Not applicable.
1. Field of the Invention
The invention relates generally to roller cone drill bits for drilling earth formations, and more specifically to roller cone drill bits having optimized cutting element counts for reduced tracking and/or increased drilling performance.
2. Background Art
Roller cone rock bits are commonly used in the oil and gas industry for drilling wells.
A roller cone drill bit typically includes a bit body with a threaded connection at one end for connecting to a drill string and a plurality of roller cones, typically three, attached at the other end and able to rotate with respect to the bit body. Disposed on each of the cones is a plurality of cutting elements, typically arranged in rows, about the surface of the cones. The cutting elements may comprise tungsten carbide inserts, polycrystalline diamond compacts, or milled steel teeth.
Significant expense is involved in the design and manufacture of drill bits to produce drill bits with increased drilling efficiency and longevity. Roller cone bits are more complex in design than fixed cutter bits, in that the cutting surfaces of the bit are disposed on roller cones. Each of the roller cones independently rotates relative to the rotation of the bit body about an axis oblique to the axis of the bit body. Because the roller cones rotate independent of each other, the rotational speed of each cone is typically different. For a given cone, the cone rotation speed generally can be determined from the rotational speed of the bit and the effective radius of the “drive row” of the cone. The effective radius of a cone is generally related to the radial extent of the cutting elements on the cone that extend axially the farthest, with respect to the bit axis, toward the bottomhole. These cutting elements typically carry higher loads and may be considered as generally located on a so-called “drive row”. The cutting elements located on the cone to drill the full diameter of the bit are referred above to as the “gage row”.
Adding to the complexity of roller cone bit designs, cutting elements disposed on the cones of the roller cone bit deform the earth formation by a combination of compressive fracturing and shearing. Additionally, most modern roller cone bit designs have cutting elements arranged on each cone so that cutting elements on adjacent cones intermesh between the adjacent cones, as indicated for example at 29 in
Because of the complexity of roller cone bit designs, roller cone bits have been largely developed through a trial and error process that involves selecting an initial design, field testing the initial design, and then modifying the design to improve drilling performance. For example, when a bit design has been shown to result in cutting elements an one cone being worn down faster than cutting elements on another cone, a new bit design may be developed by simply adding more cutting elements to the cone that bad cutting elements that wore down faster in hopes of reducing wear on each of the cutting elements on that cone.
In more recent years, this trial and error process has been used in conjunction with other processes and programs proposed to predict characteristics associated with the drilling performance of the bit. For example, U.S. Pat. Nos. 6,213,225 and 6,986,395, issued to Chen, propose an optimization process for equalizing the downward (axial) force on each of the cones of a drill bit. U.S. Pat. No. 6,516,293 and U.S. Pat. No. 6,873,947, issued to Huang et al., disclose methods for designing roller cone drill bits which include simulating the drilling performance of a bit, adjusting a design parameter, and repeating the simulating and adjusting until an optimized performance is obtained.
The problem with current roller cone drill bit designs is that the resulting arrangements ore often arrived at somewhat arbitrarily. As a result, many prior art bits may provide less than optimal drilling performance due to problems which may not be readily detected, such as “tracking” and “slipping.” Tracking occurs when cutting elements on a drill bit fall into previous impressions formed by other cutting elements at preceding moments in time during revolution of the drill bit. Slipping is related to tracking and occurs when cutting elements strike a portion of previous impressions made and then slide into the previous impressions rather than cutting into the uncut formation.
Cutting elements do not cut effectively when they fall or slide into previous impressions made by other cutting elements. In particular, tracking is inefficient because no fresh rock is cut. Slipping also should be avoided because it can result in uneven wear on cutting elements which can result in premature cutting element failure. Thus, tracking and slipping during drilling can lead to low penetration rates and in many cases uneven wear on the cutting elements and cone shell. By making proper adjustments to the arrangement of cutting elements on a bit, problems such as tracking and slipping can be significantly reduced. This is especially true for cutting elements on a drive row of a cone because the drive row generally governs the rotation speed of the cone.
Prior art exists for varying the orientation of asymmetric cutting elements on a bit to address tracking concerns. For example, U.S. Pat. No. 6,401,839, issued to Chen, discloses varying the orientation of the crests of chisel-type cutting elements within a row, or between overlapping rows of different cones, to reduce tracking problems and improve drilling performance. U.S. Pat. Nos. 6,527,068 and 6,827,161, issued to Singh, disclose methods for designing bits by simulating drilling with a bit to determine its drilling performance and then adjusting the orientation of at least one non-axisymmetric cutting element on the bit and repeating the simulating and determining until a performance parameter is determined to be at an optimum value. U.S. Pat. No. 6,942,045, issued to Dennis, discloses a method of using cutting elements with different geometries on a row of a bit to cut the same track of formation and help reduce tracking problems. However, in many drilling applications, such as the drilling of harder formations, the use of asymmetric cutting elements such as chisel-type cutting elements are not desired due to their poorer performance in these applications.
Prior art also exists for using different pitch patterns on a given row to address the tracking concerns. For example, U.S. patent application Ser. Nos. 10/353,869 (now U.S. Pat. No. 7,234,549) and 10/854,067 (now U.S. Pat. No. 7,292,967), titled “Methods for evaluating cutting arrangements for drill bits and their application to roller cone drill bit designs,” which are assigned to the assignee of the present invention and incorporated herein by reference, disclose, inter alia, designing drill bits by varying the pitch pattern between cutting elements in a row to help reduce tracking problems and improve drilling performance.
While the above approaches are considered useful in particular applications, in other applications the use of asymmetric cutting elements is not desired and the use of different pitch patterns can be difficult to implement and can result in a more complex approach to drill bit design and manufacture than necessary for addressing tracking concerns. What is desired is a simplified design approach that results in reduced tracking for particular applications without sacrificing bit life or requiring increased time or cost associated with design and manufacturing.
In accordance with one aspect, the present invention provides a roller cone drill bit including a plurality of roller cones, each having a plurality of cutting elements mounted thereon. The cutting elements are arranged in rows on each of the cones. The rows include at least a gage row and a plurality of interior rows positioned radially interior from the gage row. The rows are arranged on the cones such that when viewed in rotated profile, cutting element profiles partially overlap with other cutting element profiles and the first three interior rows adjacent the gage row each have a cutting element count that is selected from the group of 16, 18, 21 and 26.
In accordance with another aspect, the present invention provides a roller cone drill bit having an IADC formation classification within the range of 54 to 84. The drill bit includes a plurality of roller cones, each having a plurality of cutting elements mounted thereon and arranged in rows. The rows on each cone include at least a gage row, and a first interior row that is radially interior from the gage row. The first interior row on each of the cones has a cutting element count selected from the group of 16, 18, 21 and 26.
In accordance with another aspect, the present invention provides a roller cone drill bit having three cones rotatably mounted to the bit body. Each of the cones has a plurality of cutting elements thereon and arranged in rows. The rows include at least a gage row and a first row ulterior from the gage row with respect to the bit axis. At least one cone on the bit has a cone speed ratio of around 1.4. The first interior row on each of the cones also has a cutting element count comprising one selected from the group of 16, 18, 21 and 26.
In accordance with another aspect, the present invention provides a roller cone drill bit having a plurality of roller cones rotatably mounted to a bit body, wherein each roller cone has a plurality of cutting elements mounted thereon. The cutting elements are arranged in rows on each of the cones. The rows including at least a gage row and a plurality of interior rows positioned radially interior from the gage row. The rows are arranged on each of the cones such that cutting element profiles partially overlap with other cutting element profiles when viewed in rotated profile. Additionally, the interior rows on a first one-third of the cone profile between the bit axis and gage and adjacent a gage row each have a cutting element count selected from the group of 16, 18, 21 and 26.
Other aspects and advantages of the present invention will be apparent from the following description and the appended claims.
The present invention provides roller cone drill bits having optimized cutting element counts for reduced tracking and/or improved drilling performance for given applications. Using programs, such as ones disclosed in U.S. Pat. No. 6,516,293 or U.S. Pat. No. 6,873,947 to Huang tn conjunction with other programs, such as the ones disclosed in U.S. Pat. Nos. 7,234,549 and 7,292,967 to McDonough, which are all assigned to the assignee of the present invention and incorporated herein by reference, it has been discovered that tracking issues can be satisfactorily addressed in selected applications by simply changing one or more cutting element counts on a row of a roller cone of a bit to a cutting element count that has been found to perform better at the given cone speed or in the given drilling application. By changing cutting element counts on rows instead of pitch patterns or insert geometries to address tracking and performance problems in these applications, simplicity in bit design and manufacture, as well as increased drilling life, can be achieved.
Thus, in accordance with one aspect, the present invention provides a roller cone drill bit having cutting element counts for rows selected dependent upon the cone speed expected during drilling. Tracking problems are generally cone speed dependent. Accordingly, cutting element counts that have been found to result in reduced tracking at the expected cone speeds are proposed for particular applications.
In accordance with another aspect of the present invention, cutting element counts are selected for rows on a roller cone drill bit dependent upon the given drilling application. Tracking problems for tows having particular cutting element counts have been also shown to be drilling application related. This is because particular cone speeds are more prevalent for particular drilling applications. Thus, in accordance with this aspect of the present invention, cutting element counts found to result in reduced tracking for bits designed for particular applications are also proposed.
In accordance with another aspect of the present invention, cutting element counts for rows on a roller cone drill bit may be selected dependent upon other aspects of the bit geometry which have been determined to influence or generally govern the relative rotation of the cones with respect to a rotation about the bit axis.
Now, referring to
Further, in accordance with one aspect of the present invention, the bit is configured such that it has a resulting IADC classification within the range of 54 to 84. Those skilled in the art will appreciate that the International Association of Drilling Contractors (IADC) has established a bit classification system for the identification of bits suited for particular drilling applications. According to this system, each bit falls within a particular 3-digit IADC bit classification. The first digit in the IADC classification designates the formation “series” which indicates the type of cutting elements used on the roller cones of the bit as well as the hardness of the formation the bit is designed to drill. As shown for example in
The second digit in the IADC bit classification designates the formation “type” within a given series which represent a further breakdown of the formation type to be drilled by the designated bit. As shown in
The third digit of the IADC classification code relates to bearing design and gage protection and is, thus, omitted herein as extraneous.
Those skilled in the art will further appreciate that as formations to be drilled become progressively harder, the cutting elements used on the bits generally become relatively shorter with respect to their extension length from the surface of the roller cone. Cutting element extension lengths may be described in terms of a cutting element extension length to cutting element diameter ratio, as disclosed for example in U.S. Pat. No. 6,561,292. Bits in IADC series 5 to 8 typically have cutting element extension to diameter ratios which are less than 0.829. For bits with an IADC series of 6 or higher, this ratio is typically less than 0.75. For bits with an IADC series of 7 and 8, this ratio is typically less than 0.5.
Those skilled in the art also appreciate that roller cone drill bits designed to drill medium hard to extremely hard and abrasive formations typically include a “staggered” row of cutting elements arranged on at least one of the cones. For example, as shown for the bit in
In general, the inventors have discovered that cutting element counts of 5, 7, 10, 12, 15, 17, 19, 20, 22, and 25 when used for interior rows proximal a gage row on roller cone drill bits with IADC classifications within the range of 54 to 84 do not work as well in the given applications and tend to result in tracking problems. Thus, in accordance with an aspect of the present invention, a first interior row adjacent a gage row, or a drive row, on each roller cone of a roller cone drill bit having an IADC classification within the range of 54 to 84 preferably has a cutting element count (number of cutting elements on a row) selected from 13, 14, 16, 18, 21, or 26. Using these cutting element counts on first interior rows or drive rows of a roller cone bit have been found to result in improved drilling performance in the designated applications.
Referring to
The general term “cutting elements” is used herein to refer to the primary cutting elements disposed on the bit which generally extend to cut the bottomhole. Using cutting element counts as noted above on each of the first three rows 32 adjacent the gage rows 31 of a bit having an IADC classification within the rage of 54-84 has been found to result in improved drilling performance over conventional bits which have other cutting element counts in one or more of the first three rows adjacent gage.
Further, in one or more embodiments, the selected number of interior rows adjacent gage having a cutting element count of 13, 14, 16, 18, 21, or 26 may comprise a first five interior rows, 32 and 33 adjacent the gage rows 31. In such case each of the first five rows of cutting elements, 32 and 33, adjacent the gage rows 31 when viewed in rotated profile will have a cutting element count comprising one selected from the group of 13, 14, 16, 18, 21, or 26. For example, in one embodiment, a bit may be configured to have a first row adjacent gage comprising 18 cutting elements, second and third rows from gage comprising 16, 18, or 21 cutting elements, a fourth row from gage comprising 13, 14, or 16 cutting elements, and a fifth row from gage comprising 13, 14, 16, or 18 cutting elements. Again, for particular embodiments, this selection may be limited to cutting element counts of 13, 16, 18 and 21, but cutting element counts of 14 have been shown to work just as well and are thus useful for other embodiments of the present invention. Bits configured to have more than three rows adjacent gage with cutting element counts identified as preferred or optimal for interior rows on bits having IADC classifications within the rage of 54 to 84, and more particularly with IADC classifications within the range of 81 to 84, have been found to provide an additional improvement in drilling performance in particular application compared to other conventional bits used in these applications.
In addition to having a first five interior rows, 32 and 33, adjacent the gage rows 31, each comprising a cutting element count selected from the group of 13, 14, 16, 16, 21, and 26, in one or more embodiments, some or ail of the remaining interior rows, 34 and 35, on the bit 30 may each comprise a cutting element count comprising one selected from the group of 1, 2, 3, 4, 6, 8, 11, 13, 14 and 16 cutting elements. In a particular embodiment all of the remaining interior rows may comprise cutting element counts selected from the group of 1, 2, 3, 4, 6, 8, 11, 13, 14, and 16 to avoid having interior rows with cutting element counts that have been found to not work as well in particular applications. While this may be done in one or more embodiments, it is generally believed that using cutting element counts identified as preferred or optimal for particular applications on at least the first three interior rows 32 adjacent gage rows 31 can provide a useful performance improvement over conventional bits used in these applications. This is because in many of these applications the rows disposed on the bit proximal to the gage rows 31 tend to extend axially farthest from the axis of rotation of the cones and, thus, tend to have a significant effect on the rotation speed of the cone.
As stated above, tracking problems for a row having a selected number of cutting elements are generally cone speed dependent. For example, it has been determined that average cone speeds for many bits designed for applications described above are typically around 1.4 times the rotation speed of the bit. It also has been discovered that curing element counts of 1, 2, 3, 4, 6, 8, 11, 13, 14, 16, 18, 21, or 26 perform better for bits in applications that involve similar cone to bit speeds ratios (or cone to bit rotation ratios), such as cone to bit speeds ratios of between 1.350 and 1.475, and more particularly for those having cone to bit speed ratios of 1.4+/−0.025. These particular cutting element counts have been found to result in reduced tracking and improved drilling performance for bits having average cone speed ratios within these ranges. Therefore, in accordance with another aspect of the present invention, a roller cone drill bit may be provided having cutting element counts selected dependent on the cone speeds or cone to bit rotation ratios expected during drilling.
As noted in the Background herein, those skilled in the art will appreciate that the rotation speed of a cone generally can be approximated from the rotational speed of the bit and the effective radius of the “drive row”. The effective radius of a drive row of a cone is generally related to the radial extent of the cutting elements that extend axially the farthest, with respect to the bit axis, toward the bottomhole. These cutting elements typically experience larger forces and are considered to form what is known as a so-called “drive row” on the cone. The drive row is the row or rows that generally govern the rotation speed of the cones.
One method for estimating the position of a drive row is illustrated, in
Referring to
Referring to
A first cone 40 includes a gage row of cutting elements 41 and a plurality of interior rows of cutting elements positioned radially interior (with respect to the central axis 33) from the gage row 41. The gage row of cutting elements 41 are generally positioned to cut to the gage diameter of the bit. The interior rows of cutting elements are positioned radially inward from the gage diameter and function to cut the bottom of the bore hole. The plurality of interior rows of cutting elements include a first interior row of cutting elements 42 positioned adjacent the gage row 41, a second interior row of cutting elements 43, a third interior row of cutting elements 44, and a fourth interior row of cutting elements 45. The cone 40 further includes a centrally located cutting element 46 disposed on a nose portion 49 of the cone 40. The first cone 40 also includes a “heel row” of cutting elements 47 disposed on a heel surface 48 of the cone. The heel row cutting elements 47 are positioned to help maintain the gage diameter of the wellbore drilled. The first cone 40 may also include “ridge row” cutting elements (not shown) which may be positioned to extend between adjacent rows of cutting elements on the cone to break up ridges of formation that may form and protrude between rows of cutting elements during drilling. Those skilled in the art will appreciate that “ridge row” cutting elements are cutting elements that do not extend to the bottomhole but, rather, have significantly shorter extension lengths from the cone surface and may be included on the cone to minimize formation contact with the softer cone body. Ridge row cutting elements are typically arranged dependent upon the other cutting elements arranged on the bit.
The second cone 50 also includes a gage row of cutting elements 51 and a plurality of interior rows of cutting elements, positioned radially interior from the gage row 51. The interior rows of cutting elements include a first interior row of cutting elements 52 positioned adjacent the gage row 51, a second interior row of cutting elements 53, a third interior row of cutting elements 54, and a fourth interior row of cutting elements 55. The second cone 50 also includes a centrally located row of cutting elements 56 which is disposed about the nose portion 59 of the cone. The second cone 50 further includes a “heel row” of cutting elements 57 disposed on a heel surface 58 of the cone and may include one or more “ridge rows” of cutting elements (not shown) positioned between adjacent rows of cutting elements on the cone to break up ridges of formation that may protrude between rows during drilling.
The third cone 60 also includes a gage row of cutting elements 61 and a plurality of interior rows of cutting elements positioned radially interior from the gage row 61. The plurality of interior rows on the third cone 60 include a first interior row of cutting elements 62 positioned adjacent the gage row 61, a second interior row of cutting elements 63, a third interior row of cutting elements 64, and a fourth interior row of cutting elements 65 proximal a nose portion 69 of the cone body 60. The third cone 60 further includes a “heel row” of cutting elements 67 disposed on a heel surface 68 of the third cone and may additionally include one of more “ridge rows” of cutting elements (not shown) disposed between selected rows of cutting elements to help break up ridges of formation that may protrude between rows during drilling.
In accordance with aspects of the present invention, a plurality of selected interior rows on the roller cones may each have a cutting element count comprising one selected from the group of 1, 2, 4, 6, 8, 11, 13, 14, 16, 18, 21, and 26. In one or more embodiments, the selected interior rows may comprise three or more interior rows positioned proximal the gage rows when viewed in rotated profile. In one or more embodiments, the selected interior rows may comprise at least a drive row on each of the cones. Additionally, in one or more embodiments, the selected interior rows on the bit may comprise all or substantially all of the interior rows positioned on the bit to cut the bottomhole.
Referring to the specific example as shown in
A bit designed in accordance with
Referring to
Referring to
Similarly, the second cone 50 in
The third cone 60 in this case does not include a staggered row with respect to the gage row 61. Thus, the position about the circumference of each cutting element in the first interior row 62 may be generally positioned independent of the azimuthal (rotary) position of a cutting element in the gage row 61.
The particular bit design shown in
The bit shown in
In accordance with another aspect of the present invention, instead of describing a bit in terms of a calculated rotation ratio or an assigned IADC classification, a bit in accordance with an embodiment of the present invention may be defined in terms of selected geometric parameters related to the cutting structure layout of the bit. For example, in one or more embodiments, a bit in accordance with the present invention may comprise a bit having a plurality of cones with cutting elements mounted on the cones wherein at least one of the cutting elements on each of the cones has a reference point P at ⅓ of its extension height horn the insert tip along the insert axis which lies within a geometric envelope defined between 50% and 90% of the distance from the bit centerline to the gage diameter of the bit and between boundaries corresponding to cone to bit rotation ratios (or bit to cone radius ratios) of 1.350 and 1.475 as shown in
In accordance with the above aspect of the invention, in one or more embodiments, the at least one cutting element on each of the cones will have a reference point P at ⅓ of its extension height which lies within the geometric envelope defined between 50% and 85% of the distance from the bit centerline to the gage diameter of the bit and between boundaries corresponding to cone to bit rotation ratios (or bit to cone radius ratios) of 1.350 and 1.475, and more preferably between boundaries corresponding to cone to bit rotation ratios of 1.375 and 1.450. For the embodiment shown in
Another embodiment of a bit designed in accordance with aspects of the present invention is shown in
The bit in this case included a total of 13 interior rows as shown (72-76, 82-85, 92-95), wherein the remaining interior rows on the bit were selected to have cutting element counts of 1, 2, 3, 4, 6, 8, 11, or 13. More specifically the first cone 70 included interior rows 72-76 as shown which had cutting element counts selected as 16, 18, 11, 4 and 1, respectively; the second cone 80 included interior rows 82-85 as shown which had cutting element counts of 21, 13, 6, and 1, respectively; the third cone 90 included interior rows 92-95 as shown which had cutting element counts selected as 21, 16, 8, and 3, respectively. Several similar bits have since been run in Travis Peak & Cotton Valley formation applications and have been found to provide advantageously improved performance over the prior art bits previously used. As noted above, in addition to the preferred cutting element counts noted above, a cutting element count of 14 may also be used to achieve similar results and, thus, is considered a preferred count in accordance with aspects of the present invention.
The bit also included “ridge row” cutting elements between interior rows as shown. More specifically, the first cone 70 included a ridge row of cutting elements 75a which comprised 4 ridge cutting elements 75a staggered with the cutting elements of the fourth interior row 75 on the first cone 70. The second cone 80 also included a ridge row of cutting elements 85a which comprised 2 ridge cutting elements 85a staggered with the cutting elements of the fourth interior row 85 of the second cone 80. The third cone 90 also included a row of ridge row cutting elements 95a which comprised 3 ridge cutting elements 95a staggered with the cutting elements of the fourth interior row 95 on the third cone 90.
The bit further included heel row cutting elements 77, 87, 97 on each of the cones positioned on the heel surfaces 78, 88, 98 of the cones help maintain the full gage diameter of the bit cut by the gage cutting elements 71, 81, 91 on the cones 70, 80, 90. In this case the gage cutting elements as well as the heel row cutting elements each bad a cutting element count of one selected from the group of 16, 18, 21, and 26. However, it should be appreciated that other cutting element counts may be used for these rows in other embodiments without departing from the scope of the present invention.
Embodiments in accordance with the present invention have been found to result in improved drilling rates and reduced risk of damage to the bit cutting structure during drilling in selected applications. In particular, field tests have shown that bits designed having cutting element counts as described above may be used to drill faster and/or longer in the applications noted above than prior art counterparts. Further, it has been shown that embodiments in accordance with aspects of the present invention may provide improve ROP and/or improved bit life in harder formation applications where tracking can be an issue that may not be readily apparent form the dull conditions of the bits. Designing bits having optimizing cutting element counts as described above on selected rows of the roller cone drill bits may result in drill bits that drill faster and further, which can result in reduced drilling time and costs compared to conventional bits used. Additionally, it should be understood that the various aspects of the invention can be implemented on other drill bits, such as those in which the cutting elements are formed integrally with the body of the roller cone.
While the invention has been described with respect to a limited number of embodiments, those skilled in the art, having benefit of this disclosure, will appreciate that other embodiments can be devised which do not depart from the scope of the invention as disclosed herein. Accordingly, the scope of the invention should be limited only by the attached claims.
This application claims priority, pursuant to 35 U.S.C. §119(e), to U.S. Provisional Application No. 60/880,820 filed Jan. 16, 2007, which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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60880820 | Jan 2007 | US |