The present disclosure relates generally to controlling pressure during perforating operations.
Perforating operations can be performed in a wellbore that has been drilled or otherwise created in a subterranean formation. Perforating operations create some sort of trauma (e.g., explosion, penetration) to the wellbore and penetrate into the subterranean formation. Such perforating operations are used to extract one or more resources (e.g., oil, natural gas, water, steam) from within the subterranean formation into the wellbore. Once in the wellbore, such resources can be extracted. At times, the wellbore is cased with casing pipe, usually made of metal, to prepare the wellbore for extraction of one or more materials from the subterranean formation. In such a case, the perforating operations can penetrate both the casing pipe and the subterranean formation.
In general, in one aspect, the disclosure relates to a method for controlling pressure in a wellbore during a perforating operation. The method can include positioning a perforating tool within the wellbore, where the perforating tool includes a gun and an energetic chamber. The method can also include igniting an energetic within the energetic chamber to generate a propellant. The method can further include igniting at least one charge within the gun, where the at least one charge is ignited toward a wall of the wellbore adjacent to the gun. The method can also include directing the propellant from the energetic chamber into the gun.
In another aspect, the disclosure can generally relate to a perforating tool. The perforating tool can include a gun having at least one charge, where the at least one charge is directed radially away from the gun toward a wall of a wellbore. The perforating tool can also include a cord operatively coupled to the charge and to a first control mechanism, where the first control mechanism initiates the ignition of the at least one charge using the cord. The perforating tool can further include an energetic chamber comprising an energetic. The perforating tool can also include a passage disposed between the energetic chamber and the gun, where the passage has an open position and a closed position, where the passage is in the closed position when the energetic is in a neutral state, and where the passage is in the open position when the energetic is ignited to generate a propellant. The propellant can move from the energetic chamber to the gun when the passage is in the open position.
In yet another aspect, the disclosure can generally relate to a perforating system. The perforating system can include a wellbore disposed within a subterranean formation. The perforating system can also include a first control mechanism. The perforating system can further include a perforating tool operatively coupled to the first control mechanism and disposed within the wellbore. The perforating tool can include a gun having at least one charge, where the at least one charge is directed radially away from the gun toward a wall of the wellbore. The perforating tool can also include a cord operatively coupled to the at least one charge and to the first control mechanism, where the first control mechanism initiates the ignition of the at least one charge using the cord. The perforating tool can further include an energetic chamber having an energetic. The perforating tool can also include a passage disposed between the energetic chamber and the gun, where the passage has an open position and a closed position, where the passage is in the closed position when the energetic is in a neutral state, and where the passage is in the open position when the energetic is ignited to generate a propellant. The propellant can move from the energetic chamber to the gun when the passage is in the open position.
These and other aspects, objects, features, and embodiments will be apparent from the following description and the appended claims.
The drawings illustrate only example embodiments of controlling pressure during perforating operations and are therefore not to be considered limiting of its scope, as controlling pressure during perforating operations may admit to other equally effective embodiments. The elements and features shown in the drawings are not necessarily to scale, emphasis instead being placed upon clearly illustrating the principles of the example embodiments. Additionally, certain dimensions or positionings may be exaggerated to help visually convey such principles. In the drawings, reference numerals designate like or corresponding, but not necessarily identical, elements.
Example embodiments of controlling pressure during perforating operations will now be described in detail with reference to the accompanying figures. Like, but not necessarily the same or identical, elements in the various figures are denoted by like reference numerals for consistency. In the following detailed description of the example embodiments, numerous specific details are set forth in order to provide a more thorough understanding of the disclosure herein. However, it will be apparent to one of ordinary skill in the art that the example embodiments herein may be practiced without these specific details. In other instances, well-known features have not been described in detail to avoid unnecessarily complicating the description. As used herein, a length, a width, and height can each generally be described as lateral directions.
A user as described herein may be any person that interacts with an example perforating tool for controlling pressure during perforating operations. Examples of a user may include, but are not limited to, a roughneck, a company representative, a drilling engineer, a completion engineer, a tool pusher, a service hand, a mechanic, an operator, a consultant, a contractor, and a manufacturer's representative.
Referring now to
The wellbore 120 can have one or more of a number of segments, where each segment can have one or more of a number of dimensions. Examples of such dimensions can include, but are not limited to, size (e.g., diameter) of the wellbore 120, a curvature of the wellbore 120, a total vertical depth of the wellbore 120, a measured depth of the wellbore 120, and a horizontal displacement of the wellbore 120. The field equipment 130 used to create the wellbore 120 can be positioned and/or assembled at the surface 102. The field equipment 130 can include, but is not limited to, a derrick, a tool pusher, a clamp, a tong, drill pipe, a drill bit, and casing pipe. The field equipment 130 can also include one or more devices that measure and/or control various aspects (e.g., direction of wellbore 120, pressure) of a field operation associated with the wellbore 120. For example, the field equipment 130 can include a wireline tool that is run through the wellbore 120 to provide detailed information (e.g., formation characteristics) throughout the wellbore 120. Such information can help determine, for example, where a perforating operation should be performed within a wellbore and how much charge should be used to perform the perforating operation.
The field equipment 130 can also include one or more control mechanisms. A control mechanism can be operatively coupled to at least a portion (e.g., gun, energetic chamber) of a perforation tool. A control mechanism can initiate an ignition of an energetic and/or charge of a perforation tool. A control mechanism can initiate the ignition of at least a portion of a perforation tool by sending a fixed amount of energy and/or a controlled amount of energy to the perforation tool. In any case, the energy delivered by the control mechanism can be any form of energy, including but not limited to electrical energy, hydraulic energy, and mechanical energy.
In some cases, when the wellbore has been drilled, casing 150 is inserted into the wellbore. The casing 150 can include a number of casing pipes 152 that are mechanically (e.g., threadably) coupled to each other. A coupling member 154 can be used at each end of a casing pipe 152 to enable the mechanical coupling of two casing pipes 152. Each casing pipe 152 can have a body 170 that has a length 172 and a width 174. The length 172 of the body 170 of a casing pipe 152 can vary. For example, a common length 172 of the body 170 is approximately 40 feet. The length 172 can be longer (e.g., 60 feet) or shorter (e.g., 10 feet) than 40 feet.
The width 174 can also vary and can depend on the cross-sectional shape of the body 170. For example, when the cross-sectional shape of the body 170 is circular, the width 174 can refer to an outer diameter, an inner diameter, or some other form of measurement of the body 170 of the casing pipe 152. Examples of a width 174 in terms of an outer diameter can include, but are not limited to, 5 inches, 7 inches, 7⅝ inches, 8⅝ inches, 10¾ inches, 13⅜ inches, and 14 inches. Generally, the width 174 of the casing pipe 152 decreases as the depth of the wellbore increases. Also, the width 174 of the casing pipe 152 can be approximately the same as, or slightly less than, the width of the wellbore 120 at a particular depth of the wellbore 120.
In some cases, when casing 150 is inserted into a wellbore 120, other components and/or equipment can be installed in the wellbore 120. Examples of such equipment can include, but are not limited to, packers (e.g., inflatable packer, hookwall packer, compression-set packer), tubulars (e.g., casing 150, production tubing), and electrical devices (e.g., pumps, motors).
When a wellbore 120 is being completed, casing 150 is inserted into the wellbore 120 along with other production equipment (e.g., pump assemblies, motors). Such production equipment is used to send material 444 from within the casing 150 to the surface 102. In order for material 444 from the formation 110 to enter the casing 150, the casing 150 is perforated. The casing 150 is often perforated once the casing 150 has been inserted into the wellbore 120 and, in some cases, cemented or otherwise adhered in place within the wellbore 120 by pouring cement in the gap 280 between the wellbore 120 and the casing 150. In such a case, in addition to perforating the casing 150 (and in some cases cement or other similar material), the wellbore 120 can also be perforated to help extract the material 444 within the formation 110.
The casing 150 and/or wellbore 120 can be perforated by performing a perforating operation. A perforating operation can be performed in one or more of a number of ways. For example, a perforating tool (as shown and described below with respect to
Referring to
The perforating tool 210 can also include a cord 224 that is disposed inside the gun 220 and is operatively (e.g., electrically) coupled to one or more of the charges 222. The cord 224 can also be operatively coupled to one or more control mechanisms, as described above with respect to the field equipment 130 of
The cord 224 can be a cable of any type (e.g., fiber optic, electrical, instrumentation) having one or more conductors capable of carrying an amount of energy (e.g., current, voltage) that is fixed and/or controlled. In other instances, the cord 224 may contain an energetic that explodes to initiate the explosive or energetic in the charges 222. In certain example embodiments, the cord 224 is omitted from the perforating tool 210, and the amount of energy delivered to the charge 222 is performed using some other means (e.g., wirelessly, using a locally placed battery) triggered using one or more of a number of devices (e.g., a timer, a sensor).
In certain example embodiments, the energetic chamber 240 of the perforating tool 210 includes an energetic 250 that is disposed within the energetic chamber 240. The energetic 250 can be a type of explosive. Examples of such an explosive can include, but are not limited to, solid fuel, potassium chlorate, potassium perchlorate, plasticized nitrocellulose, hydrates, and hydroxides. The energetic 250, while explosive, can be in a neutral state up until the perforating operation is performed.
The energetic chamber 240 can be located in one or more of a number of positions relative to the gun 220. For example, as shown in
In certain example embodiments, the cord 224 is also disposed within the energetic chamber 240. In such a case, the cord 224 can also be operatively coupled to the energetic chamber 240. The cord 224 can ignite the energetic 250 in the energetic chamber 240 to generate a propellant. Specifically, the energetic 250, when reacted with some form of energy (e.g., heat, power), creates a propellant (usually a gas) and, in some cases, a byproduct. Alternatively, an additional cord (or some other mechanism) can be used to ignite the energetic 250. The energetic 250 can also be ignited using some other components and/or methods, as described above with respect to igniting the charge 222.
In certain example embodiments, the energetic chamber 240 also includes a passage 270 disposed between the energetic chamber 240 and the gun 220. The passage 270 can have an open position and a closed position. The passage 270 can be in the closed position when the energetic 250 is in a neutral state. The passage 270 can be in the open position when the energetic 250 is ignited to generate a propellant 350, as described below with respect to
The passage 270 can have one or more of a number of different configurations. For example, the passage 270 can be a sliding sleeve that slides from a closed position to an open position upon the occurrence of an event (e.g., when a propellant is generated from the energetic). As another example, the passage 270 can be a rupture mechanism (e.g., a disk) that ruptures (changes to an open position) upon the occurrence of an event.
Before the charges 222 of the perforating tool 210 are ignited, certain conditions within the wellbore 120 can exist. For example, the hydrostatic pressure in the wellbore 120 can be more or less than the pressure that is generated by detonation of the energetic in the charges 222 in the gun 220. The pressure generated by the detonation of the charges 222 can be determined using, for example, the type of explosive used in the charge 222 and the amount of the explosive used in the charge 222.
Referring to
If the resultant pressure inside the gun 220 is less than the hydrostatic pressure inside the wellbore 120, there is a potential for fluids from the wellbore 120 to flow into the gun 220 through the holes 323 in the outer wall of the gun 220. Such an occurrence can be called a Dynamic Underbalance (DUB). An example of a pressure (DUB) trace within a wellbore 120 during a perforating operation is shown below with respect to
With regard to the energetic chamber 240, the energetic 250 is ignited, which generates a propellant 350 (usually a gas, as described above). The energetic 250 can be ignited using the same or a different control mechanism, with or without the cord 224, relative to igniting the charges 222 of the gun 220. For example, the cord 224 that is used to trigger the charges 222 also triggers the energetic 250 in the energetic chamber 240. In such a case, a single control mechanism can initiate both the charges 222 and the energetic 250. Thus, the pressure created by the propellant 350 in the gun 220 is not controlled.
As another example, the energetic 250 can be ignited using a second control mechanism using a different cord (or different triggering mechanism), where the second control mechanism delivers a controlled amount of energy to the energetic chamber 240. In such a case, for a known (constant) mass of the energetic 250, the controlled amount of energy (e.g., signal, current, voltage) delivered to the energetic chamber 240 can be directly proportional to the pressure created by the propellant 350. Thus, the pressure created by the propellant 350 in the gun 220 is controlled.
In certain example embodiments, controlling the pressure created by the propellant 350 in the gun 220 can be beneficial to strike a better balance between applying too little pressure in the gun 220 (which collapses the perforation tunnels 321) and applying too much pressure in the gun 220 (which fails to induce the material 444 to enter the wellbore 120 from the formation 110).
In addition, the passage 270 can change from a closed position to an open position, allowing the propellant 350 generated in the energetic chamber 240 to move through the passage 270 to the gun 220. In certain example embodiments, the passage 270 changes from the closed position to the open position in response to a change (increase) in pressure in the energetic chamber 240 caused by the formation of the propellant 270 from the energetic 250. In other words, the pressure in the energetic chamber 240 caused by the energetic 250 can be less than (in some cases, significantly so) the pressure in the energetic chamber 240 caused by the propellant 270.
Referring to
Some amount of the materials 444 can also enter inside the gun 220 through the holes 323. The amount of the materials 444 that enter inside the gun 220 through the holes 323 can vary depending, for example, on the pressure inside the gun 220 and the free volume inside the gun 220. The lower the pressure inside the gun 220 (which corresponds to a higher DUB), the more of the materials 444 that enter inside the gun 220 through the holes 323 and into other parts of the cavity 410 within the wellbore 120. When the DUB is too high, the perforation tunnels 321 can collapse. In addition, or in the alternative, when the DUB is too high, equipment (e.g., packers, tubulars, electrical devices) that is positioned within the wellbore 120 can become damaged or destroyed. Such problems can occur within a wellbore 120 in any formation, but can be more likely to occur in a deep field or formation 110, such as is found in a deepwater completion.
At the other extreme, when a DUB is too low, the materials 444 will not be induced to leave the formation 110 through the perforation tunnels 321 because of the relatively low pressure in the wellbore 120. Thus, a balance must be achieved to create a proper pressure in the wellbore 120 (and, more specifically, in the perforating tool 210) to induce materials 444 from the formation 110 without collapsing the perforation tunnels 321 through which the materials 444 can use to enter the wellbore 120. Thus, the propellant 350 that is generated from the energetic 250, whether using a standard amount of energy or a controlled amount of energy, provides a sufficient pressure within the gun 220 to provide a DUB that is not too high or too low.
In certain example embodiments, the passage 270 changes from the open position back to the closed position when some amount of the propellant 350 has left the energetic chamber 240 (i.e., when the pressure within the energetic chamber 240 drops below a certain level or threshold pressure). Alternatively, the passage 270 remains in the open position after changing state from the closed position.
Referring to
In this example, after the extreme spikes at time 502 have subsided, the pressure 522 of the natural pressure track 520 and the pressure 512 of the enhanced pressure track 510 reach their low pressure point of approximately 1500 psi. After time 504, the pressure 513 of the enhanced pressure track 510 is raised due to the pressure generated by the propellant 350, while the pressure 523 of the natural pressure track 520, without the benefit of the propellant 350, remains much lower than the pressure 513.
Referring to
Referring now to
In step 704, an energetic 250 within the energetic chamber 240 is ignited to generate a propellant 350. The energetic 250 can be ignited using a control mechanism that sends an amount of energy to the energetic chamber 240. The control mechanism can use a cord 224 to send the amount of energy to the energetic chamber 240. In such a case, the amount of energy reacts with the energetic 250 to generate the propellant 350. The amount of energy can be controlled (a controlled amount of energy) or standard (a standard amount of energy). In certain example embodiments, the amount of energy used to ignite the energetic 250 is based, at least in part, on the amount of energetic 250 in the energetic chamber 240.
In step 706, one or more charges 222 is ignited within the gun 220. In certain example embodiments, the charge 222 is ignited toward a wall of the wellbore 120 adjacent to the gun 220. The charges 222 can be ignited using a control mechanism that sends an amount of energy to the gun 220. Such a control mechanism can be the same or different than the control mechanism used to ignite the energetic 250. The control mechanism can use a cord 224 to send the amount of energy to the gun 220. In such a case, the cord 224 can be disposed in the gun 220 and operatively coupled to the control mechanism. The amount of energy delivered to the charges 222 in the gun 220 can be controlled or standard.
In certain example embodiments, the charges 222 are ignited at a point in time that is substantially the same as when the energetic 250 is ignited. Alternatively, the charges 222 can be ignited at a point in time that is before or after when the energetic 250 is ignited. When the charges 222 are ignited, one or more tunnels 321 are created, forming a hole 323 in the gun 220, hole 324 in the casing 150, and a hole 325 in the wall of the wellbore 120.
In step 708, the propellant 350 is directed from the energetic chamber 240 intothe gun 220. In certain example embodiments, the passage 270 is used to direct the propellant 350 from the energetic chamber 240 into the gun 220. In such a case, the passage 270 changes from a closed position to an open position. The passage 270 can change from a closed position to an open position based on one or more of a number of factors. For example, the increase in pressure caused by the formation of the propellant 350 in the energetic chamber 240 can cause the passage 270 to change from a closed position to an open position. In such a case, the propellant 350 is directed into the gun 220 when the propellant 350 is generated from the energetic 250 in the energetic chamber 240. Directing the propellant 350 from the energetic chamber 240 into the gun 220 can increase the pressure within the gun 220. When the propellant 350 is directed from the energetic chamber 240 into the gun 220, the propellant 350 can naturally flow toward the holes 325 in the wall of the wellbore 120. When the propellant 350 is directed from the energetic chamber 240 into the gun 220, the method 700 ends at the END step.
Results of a test program using example embodiments described herein are described and listed below. The objective of the test program is to compare the depth of penetration and amount of open perforation tunnel of deep penetrating (DP) and big hole (BH) charges from three different sources (companies) for completions at a site with the following formation and borehole characteristics:
The test mechanism consists of a pressure vessel that allows for the application of pressure to simulate downhole conditions of confining stress, pore pressure, and wellbore pressure. A simulated wellbore holds wellbore fluid and a laboratory perforating gun module. The core is enclosed in a rubber sleeve to prevent communication with the confining fluid, and an end plate is used to impart pore pressure. The charge is fired through a steel plate representing the casing and a cement plug representing the cement in the well before penetrating the core. The tests for this program did not involve flowing any fluids before or after the perforating event. The following test parameters apply:
where the difference in fluid gaps are due to differences in the guns used.
After firing each charge, the core was either scanned using computerized tomography (CAT scan) technology to obtain the length of the perforation tunnel, and/or split open to measure the length of the open perforation tunnel and total length of penetration. The following table shows a summary of the results of the testing:
The experiment shows that similar gram weight charges for both the deep penetrating and big hole charges from both Company B and Company A gave comparable penetrations at the same wellbore dynamic condition (i.e., dynamically underbalanced). In addition, the 26.4 gm DP charge used by Company C provided the deepest penetration as expected based on the gram loading. Further, incorporation of an engineered dynamic underbalance (DUB) enhanced the amount of open perforation tunnel.
The systems, methods, and apparatuses described herein allow for controlling pressure within a gun that discharges one or more charges to create one or more tunnels in the formation that surrounds a wellbore. Controlling the pressure within the gun is important when extracting materials from the formation. If the pressure of the gun is too high, the materials may not be induced into the wellbore from the formation through the tunnels. Alternatively, if the pressure of the gun is too low, the tunnels formed in the formation may collapse, trapping much of the material in the formation. Further, when the pressure of the gun is too high, equipment (e.g., packers, pump systems, tubing) disposed in the wellbore can be damaged. Thus, by controlling pressure within the gun using example embodiments, the adverse results described above with respect to pressure extremes may be reduced or eliminated.
Example embodiments can be used in shallow wellbores, horizontal wellbores, and/or wellbores with severe curvature. Thus, example embodiments allow for placement of casing pipe in a wider variety of wellbores, reducing costs and improving efficiency. Example embodiments can be used in one or more of a number of different rock formations and using one or more of a number of energetics. Further, by sending a controlled amount of energy to ignite the energetic, the pressure of the gun after igniting the charges can be controlled more precisely.
Although embodiments described herein are made with reference to example embodiments, it should be appreciated by those skilled in the art that various modifications are well within the scope and spirit of this disclosure. Those skilled in the art will appreciate that the example embodiments described herein are not limited to any specifically discussed application and that the embodiments described herein are illustrative and not restrictive. From the description of the example embodiments, equivalents of the elements shown therein will suggest themselves to those skilled in the art, and ways of constructing other embodiments using the present disclosure will suggest themselves to practitioners of the art. Therefore, the scope of the example embodiments is not limited herein.
This application claims priority under 35 U.S.C. §119 to U.S. Provisional Patent Application Ser. No. 61/809,959, titled “Controlling Pressure During Perforating Operations” and filed on Apr. 9, 2013, the entire contents of which are hereby incorporated herein by reference.
Number | Date | Country | |
---|---|---|---|
61809959 | Apr 2013 | US |