BR112021020954B1 - CANNON, CANNONING, AND, METHOD - Google Patents

Abstract

PERFORMANCE CANNON. A perforation cannon and method by which a perforation charge of the perforation cannon is detonated. Detonating the perforation charge produces shock waves. In some embodiments, detonating the perforation charge also perforates a wellbore proximate to an underground formation. After detonating the perforation charge, the first and second components of a binary energetic of the perforation cannon are fragmented by the shock waves, mixed by the shock waves, and activated by the shock waves to increase an internal energy of the perforation cannon. In some embodiments, increasing the internal energy of the perforation cannon after detonating the perforation charge delays and/or decreases pressure extraction from the wellbore.

Description

Cross Reference to Related Request

[001] This application claims the benefit of the filing date and priority of U.S. Patent Application 62/861,192, filed June 13, 2019, the full disclosure of which is incorporated herein by reference.

[002] This application also claims the benefit of the filing date and priority of U.S. Patent Application No. 16/524,956 filed July 29, 2019 with Attorney File No. 7523.2059US01, the full disclosure of which is incorporated herein by reference.

Technical Field

[003] The present application relates generally to perforating wellbore holes and, more particularly, to perforating guns including reactive components that provide an additional energy source to reduce wellbore extraction after detonating perforating charges.

Fundamentals

[004] Wellbores are typically drilled using a drill string with a drill bit attached to the lower free end and then completed by positioning a casing string into the wellbore and cementing the casing string in place. Casing increases the integrity of the wellbore, but requires perforation to provide a flow path between the surface and selected subsurface formation(s) for the injection of treatment chemicals into the surrounding formation(s) to stimulate production, to receive hydrocarbon flow from the formation(s), and to allow the introduction of fluids for reservoir management or disposal purposes.

[005] Perforation has conventionally been accomplished by lowering a perforation gun on a carrier down the casing string. Once a desired depth is reached through the formation of interest and the gun is secured, it is fired. The gun may have one or many charges in it which are detonated using a firing control, which may be activated from the surface via wireline or by hydraulic or mechanical means. Once activated, each charge is detonated to perforate (penetrate) the casing, the cement and, up to a short distance, the formation. This establishes the desired fluid communication between the interior of the casing and the formation.

[006] Typical hollow charge carrier perforation guns used in service operations to perforate a formation generally include an elongated tubular outer housing in the form of a carrier tube within which is received an elongated tubular frame in the form of a charge tube. Explosive perforation charges are mounted in the charge tube and are ballistically connected via explosive detonation cord. In some cases, the charge tube may be located relative to the carrier tube to align the shaped perforation charges with thin sections of the carrier tube. In many cases, such perforation guns are not capable of effectively perforating a well with high pore pressures using a low shot density perforation gun. For example, such wells may need to be perforated in a completion scheme that does not necessarily require high flow area, but does require a certain threshold of connectivity between the wellbore and the formation.

[007] Due to a combination of factors, after the perforation charges are detonated, the wellbore is typically in a much higher energy state compared to the internal volume of the perforation gun. Such factors may include, but are not limited to, high wellbore pressure, low shot density, a low amount of internal volume fill for the perforation gun, and/or high temperature explosives. The result of this scenario is a perforation event that causes a significant inrush of wellbore fluid into the perforation gun, resulting in a large transient reduction in wellbore pressure; if the wellbore pressure drops to a value below the reservoir pore fluid pressure, this condition is termed dynamic underbalance. An excessive amount of dynamic underbalance can result in sand inrush or tunnel collapse. To reduce overextraction within the wellbore, an additional energy source contained within the perforation gun is desirable.

Brief Description of the Drawings

[008] Figure 1 is a schematic illustration of an offshore oil and gas platform operably coupled to a subsurface well perforation system, in accordance with one or more embodiments of the present disclosure.

[009] Figure 2 is an enlarged elevational view of a well perforating gun of the well perforating system of Figure 1, in accordance with one or more embodiments of the present disclosure.

[0010] Figure 3A is a cross-sectional view of the perforation gun of Figure 2, according to one or more embodiments of the present disclosure. Figure 3B is a cross-sectional view of the perforation gun of Figure 3A, said perforation gun including a charging tube and a filling body positioned within the charging tube, said filling body being divided into divider segments, according to one or more embodiments of the present disclosure. Figure 3C is a cross-sectional view similar to that shown in Figure 3B, except that the perforation gun is shown in a detonated state, according to one or more embodiments of the present disclosure. Figure 3D is a cross-sectional view similar to that shown in Figure 3A, except that the perforation gun is shown in a detonated state, according to one or more embodiments of the present disclosure. Figure 3E is a cross-sectional view similar to that shown in Figure 3B, except that at least some of the divider segments of the filling body are subdivided into smaller divider segments, in accordance with one or more embodiments of the present disclosure. Figure 4A is a cross-sectional view of the perforation barrel of Figure 2, said perforation barrel including a charging tube and a filling body positioned within the charging tube, said filling body being divided into divider segments, in accordance with one or more embodiments of the present disclosure. Figure 4B is a cross-sectional view similar to that shown in Figure 4A, except that at least some of the divider segments of the filling body are subdivided into smaller divider segments, in accordance with one or more embodiments of the present disclosure. Figure 5A is a perspective view of the perforation barrel of Figure 2, said perforation barrel including a charging tube, a carrier tube, and a filling body positioned between the charging tube and the carrier tube, said carrier tube ... filler being divided into divider segments, according to one or more embodiments of the present disclosure. Figure 5B is a perspective view similar to that shown in Figure 4A, except that at least some of the divider segments of the filler body are subdivided into smaller divider segments, according to one or more embodiments of the present disclosure. Figure 5C is an enlarged elevation view of another embodiment of the subdivided divider segments of Figure 5B, in which the gaps between the subdivided divider segments extend in an angular orientation with respect to the longitudinal axis of the perforation barrel, according to one or more embodiments of the present disclosure. Figure 5D is an enlarged perspective view of another embodiment in which the divider segments of Figure 5A each include ribs or saw teeth on opposite end portions thereof, according to one or more embodiments of the present disclosure. Figure 5E is an elevation view of the divider segment of Figure 5D, according to one or more embodiments of the present disclosure. Figure 6 is a flow diagram of a method for implementing one or more embodiments of the present disclosure. Detailed Description Referring to Figure 1, in one embodiment, an offshore oil and gas rig is schematically illustrated and generally referred to by the reference numeral 100. In one embodiment, the offshore oil and gas rig 100 includes a semi-submersible platform 105 that is positioned over a submerged oil and gas formation 110 located below a seabed 115. A subsea conduit 120 extends from a deck 125 of the platform 105 to a subsea wellhead facility 130. One or more pressure control devices 135, such as, for example, blowout preventer assemblies (BOPs) and/or other equipment associated with drilling or producing a wellbore, may be provided at the subsea wellhead facility 130 or elsewhere in the system. The platform 105 may also include a hoisting apparatus 140, a derrick 145, a crane 150, a hook 155, and a swivel 160, the components of which are operable together to raise and lower a transport string 165. The transport string 165 may be, include, or be part of, for example, a casing, a drill string, a completion string, a work string, a pipe joint, coiled tubing, production tubing, other types of pipe or tubing strings, and/or other types of transport strings, such as wire rope, smooth rope, and/or the like. The platform 105 may also include a kelly, a rotary table, a top drive unit, and/or other equipment associated with the rotation and/or translation of the transport string 165. A wellbore 170 extends from the subsea wellhead installation 130 and through the various onshore strata, including the submerged oil and gas formation 110. At least a portion of the wellbore 170 includes a casing 175 secured therein by cement 180 (not visible in Figure 1; shown in Figure 2). The transport string 165 is, includes, or is operatively coupled to a well perforating system 185 installed within the wellbore 170 and adapted to perforate the casing 175, the cement 180, and the wellbore 170 proximate the submerged oil and gas formation 110. Referring to Figure 2, in various embodiments, the well perforating system 185 of Figure 1 includes a perforating gun 190 extending into the wellbore 170, which wellbore is lined with the casing 175 and the cement 180. The perforating gun 190 is operable to form perforations 195 through the casing 175 and the cement 180 such that fluid communication is established between the casing 175 and the submerged oil and gas formation 110 surrounding the wellbore 170. More In particular, the perforation gun 190 includes perforation charges that are detonable to form perforations 195 through the casing 175 and cement 180. In some systems, after the perforation charges are detonated, there may be a reduction in wellbore pressure due to wellbore fluids flowing into the perforation gun (detonated). The perforation gun 190 of the present disclosure addresses this problem by preventing, or at least reducing, the reduction in pressure in the wellbore 170 following detonation of the perforation charges, as described in more detail below. In various embodiments, one or more components of the perforation barrel 190 described herein may be integrated with one or more other components of the perforation barrel 190. Accordingly, other perforation barrels that do not include each and every component of the perforation barrel 190 described herein may nevertheless fall within the scope of the present disclosure. Referring to Figure 3A , in various embodiments, the perforation barrel 190 includes a charging tube 200, a filler body 205 extending within the charging tube 200, and perforation charges 210 extending within and supported by the filler body 205. The charging tube 200 extends within a carrier tube 215. In various embodiments, a debris shield 220 extends between the charging tube 200 and the carrier tube 215. Alternatively, the debris shield 220 may be omitted. In various embodiments, the charge tube 200, the debris shield 220, and/or the carrier tube 215 are coaxial. The carrier tube 215 includes barrel ports, such as, for example, corrugations 225 (i.e., thin-walled recessed areas) that are radially and axially aligned with respective barrel charges 210 (e.g., shaped charges). The charging tube 200 includes barrel ports, such as, for example, openings 230 that are radially and axially aligned with respective barrel charges 210. In various embodiments, the openings 230 in the charging tube 200 are sized and shaped to permit maintenance and/or installation of the barrel charges 210 therethrough when the filler body 205 extends within the charging tube 200. The filler body 205 includes cavities 235 in which respective barrel charges 210 are disposed. An axial passage 240 is formed through the packing body 205 to accommodate a detonation mechanism (not shown) for the perforating charges 210. The debris shield 220 includes gun ports, such as, for example, openings 245 that are radially and axially aligned with the respective perforating charges 210. In various embodiments, the openings 245 of the debris shield 220 are relatively smaller in shape than the corresponding openings 230 of the charge tube 200. As a result, the debris shield 220 prevents, or at least obstructs, fallout and other debris from exiting the perforating gun 190 and collecting in the wellbore 170 (shown in FIGS. 1 and 2 ) during and/or after detonation of the perforating charges 210. Referring to FIG. 3B , in various embodiments, the packing body 205 is divided into divider segments. 250. The divider segments 250 are arranged within the loading tube 200 in a longitudinal stack. More particularly, during assembly of the perforation barrel 190, the charging tube 200 acts as a support structure on which the divider segments 250 are stacked and on which the perforation charges 210 are operably coupled to the detonation mechanism (not shown) extending within the axial passage 240. The divider segments 250 each include opposing end portions 255a and 255b and an outer surface 260 extending between the opposing end portions 255a and 255b. Concavities 265 are formed in the end portion 255a and through the outer surface 260. For example, three (3) of the concavities 265 may be formed in the end portion 255a and spaced circumferentially by 120 degrees. In other instances, one (1), two (2), four (4) or more of the concavities 265 may be formed in the end portion 255a. The concavities 265 are sized and shaped (e.g., in a semi-cylindrical, semi-conical or similar shape) to accommodate the respective first portions of the perforation charges 210. Likewise, concavities 270 are formed in the end portion 255b and across the outer surface 260. For example, three (3) of the concavities 270 may be formed in the end portion 255b and spaced circumferentially by 120 degrees. In other instances, one (1), two (2), four (4) or more of the concavities 270 may be formed in the end portion 255b. The concavities 270 are sized and shaped (e.g., in a semi-cylindrical, semi-conical, or the like shape) to accommodate respective second portions of the perforation charges 210. In various embodiments, as in Figure 3B, the concavities 265 in the end portion 255a are circumferentially offset from (e.g., by 60 degrees) and interposed between the concavities 270 in the end portion 255b. The perforation charges 210 are supported between adjacent segments of the divider segments 250. More particularly, the divider segments 250 are arranged such that respective concavities 265 and 270 in adjacent segments of the divider segments 250 are aligned to form sockets 235 in the filler body 205. As shown in Figure 3B, the sockets 235 and thus the perforation charges perforation charges 210, may be spaced longitudinally along the charge tube 200. For example, the perforation charges 210 may extend helically along the charge tube 200. In various embodiments, the perforation charges 210 each include a charge case 275, an energetic compound 280, a liner 285 defining a bell-shaped void 290 pointing toward a blasting end of the perforation charge 210, and an energetic booster 295. The energetic boosters 295 are each operably coupled to the detonation mechanism (not shown) extending within the axial passage 240 to facilitate detonation of the perforation charges 210. An outer flange 300 may be formed on the charge case 275 at the blasting end of each of the perforation charges 210. In various embodiments, adjacent segments of the segments Dividers 250 support the perforation charges 210 on respective outer flanges 300 thereof. In various embodiments, adjacent segments of divider segments 250 are spaced by gaps 305. For example, gaps 305 may ensure that divider segments 250 do not come into direct contact with each other prior to detonation of the perforation charges 210. For another example, gaps 305 may allow room for controlled expansion of each outer charge case 275 of perforation charge 210. For yet another example, gaps 305 may allow room for collection and recombination of debris and scatter material during and/or after detonation of the perforation charges 210. Although gaps 305 are shown in Figure 3B extending in a perpendicular orientation with respect to a longitudinal axis of perforation barrel 190, gaps 305 may instead extend in a perpendicular orientation angular (e.g., acute and/or obtuse) with respect to the longitudinal axis of the perforation cannon 190. The charging tube 200 may also include openings 310 opposite the openings 230, which openings are aligned with the clearances 305 to provide additional volume for reconsolidation of scatter material and other material during and/or after detonation of the perforation charges 210. Additionally, at least respective portions of the charging cases 275 may be spaced from the divider segments 250 by clearances 315. The clearances 315 allow room for controlled expansion of the charging cases 275 and collection and recombination of debris and scatter material during and/or after detonation of the perforation charges 210. Referring to Figures 3C and 3D, in various embodiments, a series of perforation charges 210 may be detonated to form perforations 195 through the casing 175 and cement 180 such that fluid communication is established between casing 175 and submerged oil and gas formation 110 surrounding wellbore 170. After perforation charges 210 have been detonated, as indicated by reference numerals 210', debris and scatter collect and recombine in clearances 305, openings 310, and/or clearances 315, as indicated by reference numerals 305', 310', and 315'. Specifically, detonation of perforation charges 210 causes a shock wave to travel between adjacent segments of divider segments 250. Propagation of this wave across the free surfaces of divider segments 250 creates a tensile wave at the boundaries of said divider segments 250. Simultaneously, a compression wave is reflected back. Both the forward transmitted wave and the reflected wave are lower in magnitude than the initial shock wave. The tensile wave acting on the free surfaces of the divider segments 250 may pull away material as it moves through the gap 305, thereby producing scatter. Additionally, or instead, the divider segments 250 may be broken into debris and scattered in other ways upon detonation of the perforation charges 210. The charge tube 200 and debris shield 220 retain debris and scatter within the perforation barrel 190. Due to a combination of factors including, but not limited to, high wellbore pressures, low shot density, a low amount of internal volume fill, and/or high temperature energetics, the wellbore 170 may be in a much higher energy state than the internal volume of the perforating gun 190 following detonation of the perforating charges 210. In view of such factors, the execution of a perforating event may create a high dynamic underbalance resulting in possible sand ingress or tunnel collapse at or near the wellbore 170. Accordingly, to combat such overdrafting within the wellbore 170, an additional energy source contained within the perforating gun 190 is desirable. The well perforating system 185 of the present disclosure aims to provide such an additional energy source. Specifically, in various embodiments, adjacent components of the perforation gun 190 together form a two-component or binary energetic, including first and second components, neither of which is energetic by itself, but which must be mixed together in order to become energetic. Such a binary energetic provides a way to control internal energy (e.g., pressure transients) of the perforation gun 190, especially in cases in which the perforation gun 190 itself (i.e., the perforation charges 210) has low internal energy due to low shot densities (low energetic density per free volume) or low energetic output (high temperature energetic). Furthermore, the added binary materials are essentially inert (non-energetic) binary materials that are capable of adding internal energy to the perforation gun without changing the carriage rating of the loaded perforation gun. The added binary materials allow the well perforation system 185 to effectively perforate a well with high pore pressures, even if the perforation gun 190 has a low shot density or low energetic output. Accordingly, the well perforation system 185 may be valuable in a completion scheme that does not necessarily require a high flow area, but does require a certain threshold level of connectivity between the wellbore 170 and the submerged oil and gas formation 110 (e.g., via deep penetration or "DP" charges). In various embodiments, the cuttings shield 220, the charge pipe 200, at least one of the charge casings 275, and/or at least one of the divider segments 250 may be, include, or be part of the first component of the binary energetic. For example, the first binary energetic component may be provided via a coating on the debris shield 220, the cargo tube 200, the at least one of the cargo boxes 275, and/or the at least one of the divider segments 250. For another example, the first binary energetic component may be or include a thin pellet provided adjacent to the debris shield 220, the cargo tube 200, the at least one of the cargo boxes 275, and/or the at least one of the divider segments 250. In various embodiments, the debris shield 220, the cargo tube 200, the at least one of the cargo boxes 175, and/or the at least one of the divider segments 250 may be, include, or be part of the second binary energetic component. For example, the second component of the binary energetic may be provided via a coating on the debris shield 220, the charging tube 200, the at least one of the charging boxes 275, and/or the at least one of the divider segments 250. For another example, the second component of the binary energetic may be or include a thin pellet provided adjacent the debris shield 220, the charging tube 200, the at least one of the charging boxes 275, and/or the at least one of the divider segments 250. In various embodiments, the first and second components of the binary energetic are configured to react in an Oxidation-Reduction reaction. For example, one of the first and second components of the binary energetic may be Iron II Oxide (Fe2O3) and the other of the first and second components of the binary energetic may be Aluminum (Al) or Magnesium (Mg). For another example, one of the first and second components of the binary energetic might be Iron II, III Oxide (Fe3O4) and the other of the first and second components of the binary energetic might be Aluminum (Al) or Magnesium (Mg). For still another example, one of the first and second components of the binary energetic might be Copper II Oxide (CuO) and the other of the first and second components of the binary energetic might be Aluminum (Al) or Magnesium (Mg). For still another example, one of the first and second components of the binary energetic might be Manganese Dioxide (MnO2) and the other of the first and second components of the binary energetic might be Aluminum (Al) or Magnesium (Mg). For still another example, one of the first and second components of the binary energetic might be Manganese III Oxide (MnO3) and the other of the first and second components of the binary energetic might be Aluminum (Al) or Magnesium (Mg). For yet another example, one of the first and second components of the binary energetic might be Molybdenum VI Oxide (MoO3) and the other of the first and second components of the binary energetic might be Aluminum (Al) or Magnesium (Mg). For yet another example, one of the first and second components of the binary energetic might be Aluminum Tantalum and the other of the first and second components of the binary energetic might be Aluminum (Al) or Magnesium (Mg). For yet another example, one of the first and second components of the binary energetic might be Bismuth III Oxide (Bi2O3) and the other of the first and second components of the binary energetic might be Aluminum (Al) or Magnesium (Mg). In operation, after the perforation charges 210 explode to perforate the wellbore 170 proximate to the submerged oil and gas formation 110, the shock-induced mixing and activation of the first and second components of the binary energetic prevents, or at least reduces, a reduction in pressure in the wellbore 170 due to fluids in the wellbore 170 flowing into the perforation perforation 190. More particularly, after the well perforation system 185 is detonated, energetically driven shock waves from the detonation of the perforation charges 210 create ejecta (e.g., through scattering) of internal components of the perforation gun 190, said internal components including at least the first and second components of the binary energetic. The ejecta of the first and second components of the binary energetic are mixed by the shock waves. Furthermore, a reaction between the first and second mixed components of the binary energetic is initiated by the shock waves, which reaction releases enthalpy through the interaction of the newly formed highly energized binary mixture. More particularly, the reaction between the first and second mixed components of the binary energetic releases enthalpy in the form of heat, vaporization, or a combination thereof. For example, copper(II) oxide (CuO) rapidly evolves in an intermetallic reaction, and when a subsequent Cu-Cu bond is broken, it is released as a monatomic gas (Cu). As a result, the binary mixing reduces the mismatch in energy states between the internal volume of the perforation gun 190 and the wellbore 170, providing additional internal energy to the perforation gun 190. Furthermore, reacted products and unused reactants may occupy a substantial remaining volume within the perforation gun 190, thereby acting as gun filler. In various embodiments, at least the clearances 305, the openings 310, and/or the clearances 315 serve as a reaction vessel in which the ejecta of the first and second components of the binary energetic is collected and reconsolidated, as indicated by reference numerals 305', 310', and 315' in FIGS. 3C and 3D. Specifically, when the gaps 305, the openings 310, and/or the gaps 315 are filled with the ejecta of the first and second binary energetic components, the first and second binary energetic components are capable of reacting with each other in a highly confined manner, such that the void volume acts as a small reaction vessel that confines (or nearly confines) the reaction of the first and second components. Referring to Figure 3E, with continued reference to Figure 3B, in various embodiments, one or more of the divider segments 250 may be subdivided into divider segments 250'. At least one of the divider segments 250' may be, include, or be part of the first binary energetic component. For example, the first binary energetic component may be provided via a coating on the at least one of the divider segments 250'. For another example, the first binary energetic component may be or include a thin wafer provided adjacent to the at least one of the divider segments 250'. Additionally, or instead, at least one of the divider segments 250' may be, include, or be part of the second binary energetic component. For example, the second binary energetic component may be provided through a coating on the at least one of the divider segments 250'. For another example, the second binary energetic component may be or include a thin wafer provided adjacent to the at least one of the divider segments 250'. Upon detonation of the perforation charges 210, the divider segments 250' may be divided into cuttings and dispersions in a manner substantially similar to the manner in which the divider segments 250 are divided into cuttings and dispersions upon detonation of the perforation charges 210. However, due to their thickness and/or overall geometry, the divider segments 250' may produce a more complete mass of reactants for the mixing and shock-induced activation of the first and second components of the binary energetics compared to the divider segments 250. An axial thickness and/or overall geometry of the divider segments 250' may be varied, depending on the specific needs of the wellbore 170. By varying the thickness and/or overall geometry of the divider segments 250', the volume of the clearances 305 and/or the clearances 315 may be controlled, thereby allowing an operator to easily select an overall desired free volume of the perforation gun 190. As As a result, the free volume of the perforation cannon 190 can be varied with fine resolution along a sliding scale from a minimum free volume to a maximum free volume. To promote the creation of debris and scattering, the divider segments 250' can be formed from a longitudinal stack of disks or plates, a coaxial arrangement of sleeves, another suitable arrangement, or any combination thereof. Referring to Figure 4A, in various embodiments, the divider segments 250 can be replaced by divider segments 320. At least one of the divider segments 320 can be, include, or be part of the first component of the binary energetic. For example, the first component of the binary energetic can be provided through a coating on the at least one of the divider segments 320. For another example, the first component of the binary energetic can be or include a thin wafer provided adjacent to the at least one of the divider segments 320. Additionally, or instead, at least one of the divider segments 320 can be, include, or be part of the second component of the binary energetic. For example, the second component of the binary energetic may be provided through a coating on at least one of the divider segments 320. For another example, the second component of the binary energetic may be or include a thin pellet provided adjacent to at least one of the divider segments 320. Upon detonation of the perforation charges 210, the divider segments 320 may be divided into debris and scatter in a manner substantially similar to the manner in which the divider segments 250 are divided into debris and scatter upon detonation of the perforation charges 210. Additionally, the divider segments 320 are similar to the divider segments 250 except that: three (3) of the concavities 265 are replaced by one (1) concavity 325 at the end portion 255a; three (3) of the concavities 270 are replaced by one (1) concavity 330 at the end portion 255b; adjacent concavities of concavities 325 and 330 together form sockets 235; openings 230 of charging tube 200, openings 245 of debris shield 220, and corrugations 225 of carrier tube 215 are repositioned to be radially and axially aligned with perforation charges 210 supported within sockets 235 formed by cavities 325 and 330; and axial passage 240 is replaced by an external groove (not shown) formed around filler body 325 (e.g., helically) to accommodate the detonation mechanism (not shown). The sockets 235 (and thus the perforation charges 210) may be arranged helically along the charge tube 200. For example, the divider segments 320 may be rotated 60 degrees per segment along the charge tube 200. Referring to Figure 4B, with continued reference to Figure 4A, in various embodiments, one or more of the divider segments 320 may be subdivided into divider segments 320'. At least one of the divider segments 320' may be, include, or be part of the first component of the binary energetic. For example, the first component of the binary energetic may be provided through a coating on the at least one of the divider segments 320'. For another example, the first component of the binary energetic may be or include a thin wafer provided adjacent to the at least one of the divider segments 320'. Additionally, or instead, at least one of the divider segments 320' may be, include, or be part of the second component of the binary energetic. For example, the second component of the binary energetic may be provided via a coating on the at least one of the divider segments 320'. For another example, the second component of the binary energetic may be or include a thin pellet provided adjacent to the at least one of the divider segments 320'. Upon detonation of the perforation charges 210, the divider segments 320' may be divided into debris and dispersions in a manner substantially similar to the manner in which the divider segments 320 are divided into debris and dispersions upon detonation of the perforation charges 210. However, due to their thickness and/or overall geometry, the divider segments 320' may produce a more complete mass of reactants for the mixing and shock-induced activation of the first and second components of the binary energetic (as compared to the divider segments 320). An axial thickness and/or overall geometry of the divider segments 320' can be varied, depending on the specific wellbore needs. By varying the thickness and/or overall geometry of the divider segments 320', the volume of the clearances 305 and/or the clearances 315 can be controlled, thereby allowing an operator to easily select an overall desired free volume of the perforating gun 190. As a result, the free volume of the perforating gun 190 can be varied with fine resolution from a minimum free volume to a maximum free volume. To promote creation of dispersions, the divider segments 320' may be formed from a longitudinal stack of discs or plates, a coaxial arrangement of sleeves, another suitable arrangement, or any combination thereof. Referring to Figure 5A, in various embodiments, a filler body 335 is positioned (e.g., annularly) between the conveyor tube 215 and the loading tube 200, said filler body 335 being divided into divider segments 340. At least one of the divider segments 340 may be, include, or be part of the first component of the binary energetic. For example, the first component of the binary energetic may be provided through a coating on the at least one of the divider segments 340. For another example, the first component of the binary energetic may be or include a thin pellet provided adjacent to the at least one of the divider segments 340. Additionally, or instead, at least one of the divider segments 340 may be, include, or be part of the second component of the binary energetic. For example, the second binary energetic component may be provided through a coating on at least one of the divider segments 340. For another example, the second binary energetic component may be or include a thin pellet provided adjacent to at least one of the divider segments 340. Upon detonation of the perforation charges 210, the divider segments 340 may be divided into debris and dispersions in a manner substantially similar to the manner in which the divider segments 250 are divided into debris and dispersions upon detonation of the perforation charges 210. Additionally, adjacent segments of the divider segments 340 may be shaped to cooperate with one another to form recesses 345 (e.g., cutouts). In this regard, in various embodiments, the divider segments 340 each overlap adjacent loads of the perforation charges 210. For example, each of the divider segments 340 may be disposed axially along the charge tube 200 between successive loads of the perforation charges 210. Accordingly, each of the divider segments 340 may include partial recesses 350 and 355 formed at respective opposite end portions 360a and 360b thereof. As a result, the partial recesses 350 and 355 of adjacent segments of divider segments 340 together comprise one of the recesses 345 over a corresponding load of perforation charges 210. While adjacent segments of divider segments 340 may abut one another, in various embodiments, gaps 365 are instead formed between adjacent segments of divider segments 340. The gaps 365 are variable in size by adjusting the respective lengths of divider segments 340. In this regard, divider segments 340 may be produced with different lengths to vary the free gun volume available outside of charge tube 200, resulting in a highly adjustable free gun volume. Upon detonation of perforation charges 210, the gaps 365 may collect and reconsolidate debris and scatter in a manner similar to the manner in which the gaps 305 collect and reconsolidate debris and scatter, as discussed above. In various embodiments, clearances 365 serve as a reaction vessel in which ejecta from the first and second components of the binary energetic are collected and reconsolidated. Specifically, when the gaps 365 are filled with the ejecta of the first and second binary energetic components, the first and second binary energetic components are able to react with each other in a highly confined manner, such that the void volume acts as a small reaction vessel confining (or nearly confining) the reaction of the first and second components. In addition to the recesses 345, one or more of the divider segments 340 may include a groove 370 formed therein to allow the detonation cord to extend through the packing body 335. In various embodiments, the groove 370 may be helical along the length of the packing body 335 from one end of the packing body 335 to the other, such that when a plurality of the divider segments 340 are positioned adjacent to each other, a helical path for a detonation cord (not shown) is formed along a portion of the length of the perforating barrel. 190. Referring to Figure 5B, with continued reference to Figure 5A, in various embodiments, one or more of the divider segments 340 may be subdivided into divider segments 340'. At least one of the divider segments 340' may be, include, or be part of the first component of the binary energetic. For example, the first component of the binary energetic may be provided via a coating on at least one of the divider segments 340'. For another example, the first component of the binary energetic may be or include a thin wafer provided adjacent to the at least one segment of the divider segments 340'. Additionally, or instead, at least one of the divider segments 340' may be, include, or be part of the second component of the binary energetic. For example, the second component of the binary energetic may be provided via a coating on at least one of the divider segments 340'. For another example, the second component of the binary energetic may be or include a thin wafer provided adjacent to at least one of the divider segments 340'. Upon detonation of the perforation charges 210, the divider segments 340 may be divided into cuttings and dispersions in a manner substantially similar to the manner in which the divider segments 340 are divided into cuttings and dispersions upon detonation of the perforation charges 210. However, due to their thickness and/or overall geometry, the divider segments 340' may produce a more complete mass of reactants for the mixing and shock-induced activation of the first and second components of the binary energetic (compared to the divider segments 340). An axial thickness and/or overall geometry of the divider segments 340' may be varied, depending on the specific wellbore requirements. By varying the thickness and/or overall geometry of the divider segments 340', the volume of the gaps 365 and/or the clearances 365 can be controlled, thereby allowing an operator to easily select an overall desired free volume of the perforation barrel 190. As a result, the free volume of the perforation barrel 190 can be varied with fine resolution from a minimum free volume to a maximum free volume. Referring to Figure 5C, in various embodiments, rather than extending in a perpendicular orientation with respect to a longitudinal axis of the perforation barrel 190, as shown in Figures 5A and 5B, the gaps 365 can instead extend in an angular (e.g., acute and/or obtuse) orientation with respect to the longitudinal axis of the perforation barrel 190. Referring to Figures 5D and 5E, in various embodiments, each of the divider segments 340 can include ribs or saw teeth 375 formed at respective opposite end portions 360a and 360b thereof. The saw teeth 375 create microjets to promote the creation of dispersions of the divider segments 340 upon detonation of the perforation charges 210. More particularly, the saw teeth 375 provide additional surface area on the free surfaces of the divider segments 340 for the shock wave created by detonation of the perforation charges 210 to act upon. As a result, the saw teeth 375 enhance dispersion and mixing of cuttings and dispersed materials from the divider segments 340. Referring to Figure 6 , in one embodiment, a method of perforating a wellbore while delaying or decreasing extraction is generally referred to by reference numeral 400. The method includes, in a step 402, detonating a perforation charge from a perforation gun to produce shock waves and perforate a wellbore. The perforating charge may comprise a plurality of separate perforating charges. Perforating the wellbore may include perforating: a carrier pipe in which the perforating charge is housed, a wellbore casing, cement around the wellbore casing, and/or an underground formation. Method 400 also includes, in a step 404, fragmenting a first component of a binary energetic using the shock waves produced by performing step 402. Method 400 also includes, in a step 406, fragmenting a second component of the binary energetic using the shock waves produced by performing step 402. In this regard, the first component and/or the second component of the binary energetic include physical components of the cannon blast, which physical components fragment into ejecta in response to the shock waves. The method also includes, in a step 408, mixing the first component and the second component of the binary energetic using the shock waves produced by performing step 402. In this regard, the first and second components of the binary energetic may need to be mixed in order to react properly. In other words, the first and second components may each be inert in isolation, but may form an energetic when mixed together. Finally, the method also includes, in a step 410, activating the mixed binary energetic in the perforation gun using the shock waves produced by performing step 402. The binary material may have a threshold energy level below which it does not explode, but above which it does explode. In this regard, the shock waves produced by performing step 402 may impart a sufficient level of energy to the binary energetic to activate it (e.g., cause it to explode). Notably, steps 404 and 406 may be omitted in some embodiments in which the first and second components of the binary energetic do not require fragmentation as illustrated in Figure 6 with bypass arrow 412. In this regard, the first component and/or the second component may be stored in the perforation gun in a form that does not require fragmentation to facilitate reactive mixing of the first and second components. For example, each of the first component and the second component may be provided in a granular or powdered form. In order to prevent mixing of the first component with the second component prior to detonation of the perforation charge, the first component and the second component may be separated by a wall, membrane, or other feature of the perforation gun (e.g., divider segment) that is cracked, broken, or otherwise damaged by the shock waves when detonation occurs to allow the first and second components to mix. Furthermore, step 406 may be omitted and step 404 may be retained in some embodiments in which one of the first and second components requires fragmentation while the other of the first and second components does not require fragmentation for adequate mixing, as illustrated in Figure 6 by bypass arrow 414. For example, the first component of the binary energetic may be provided in the form of one of the physical components of the perforation gun (e.g., the charge tube or the filler body) and the second component may be provided in a granular or powder form. A perforation gun has been disclosed. The perforating gun generally includes: a perforating charge that is detonable to produce shock waves within the perforating gun; and first and second components of a binary energetic that are mixable and activatable by the shock waves upon detonation of the perforating charge to increase an internal energy of the perforating gun. In other embodiments, the perforating gun generally includes: a plurality of perforating charges configured to perforate a wellbore; a plurality of charge boxes, each charge box housing one of the plurality of perforating charges; a charge tube housing the plurality of charge boxes; a carrier tube housing the charge tube; a packing body comprising a plurality of divider segments aligned longitudinally along a central axis of the perforating gun; a first component of a binary energetic; and a second component of the binary energetic; wherein the first and second components of the binary energetic are mixable and activatable by detonation shock waves of the plurality of perforation charges. The foregoing perforation gun embodiments may include one or more of the following elements, alone or in combination with one another: The perforation charge is further detonable to perforate a wellbore proximate to an underground formation. The perforation gun includes a charging tube in which the perforation charge is mounted. The charging tube comprises the first component and/or the second component of the binary energetic. The perforation gun includes a carrier tube in which the charging tube extends. The carrier tube comprises the first component and/or the second component of the binary energetic. The perforation gun includes a packing body that is subdivided into at least first and second divider segments, wherein the first divider segment comprises the first component of the binary energetic. The second divider segment comprises the second component of the binary energetic. The packing body extends within the charging tube and supports the perforation charge. perforation. The packing body extends within a defined space between the charging tube and the carrier tube. The perforation charges are configured to perforate a wellbore. At least one of the plurality of charging cases, the charging tube, the carrier tube or the packing body comprises the first component of the binary energetic. At least one of the plurality of charging cases, the charging tube, the carrier tube or the packing body comprises the second component of the binary energetic. One of the first and second components of the binary energetic comprises Iron II Oxide (Fe2O3), Iron II, III Oxide (Fe3O4), Copper II Oxide (CuO), Manganese Dioxide (MnO2), Manganese III Oxide (MnO3), Molybdenum VI Oxide (MoO3), Aluminum Tantalum or Bismuth III Oxide (Bi2O3); and the other of the first and second binary energetic components comprises Aluminum (Al) and/or Magnesium (Mg). The packing body is disposed between the carrier tube and the charging tube; a groove extends along an outer surface of the packing body; and a detonating cord is capable of being disposed within the groove to initiate the perforating charges. The packing body is disposed within the charging tube; and each of the divider segments comprises a cavity for housing a portion of one of the plurality of charge cases. A method has also been disclosed. The method generally includes: detonating a perforating charge from a perforating gun to produce shock waves within the perforating gun and perforating a wellbore proximate to an underground formation; and after detonating the perforation charge, using the shock waves to activate a binary energetic in the perforation cannon.The foregoing method embodiment may include one or more of the following elements, either alone or in combination with one another:Detonating the perforation charge perforates a wellbore near an underground formation. The binary energetic comprises first and second components, each comprising a substance that is inert in isolation but reactive when mixed with the other of the first and second components. The method includes, after detonating the perforation charge and prior to activating the binary energetic, utilizing shock waves to mix the first and second components of the binary energetic. The method includes, after detonating the perforation charge and prior to mixing the binary energetic, utilizing shock waves to fragment at least one of the first and second components of the binary energetic. Activating the binary energetic in the perforation gun increases an internal energy of the perforation gun; and the method further comprises utilizing the internal energy to delay and/or decrease pressure extraction within the wellbore. It is understood that variations may be made to the foregoing without departing from the scope of the present disclosure. In various embodiments, the elements and teachings of the various embodiments may be combined in whole or in part in some or all of the embodiments. Furthermore, one or more of the elements and teachings of the various embodiments may be omitted, at least in part, and/or combined, at least in part, with one or more of the other elements and teachings of the various embodiments. Any spatial references, such as, for example, "top", "bottom", "above", "below", "between", "bottom", "vertical", "horizontal", "angled", "up", "down", "side by side", "left to right", "right to left", "top to bottom", "bottom to top", "top", "bottom to top", "top to bottom", etc., are for purposes of illustration only and do not limit the specific orientation or location of the structure described above. In various embodiments, although different steps, processes, and procedures are described as appearing as distinct acts, one or more of the steps, one or more of the processes, and/or one or more of the procedures may also be performed in different orders, simultaneously and/or sequentially. In various embodiments, the steps, processes, and/or procedures may be merged into one or more steps, processes, and/or procedures. In various embodiments, one or more of the operational steps in each embodiment may be omitted. Furthermore, in some cases, some features of the present disclosure may be employed without a corresponding use of the other features. Furthermore, one or more of the embodiments and/or variations described above may be combined in whole or in part with any one or more of the other embodiments and/or variations described above. Although various embodiments have been described in detail above, the embodiments described are illustrative only and are not limiting, and those skilled in the art will readily appreciate that many other modifications, changes, and/or substitutions are possible in the embodiments without departing materially from the novel teachings and advantages of the present disclosure. Accordingly, all such modifications, changes, and/or substitutions are intended to be included within the scope of this disclosure as defined in the following claims. In the claims, any means plus function clauses are intended to cover the structures described herein as performing the recited function and not only structural equivalents, but also equivalent structures. Further, it is the express intent of the applicant not to invoke 35 U.S.C. § 112, paragraph 6 for any limitations on any of the claims herein, except for those in which the claim expressly uses the word "means" together with an associated function.

Claims (10)

1. A perforation cannon (190) comprising: a perforation charge (210) that is detonable to produce shock waves within the perforation cannon (190); and first and second components of a binary energetic positioned within the perforation cannon (190); wherein the perforation cannon (190) is actuable from a first configuration in which: the perforation charge (210) is not detonated; and said first and second components of the binary energetic are separated; to a second configuration in which: the perforation charge (210) is detonated; and said first and second components of the binary energetic are mixed by the shock waves produced from detonation of the perforation charge (210); and a third configuration, in which said first and second mixed binary energetic components are activated in that perforation gun (190) to increase an internal energy of the perforation gun (190). 2. A perforating cannon (190) according to claim 1, further comprising: a charging tube (200) in which the perforating charge (210) is mounted; optionally, wherein said charging tube (200) comprises the first component and the second component of the binary energetic. 3. The perforating cannon (190) of claim 2, further comprising: a conveyor tube (215) into which the loading tube (200) extends; optionally, wherein the conveyor tube (215) comprises the first component and the second component of the binary energetic. 4. The perforating cannon (190) of claim 3, further comprising: a filling body (205) that is subdivided into at least first and second divider segments (320), wherein said first divider segment comprises the first component of the binary energetic; wherein the second divider segment comprises the second component of the binary energetic; wherein the filling body (205) extends within the loading tube (200) and supports the perforating charge (210); and wherein the filling body (205) extends within a space defined between the loading tube (200) and the carrier tube (215). 5. A perforation cannon (190) comprising: a plurality of perforation charges (210); a plurality of charging boxes (275), each of the charging boxes (275) housing one of the plurality of perforation charges (210); a charging tube (200) housing that plurality of charging boxes (275); a conveyor tube (215) housing the charging tube (200); a filling body (205) comprising a plurality of divider segments (320) aligned longitudinally along a central axis of the perforation cannon (190); a first component of a binary energetic; and a second component of the binary energetic; wherein said first and second components of the binary energetic are mixable and activatable by shock waves from detonation of the plurality of perforation charges (210). 6. The perforating cannon (190) of claim 5, wherein at least one of the plurality of charging boxes (275), the charging tube (200), the conveyor tube (215), or the filling body (205) comprises the first component of the binary energetic; wherein at least one of the plurality of charging boxes (275), the charging tube (200), the conveyor tube (215), or the filling body (205) comprises the second component of the binary energetic; wherein: one of the first and second components comprises Iron II Oxide (Fe2O3), Iron II, III Oxide (Fe3O4), Copper II Oxide (CuO), Manganese Dioxide (MnO2), Manganese III Oxide (MnO3), Molybdenum VI Oxide (MoO3), Aluminum Tantalum, or Copper Oxide Bismuth III (Bi2O3); and the other of the first and second components of the binary energy comprises Aluminum (Al) or Magnesium (Mg). 7. The perforating cannon (190) of claim 5, wherein: the filling body (205) is disposed between the carrier tube (215) and the charging tube (200); a groove (370) extends along an outer surface (260) of the filling body (205); and a detonating cord is capable of being disposed within the groove (370) to initiate perforating charges (210); wherein: the filling body (205) is disposed within the charging tube (200); and each of said divider segments (320) comprises a cavity for housing a portion of a box of the plurality of charging boxes (275). 8. A method comprising: detonating a perforation charge (210) from a perforation cannon (190) to produce shock waves within the perforation cannon (190); after detonating the perforation charge (210), mixing, using the shock waves, a binary energetic into the perforation cannon (190); and after mixing the binary energetic into the perforation cannon (190), activating the binary energetic in the perforation cannon (190). 9. The method of claim 8, wherein the binary energetic comprises first and second components, each comprising a substance that is inert in isolation but reactive when mixed with the other of the first and second components; wherein: activating the binary energetic in the perforating gun (190) increases an internal energy of the perforating gun (190); and the method further comprises utilizing the internal energy to retard and decrease pressure extraction within the wellbore. 10. The method of claim 9, further comprising: after detonating the cannon charge (210) and before activating the binary energetic, using the shock waves to mix the first and second components of the binary energetic; and after detonating the cannon charge (210) and before mixing the binary energetic, using the shock waves to fragment at least one of the first and second components of the binary energetic.