This disclosure relates generally to coring tools for forming core samples from earth formations and methods of making such coring tools. More specifically, disclosed embodiments relate to coring tools that may enable users to more easily analyze the behavior of the coring tools and components thereof during use.
When exploring a subterranean formation for desired resources, such as, for example, oil, gas, and water, a coring tool may be employed to procure a core sample from the subterranean formation. Typically, the coring tool includes an outer barrel having a coring bit secured to an end of the outer barrel. The outer barrel may be rotated and axial loads (e.g., weight on bit) may be transmitted from the outer barrel to the coring bit to drive the coring bit into an underlying earth formation. The coring bit may include a bore at or near a center of the coring bit, such that the coring bit may remove earthen material from around a cylindrical core sample. As the coring bit advances, the core sample may be received into an inner barrel located within the outer barrel. The outer barrel may be rotatable with respect to the inner barrel, such that the inner barrel may remain at least substantially stationary while the core sample is received therein.
During the coring process, the inner barrel may occasionally exhibit undesirable behaviors that may reduce the quality of the core sample. For example, downhole vibrations, unintended rotation of the inner barrel, contact or other interaction with the outer barrel, and lateral displacement of the inner barrel may cause the inner barrel to contact or otherwise interact with the core sample. Such contact may damage or contaminate the core sample, reducing its value as a representative sample of the earth formation.
In some embodiments, coring tools for procuring core samples from an earth formations may include an inner barrel and an outer barrel located around, and rotatable with respect to, the inner barrel. A coring bit may be affixed to an end of the outer barrel. A sensor module may be rotationally secured to the inner barrel. The sensor module may include at least one sensor configured to measure a dynamic response of the inner barrel during a coring process and a nontransitory memory operatively connected to the at least one sensor, the nontransitory memory configured to store data generated by the at least one sensor.
In other embodiments, methods of making coring tools for procuring core samples from earth formations may involve placing an inner barrel within an outer barrel, and rendering the outer barrel rotatable with respect to the inner barrel. A coring bit may be affixed to an end of the outer barrel. A sensor module may be rotationally secured to the inner barrel. The sensor module may include at least one sensor configured to measure a dynamic response of the inner barrel during a coring process and a nontransitory memory operatively connected to the at least one sensor, the nontransitory memory configured to store data generated by the at least one sensor.
While this disclosure concludes with claims particularly pointing out and distinctly claiming specific embodiments, various features and advantages of embodiments within the scope of this disclosure may be more readily ascertained from the following description when read in conjunction with the accompanying drawings, in which:
The illustrations presented in this disclosure are not meant to be actual views of any particular coring tool, sensor module and associated housing, or component thereof, but are merely idealized representations employed to describe illustrative embodiments. Thus, the drawings are not necessarily to scale.
As used herein, the terms “substantially” and “about” in reference to a given parameter, property, or condition means and includes to a degree that one of ordinary skill in the art would understand that the given parameter, property, or condition is met with a degree of variance, such as within acceptable manufacturing tolerances. For example, a parameter that is substantially or about a specified value may be at least about 90% the specified value, at least about 95% the specified value, at least about 99% the specified value, or even at least about 99.9% the specified value.
Disclosed embodiments relate generally to coring tools that may enable users to more easily analyze the behavior of the coring tools and components thereof during use. More specifically, disclosed are embodiments of coring tools that may include sensor modules rotationally secured to inner barrels of the coring tools, which may enable better analysis of the dynamic response of the inner barrel during a coring process.
The coring tool 100 may further include an inner barrel 120 located within, and at least substantially rotationally stationary with respect to, the outer barrel 102. The inner barrel 120 may be or include another tubular member sized and shaped to receive the core sample as the core sample advances from the coring bit 104 farther into the coring tool 100. Rendering the outer barrel 102 rotatable with respect to the inner barrel 120 enables the inner barrel 120 to remain at least substantially stationary as the outer barrel 102 is rotated and a core sample advances into the inner barrel 120. Maintaining the inner barrel 120 at least substantially stationary during the coring process reduces the likelihood that that the core sample will be damaged by movement of the inner barrel 120 relative to the core sample. The inner barrel 120 may be suspended from a swivel assembly 122 at an end 124 of the inner barrel 120 opposite the coring bit 104. More specifically, an end of the swivel assembly 122 located distal from the coring bit 104 may be secured to, and rotatable with, the outer barrel 102. An end of the swivel assembly 122 located proximate to the coring bit 104 may be secured indirectly to the inner barrel 120. The swivel assembly 122 may include a bearing 126 located between its ends such that the likelihood that rotation of the outer barrel 102 is translated to rotation of the inner barrel 120 is reduced (e.g., minimized or eliminated).
The coring tool 100 may also include a sensor module 132 rotationally secured to the inner barrel 120. The sensor module 132 may be located between the swivel assembly 122 and the inner barrel 120. For example, the sensor module 132 may be located proximate to the end 124 of the inner barrel 120 located opposite the coring bit 104. More specifically, the sensor module 132 may be supported by a housing 134 interposed between, and directly affixed to, the swivel assembly 122 and the end 124 of the inner barrel 120. Spatial constraints may render placing sensor modules 132 on and in coring tools difficult, and particularly so when attempting to measure the dynamic response of the inner barrel 120. For example, the lateral dimensions of the coring tool 100 may be constrained by the size of the borehole in which the coring tool 100 may be inserted, and operators may generally desire to obtain as large a core sample as feasible, rendering the lateral space available for components of the coring tool 100 limited without any added sensor modules 132. As another example, there may be little longitudinal space to accommodate a sensor module 132 because the longitudinal space proximate to the radial periphery of the coring tool 100 may be occupied by structural components, such as, for example, the outer barrel 102 and the inner barrel 120, and the longitudinal space proximate to the radial center of the coring tool 100 may remain vacant to enable the core sample to enter the inner barrel 120. Continuing the example, the general desire to obtain as large a core sample as feasible may also limit the longitudinal space available for placement of a sensor module 132 in the coring tool 100.
The space for accommodating a sensor module 132 configured to measure the dynamic response of the inner barrel 120 may be particularly limited. For example, the inner barrel 120 may be contained within the outer barrel 102, drilling fluid may flow in an annular space 138 between the inner barrel 120 and the outer barrel 102 to cool and lubricate the coring bit 104, and a leading end 136 of the inner barrel 120 located proximate to the coring bit 104 may need to be free of occupying material to enable the core sample to enter the inner barrel 120. The placement of the sensor module 132, and the housing 134 facilitating such placement, may enable more complete detection of the dynamics of the inner barrel 120, without impeding advancement of the core sample into the inner barrel 120, at least substantially without interfering with operation of any other component or components of the coring tool 100.
A shortest distance d1 between the sensor module 132 and the coring bit 104 may be, for example, at least about 25 feet (˜7.6 m) to accommodate a length of a core sample received in the inner barrel 120. More specifically, the shortest distance d1 between the sensor module 132 and the coring bit 104 may be, for example, between about 25 feet (˜7.6 m) and about 60 feet (˜18 m). As a specific, nonlimiting example, the shortest distance d1 between the sensor module 132 and the coring bit 104 may be, for example, between about 25 feet (˜7.6 m) and about 30 feet (˜9.1 m).
In some embodiments, the sensor module 132 may be operatively connected to a downhole communication system 140 configured to transmit the data generated by the sensor module 132. For example, the downhole communication system 140 may be located in the housing 134 with the sensor module 132, within the sensor module 132 itself, in another portion of the coring tool 100 (e.g., above the swivel assembly 122), or in a sub connected directly to the coring tool 100 or distanced from the coring tool 100 by one or more intervening components (e.g., drill collars, a downhole motor, a reamer, a section of drilling pipe, etc.). The downhole communication system 140 may transmit the data generated by the sensor module 132 utilizing, for example, a wireline connection, mud-pulse telemetry, etc. The downhole communication system 140 may send the data generated by the sensor module 132 to a surface station while the coring tool 100 is used to procure a core sample, enabling real-time analysis of the dynamic response of the inner barrel 120 during coring and corresponding adjustment of operational parameters (e.g., weight-on-bit, rotational speed, torque, etc.) to mitigate undesirable inner barrel 120 behavior.
In other embodiments, the sensor module 132 may include nontransitory memory 184 (see
The sensor module 132 may be retained within the recess 142 by at least one of a snap ring 160, an interference fit, a threaded connection 162, and an adhesive material 164. For example, the sensor module 132 may be placed proximate to the ledge 152 within the recess 142, and the snap ring 160 may be positioned partially within an annular groove 166 extending from the recess 142 radially outward into the body 144 to retain the sensor module 132 within the recess 142. As another example, an average outer diameter D3 of the sensor module 132 may be between about 0.1% and about 0.25% smaller than the average outer diameter D1 of the recess 142, and friction between an outer surface 168 of the sensor module 132 and an inner surface 170 of the recess 142 may retain the sensor module 132 within the recess 142. As yet another example, the outer surface 168 of the sensor module 132 and the inner surface 170 of the recess 142 may be complementarily threaded, such that the sensor module 132 may be threadedly engaged with the inner surface 170 of the recess 142. As still another example, an adhesive material 164 may be interposed between the outer surface 168 of the sensor module 132 and the inner surface 170 of the recess 142 to retain the sensor module 132 within the recess 142 by adhesion. As a final example, the sensor module 132 may be retained within the recess 142 by any combination or subcombination of the snap ring 160, interference fit, threaded connection 162, and adhesive material 164.
The sensor module 132 may include a switch 172, which may be configured to activate the sensor module 132 in response to a predetermined triggering condition. For example, the switch 172 may be configured to activate the sensor module 132 in response to a predetermined, detectable, environmental triggering condition or in response to a predetermined, user-initiated triggering condition. More specifically, the switch 172 may include, for example, a temperature sensor, a pressure sensor, or a temperature sensor and a pressure sensor, and may be configured to activate the sensor module 132 when a detected temperature, a detected pressure, or a detected temperature and a detected pressure meet or exceed a predetermined triggering temperature, pressure, or temperature and pressure. As another more specific example, the switch 172 may be operatively connected to a surface control unit 174 (see
The sensor module 132 may include, for example, at least one sensor 176 configured to measure one or more properties indicative of the dynamic response of the inner barrel 120 (see
The sensor module 132 may further include nontransitory memory 184 operatively connected to the one or more sensors 176, the nontransitory memory 184 configured to store the data generated by the sensor module 132 locally within the sensor module 132. For example, the nontransitory memory 184 may include, for example, dynamic, random-access memory (DRAM), static random-access memory (SRAM), erasable programmable read-only memory (EPROM), electrically erasable programmable read-only memory (EEPROM), flash memory, etc. In some embodiments where the sensor module 132 includes nontransitory memory 184, the sensor module 132 may not be connected to the surface for real-time transmission of data, lacking a downhole communication system 140, as described previously in connection with
In some embodiments, such as that shown in
When the housing 186 and sensor module 132 are located between sections 120A and 120B of the inner barrel 120, they may be positioned within the coring tool 100 (see
In embodiments where the housing 186 and sensor module 132 are located between sections 120A and 120B of the inner barrel 120, such as that shown in
An average outer diameter D4 of the passageway 190 may be greater than, or at least substantially equal to, the average outer diameter D2 of the inner bore 148 of the housing 186. Because the core sample may be required to advance through the passageway 190 in the sensor module 132 and the inner bore 148 of the housing 186, a maximum diameter of the core sample may be at least substantially equal to, or less than, the average outer diameter D2 of the inner bore 148 and the average outer diameter D4 of the passageway 190.
The end 158 of the housing 192 may be located at least partially within the bore 118 that extends longitudinally through the body 108 of the coring bit 104. A surface 196 of the body 108 defining the bore 118 may extend radially outward from a radially innermost portion of the bore 118 to a radially outermost portion of the bore 118 to form a ledge 198 located longitudinally between the face 112 and a trailing end 200 of the coring bit 104. The end 158 of the housing 192 may be located at least partially within a recess 202 defined by the ledge 198 and the surface 196 of the body 108 defining the bore 118. In some embodiments, the end 158 of the housing 192 may be longitudinally spaced from the ledge 198 and radially spaced from the surface 196 defining the bore 118, enabling the coring bit 104 to rotate relative to the housing 192, the sensor module 132 supported therein, and the inner barrel 120 connected thereto. For example, a longitudinal standoff 204 between the ledge 198 and the end 158 of the housing 192 may be at least about 1 mm. More specifically, the longitudinal standoff 204 may be, for example, between about 1 mm and about 2 mm when the coring tool 100 (see
When the housing 192 and sensor module 132 are located proximate to the coring bit 104, they may be positioned within the coring tool 100 (see
In embodiments where the housing 192 and sensor module 132 are located proximate to the coring bit 104, such as that shown in
The average outer diameter D4 of the passageway 190 may be greater than, or at least substantially equal to, the inner gage 116 of the coring bit 104. Because the core sample may be required to advance through the passageway 190 in the sensor module 132 and the inner bore 148 of the housing 192, a maximum diameter of the core sample may be at least substantially equal to, or less than, the average outer diameter D2 of the inner bore 148 and the average outer diameter D4 of the passageway 190.
While various features have been shown in connection with specific embodiments in
Additional, nonlimiting embodiments within the scope of this disclosure include the following:
A coring tool for procuring a core sample from an earth formation, comprising: an inner barrel; an outer barrel located around, and rotatable with respect to, the inner barrel; a coring bit affixed to an end of the outer barrel; and a sensor module rotationally secured to the inner barrel, the sensor module comprising: at least one sensor configured to measure a dynamic response of the inner barrel during a coring process; and a nontransitory memory operatively connected to the at least one sensor, the nontransitory memory configured to store data generated by the at least one sensor.
The coring tool of Embodiment 1, wherein the sensor module is located proximate to an end of the inner barrel located opposite the coring bit.
The coring tool of Embodiment 2, wherein a shortest distance between the sensor module and the coring bit is at least about 25 feet (˜7.6 m).
The coring tool of Embodiment 2 or Embodiment 3, wherein the sensor module is supported in a housing affixed to an end of the inner barrel opposite the coring bit.
The coring tool of Embodiment 4, wherein the sensor module is retained within a recess in the housing, the recess having a larger average outer diameter than an average outer diameter of a bore extending through the housing between the recess and the coring bit.
The coring tool of Embodiment 5, wherein the sensor module is retained within the recess by at least one of a snap ring, an interference fit, a threaded connection, and an adhesive material.
The coring tool of any one of Embodiments 4 through 6, further comprising a swivel assembly rotatably supporting the inner barrel within the outer barrel, and wherein the housing is interposed between, and directly secured to, the swivel assembly and the inner barrel.
The coring tool of Embodiment 1, wherein the sensor module is located proximate to the coring bit.
The coring tool of Embodiment 8, wherein the sensor module comprises a passageway extending longitudinally through the sensor module.
The coring tool of Embodiment 8 or Embodiment 9, wherein the sensor module is supported in a housing affixed to an end of the inner barrel proximate to the coring bit.
The coring tool of Embodiment 10, wherein a longitudinal standoff between the housing and the coring bit is at least about 1 mm and wherein a radial standoff between the housing and the coring bit is at least about 0.5 mm.
The coring tool of Embodiment 1, wherein the sensor module is supported in a housing affixed to ends of sections of the inner barrel.
The coring tool of Embodiment 12, wherein a shortest distance between the sensor module and the coring bit is at least about 25 feet (˜7.6 m) and wherein a shortest distance between the sensor module and a swivel assembly from which the inner barrel is supported is at least about 25 feet (˜7.6 m).
The coring tool of any one of Embodiments 1 through 13, wherein the sensor module comprises a switch configured to activate the sensor module in response to a predetermined triggering condition.
The coring tool of any one of Embodiments 1 through 14, wherein the sensor module is operatively connected to a downhole communication system configured to transmit the data generated by the at least one sensor to a surface while the coring tool is used to procure the core sample.
The coring tool of any one of Embodiments 1 through 15, wherein the at least one sensor comprises at least one of an accelerometer, a temperature sensor, and a magnetometer.
A method of making a coring tool for procuring a core sample from an earth formation, the method comprising: placing an inner barrel within an outer barrel, and rendering the outer barrel rotatable with respect to the inner barrel; affixing a coring bit to an end of the outer barrel; and rotationally securing a sensor module to the inner barrel, the sensor module comprising: at least one sensor configured to measure a dynamic response of the inner barrel during a coring process; and a nontransitory memory operatively connected to the at least one sensor, the nontransitory memory configured to store data generated by the at least one sensor.
The method of Embodiment 17, further comprising placing the sensor module proximate to an end of the inner barrel located opposite the coring bit.
The method of Embodiment 18, wherein placing the sensor module proximate to the end of the inner barrel comprises rendering a shortest distance between the sensor module and the coring bit at least about 25 feet (˜7.6 m).
The method of Embodiment 18 or Embodiment 19, further comprising supporting the sensor module in a housing affixed to an end of the inner barrel opposite the coring bit.
The method of Embodiment 20, wherein supporting the sensor module in the housing comprises retaining the sensor module within a recess in the housing, the recess having a larger average outer diameter than an average outer diameter of a bore extending through the housing between the recess and the coring bit.
The method of Embodiment 21, wherein retaining the sensor module within the recess in the housing comprises retaining the sensor module within the recess by at least one of a snap ring, an interference fit, a threaded connection, and an adhesive material.
The method of any one of Embodiments 20 through 22, wherein rendering the outer barrel rotatable with respect to the inner barrel comprises rotationally supporting the inner barrel from a swivel assembly within the outer barrel, and further comprising placing the housing between, and directly securing the housing to, the swivel assembly and the inner barrel.
The method of Embodiment 17, further comprising supporting the sensor module in a housing and affixing the housing to ends of sections of the inner barrel.
The method of Embodiment 17, further comprising placing affixing a housing supporting the sensor module proximate to an end of the inner barrel located opposite proximate to the coring bit.
The method of any one of Embodiments 17 through 25, further comprising selecting the sensor module to include a switch configured to activate the sensor module in response to a predetermined triggering condition.
The method of any one of Embodiments 17 through 25, further comprising operatively connecting the sensor module to a downhole communication system configured to transmit the data generated by the at least one sensor to a surface while the coring tool is used to procure the core sample.
The method of any one of Embodiments 17 through 25, further comprising selecting the at least one sensor to include at least one of an accelerometer, a temperature sensor, and a magnetometer.
A method of measuring a dynamic response of at least a portion of a coring tool when procuring a core sample from an earth formation, the method comprising: rotating an outer barrel with respect to an inner barrel; advancing a coring bit located at an end of the outer barrel into an underlying earth formation; receiving at least a portion of a core sample within the inner barrel; and measuring a dynamic response of the inner barrel utilizing a sensor module rotationally secured to the inner barrel, the sensor module comprising: at least one sensor configured to measure a dynamic response of the inner barrel during a coring process; and a nontransitory memory operatively connected to the at least one sensor, the nontransitory memory configured to store data generated by the at least one sensor.
While certain illustrative embodiments have been described in connection with the figures, those of ordinary skill in the art will recognize and appreciate that the scope of this disclosure is not limited to those embodiments explicitly shown and described in this disclosure. Rather, many additions, deletions, and modifications to the embodiments described in this disclosure may be made to produce embodiments within the scope of this disclosure, such as those specifically claimed, including legal equivalents. In addition, features from one disclosed embodiment may be combined with features of another disclosed embodiment while still being within the scope of this disclosure, as contemplated by the inventors.