 cm or larger than 3.0 cm.
- expandable proppant 100 may include an expandable outer shell layer 105 . Expandable proppant 100 may also include one or more internal expandable portions. 110 . Expandable proppant 100 may also include one or more apertures 115 that may be formed as a result of the structural configuration of expandable outer shell layer 105 and/or internal expandable portions 110 . Expandable proppant 100 may further include a locking mechanism 120 and or a spring 125 . The spring 125 and/or locking mechanism 120 may be used to facilitate expansion of expandable proppant 100 and may further prevent expandable proppant 100 from collapsing into a closed position.
- expandable proppant 100 includes internal expandable portions 110 that are partially expanded outwardly, outside of the initial diameter of expandable outer shell layer 105 when expandable proppant 100 was in the closed position.
- the amount of expansion may vary according to the properties of expandable proppant 100 , as well as the requirements of the operation.
- expandable proppant 100 in a partially expanded or in an open position may expand to a size at least 10 percent greater in a partially expanded or open position than in a closed position.
- expandable proppant 100 in a partially expanded or open position may expand to a size between 20 and 50 percent greater in a partially expanded or open position than in a closed position.
- expandable proppant 100 in a partially expanded position or open position may expand to a size between 50 and 100 percent greater in a partially expanded or open position than in a closed position. In another embodiment, expandable proppant 100 in a partially expanded or open position may expand to a size more than 100 percent greater in a partially open or open position than in a closed position.
- expandable proppant 100 may be stopped by the formation into which expandable proppant 100 is deployed or when activation ceases. Depending on the fracture size, expandable proppant 100 may continuously expand until either expandable proppant 100 has reached its expansion limits or until the formation restricts further expansion or activation trigger ceases. Thus, in some embodiments, expandable proppant 100 may expand to 100 percent of its expansion size, while in other embodiment, expandable proppant 100 may only expand into a partially expanded position, which may be anything percentage of its expansion size between zero percent, in a closed position, to 100 percent, in an open position.
- FIG. 6 a side view of an expandable proppant according to embodiments of the present invention is shown.
- the expandable proppant 100 is illustrated in a closed or unexpanded position.
- expandable proppant 100 may be relatively small, for example, having a diameter between 0.25 and 0.5 cm, between 0.25 and 1.0 cm, between 0.75 and 1.5 cm, between 1.0 and 3.0 cm, or larger.
- the expandable proppant in the closed position may have a diameter smaller than 0.25 cm or larger than 3.0 cm.
- expandable proppant 100 may include an expandable outer shell layer 105 .
- Expandable proppant 100 may also include an internal expandable portion 110 .
- the internal expandable portion 110 may be a separate structural component from expandable outer shell layer 105 or internal expandable portion 110 may be a portion of expandable outer shell layer 105 .
- internal expandable portion 110 may be a portion of expandable outer shell layer 105 .
- the expandable outer shell layer 105 is folded inwardly such that internal expandable portion 110 is substantially inside expandable outer shell layer 105 , in this embodiment, expandable proppant 100 has a generally rectangular or cube-shaped geometry.
- apertures 115 may be formed between the structural components of expandable proppant 100 , i.e., internal expandable portion 110 and/or expandable outer shell layer 105 .
- apertures 115 may be relatively small, e.g., 0.1 cm or less, while in other embodiments apertures 115 may be relatively large, e.g., 1.0 cm or more.
- the size of apertures 115 may be a function of how expandable proppant 100 may be. Additionally, the size and/or number of apertures 115 may be a product the configuration of expandable outer shell layer 105 and/or the configuration of internal expandable portion 110 .
- Expandable outer shell layer 105 may be configured to expand in various directions, such as radially, latitudinally, longitudinally, and/or azimuthally.
- expandable proppant 100 In a closed position, expandable proppant 100 may have a diameter than is at least 10 percent smaller than when expandable proppant 100 is in a closed position. in another embodiment, expandable proppant 100 may have a diameter that is between 20 and 50 percent smaller than when expandable proppant 100 is in an open position. In other embodiment, expandable proppant 100 in a closed position may have a diameter that is between 50 and 100 percent smaller than when expandable proppant 100 is in an open position. In still another embodiment, expandable proppant 100 in a closed position may have a diameter that is more than 100 percent smaller than when expandable proppant is in a closed position.
- expandable outer shell layer 105 may be configured to expand at least one of as radially, latitudinally, longitudinally, and/or azimuthally. The expandable outer shell layer 105 may thus expand until the expansion is stopped by the size of the fracture into which expandable proppant 100 is deployed or when an activation trigger ceases. As part of the expansion of expandable proppant 100 , one or more of the internal expandable portions 110 may also expand into contact with the formation. Further explanation of the expansion of expandable proppant 100 is described below with respect to FIG. 7 .
- expandable proppant 100 is illustrated in a partially expanded position.
- expandable proppant 100 may be relatively small, for example, having a diameter between 0.25 and 0.5 cm, between 0.25 and 1.0 cm, between 0.75 and 1.5 cm, between 1.0 and 3.0 cm, or larger.
- the expandable proppant in the partially expanded position may have a diameter smaller than 0.25 cm or larger than 3.0 cm.
- expanded proppant 100 in an open position, expanded proppant 100 have a diameter between 0.25 and 0.5 cm, between 0.25 and 1.0 cm, between 0.75 and 1.5 cm, between 1.0 and 3.0 cm, or larger.
- the expandable proppant 100 in the open position may have a diameter smaller than 0.25 cm or larger than 3.0 cm.
- expandable proppant 100 may include an expandable outer shell layer 105 . Expandable proppant 100 may also include one or more internal expandable portions. 110 . Expandable proppant 100 may also include one or more apertures 115 that may be formed as a result of the structural configuration of expandable outer shell layer 105 and/or internal expandable portions 110 . Expandable proppant 100 may further include a locking mechanism 120 and or a spring 125 . The spring 125 and/or locking mechanism 120 may be used to facilitate expansion of expandable proppant 100 and may further prevent expandable proppant 100 from collapsing into a closed position.
- expandable proppant 100 includes internal expandable portions 110 that are partially expanded outwardly, outside of the initial diameter of expandable outer shell layer 105 when expandable proppant 100 was in the closed position.
- the amount of expansion may vary according to the properties of expandable proppant 100 , as well as the requirements of the operation.
- expandable proppant 100 in a partially expanded or in an open position may expand to a size at least 10 percent greater in a partially expanded or open position than in a closed position.
- expandable proppant 100 in a partially expanded or open position may expand to a size between 20 and 50 percent greater in a partially expanded or open position than in a closed position.
- expandable proppant 100 in a partially expanded position or open position may expand to a size between 50 and 100 percent greater in a partially expanded or open position than in a closed position. In another embodiment, expandable proppant 100 in a partially expanded or open position may expand to a size more than 100 percent greater in a partially open or open position than in a closed position.
- expandable proppant 100 may be stopped by the formation into which expandable proppant 100 is deployed or when an activation trigger ceases. Depending on the fracture size, expandable proppant 100 may continuously expand until either expandable proppant 100 has reached its expansion limits or until the formation restricts further expansion or until an activation trigger ceases. Thus, in some embodiments, expandable proppant 100 may expand to 100 percent of its expansion size, while in other embodiment, expandable proppant 100 may only expand into a partially expanded position, which may be anything percentage of its expansion size between zero percent, in a closed position, to 100 percent, in an open position.
- FIG. 8 a cross-section of a wellbore according to embodiments of the present invention is shown.
- an expandable proppant 100 is shown deployed within a wellbore 130 .
- Wellbore 130 may include any type of wellbore 130 known in the art. As such, wellbore 130 may be liner or unlined as well as cased or encased.
- wellbore 130 has a large fracture 135 as well as a number of small fractures 140 . As described above, large fracture 135 may have been caused by perforation or hydraulic fracturing, while small fractures 140 are generally formed through hydraulic fracturing or stress created on formation by stimulation.
- Expandable proppant 100 includes an expandable outer shell layer 105 . Expandable proppant 100 also includes one or more internal expandable portions 110 . In this embodiment, expandable proppant 100 is illustrated holding open large fracture 135 . Internal expandable portions 110 are shown contacting large fracture 135 , thereby preventing large fracture 135 from collapsing and/or making it larger through use of an activation system, e.g., mechanical, explosion, chemical, pneumatic, hydraulic, etc. Because large fracture 135 is held open, and thus has a larger diameter than a collapsed fracture, hydrocarbons may flow in direction A from small fractures 140 , through large fracture 135 in direction B, and into wellbore 130 in direction C to the surface (not shown) with minimal flow limitation or restriction.
- an activation system e.g., mechanical, explosion, chemical, pneumatic, hydraulic, etc.
- chemicals, dissolving gels, and/or biodegradable material may be added inside or in the outer layer of the expandable proppant to help minimize a plugging effect caused by scaling, paraffin precipitation, asphaltine precipitation, hydrates or other precipitates.
- expandable proppant 100 includes a plurality of smaller expandable proppants 102 disposed within.
- the nesting of smaller expandable proppants 102 within relatively larger expandable proppant 100 allows for the smaller expandable proppants 102 to be deployed at a later time than expandable proppant 100 .
- expandable proppant 100 may be deployed in a well and activated, thereby causing expandable proppant 100 to expand. After or during expansion of expandable proppant 100 , smaller expandable proppants 102 may be released from within expandable proppant 100 , thereby allowing smaller expandable proppants 102 to expand within the well.
- smaller expandable proppants 102 may be activated at the same time as expandable proppant 100 or after activation of expandable proppant 100 . Additionally, the expansion of smaller expandable proppants 102 may be activated by the same trigger as expandable proppant 100 or due to a different activation signal/trigger. In certain embodiments, multiple nested layers of expandable proppants 100 and smaller expandable proppants 102 may be used. In such an embodiment, expandable proppant 100 may have a smaller expandable proppant 102 disposed inside, while a third, still smaller expandable proppant is disposed within smaller expandable proppant 102 .
- expandable proppant 100 may have two, three, four, five, or more nested layers therewithin.
- multiple smaller expandable proppants 102 may be disposed directly within expandable proppant 100 .
- one, two, three, four, five, or more smaller expandable proppants 102 may be disposed within expandable proppant 100 .
- FIG. 9 a cross-section of a wellbore according to embodiments of the present invention is shown.
- multiple expandable proppants 100 are shown deployed within a wellbore 130 .
- wellbore 130 has a large fracture 135 as well as a number of small fractures 140 .
- multiple expandable proppants 100 may be disposed therein.
- three expandable proppants 100 have been released, however, in other embodiments, one, two, four, five, or more expandable proppants 100 may be disposed in large fracture 135 .
- expandable proppants 100 may be in various stages of expansion. As illustrated, first expandable proppant 101 is in an open position, thereby holding open the largest area of large fracture 135 . Second expandable proppant 102 is partially expanded, thereby holding open a partially constricted section of large fracture 135 . Third expandable proppant 103 is in a closed position, and is essentially wedged into a constriction within large fracture 135 ,
- FIG. 10 a cross-section of a wellbore according to embodiments of the present invention is shown.
- multiple expandable proppants 100 are shown deployed within a wellbore 130 .
- wellbore 130 has two large fractures or perforations 135 .
- Expandable proppant 100 includes an expandable outer shell layer 105 . Expandable proppant 100 also includes one or more internal expandable portions 110 . In this embodiment, expandable proppant 100 is illustrated holding open large fracture or perforations 135 . Internal expandable portions 110 are shown contacting large fractures or perforations 135 , thereby preventing large fractures or perforations 135 from collapsing and/or making it larger through use of an activation system, e.g., mechanical, explosion, chemical, pneumatic, hydraulic, etc.
- an activation system e.g., mechanical, explosion, chemical, pneumatic, hydraulic, etc.
- hydrocarbons may flow in direction A through large fractures or perforation 135 in direction B, and into wellbore 130 in direction C to the surface (not shown) with minimal flow limitation or restriction.
- hydrocarbons may be produced from either one of large fractures/perforation 135 or from both of large fractures/perforations 135 .
- more than two large fractures or perforations 135 may be formed in order to further increase the production from wellbore 130 .
- FIG. 11 a cross-section of a wellbore according to embodiments of the present invention is shown.
- multiple expandable proppants 100 are shown deployed within a wellbore 130 .
- wellbore 130 has four large fractures/perforations 135 .
- Expandable proppant 100 includes an expandable outer shell layer 105 . Expandable proppant 100 also includes one or more internal expandable portions 110 . In this embodiment, expandable proppant 100 is illustrated holding open large fracture/perforation 135 . Internal expandable portions 110 are shown contacting large fractures/perforations 135 , thereby preventing large fractures/perforations 135 from collapsing and/or making it larger through use of an activation system, e.g., mechanical, explosion, chemical, pneumatic, hydraulic, etc.
- an activation system e.g., mechanical, explosion, chemical, pneumatic, hydraulic, etc.
- hydrocarbons may flow in direction A through large fracture 135 in direction B, and into wellbore 130 in direction C to the surface (not shown) with minimal flow limitation or restriction.
- hydrocarbons may be produced from either one of large fractures/perforations 135 or from more than one of the large fractures/perforations 135 .
- more than four large fractures/perforations 135 may be formed in order to further increase the production from wellbore 130 .
- FIG. 12 a cross-section of a wellbore according to embodiments of the present invention is shown.
- multiple expandable proppants 100 are shown deployed within a wellbore 130 .
- wellbore 130 has four large fractures/perforations 135 .
- one or more wellbore separators 145 such as packers/multi-stage fracturing systems, may be deployed in order to divide the wellbore 130 into separate sections, thereby allowing for controlled production.
- wellbore separator 145 a may be opened while wellbore separators 145 b and 145 c may be closed, thereby allowing production from the area between wellbore separators 145 a and 145 b.
- wellbore separators 145 a and 145 b may be opened, thereby allowing for production between wellbore separators 145 a and 145 c.
- wellbore separators 145 a, 145 b, and 145 c may be opened, thereby allowing production from all areas of wellbore 130 .
- Expandable proppant 100 includes an expandable outer shell layer 105 . Expandable proppant 100 also includes one or more internal expandable portions 110 . In this embodiment, expandable proppant 100 is illustrated holding open large fracture/perforation 135 . Internal expandable portions 110 are shown contacting large fractures/perforation 135 , thereby preventing large fractures/perforations 135 from collapsing and/or making it larger through use of an activation system, e.g., mechanical, explosion, chemical, pneumatic, hydraulic, etc.
- an activation system e.g., mechanical, explosion, chemical, pneumatic, hydraulic, etc.
- hydrocarbons may flow in direction A through large fracture 135 in direction B, and into wellbore 130 in direction C to the surface (not shown) with minimal flow limitation or restriction.
- hydrocarbons may be produced from either one of large fractures/perforations 135 or from more than one of the large fractures/perforations 135 .
- more than four large fractures/perforations 135 may be formed in order to further increase the production from wellbore 130 .
- proppant may be delivered using a proppant delivery system 150 .
- the proppant delivery system 150 may include a tool body 155 with an expandable injector 160 disposed on at least one side of tool body 155 .
- the proppant delivery system 150 may further include an expandable proppant (not shown) that is initially disposed within tool body 155 or expandable injector 160 .
- the proppant delivery system 150 may deployed within one or more than one wellbore separations (reference character 145 of FIG. 12 , such as packers/multi-stage fracturing systems, may be deployed in order to divide the wellbore 130 into separate sections, thereby allowing for controlled production.
- Components of proppant delivery system 150 may be formed from various materials such as, for example, metals, metal alloys, plastics, and composites thereof.
- tool body 155 may be formed from stainless steel
- expandable injector 160 may be formed from a plastic or KEVLAR® (a para-aramid synthetic fiber).
- KEVLAR® a para-aramid synthetic fiber
- expandable injector 160 is configured to expand laterally, longitudinally, radially, azimuthally, or in any direction into the downhole formation.
- expandable injector 160 may include a telescopic configuration, in which smaller sections 165 fit within larger sections 167 , thereby allowing expandable injector 160 to expand outwardly into the downhole formation.
- expandable injector 160 may be configured to expand and/or collapse using methods other than telescopic expansion, such as, for example, through folding, breaking down, screw-type expansion, etc.
- the distal end of the expandable injector 160 may further include a perforation charge 170 that is configured to detonate when in or in proximity to the downhole formation or tubular liner.
- perforation charges 170 that may be used with proppant delivery system 150 include explosive devices that use a cavity-effect explosive reaction to generate a high-pressure, high-velocity jet that creates a perforation tunnel.
- the shape of the explosive material and the lining may determine the shape of the jet and performance characteristics of the charge 170 .
- the high pressure and velocity of the jet causes materials, such as steel, cement, and rock to flow plastically around the jet path, thereby creating a perforation tunnel through downhole formation or liners disposed therein.
- Those of ordinary skill in the art will appreciate that various types or perforation charges 170 may be used according to embodiments disclosed herein.
- the expandable injector may further include a locking mechanism 175 that allows expandable injector 160 to lock into an open position.
- a locking mechanism 175 that allows expandable injector 160 to lock into an open position.
- expandable injector 160 may be actuated, thereby extending expandable injector 160 into the formation.
- the expansion of expandable injector 160 may cause the formation to fracture in certain operations, while in other operations, a perforation charge 170 may cause the initial fracture into which expandable injector 160 is inserted.
- expandable injector 160 may also include one or more apertures 180 .
- Apertures 180 may extend substantially through expandable injector 160 , thereby allowing fluid communication between the inside and outside of expandable injector 160 .
- the apertures 180 may be sealed, thereby preventing fluids in the wellbore to enter tool body 155 .
- the seals may include physical seals, such as removable plugs or elastomers that are disposed in the apertures 180 . The seals may be removed by physical, pneumatic, explosive, mechanical, or chemical means.
- fluid pressure may remove the seals
- air pressure differentials, or added chemicals may be used to remove or otherwise dissolve the seals.
- the expandable injector may not have seals and thus be exposed to the downhole environment.
- the proppant delivery system 150 may also use one or more shear pins 185 or other frangible material, thereby allowing the tool body 155 to be seperable from, for example, expandable injector 160 .
- Such shear pins 185 may thereby allow a pull from the surface to shear the pins, thereby allowing tool body 155 to be retrieved from the wellbore while allowing expandable injector 160 to remain downhole and facilitate hydrocarbon production and efficient connectivity to the formation.
- the proppant that is disposed within proppant delivery system 150 may be a proppant substantially as described above, in which the proppant is configured to expand outwardly.
- FIGS. 14-21 cross-sectional views of a proppant delivery system and expandable proppant disposed within a wellbore according to embodiments of the present invention are shown. Use of the proppants and proppant delivery systems described above may thereby allow the production of hydrocarbons from wells to be increased.
- a proppant delivery system 150 is shown disposed in a wellbore 130 .
- the proppant delivery system 150 may be disposed in wellbore 130 using various techniques. For example, in one embodiment, proppant delivery system 150 may be run into wellbore 130 on tubulars, coiled tubing, wireline, or the like. In such an embodiment, proppant delivery system 150 may thus be pushed or pulled into a desired location within wellbore 130 . In another embodiment, proppant delivery system 150 may be disposed within wellbore 130 , allowing proppant delivery system 150 to be gravity fed to a desired location within wellbore 130 .
- proppant delivery system 150 may include motive means, thereby allowing an operator to actively control the placement of proppant delivery system 150 within wellbore 130 .
- Examples of active proppant delivery system 150 may include wheel or tracked-based delivery systems, as well as be a part of or within a multi-stage fracturing system used in hydraulic fracturing and/or production/workover operations.
- proppant delivery system 150 may be actuated. Actuation may include expanding expandable injector 160 into contact with the wellbore 130 . In certain embodiments, the force of the expansion of expandable injector 160 and the resultant contact with wellbore 130 may result in a fracture within the sidewall of wellbore 130 . After a fracture 190 is formed in wellbore 130 , a perforation charge 170 may be detonated, thereby causing a larger fracture in the formation. The fracture may be caused by, for example, jetting or chemical cutting.
- the perforation charge 170 may be used to increase the size of the fracture.
- Further actuation of proppant delivery system 150 may include further expansion of expandable injector 160 .
- expandable injector 160 telescopically expands into the fracture, thereby allowing proppants to be released therefrom.
- Actuation of proppant delivery system 150 may occur through various means including, for example, mechanical, electric, hydraulic, chemical, explosion, pneumatic, or other types of actuation systems known in the art.
- a signal is sent from the surface that causes actuation of proppant delivery system 150 .
- the signal may then cause expandable injector 160 to expand and/or perforation charge 170 to be released or detonate.
- the expansion of expandable injector 160 may be caused by the signal sent from the surface or may result from subsequently flowing a fluid through proppant delivery system 150 . After expansion, expandable injector 160 may be held in place using one or more locking mechanisms 175 .
- expandable proppant 100 may be released into the fractures.
- relatively small or relatively large numbers of expandable proppants 100 may be injected from proppant delivery system 150 into wellbore 130 .
- one expandable proppant 100 may be injected into a fracture, while in other embodiments, two, three, four, five, or more expandable proppants 100 may be injected into the fracture.
- more than ten expandable proppants 100 may he injected, and in till other embodiments, more than 50 expandable proppants 100 may be injected.
- the number of proppants may be less than is required in a typical fracturing and proppant injection operation or the expandable proppants 100 may be used in conjunction with conventional proppants like sand, ceramics, etc.
- expandable proppant 100 expands into contact with the fractures created in wellbore 130 . Once the expandable proppant 100 is inside the fracture it may continue to expand until the size of the fracture prevents further expansion or until an activation action ceases. The fracture may then be held open by the expanded proppant. in certain embodiments the proppant may withstand formation pressure of 1000 psi, 2000 psi, 4000 psi, 6000 psi, or greater.
- the formation is prevented from collapsing over time, thereby allowing the fracture to remain relatively large. Because the expandable proppant 100 holds open the downhole formation, production rates may be increased for longer periods of time with minimal flow limitation or restriction. Furthermore, chemicals, dissolving gels, biodegradable material, and the like may be added inside or in the outer layer of the expandable proppant 10 that could help minimize the plugging effect due to scaling, paraffin precipitation, asphaltine precipitation, hydrates or other precipitations.
- expandable proppant 100 may expand as a result of mechanical expansion of one or more components of expandable proppant 100 .
- mechanical expansion may include, for example, actuation of springs, torsion bars, or other mechanical components.
- pneumatic or hydraulic expansion may result by applying, flowing, or otherwise contacting expandable proppant 100 with a fluid.
- fluids include, for example, water-based fluids, oil-based fluids, synthetic-based fluids, guar, nitrogen, carbon dioxide, air, and any other fluid that may be used in fracturing operations.
- expandable proppant 100 may be coated or covered in a dissolvable substance.
- the dissolvable substance may be removed by a fluid or chemical substance that is flowed into the wellbore. After removal of the dissolvable substance, the expandable proppant 100 may then be allowed to expand.
- an explosive charge may be detonated, thereby pushing expandable proppants 100 into the wellbore and causing the expandable proppants 100 to expand into contact with the fracture.
- other substances may be injected into the wellbore to further enhance production.
- other substances may include conventional proppants, gels, dissolving agents, scale inhibitors, hydrate inhibitors, fluids, and other chemical substances as may facilitate production from the well.
- hydrocarbons may flow from fractures in wellbore 130 in direction A and into proppant delivery system 150 .
- the hydrocarbons may then flow through proppant delivery system 150 into a tubular 195 that provides fluid communication between proppant delivery system 150 and the surface of the wellbore 130 .
- the hydrocarbons may then flow in direction B to the surface of the wellbore 130 .
- hydrocarbons may flow through or around proppant delivery system 150 and into wellbore 130 and then to the surface within the wellbore 130 to the surface in direction C.
- hydrocarbons may be produced from different sections of a wellbore or multi-stage fracturing system.
- the hydrocarbons may be separated by flowing certain hydrocarbons through proppant delivery system 150 through a tubular 195 while other hydrocarbons are flowed to the surface within the wellbore 130 and not within a tubular 195 .
- hydrocarbons may flow from the formation, around and through the expandable proppants and into the proppant delivery system.
- the hydrocarbons may flow into the proppant delivery systems through the apertures described above.
- the apertures prior to production, the apertures may be opened through the application of mechanical pressure, magnetic, SMA, pneumatic pressure, a charge, or the application of a chemical additive thereto.
- the proppant delivery system may be removed from the wellbore 130 .
- an operator may pull upwardly in direction A on the tool body 15 , thereby shearing shear pins or another frangible material that connects the tool body 155 to the expandable injector 160 .
- the force of the pull may thereby disconnect the tool body 155 from the expandable injector 160 allowing the tool body 155 and any components thereof to be returned to the surface, while the expandable injector remains 160 downhole.
- the proppant delivery system 150 may be connected to the surface through various types of tubulars 195 such as, for example, coiled tubing, conventional tubing, wireline, slickline, piping, tractor systems, self-automated systems, or any other connection types as would be appreciated by se of ordinary skill in the art.
- the method of increasing hydrocarbon production may include fracturing downhole formation.
- the fracturing of the downhole formation may include, for example, detonating a perforation charge, or otherwise providing a force to the formation, thereby causing the formation to fracture.
- Methods may further include disposing an expandable proppant into the downhole formation.
- the expandable proppant may be any type of expandable proppant discussed above.
- the method may include expanding the expandable proppant into contact with the downhole formation.
- the method may include holding open the downhole formation with the expandable proppant.
- the expandable proppant may expand outwardly to a size at least ten percent greater in an open position than in a closed position.
- the expandable proppant In a closed position, the expandable proppant may have a diameter than is at least 10 percent smaller than when the expandable proppant is in a closed position.
- the expandable proppant may have a diameter that is between 20 and 50 percent smaller than when the expandable proppant is in an open position.
- the expandable proppant in a closed position may have a diameter that is between 50 and 100 percent smaller than when the expandable proppant is in an open position.
- the expandable proppant in a closed position may have a diameter that is more than 100 percent smaller than when the expandable proppant is in a closed position.
- methods disclosed herein may further include flowing proppants into the downhole formation.
- Proppants may include, for example, sized particles mixed with a fluid and may include sand grains, man-made engineered proppants, resin-coated sand or high strength ceramic materials, such as sintered bauxite.
- a proppant delivery system such as a system described in detail above, may be deployed into a wellbore.
- the expandable proppant may be disposed within the proppant delivery system.
- the proppant delivery system may include various components, such as one or more expandable injectors, one or more perforation charges, and one or more motive means, such as wheels and/or tracks or multi-stage fracturing system.
- the proppant delivery system When the proppant delivery system reaches an area within the well that is to be produced, the proppant delivery system may be actuated. Actuation may include expanding an expandable injector into contact with the formation. in certain embodiments, the force of the expansion may be sufficient to create the fracture in the downhole formation. In other embodiments a perforation charge may be detonated either before or after the expandable injector is expanded.
- one or more expandable proppants may be released into the well.
- the expandable injector and/or perforation fracture the downhole formation and then the expandable proppants are released into the fracture.
- the expandable proppants may expand in various ways including continuing to expand until they are in contact with the formation and cannot expand any further. In such a case, the expandable proppants may expand to different external diameters, so as to hold open larger sections of the fractures, while also holding open smaller sections of the fractures.
- fluids, including chemical laden fluids may be released into the fractures.
- the fluids may then dissolve an outer layer of the expandable proppants, thereby allowing the components of the expandable proppants to expand outwardly.
- expansion of the expandable proppants may be caused at least in part by a force applied to the expandable proppants.
- forces that may cause the expandable proppants to expand include, for example, hydraulic, pneumatic, explosive, or mechanical forces. The applied forces may then allow the expandable proppants to expand into contact with the downhole formation.
- the applied forces, fluids, and/or chemical laden fluids may further be used to open apertures in the expandable injector.
- the expandable injector may include a number of apertures with plugs inserted therein. The plugs may then be removed from the expandable injector due to dissolving in a fluid or the plugs may be forced out of the apertures by one or more of the forces discussed above.
- hydrocarbons may be flowed from the downhole formation to the surface.
- the hydrocarbons may flow through the expandable injector, through the body of the proppant delivery system, and/or through one or more tubulars in fluid communication between the fractures and the surface of the well.
- an upward and/or downward force may be applied to the proppant delivery system, thereby separating the body of the proppant delivery system from the expandable injector.
- the applied force may shear one or more shear pins or other frangible component connecting the body to the expandable injector.
- embodiments of the present disclosure may provide for increased hydrocarbon production from fractured wells. Because the fractures may he held open to greater widths hydrocarbon flow may be increased, thereby increasing the productivity of the well.
- embodiments of the present disclosure may also provide expandable proppants that may expand outwardly to a size at least ten percent greater in an open position than in a closed position.
- the expandable proppant In a closed position, the expandable proppant may have a diameter than is at least 10 percent smaller than when the expandable proppant is in a closed position.
- the expandable proppant may have a diameter that is between 20 and 50 percent smaller than when the expandable proppant is in an open position.
- the expandable proppant in a closed position may have a diameter that is between 50 and 100 percent smaller than when the expandable proppant is in an open position.
- the expandable proppant in a closed position may have a diameter that is more than 100 percent smaller than when the expandable proppant is in a closed position.
- embodiments of the present disclosure may also provide a proppant delivery system that may be used to deliver and deploy expandable proppants within fractures of the wellbore.
- embodiments of the present disclosure may also provide an expandable proppant having an expandable outer shell layer that is configured to expand outwardly to a size between 10% and 100% greater in an open position than in a closed position.
- embodiments of the present disclosure may also provide an expandable proppant having treating agents disposed within the proppant, such as within the expandable outer shell, or in a portion of the proppant inside the expandable outer shell.
- Treating agents may include chemical compositions configured to remove or inhibit scale, paraffin, asphaltenes, corrosion, and/or prevent wellbore plugging, as well as be used to plug portion of a well or divert flow within a well.
- the treating agents may be applied to a portion of the expandable proppant, absorbed within a portion of the expandable proppant, desorbed within a portion of the expandable proppant
- embodiments of the present disclosure may also provide a proppant delivery system that is disposed in or is part of a multi-stage system.
- the multi-stage system may be a fracturing or perforating system that may include, for example, one or more packers, running tools, and other components used to isolate sections of a well, deploy tools within a well, fracture a well, perforate a well, or otherwise allow production of a well.
- embodiments of the present disclosure may also provide an expandable proppant having one or more additional expandable proppants disposed therein.
- a relatively larger expandable proppant having one or more smaller expandable proppants disposed therein may be deployed in a well such that after the relatively larger expandable proppant is expanded, one or more of the smaller expandable proppants disposed therein may be expanded.
- the expansion of the relatively larger expandable proppant and the smaller expandable proppants may be activated by the same or different activation triggers.
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Abstract
A method of increasing hydrocarbon production, the method including fracturing downhole formation and disposing an expandable proppant into the downhole formation. The method further includes expanding the expandable proppant into contact with the downhole formation and holding open the downhole formation with the expandable proppant. A proppant having an expandable outer shell layer, wherein the expandable outer shell layer is configured to expand outwardly to a size at least 10 percent greater in an open position than in a closed position. A proppant delivery system having a tool body, an expandable injector disposed on the side of the tool body, and an expandable proppant disposed within the tool body.
Description
- This application claims the benefit of, or priority to, U.S. Provisional Patent Application Ser. No. 62/075,064, filed on Nov. 4, 2014, which is hereby incorporated by reference in its entirety, as well as the benefit pursuant to 35 U.S.C. §120, as a continuation application of U.S. application Ser. No. 14/636,671.
- In order to increase the productivity of hydrocarbon wells particles may be injected into the borehole in order to allow fluids to flow from the formation to the surface. One type of injectable particle that is commonly used in hydraulic fracturing operations are referred to generally as proppants. Proppants are sized particles that are mixed with fracturing fluid to hold fractures open after a hydraulic fracturing treatment. Typically proppants include, for example, sand grains, resin-coated sand, and high-strength ceramic materials, such as bauxite. While conventional proppants are useful in holding open relatively small fractures, because the proppants are relatively small, they do not efficiently hold open large fractures or keep near wellbore connectivity as efficiently as possible.
- According to one aspect of one or more embodiments of the present invention, a method of increasing hydrocarbon production, the method including fracturing downhole formation and disposing an expandable proppant into the downhole formation. The method further includes expanding the expandable proppant into contact with the downhole formation and holding open the downhole formation with the expandable proppant.
- According to another aspect of one or more embodiments of the present invention, a proppant having an expandable outer shell layer, wherein the expandable outer shell layer is configured to expand outwardly to a size at least 10 percent greater in an open position than in a closed position.
- According to another aspect of one or more embodiments of the present invention, a proppant delivery system having a tool body, an expandable injector disposed on the side of the tool body, and an expandable proppant disposed within the tool body.
- Other aspects of the present invention will be apparent from the following description and claims.
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FIG. 1 shows a side view of a proppant in an injectable position according to embodiments of the present disclosure. -
FIG. 2 shows a side view of a proppant in a partially expanded position according to embodiments of the present disclosure. -
FIG. 3 shows a side view of a proppant in an expanded position according to embodiments of the present disclosure. -
FIG. 4 shows a side view of a proppant in an injectable position according to embodiments of the present disclosure. -
FIG. 5 shows a side view of a proppant in an expanded position according to embodiments of the present disclosure. -
FIG. 6 shows a side view of a proppant in an injectable position according to embodiments of the present disclosure. -
FIG. 7 shows a side view of a proppant in an expanded position according to embodiments of the present disclosure. -
FIG. 8 shows a cross-section of a wellbore according to embodiments of the present invention. -
FIG. 9 shows a cross-section of a wellbore according to embodiments of the present invention. -
FIG. 10 shows a cross-section of a wellbore according to embodiments of the present invention. -
FIG. 11 shows a cross-section of a wellbore according to embodiments of the present invention. -
FIG. 12 shows a cross-section of a wellbore according to embodiments of the present invention. -
FIG. 13 shows a proppant delivery system according to embodiments of the present invention. -
FIG. 14 shows a proppant delivery system in a wellbore according to embodiments of the present invention. -
FIG. 15 shows a proppant delivery system in a wellbore according to embodiments of the present invention. -
FIG. 16 shows a proppant delivery system in a wellbore according to embodiments of the present invention. -
FIG. 17 shows a proppant delivery system in a wellbore according to embodiments of the present invention. -
FIG. 18 shows a proppant delivery system in a wellbore according to embodiments of the present invention. -
FIG. 19 shows a proppant delivery system in a wellbore according to embodiments of the present invention. -
FIG. 20 shows a proppant delivery system in a wellbore according to embodiments of the present invention. -
FIG. 21 shows a proppant delivery system in a wellbore according to embodiments of the present invention. - One or more embodiments of the present invention are described in detail with reference to the accompanying figures. For consistency, like elements in the various figures are denoted by like reference numerals. In the following detailed description of the present invention, specific details are set forth in order to provide a thorough understanding of the present invention. In other instances, well-known features to one of ordinary skill in the art are not described to avoid obscuring the description of the present invention.
- Embodiments of the present invention are directed to apparatuses, systems, and methods for disposing proppants into downhole formation. Generally, proppants are sized particles that are mixed with fracturing fluid and used to hold fractures open after hydraulic fracturing. Conventionally, proppants include naturally occurring sand grains, man-made or specially engineered proppants, such as resin-coated sand or high-strength ceramic materials such as sintered bauxite, may be used. Proppant materials may be carefully sorted for size and sphericity to provide an efficient conduit for production of fluid from the reservoir to the wellbore. While such conventional proppants may be useful in certain applications, such proppants may fail under overburden formation pressure, block production routes, provide for small increases in fracture size, and provide unreliable wellbore connectivity to stimulated formation thereby resulting in inefficient stimulation and unreliable increases in production.
- Prior to or contemporaneous with injection of proppants into formation, the formation is typically fractured. Fracturing, also referred to as hydraulic fracturing, is a stimulation treatment that is routinely performed on oil and gas wells in low-permeability reservoirs. Specially engineered fluids are pumped at high pressure and rate into the reservoir that is treated, thereby causing vertical fractures to open. The fractures extend away from the wellbore in opposing directions according to the natural stresses within the formation. The proppant may be pumped in after hydraulic fracturing or along with the fracturing fluid, thereby helping to keep the formed fractures open.
- In certain wells it may also be necessary to perforate the well prior to hydraulic fracturing operations or production. Perforating refers to the process of creating holes in the casing, liner, or well formation that allows more efficient communication between the reservoir and the wellbore. In order to perforate a well, a perforating gun having one or more shaped explosive charges is disposed in the well to a desired location. The charges are then detonated, thereby creating a perforation in the well, casing and/or liner.
- The size and shape of the perforation may vary based on the type and shape of the charges that are used. Generally, the perforation may vary in diameter closer to the wellbore, thereby providing channels for the production of fluids at a location closest to the well. While the perforation diameter may be large initially, over time, formation pinching, scaling, paraffin/asphaltene, fill, formation pressure depletion, and other sources may plug or collapse the channels, thereby restricting the flow of hydrocarbons therethrough. While hydraulic fracturing and proppant injection may hold smaller fractured channels open, it may be difficult and/or risky to perform a fracture job using proppant packed together to a size big enough to open a fracture as big as the perforation diameter near the wellbore. Usually the fracture width created from a fracture job, near wellbore, is ¼ to ½ inch in width. Also it is difficult for proppants to hold open larger fracture channels. As such, traditional proppants are not effective in maintaining the large channels near wellbore.
- Proppants and proppant delivery systems according to embodiments of the present disclosure may be used to efficiently hold open the large channels closest to the wellbore (e.g., near the wellbore), as well as hold open the smaller channels that extend into the formation. Various expandable proppants and proppants delivery systems are described below, which may be capable of holding open fractures in formation, thereby increasing well productivity.
- As used herein, the term fracture refers to any cracks that are formed downhole. Examples of fractures may include cracks that form as a result of hydraulic fracturing, as described above, or may refer to cracks formed from perforation. Fracture may also refer to cracks in formation formed naturally, due to boring (such as drilling into the formation), or due to chemical treatment, such as acid stimulation. Those of ordinary skill in the art will appreciate that fractures in formation may be formed by any type of human or mechanical induced activity, or may be caused naturally due to seismic or other natural phenomena.
- Referring initially to
FIG. 1 , a side view of an expandable proppant according to embodiments of the present invention is shown. In this embodiment, theexpandable proppant 100 is illustrated in a closed or unexpanded position. In the closed position,expandable proppant 100 may be relatively small, for example, having a diameter between 0.25 and 0.5 cm, between 0.25 and 1.0 cm, between 0.75 and 1.5 cm, between 1.0 and 3.0 cm, or larger. In certain embodiments, the expandable proppant in the closed position may have a diameter smaller than 0.25 cm or larger than 3.0 cm. - In one embodiment,
expandable proppant 100 may include an expandableouter shell layer 105. Expandableouter shell layer 105 may be manufactured from various materials include, for example, smart memory alloys (SMA), graphene, metals, metal alloys, polymer, ceramics, KEVLAR® (a para-aramid synthetic fiber), plastics, natural materials, biodegradables, and various composites therefrom. In one embodiment, expandableouter shell layer 105 may be manufactured from stainless steel. -
Expandable proppant 100 may also include an internalexpandable portion 110. The internalexpandable portion 110 may be a separate structural component from expandableouter shell layer 105 or, such as in the embodiment described and illustrated inFIG. 1 , internalexpandable portion 110 may be a portion of expandableouter shell layer 105. Thus, internalexpandable portion 110 may be a portion of expandableouter shell layer 105. In the closed position, the expandableouter shell layer 105 is folded inwardly such that internalexpandable portion 110 is substantially inside expandableouter shell layer 105. - Those of ordinary skill in the art will appreciate that between the structural components of
expandable proppant 100, i.e., internalexpandable portion 110 and/or expandableouter shell layer 105, one ormore apertures 115 may be formed. In certain embodiments,apertures 115 may be relatively small, e.g., 0.1 cm or less, while inother embodiments apertures 115 may be relatively large, e.g., 1.0 cm or more. The size ofapertures 115 may be a function of howexpandable proppant 100 may be. Additionally, the size and/or number ofapertures 115 may be a product of the configuration of the expandableouter shell layer 105 and/or the configuration of internalexpandable portion 110. - In this embodiment,
expandable proppant 100 has a generally spherical shape while in a closed position. As used herein, generally spherical does not refer to the expandableouter shell layer 105 as being completely smooth, rather, the generally spherical shape defines the general overall shape ofexpandable proppant 100. For example,expandable proppant 100 in a closed position resembles a sphere due to expandableouter shell layer 105 forming an outer boundary. Other examples of generally spherical shapedexpandable proppants 100 may include various spherical polyhedrons, hosohedrons, and the like. - Expandable
outer shell layer 105 may be configured to expand in various directions, such as radially, latitudinally, longitudinally, and/or azimuthally. In a closed. position,expandable proppant 100 may have a diameter than is at least 10 percent smaller than whenexpandable proppant 100 is in a closed position. In another embodiment,expandable proppant 100 may have a diameter that is between 20 and 50 percent smaller than whenexpandable proppant 100 is in an open position. In other embodiment,expandable proppant 100 in a closed position may have a diameter that is between 50 and 100 percent smaller than whenexpandable proppant 100 is in an open position. In still another embodiment,expandable proppant 100 in a closed position may have a diameter that is more than 100 percent smaller than when expandable proppant is in a closed position. - During deployment of
expandable proppant 100, expandableouter shell layer 105 may be configured to expand at least one of as radially, latitudinally, longitudinally, and/or azimuthally. The expandableouter shell layer 105 may thus expand until the expansion is stopped by the size of the fracture into whichexpandable proppant 100 is deployed. As part of the expansion ofexpandable proppant 100, one or more of the internalexpandable portions 110 may also expand into contact with the formation. Further explanation of the expansion ofexpandable proppant 100 is described below with respect toFIGS. 2 and 3 . - Referring to
FIG. 2 , a side view of an expandable proppant according to embodiments of the present invention is shown. In this embodiment,expandable proppant 100 is illustrated in a partially expanded position. In the partially expanded position,expandable proppant 100 may be relatively small, for example, having a diameter between 0.25 and 0.5 cm, between 0.25 and 1.0 cm, between 0.75 and 1.5 cm, between 1.0 and 3.0 cm, or larger. In certain embodiments, the expandable proppant in the partially expanded position may have a diameter smaller than 0.25 cm or larger than 3.0 cm. - As explained above,
expandable proppant 100 may include an expandableouter shell layer 105.Expandable proppant 100 may also include one or more internal expandable portions. 110.Expandable proppant 100 may also include one ormore apertures 115 that may be formed as a result of the structural configuration of expandableouter shell layer 105 and/or internalexpandable portions 110. - In the partially expanded position,
expandable proppant 100 includes internalexpandable portions 110 that are partially expanded outwardly, outside of the initial diameter of expandableouter shell layer 105 whenexpandable proppant 100 was in the closed position. The amount of expansion may vary according to the properties ofexpandable proppant 100, as well as the requirements of the operation. In one embodiment,expandable proppant 100 in a partially expanded position may expand to a size at least 10 percent greater in a partially expanded position than in a closed position. In another embodiment,expandable proppant 100 in a partially expanded position may expand to a size between 20 and 50 percent greater in a partially expanded position than in a closed position. In another embodiment,expandable proppant 100 in a partially expanded position may expand to a size between 50 and 100 percent greater in a partially expanded position than in a closed position. In another embodiment,expandable proppant 100 in a partially expanded position may expand to a size more than 100 percent greater in a partially expanded position than in a closed position. - The expansion of
expandable proppant 100 may be stopped by the formation into whichexpandable proppant 100 is deployed. Depending on the fracture size,expandable proppant 100 may continuously expand until eitherexpandable proppant 100 has reached its expansion limits, until the formation restricts further expansion, or until activation ceases. Thus, in some embodiments,expandable proppant 100 may expand to 100 percent of its expansion size, while in other embodiment,expandable proppant 100 may only expand into a partially expanded position, which may be anything percentage of its expansion size between zero percent, in a closed position, to 100 percent, in an open position. - Referring to
FIG. 3 , a side view of an expandable proppant according to embodiments of the present invention is shown. In this embodiment,expandable proppant 100 is illustrated in a partially expanded position. In the partially expanded position,expandable proppant 100 may have a diameter between 0.25 and 0.5 cm, between 0.25 and 1.0 cm, between 0.75 and 1.5 cm, between 1.0 and 3.0 cm, or larger. In certain embodiments, the expandable proppant in the partially expanded position may have a diameter smaller than 0.25 cm or larger than 3.0 cm. - As explained above,
expandable proppant 100 may include an expandableouter shell layer 105.Expandable proppant 100 may also include one or more internal expandable portions. 110.Expandable proppant 100 may also include one ormore apertures 115 that may be formed as a result of the structural configuration of expandableouter shell layer 105 and/or internalexpandable portions 110. - In certain embodiments,
expandable proppant 100 may also include secondary internalexpandable portions 112. Secondaryexpandable portions 112 may be configured to expand at the same time or after expansion of internalexpandable portions 110. Those of ordinary skill in the art will appreciate that secondaryexpandable portions 112 may be formed from the same or different materials as internalexpandable portions 110, and as such, may be capable of withstanding less or greater forces. In certain embodiments, in addition to secondaryexpandable portions 112,expandable proppant 100 may further include tertiary expandable portions (not shown), quaternary expandable portions (not shown) or other numbers of expandable portions. The additional expandable portions may be configured to expand at the same time or at different intervals, depending on the requirements of the operation. - As illustrated, in an open position, the internal
expandable portions 110 have fully expanded out of expandableouter shell layer 105. In order to holdexpandable proppant 100 in the open position, one ormore locking mechanisms 120 may be used to hold expandable proppant open. In one embodiment,locking mechanism 120 may include a ratchet locking mechanism. A ratchet locking mechanism may allow continuous linear or rotary motion in a single direction, thereby preventing motion in an opposite direction. Depending on the type and geometry ofexpandable proppant 100, the ratchet locking mechanism may include a gear and pawl system or a linear system with rows of interlocking teeth. - In still other embodiments,
expandable proppant 100 may include aspring 125 or torsion bar. In such embodiments,spring 125 may biasexpandable proppant 100 in an open position. In a closed position,spring 125 may be compressed, such that open release into a fracture,spring 125 may force expandable proppant open into either a partially expanded or open position. Depending on the properties ofspring 125,spring 125 may be capable of resisting compression forces, thereby allowingspring 125 to also be lockingmechanism 120. However, in other embodiments,spring 125 may be a part oflocking mechanism 120, such thatspring 125 initially causesexpandable proppant 100 to expand, while lockingmechanism 120 holdsexpandable proppant 100 in a partially expanded or open position. - In addition to using
spring 125 or the inherent properties ofexpandable proppant 100 to cause the expansion ofexpandable proppant 100 into a partially expanded or open position, external expanders may also be used. For example,expandable proppant 100 may be actuated by external mechanical, hydraulic, explosive, SMA, magnetic, pneumatic, or chemical actuators. In one embodiment, an electrical charge may be used to causeexpandable proppant 100 to expand, while in another embodiment an explosive charge may causeexpandable proppant 100 to expand. In still other embodiment, an outer coating may be disposed aroundexpandable proppant 100. The outer coating may dissolve when contacted by a certain chemical or chemical compound. In still other embodiments,expandable proppant 100 may be stored within a delivery device, which compressesexpandable proppant 100 into a closed position. Upon release ofexpandable proppant 100 from the delivery device, expandable proppant may naturally expand or be forced open by, for example a hydraulic, explosive, mechanical, chemical reaction, SMA, or pneumatic force. Those of ordinary skill in the art will appreciate that various other ways of expandingexpandable proppant 100 are within the scope of the present disclosure. - Referring to
FIG. 4 , a side view of an expandable proppant according to embodiments of the present invention is shown. In this embodiment, theexpandable proppant 100 is illustrated in a closed or unexpanded position. In the closed position,expandable proppant 100 may be relatively small, for example, having a diameter between 0.25 and 0.5 cm, between 0.25 and 1.0 cm, between 0.75 and 1.5 cm, between 1.0 and 3.0 cm, or larger. In certain embodiments, the expandable proppant in the closed position may have a diameter smaller than 0.25 cm or larger than 3.0 cm. - In one embodiment,
expandable proppant 100 may include an expandableouter shell layer 105.Expandable proppant 100 may also include an internalexpandable portion 110. The internalexpandable portion 110 may be a separate structural component from expandableouter shell layer 105 or internalexpandable portion 110 may be a portion of expandableouter shell layer 105. Thus, internalexpandable portion 110 may be a portion of expandableouter shell layer 105. In the closed position, the expandableouter shell layer 105 is folded inwardly such that internalexpandable portion 110 is substantially inside expandableouter shell layer 105. - Those of ordinary skill in the art will appreciate that between the structural components of
expandable proppant 100, i.e., internalexpandable portion 110 and/or expandableouter shell layer 105, one ormore apertures 115 may be formed. In certain embodiments,apertures 115 may be relatively small, e.g., 0.1 cm or less, while inother embodiments apertures 115 may be relatively large, e.g., 1.0 cm or more. The size ofapertures 115 may be a function of howexpandable proppant 100 may be. Additionally, the size and/or number ofapertures 115 may be a product the configuration of expandableouter shell layer 105 and/or the configuration of internalexpandable portion 110, - In this embodiment,
expandable proppant 100 has a generally irregular geometry that resembles a star shape. In other embodiments, the geometry ofexpandable proppant 100 may be generally spherical, rhombus, cubical, rectangular, triangular, hexagonal, trapezoidal, or any other general shape that allowsexpandable proppant 100 to expand. - Expandable
outer shell layer 105 may be configured to expand in various directions, such as radially, latitudinally, longitudinally, and/or azimuthally. In a closed position,expandable proppant 100 may have a diameter than is at least 10 percent smaller than whenexpandable proppant 100 is in a closed position. In another embodiment,expandable proppant 100 may have a diameter that is between 20 and 50 percent smaller than whenexpandable proppant 100 is in an open position. In other embodiment,expandable proppant 100 in a closed position may have a diameter that is between 50 and 100 percent smaller than whenexpandable proppant 100 is in an open position, In still another embodiment,expandable proppant 100 in a closed position may have a diameter that is more than 100 percent smaller than when expandable proppant is in a closed position. - During deployment of
expandable proppant 100, expandableouter shell layer 105 may be configured to expand at least one of as radially, latitudinally, longitudinally, and/or azimuthally. The expandableouter shell layer 105 may thus expand until the expansion is stopped by the size of the fracture into whichexpandable proppant 100 is deployed or when activation ceases. As part of the expansion ofexpandable proppant 100, one or more of the internalexpandable portions 110 may also expand into contact with the formation. Further explanation of the expansion ofexpandable proppant 100 is described below with respect toFIG. 5 . - Referring to
FIG. 5 , a side view of an expandable proppant according to embodiments of the present invention is shown. In this embodiment,expandable proppant 100 is illustrated in a partially expanded position. In the partially expanded position,expandable proppant 100 may be relatively small, for example, having a diameter between 0.25 and 0.5 cm, between 0.25 and 1.0 cm, between 0.75 and 1.5 cm, between 1.0 and 3.0 cm, or larger. in certain embodiments, the expandable proppant in the partially expanded position may have a diameter smaller than 0.25 cm or larger than 3.0 cm. Those of ordinary skill in the art will appreciate that in an open position, expandedproppant 100 have a diameter between 0.25 and 0.5 cm, between 0.25 and 1.0 cm, between 0.75 and 1.5 cm, between 1,0 and 3.0 cm, or larger. In certain embodiments, theexpandable proppant 100 in the open position may have a diameter smaller than 0.25 cm or larger than 3.0 cm. - As explained above,
expandable proppant 100 may include an expandableouter shell layer 105.Expandable proppant 100 may also include one or more internal expandable portions. 110.Expandable proppant 100 may also include one ormore apertures 115 that may be formed as a result of the structural configuration of expandableouter shell layer 105 and/or internalexpandable portions 110.Expandable proppant 100 may further include alocking mechanism 120 and or aspring 125. Thespring 125 and/orlocking mechanism 120 may be used to facilitate expansion ofexpandable proppant 100 and may further preventexpandable proppant 100 from collapsing into a closed position. - In the partially expand or in the open positions,
expandable proppant 100 includes internalexpandable portions 110 that are partially expanded outwardly, outside of the initial diameter of expandableouter shell layer 105 whenexpandable proppant 100 was in the closed position. The amount of expansion may vary according to the properties ofexpandable proppant 100, as well as the requirements of the operation. In one embodiment,expandable proppant 100 in a partially expanded or in an open position may expand to a size at least 10 percent greater in a partially expanded or open position than in a closed position. In another embodiment,expandable proppant 100 in a partially expanded or open position may expand to a size between 20 and 50 percent greater in a partially expanded or open position than in a closed position. In another embodiment,expandable proppant 100 in a partially expanded position or open position may expand to a size between 50 and 100 percent greater in a partially expanded or open position than in a closed position. In another embodiment,expandable proppant 100 in a partially expanded or open position may expand to a size more than 100 percent greater in a partially open or open position than in a closed position. - The expansion of
expandable proppant 100 may be stopped by the formation into whichexpandable proppant 100 is deployed or when activation ceases. Depending on the fracture size,expandable proppant 100 may continuously expand until eitherexpandable proppant 100 has reached its expansion limits or until the formation restricts further expansion or activation trigger ceases. Thus, in some embodiments,expandable proppant 100 may expand to 100 percent of its expansion size, while in other embodiment,expandable proppant 100 may only expand into a partially expanded position, which may be anything percentage of its expansion size between zero percent, in a closed position, to 100 percent, in an open position. - Referring to
FIG. 6 , a side view of an expandable proppant according to embodiments of the present invention is shown. In this embodiment, theexpandable proppant 100 is illustrated in a closed or unexpanded position. In the closed position,expandable proppant 100 may be relatively small, for example, having a diameter between 0.25 and 0.5 cm, between 0.25 and 1.0 cm, between 0.75 and 1.5 cm, between 1.0 and 3.0 cm, or larger. In certain embodiments, the expandable proppant in the closed position may have a diameter smaller than 0.25 cm or larger than 3.0 cm. - In one embodiment,
expandable proppant 100 may include an expandableouter shell layer 105.Expandable proppant 100 may also include an internalexpandable portion 110. The internalexpandable portion 110 may be a separate structural component from expandableouter shell layer 105 or internalexpandable portion 110 may be a portion of expandableouter shell layer 105. Thus, internalexpandable portion 110 may be a portion of expandableouter shell layer 105. In the closed position, the expandableouter shell layer 105 is folded inwardly such that internalexpandable portion 110 is substantially inside expandableouter shell layer 105, in this embodiment,expandable proppant 100 has a generally rectangular or cube-shaped geometry. - Those of ordinary skill in the art will appreciate that between the structural components of
expandable proppant 100, i.e., internalexpandable portion 110 and/or expandableouter shell layer 105, one ormore apertures 115 may be formed. In certain embodiments,apertures 115 may be relatively small, e.g., 0.1 cm or less, while inother embodiments apertures 115 may be relatively large, e.g., 1.0 cm or more. The size ofapertures 115 may be a function of howexpandable proppant 100 may be. Additionally, the size and/or number ofapertures 115 may be a product the configuration of expandableouter shell layer 105 and/or the configuration of internalexpandable portion 110. - Expandable
outer shell layer 105 may be configured to expand in various directions, such as radially, latitudinally, longitudinally, and/or azimuthally. In a closed position,expandable proppant 100 may have a diameter than is at least 10 percent smaller than whenexpandable proppant 100 is in a closed position. in another embodiment,expandable proppant 100 may have a diameter that is between 20 and 50 percent smaller than whenexpandable proppant 100 is in an open position. In other embodiment,expandable proppant 100 in a closed position may have a diameter that is between 50 and 100 percent smaller than whenexpandable proppant 100 is in an open position. In still another embodiment,expandable proppant 100 in a closed position may have a diameter that is more than 100 percent smaller than when expandable proppant is in a closed position. - During deployment of
expandable proppant 100, expandableouter shell layer 105 may be configured to expand at least one of as radially, latitudinally, longitudinally, and/or azimuthally. The expandableouter shell layer 105 may thus expand until the expansion is stopped by the size of the fracture into whichexpandable proppant 100 is deployed or when an activation trigger ceases. As part of the expansion ofexpandable proppant 100, one or more of the internalexpandable portions 110 may also expand into contact with the formation. Further explanation of the expansion ofexpandable proppant 100 is described below with respect toFIG. 7 . - Referring to
FIG. 7 , a side view of an expandable proppant according to embodiments of the present invention is shown. In this embodiment,expandable proppant 100 is illustrated in a partially expanded position. In the partially expanded position,expandable proppant 100 may be relatively small, for example, having a diameter between 0.25 and 0.5 cm, between 0.25 and 1.0 cm, between 0.75 and 1.5 cm, between 1.0 and 3.0 cm, or larger. In certain embodiments, the expandable proppant in the partially expanded position may have a diameter smaller than 0.25 cm or larger than 3.0 cm. Those of ordinary skill in the art will appreciate that in an open position, expandedproppant 100 have a diameter between 0.25 and 0.5 cm, between 0.25 and 1.0 cm, between 0.75 and 1.5 cm, between 1.0 and 3.0 cm, or larger. In certain embodiments, theexpandable proppant 100 in the open position may have a diameter smaller than 0.25 cm or larger than 3.0 cm. - As explained above,
expandable proppant 100 may include an expandableouter shell layer 105.Expandable proppant 100 may also include one or more internal expandable portions. 110.Expandable proppant 100 may also include one ormore apertures 115 that may be formed as a result of the structural configuration of expandableouter shell layer 105 and/or internalexpandable portions 110.Expandable proppant 100 may further include alocking mechanism 120 and or aspring 125. Thespring 125 and/orlocking mechanism 120 may be used to facilitate expansion ofexpandable proppant 100 and may further preventexpandable proppant 100 from collapsing into a closed position. - In the partially expand or in the open positions,
expandable proppant 100 includes internalexpandable portions 110 that are partially expanded outwardly, outside of the initial diameter of expandableouter shell layer 105 whenexpandable proppant 100 was in the closed position. The amount of expansion may vary according to the properties ofexpandable proppant 100, as well as the requirements of the operation. In one embodiment,expandable proppant 100 in a partially expanded or in an open position may expand to a size at least 10 percent greater in a partially expanded or open position than in a closed position. In another embodiment,expandable proppant 100 in a partially expanded or open position may expand to a size between 20 and 50 percent greater in a partially expanded or open position than in a closed position. In another embodiment,expandable proppant 100 in a partially expanded position or open position may expand to a size between 50 and 100 percent greater in a partially expanded or open position than in a closed position. In another embodiment,expandable proppant 100 in a partially expanded or open position may expand to a size more than 100 percent greater in a partially open or open position than in a closed position. - The expansion of
expandable proppant 100 may be stopped by the formation into whichexpandable proppant 100 is deployed or when an activation trigger ceases. Depending on the fracture size,expandable proppant 100 may continuously expand until eitherexpandable proppant 100 has reached its expansion limits or until the formation restricts further expansion or until an activation trigger ceases. Thus, in some embodiments,expandable proppant 100 may expand to 100 percent of its expansion size, while in other embodiment,expandable proppant 100 may only expand into a partially expanded position, which may be anything percentage of its expansion size between zero percent, in a closed position, to 100 percent, in an open position. - Referring to
FIG. 8 , a cross-section of a wellbore according to embodiments of the present invention is shown. In this embodiment, anexpandable proppant 100 is shown deployed within awellbore 130.Wellbore 130 may include any type ofwellbore 130 known in the art. As such,wellbore 130 may be liner or unlined as well as cased or encased. As shown,wellbore 130 has alarge fracture 135 as well as a number ofsmall fractures 140. As described above,large fracture 135 may have been caused by perforation or hydraulic fracturing, whilesmall fractures 140 are generally formed through hydraulic fracturing or stress created on formation by stimulation. -
Expandable proppant 100 includes an expandableouter shell layer 105.Expandable proppant 100 also includes one or more internalexpandable portions 110. In this embodiment,expandable proppant 100 is illustrated holding openlarge fracture 135. Internalexpandable portions 110 are shown contactinglarge fracture 135, thereby preventinglarge fracture 135 from collapsing and/or making it larger through use of an activation system, e.g., mechanical, explosion, chemical, pneumatic, hydraulic, etc. Becauselarge fracture 135 is held open, and thus has a larger diameter than a collapsed fracture, hydrocarbons may flow in direction A fromsmall fractures 140, throughlarge fracture 135 in direction B, and intowellbore 130 in direction C to the surface (not shown) with minimal flow limitation or restriction. Furthermore, chemicals, dissolving gels, and/or biodegradable material may be added inside or in the outer layer of the expandable proppant to help minimize a plugging effect caused by scaling, paraffin precipitation, asphaltine precipitation, hydrates or other precipitates. - Additionally, in this embodiment,
expandable proppant 100 includes a plurality of smallerexpandable proppants 102 disposed within. The nesting of smallerexpandable proppants 102 within relatively largerexpandable proppant 100 allows for the smallerexpandable proppants 102 to be deployed at a later time thanexpandable proppant 100. For example, in one embodiment,expandable proppant 100 may be deployed in a well and activated, thereby causingexpandable proppant 100 to expand. After or during expansion ofexpandable proppant 100, smallerexpandable proppants 102 may be released from withinexpandable proppant 100, thereby allowing smallerexpandable proppants 102 to expand within the well. Those of ordinary skill in the art will appreciate that smallerexpandable proppants 102 may be activated at the same time asexpandable proppant 100 or after activation ofexpandable proppant 100. Additionally, the expansion of smallerexpandable proppants 102 may be activated by the same trigger asexpandable proppant 100 or due to a different activation signal/trigger. In certain embodiments, multiple nested layers ofexpandable proppants 100 and smallerexpandable proppants 102 may be used. In such an embodiment,expandable proppant 100 may have a smallerexpandable proppant 102 disposed inside, while a third, still smaller expandable proppant is disposed within smallerexpandable proppant 102. The number of nested layers may vary due to constrains on the size of theexpandable proppants 100/102, however, those of ordinary skill in the art will appreciate thatexpandable proppant 100 may have two, three, four, five, or more nested layers therewithin. In still other embodiments, rather than nesting smallerexpandable proppants 102 withinexpandable proppant 100, multiple smallerexpandable proppants 102 may be disposed directly withinexpandable proppant 100. For example, one, two, three, four, five, or more smallerexpandable proppants 102 may be disposed withinexpandable proppant 100. - Referring to
FIG. 9 , a cross-section of a wellbore according to embodiments of the present invention is shown. In this embodiment, multipleexpandable proppants 100 are shown deployed within awellbore 130. As shown,wellbore 130 has alarge fracture 135 as well as a number ofsmall fractures 140. - In order to hold
large fracture 135 open and keeplarge fracture 140 are large as possible, multipleexpandable proppants 100 may be disposed therein. In this embodiment, threeexpandable proppants 100 have been released, however, in other embodiments, one, two, four, five, or moreexpandable proppants 100 may be disposed inlarge fracture 135. - Because the size of
large fracture 135 is not consistent, e.g., the fracture gets smaller the further away fromwellbore 130 it extends,expandable proppants 100 may be in various stages of expansion. As illustrated, firstexpandable proppant 101 is in an open position, thereby holding open the largest area oflarge fracture 135. Secondexpandable proppant 102 is partially expanded, thereby holding open a partially constricted section oflarge fracture 135. Thirdexpandable proppant 103 is in a closed position, and is essentially wedged into a constriction withinlarge fracture 135, - Referring to
FIG. 10 , a cross-section of a wellbore according to embodiments of the present invention is shown. In this embodiment, multipleexpandable proppants 100 are shown deployed within awellbore 130. As shown,wellbore 130 has two large fractures orperforations 135. -
Expandable proppant 100 includes an expandableouter shell layer 105.Expandable proppant 100 also includes one or more internalexpandable portions 110. In this embodiment,expandable proppant 100 is illustrated holding open large fracture orperforations 135. Internalexpandable portions 110 are shown contacting large fractures orperforations 135, thereby preventing large fractures orperforations 135 from collapsing and/or making it larger through use of an activation system, e.g., mechanical, explosion, chemical, pneumatic, hydraulic, etc. Because large fractures orperforations 135 are held open, and thus have a larger diameter than a collapsed fracture or pinch out/closed formation, hydrocarbons may flow in direction A through large fractures orperforation 135 in direction B, and intowellbore 130 in direction C to the surface (not shown) with minimal flow limitation or restriction. Depending on the requirements of the fracturing and/or production operation, hydrocarbons may be produced from either one of large fractures/perforation 135 or from both of large fractures/perforations 135. Those of ordinary skill in the art will appreciate that in certain embodiments, more than two large fractures orperforations 135 may be formed in order to further increase the production fromwellbore 130. - Referring to
FIG. 11 , a cross-section of a wellbore according to embodiments of the present invention is shown. In this embodiment, multipleexpandable proppants 100 are shown deployed within awellbore 130. As shown,wellbore 130 has four large fractures/perforations 135. -
Expandable proppant 100 includes an expandableouter shell layer 105.Expandable proppant 100 also includes one or more internalexpandable portions 110. In this embodiment,expandable proppant 100 is illustrated holding open large fracture/perforation 135. Internalexpandable portions 110 are shown contacting large fractures/perforations 135, thereby preventing large fractures/perforations 135 from collapsing and/or making it larger through use of an activation system, e.g., mechanical, explosion, chemical, pneumatic, hydraulic, etc. Because large fractures/perforations 135 are held open, and thus have a larger diameter than a collapsed fracture, hydrocarbons may flow in direction A throughlarge fracture 135 in direction B, and intowellbore 130 in direction C to the surface (not shown) with minimal flow limitation or restriction. Depending on the requirements of the fracturing and/or production operation, hydrocarbons may be produced from either one of large fractures/perforations 135 or from more than one of the large fractures/perforations 135. Those of ordinary skill in the art will appreciate that in certain embodiments, more than four large fractures/perforations 135 may be formed in order to further increase the production fromwellbore 130. - Referring to
FIG. 12 , a cross-section of a wellbore according to embodiments of the present invention is shown. In this embodiment, multipleexpandable proppants 100 are shown deployed within awellbore 130. As shown,wellbore 130 has four large fractures/perforations 135. Between the various large fractures/perforations 135 one or more wellbore separators 145, such as packers/multi-stage fracturing systems, may be deployed in order to divide thewellbore 130 into separate sections, thereby allowing for controlled production. For example, in one embodiment,wellbore separator 145 a may be opened whilewellbore separators wellbore separators wellbore separators wellbore separators wellbore separators wellbore 130. -
Expandable proppant 100 includes an expandableouter shell layer 105.Expandable proppant 100 also includes one or more internalexpandable portions 110. In this embodiment,expandable proppant 100 is illustrated holding open large fracture/perforation 135. Internalexpandable portions 110 are shown contacting large fractures/perforation 135, thereby preventing large fractures/perforations 135 from collapsing and/or making it larger through use of an activation system, e.g., mechanical, explosion, chemical, pneumatic, hydraulic, etc. Because large fractures/perforations 135 are held open, and thus have a larger diameter than a collapsed fracture, hydrocarbons may flow in direction A throughlarge fracture 135 in direction B, and intowellbore 130 in direction C to the surface (not shown) with minimal flow limitation or restriction. Depending on the requirements of the fracturing and/or production operation, hydrocarbons may be produced from either one of large fractures/perforations 135 or from more than one of the large fractures/perforations 135. Those of ordinary skill in the art will appreciate that in certain embodiments, more than four large fractures/perforations 135 may be formed in order to further increase the production fromwellbore 130. - Referring to
FIG. 13 , a side view of a proppant delivery system according to embodiments of the present disclosure is shown. In certain embodiments, proppant may be delivered using aproppant delivery system 150. In such an embodiment, theproppant delivery system 150 may include atool body 155 with anexpandable injector 160 disposed on at least one side oftool body 155. Theproppant delivery system 150 may further include an expandable proppant (not shown) that is initially disposed withintool body 155 orexpandable injector 160. Theproppant delivery system 150 may deployed within one or more than one wellbore separations (reference character 145 ofFIG. 12 , such as packers/multi-stage fracturing systems, may be deployed in order to divide thewellbore 130 into separate sections, thereby allowing for controlled production. - Components of
proppant delivery system 150, such astool body 155 and/orexpandable injector 160 may be formed from various materials such as, for example, metals, metal alloys, plastics, and composites thereof. For example, in one embodiment,tool body 155 may be formed from stainless steel, whileexpandable injector 160 may be formed from a plastic or KEVLAR® (a para-aramid synthetic fiber). Those of ordinary skill will appreciate that the particular materials used to form components ofproppant delivery system 150 may be selected based on requirements of the delivery process, the fracturing operation, or the production operation. - In certain embodiments,
expandable injector 160 is configured to expand laterally, longitudinally, radially, azimuthally, or in any direction into the downhole formation. In the embodiment illustrated inFIG. 13 ,expandable injector 160 may include a telescopic configuration, in whichsmaller sections 165 fit withinlarger sections 167, thereby allowingexpandable injector 160 to expand outwardly into the downhole formation. In still other embodiments,expandable injector 160 may be configured to expand and/or collapse using methods other than telescopic expansion, such as, for example, through folding, breaking down, screw-type expansion, etc. - In certain embodiments, the distal end of the
expandable injector 160 may further include aperforation charge 170 that is configured to detonate when in or in proximity to the downhole formation or tubular liner. Examples ofperforation charges 170 that may be used withproppant delivery system 150 include explosive devices that use a cavity-effect explosive reaction to generate a high-pressure, high-velocity jet that creates a perforation tunnel. The shape of the explosive material and the lining may determine the shape of the jet and performance characteristics of thecharge 170. The high pressure and velocity of the jet causes materials, such as steel, cement, and rock to flow plastically around the jet path, thereby creating a perforation tunnel through downhole formation or liners disposed therein. Those of ordinary skill in the art will appreciate that various types orperforation charges 170 may be used according to embodiments disclosed herein. - In certain embodiments, the expandable injector may further include a
locking mechanism 175 that allowsexpandable injector 160 to lock into an open position. Thus, as illustrated below, during operationexpandable injector 160 may be actuated, thereby extendingexpandable injector 160 into the formation. The expansion ofexpandable injector 160 may cause the formation to fracture in certain operations, while in other operations, aperforation charge 170 may cause the initial fracture into whichexpandable injector 160 is inserted. - In certain embodiments,
expandable injector 160 may also include one ormore apertures 180.Apertures 180 may extend substantially throughexpandable injector 160, thereby allowing fluid communication between the inside and outside ofexpandable injector 160. During disposition ofproppant delivery system 150 within a wellbore, theapertures 180 may be sealed, thereby preventing fluids in the wellbore to entertool body 155. The seals (not independently shown) may include physical seals, such as removable plugs or elastomers that are disposed in theapertures 180. The seals may be removed by physical, pneumatic, explosive, mechanical, or chemical means. For example, in one embodiment fluid pressure may remove the seals, while in other embodiments air pressure differentials, or added chemicals (such as acids) may be used to remove or otherwise dissolve the seals. In certain embodiments the expandable injector may not have seals and thus be exposed to the downhole environment. - The
proppant delivery system 150 may also use one or more shear pins 185 or other frangible material, thereby allowing thetool body 155 to be seperable from, for example,expandable injector 160. Such shear pins 185 may thereby allow a pull from the surface to shear the pins, thereby allowingtool body 155 to be retrieved from the wellbore while allowingexpandable injector 160 to remain downhole and facilitate hydrocarbon production and efficient connectivity to the formation. - The proppant that is disposed within
proppant delivery system 150 may be a proppant substantially as described above, in which the proppant is configured to expand outwardly. - Referring to
FIGS. 14-21 cross-sectional views of a proppant delivery system and expandable proppant disposed within a wellbore according to embodiments of the present invention are shown. Use of the proppants and proppant delivery systems described above may thereby allow the production of hydrocarbons from wells to be increased. - Referring specifically to
FIG. 14 , aproppant delivery system 150 is shown disposed in awellbore 130. Theproppant delivery system 150 may be disposed inwellbore 130 using various techniques. For example, in one embodiment,proppant delivery system 150 may be run intowellbore 130 on tubulars, coiled tubing, wireline, or the like. In such an embodiment,proppant delivery system 150 may thus be pushed or pulled into a desired location withinwellbore 130. In another embodiment,proppant delivery system 150 may be disposed withinwellbore 130, allowingproppant delivery system 150 to be gravity fed to a desired location withinwellbore 130. In still other embodiments,proppant delivery system 150 may include motive means, thereby allowing an operator to actively control the placement ofproppant delivery system 150 withinwellbore 130. Examples of activeproppant delivery system 150 may include wheel or tracked-based delivery systems, as well as be a part of or within a multi-stage fracturing system used in hydraulic fracturing and/or production/workover operations. - Referring to
FIG. 15 , afterproppant delivery system 150 is disposed at a desired location withinwellbore 130,proppant delivery system 150 may be actuated. Actuation may include expandingexpandable injector 160 into contact with thewellbore 130. In certain embodiments, the force of the expansion ofexpandable injector 160 and the resultant contact withwellbore 130 may result in a fracture within the sidewall ofwellbore 130. After afracture 190 is formed inwellbore 130, aperforation charge 170 may be detonated, thereby causing a larger fracture in the formation. The fracture may be caused by, for example, jetting or chemical cutting. - Referring to
FIG. 16 , after an initial fracture is formed in thewellbore 130, as explained above, theperforation charge 170 may be used to increase the size of the fracture. Further actuation ofproppant delivery system 150 may include further expansion ofexpandable injector 160. In this embodiment,expandable injector 160 telescopically expands into the fracture, thereby allowing proppants to be released therefrom. - Actuation of
proppant delivery system 150 may occur through various means including, for example, mechanical, electric, hydraulic, chemical, explosion, pneumatic, or other types of actuation systems known in the art. For example, in one embodiment, a signal is sent from the surface that causes actuation ofproppant delivery system 150. The signal may then causeexpandable injector 160 to expand and/orperforation charge 170 to be released or detonate. The expansion ofexpandable injector 160 may be caused by the signal sent from the surface or may result from subsequently flowing a fluid throughproppant delivery system 150. After expansion,expandable injector 160 may be held in place using one ormore locking mechanisms 175. - Referring to
FIG. 17 , after the fracture is enlarged usingexpandable injector 160 and/orperforation charge 170expandable proppant 100 may be released into the fractures. Depending on the requirements of the operation, relatively small or relatively large numbers ofexpandable proppants 100 may be injected fromproppant delivery system 150 intowellbore 130. In certain embodiments, oneexpandable proppant 100 may be injected into a fracture, while in other embodiments, two, three, four, five, or moreexpandable proppants 100 may be injected into the fracture. In still other embodiments, more than tenexpandable proppants 100 may he injected, and in till other embodiments, more than 50expandable proppants 100 may be injected. Because of the expandable nature of theexpandable proppants 100 used herewith, the number of proppants may be less than is required in a typical fracturing and proppant injection operation or theexpandable proppants 100 may be used in conjunction with conventional proppants like sand, ceramics, etc. - Referring to
FIG. 18 , after releasingexpandable proppant 100 intowellbore 130,expandable proppant 100 expands into contact with the fractures created inwellbore 130. Once theexpandable proppant 100 is inside the fracture it may continue to expand until the size of the fracture prevents further expansion or until an activation action ceases. The fracture may then be held open by the expanded proppant. in certain embodiments the proppant may withstand formation pressure of 1000 psi, 2000 psi, 4000 psi, 6000 psi, or greater. - As the
expandable proppant 100 contacts the formation, the formation is prevented from collapsing over time, thereby allowing the fracture to remain relatively large. Because theexpandable proppant 100 holds open the downhole formation, production rates may be increased for longer periods of time with minimal flow limitation or restriction. Furthermore, chemicals, dissolving gels, biodegradable material, and the like may be added inside or in the outer layer of the expandable proppant 10 that could help minimize the plugging effect due to scaling, paraffin precipitation, asphaltine precipitation, hydrates or other precipitations. - Activation of expansion of
expandable proppant 100 may occur due to mechanical expansion, pneumatic expansion, hydraulic expansion, chemical expansion, and the like. For example, in one embodiment,expandable proppant 100 may expand as a result of mechanical expansion of one or more components ofexpandable proppant 100. Such mechanical expansion may include, for example, actuation of springs, torsion bars, or other mechanical components. In another embodiment, pneumatic or hydraulic expansion may result by applying, flowing, or otherwise contactingexpandable proppant 100 with a fluid. Examples of fluids include, for example, water-based fluids, oil-based fluids, synthetic-based fluids, guar, nitrogen, carbon dioxide, air, and any other fluid that may be used in fracturing operations. In still other embodiments,expandable proppant 100 may be coated or covered in a dissolvable substance. In such an embodiment, the dissolvable substance may be removed by a fluid or chemical substance that is flowed into the wellbore. After removal of the dissolvable substance, theexpandable proppant 100 may then be allowed to expand. in still another embodiment, an explosive charge may be detonated, thereby pushingexpandable proppants 100 into the wellbore and causing theexpandable proppants 100 to expand into contact with the fracture. - Referring to
FIG. 19 , afterexpandable proppant 100 is disposed inwellbore 130, other substances may be injected into the wellbore to further enhance production. Examples of other substances may include conventional proppants, gels, dissolving agents, scale inhibitors, hydrate inhibitors, fluids, and other chemical substances as may facilitate production from the well. - Referring to
FIG. 20 , production of hydrocarbons fromwellbore 130 may be achieved through one of several options. In one embodiment, hydrocarbons may flow from fractures inwellbore 130 in direction A and intoproppant delivery system 150. The hydrocarbons may then flow throughproppant delivery system 150 into a tubular 195 that provides fluid communication betweenproppant delivery system 150 and the surface of thewellbore 130. The hydrocarbons may then flow in direction B to the surface of thewellbore 130. In another embodiment, hydrocarbons may flow through or aroundproppant delivery system 150 and intowellbore 130 and then to the surface within thewellbore 130 to the surface in direction C. In certain embodiments, hydrocarbons may be produced from different sections of a wellbore or multi-stage fracturing system. In such an embodiment, the hydrocarbons may be separated by flowing certain hydrocarbons throughproppant delivery system 150 through a tubular 195 while other hydrocarbons are flowed to the surface within thewellbore 130 and not within a tubular 195. - During production, as described above, hydrocarbons may flow from the formation, around and through the expandable proppants and into the proppant delivery system. In certain embodiments, the hydrocarbons may flow into the proppant delivery systems through the apertures described above. In such an embodiment, prior to production, the apertures may be opened through the application of mechanical pressure, magnetic, SMA, pneumatic pressure, a charge, or the application of a chemical additive thereto.
- Referring to
FIG. 21 , After theexpandable proppant 100 has been injected and expanded, the proppant delivery system may be removed from thewellbore 130. In such a situation, it may be desirable to remove thetool body 155 while keeping the expandable injector downhole 160. In order to remove just thetool body 155, an operator may pull upwardly in direction A on the tool body 15, thereby shearing shear pins or another frangible material that connects thetool body 155 to theexpandable injector 160. The force of the pull may thereby disconnect thetool body 155 from theexpandable injector 160 allowing thetool body 155 and any components thereof to be returned to the surface, while the expandable injector remains 160 downhole. Because theexpandable injector 160 remains downhole with theexpandable proppants 100, the flow path near the wellbore from the formation may remain relatively larger, thereby allowing for greater production efficiency. Theproppant delivery system 150 may be connected to the surface through various types oftubulars 195 such as, for example, coiled tubing, conventional tubing, wireline, slickline, piping, tractor systems, self-automated systems, or any other connection types as would be appreciated by se of ordinary skill in the art. - Various methods of increasing hydrocarbon production from wells are also within the scope of the present disclosure. In one embodiment, the method of increasing hydrocarbon production may include fracturing downhole formation. The fracturing of the downhole formation may include, for example, detonating a perforation charge, or otherwise providing a force to the formation, thereby causing the formation to fracture.
- Methods may further include disposing an expandable proppant into the downhole formation. The expandable proppant may be any type of expandable proppant discussed above. After disposing the expandable proppant into the downhole formation, the method may include expanding the expandable proppant into contact with the downhole formation. After the expandable proppants are expanded into contact with the downhole formation, the method may include holding open the downhole formation with the expandable proppant.
- In certain embodiments, the expandable proppant may expand outwardly to a size at least ten percent greater in an open position than in a closed position. In a closed position, the expandable proppant may have a diameter than is at least 10 percent smaller than when the expandable proppant is in a closed position. In another embodiment, the expandable proppant may have a diameter that is between 20 and 50 percent smaller than when the expandable proppant is in an open position. In other embodiments, the expandable proppant in a closed position may have a diameter that is between 50 and 100 percent smaller than when the expandable proppant is in an open position. In still another embodiment, the expandable proppant in a closed position may have a diameter that is more than 100 percent smaller than when the expandable proppant is in a closed position.
- In order to further increase hydrocarbon production, in certain embodiments, methods disclosed herein may further include flowing proppants into the downhole formation. Proppants may include, for example, sized particles mixed with a fluid and may include sand grains, man-made engineered proppants, resin-coated sand or high strength ceramic materials, such as sintered bauxite.
- In certain embodiments, a proppant delivery system, such as a system described in detail above, may be deployed into a wellbore. In such an embodiment, the expandable proppant may be disposed within the proppant delivery system. The proppant delivery system may include various components, such as one or more expandable injectors, one or more perforation charges, and one or more motive means, such as wheels and/or tracks or multi-stage fracturing system.
- When the proppant delivery system reaches an area within the well that is to be produced, the proppant delivery system may be actuated. Actuation may include expanding an expandable injector into contact with the formation. in certain embodiments, the force of the expansion may be sufficient to create the fracture in the downhole formation. In other embodiments a perforation charge may be detonated either before or after the expandable injector is expanded.
- Before, during, or after actuation of the expandable injector, one or more expandable proppants may be released into the well. In one embodiment, the expandable injector and/or perforation fracture the downhole formation and then the expandable proppants are released into the fracture. The expandable proppants may expand in various ways including continuing to expand until they are in contact with the formation and cannot expand any further. In such a case, the expandable proppants may expand to different external diameters, so as to hold open larger sections of the fractures, while also holding open smaller sections of the fractures. In order to cause the expandable proppants to expand, fluids, including chemical laden fluids may be released into the fractures. The fluids may then dissolve an outer layer of the expandable proppants, thereby allowing the components of the expandable proppants to expand outwardly. In other embodiments, expansion of the expandable proppants may be caused at least in part by a force applied to the expandable proppants. Examples of forces that may cause the expandable proppants to expand include, for example, hydraulic, pneumatic, explosive, or mechanical forces. The applied forces may then allow the expandable proppants to expand into contact with the downhole formation.
- In certain embodiments, the applied forces, fluids, and/or chemical laden fluids may further be used to open apertures in the expandable injector. For example, the expandable injector may include a number of apertures with plugs inserted therein. The plugs may then be removed from the expandable injector due to dissolving in a fluid or the plugs may be forced out of the apertures by one or more of the forces discussed above.
- After the expandable proppants are expanded within the fractures, hydrocarbons may be flowed from the downhole formation to the surface. Depending on the specifications of the well, the hydrocarbons may flow through the expandable injector, through the body of the proppant delivery system, and/or through one or more tubulars in fluid communication between the fractures and the surface of the well.
- In certain embodiments, it may be desirable to remove the proppant delivery system from the wellbore before or after the production of hydrocarbons. In such an embodiment, an upward and/or downward force may be applied to the proppant delivery system, thereby separating the body of the proppant delivery system from the expandable injector. In order to separate the body of the proppant delivery system from the expandable injector, the applied force may shear one or more shear pins or other frangible component connecting the body to the expandable injector. After separating the body from the expandable injector, the body and any components connected thereto may be removed from the well by pulling the body upwardly. The expandable injector may thus remain in the well to further hold open the fractures, thereby increasing hydrocarbon production.
- Advantageously, embodiments of the present disclosure may provide for increased hydrocarbon production from fractured wells. Because the fractures may he held open to greater widths hydrocarbon flow may be increased, thereby increasing the productivity of the well.
- Advantageously, embodiments of the present disclosure may also provide expandable proppants that may expand outwardly to a size at least ten percent greater in an open position than in a closed position. In a closed position, the expandable proppant may have a diameter than is at least 10 percent smaller than when the expandable proppant is in a closed position. In another embodiment, the expandable proppant may have a diameter that is between 20 and 50 percent smaller than when the expandable proppant is in an open position. In other embodiments, the expandable proppant in a closed position may have a diameter that is between 50 and 100 percent smaller than when the expandable proppant is in an open position. In still another embodiment, the expandable proppant in a closed position may have a diameter that is more than 100 percent smaller than when the expandable proppant is in a closed position.
- Advantageously, embodiments of the present disclosure may also provide a proppant delivery system that may be used to deliver and deploy expandable proppants within fractures of the wellbore.
- Advantageously, embodiments of the present disclosure may also provide an expandable proppant having an expandable outer shell layer that is configured to expand outwardly to a size between 10% and 100% greater in an open position than in a closed position.
- Advantageously, embodiments of the present disclosure may also provide an expandable proppant having treating agents disposed within the proppant, such as within the expandable outer shell, or in a portion of the proppant inside the expandable outer shell. Treating agents may include chemical compositions configured to remove or inhibit scale, paraffin, asphaltenes, corrosion, and/or prevent wellbore plugging, as well as be used to plug portion of a well or divert flow within a well. Additionally, the treating agents may be applied to a portion of the expandable proppant, absorbed within a portion of the expandable proppant, desorbed within a portion of the expandable proppant
- Advantageously, embodiments of the present disclosure may also provide a proppant delivery system that is disposed in or is part of a multi-stage system. The multi-stage system may be a fracturing or perforating system that may include, for example, one or more packers, running tools, and other components used to isolate sections of a well, deploy tools within a well, fracture a well, perforate a well, or otherwise allow production of a well.
- Advantageously, embodiments of the present disclosure may also provide an expandable proppant having one or more additional expandable proppants disposed therein. Thus, in certain embodiments, a relatively larger expandable proppant having one or more smaller expandable proppants disposed therein may be deployed in a well such that after the relatively larger expandable proppant is expanded, one or more of the smaller expandable proppants disposed therein may be expanded. The expansion of the relatively larger expandable proppant and the smaller expandable proppants may be activated by the same or different activation triggers.
- While the present invention has been described with respect to the above-noted embodiments, those skilled in the art, having the benefit of this disclosure, will recognize that other embodiments may be devised that are within the scope of the invention as disclosed herein. Accordingly, the scope of the invention should be limited only by the appended claims.
Claims (20)
1. A proppant delivery system comprising:
a tool body;
an expandable injector disposed on the side of the tool body;
an expandable proppant disposed within the tool body; and
a perforation charge.
2. The proppant delivery system of claim 1 , wherein the expandable proppant comprises an expandable outer shell layer and wherein the expandable outer shell layer is configured to expand outwardly to a size at least 10% greater in an open position than in a closed position.
3. The proppant delivery system of claim 1 , wherein the perforation charge is disposed on the expandable injector.
4. The proppant delivery system of claim 1 , wherein the proppant delivery system is disposed on a multi-stage system.
5. The proppant delivery system of claim 1 , wherein the expandable injector is configured to expand telescopically.
6. The proppant delivery system of claim 5 , wherein the expandable injector comprises a locking mechanism configured to lock the expandable injector in an open position.
7. The proppant delivery system of claim 5 , further comprising at least one shear pin disposed between the tool body and the expandable injector.
8. A method of increasing hydrocarbon production, the method comprising:
fracturing downhole formation;
disposing an expandable proppant into the downhole formation;
expanding the expandable proppant into contact with the downhole formation; and
holding open the downhole formation with the expandable proppant.
9. The method of claim 8 , further comprising detonating a perforation charge.
10. The method of claim 8 , further comprising flowing proppants into the downhole formation.
11. The method of claim 8 , wherein the expandable proppant expands outwardly to a size at least 10% greater in an open position than in a closed position.
12. The method of claim 11 , further comprising deploying a proppant delivery system into a wellbore, wherein the expandable proppant is disposed within the proppant delivery system.
13. The method of claim 8 , wherein the expandable proppant is configured to expand outwardly to a size between 10% and 100% greater in an open position than in a closed position.
14. The method of claim 8 , wherein the expandable proppant is configured to expand outwardly to a size more than 100% greater in an open position than in a closed position.
15. The method of claim 8 , wherein in a closed position the expandable proppant has an external diameter between 0.25 cm and 3.0 cm.
16. The method of claim 8 , further comprising moving a second proppant disposed within the expandable proppant from within the expandable proppant into contact with the downhole formation.
17. The method of claim 16 , wherein in a closed position at least one of the expandable proppant and the second proppant has an external diameter between 0.075 cm and 1.5 cm.
18. The method of claim 16 , wherein in a closed position at least one of the expandable proppant and the second proppant has an external diameter between 1.0 cm and 3.0 cm.
19. A proppant delivery system comprising:
a tool body;
an expandable injector disposed on the side of the tool body;
an expandable proppant disposed within the tool body, wherein the expandable proppant comprises an expandable outer shell layer, wherein the expandable outer shell layer is configured to expand outwardly to a size at least 10% greater in an open position than in a. closed position; and
a perforation charge.
20. The proppant delivery system of claim 19 , wherein the perforation charge is disposed on the expandable injector.
Priority Applications (1)
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US15/601,416 US20170253792A1 (en) | 2014-11-04 | 2017-05-22 | Proppant and proppant delivery system |
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US201462075064P | 2014-11-04 | 2014-11-04 | |
US14/636,671 US9657219B2 (en) | 2014-11-04 | 2015-03-03 | Proppant and proppant delivery system |
US15/601,416 US20170253792A1 (en) | 2014-11-04 | 2017-05-22 | Proppant and proppant delivery system |
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---|---|---|---|---|
CN111876143A (en) * | 2020-07-20 | 2020-11-03 | 中国石油大学(北京) | Proppant and application thereof |
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US10005953B2 (en) * | 2014-11-05 | 2018-06-26 | Board Of Supervisors Of Louisiana State University And Agricultural And Mechanical College | Shape memory polymer proppants, methods of making shape memory polymer proppants for application in hydraulic fracturing treatments |
US10315850B2 (en) * | 2017-07-13 | 2019-06-11 | 1875452 Alberta Ltd. | Proppant conveyor systems and methods of use |
US10422209B2 (en) * | 2018-01-09 | 2019-09-24 | Saudi Arabian Oil Company | Magnetic proppants for enhanced fracturing |
US10752828B2 (en) * | 2018-07-20 | 2020-08-25 | Saudi Arabian Oil Company | Processes for fracturing using shape memory alloys |
US10724327B1 (en) * | 2019-09-05 | 2020-07-28 | Saudi Arabian Oil Company | Sphere-shaped lost circulation material (LCM) having hooks and latches |
WO2021113056A1 (en) * | 2019-12-06 | 2021-06-10 | Saudi Arabian Oil Company | Methods and materials for reducing lost circulation in a wellbore |
CN114922604B (en) * | 2022-06-22 | 2023-05-30 | 西南石油大学 | Prediction method for stacking and laying morphology of propping agent in fracture |
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EP3215585A1 (en) | 2017-09-13 |
US9657219B2 (en) | 2017-05-23 |
EP3215585A4 (en) | 2018-05-09 |
BR112017009327A2 (en) | 2017-12-19 |
US20160122631A1 (en) | 2016-05-05 |
WO2016073540A1 (en) | 2016-05-12 |
MX2017005768A (en) | 2018-02-19 |
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