In conventional wellbore drilling in the oil and gas industry, a drill bit is mounted on the end of a drill string, which may be extended by adding segments of drill pipe as the well is progressively drilled to the desired depth. At the surface of the well site, a rotary drive (referred to as a “top drive”) may be provided to rotate the entire drill string, including the drill bit at the end, to drill through the subterranean formation. Alternatively, the drill bit may be rotated using a downhole mud motor without having to rotate the drill string. When drilling, drilling fluid is pumped through the drill string and discharged from the drill bit to remove cuttings and debris. The mud motor, if present in the drill string, may be selectively powered using the circulating drilling fluid.
One common type of drill bit used to drill wellbores is a “fixed cutter” bit, wherein the cutters are secured to the bit body at fixed positions. This type of bit is sometimes referred to as a “drag bit” since the cutters in one respect drag rather than roll in contact with the formation during drilling. The bit body may be formed from a high strength material, such as tungsten carbide, steel, or a composite/matrix material. A plurality of cutters (also referred to as cutter elements, cutting elements, or inserts) are attached at selected locations about the bit body. The cutters may include a substrate or support stud made of a carbide (e.g., tungsten carbide), and an ultra-hard cutting surface layer or “table” made of a polycrystalline diamond material or a polycrystalline boron nitride material deposited onto or otherwise bonded to the substrate. Such cutters are commonly referred to as polycrystalline diamond compact (“PDC”) cutters.
In fixed cutter drill bits, PDC cutters are rigidly secured to the bit body, such as by being brazed within corresponding cutter pockets defined on blades that extend from the bit body. Some of the PDC cutters are strategically positioned along the leading edges of the blades to engage the formation during drilling. In use, high forces are exerted on the PDC cutters, particularly in the forward-to-rear direction. Over time, the working surface or cutting edge of each cutter that continuously contacts the formation eventually wears down or fails.
The following figures are included to illustrate certain aspects of the present disclosure, and should not be viewed as exclusive embodiments. The subject matter disclosed is capable of considerable modifications, alterations, combinations, and equivalents in form and function, without departing from the scope of this disclosure.
The present disclosure relates to earth-penetrating drill bits and, more particularly, to rolling-type cutting or depth of cut control (DOCC) elements that can be used in drill bits. Embodiments of the disclosure are directed to retainers for the rolling DOCC elements that resist movement out of retainer groove, to thereby maintain the DOCC elements within a cavity for operation. The retainers may be arranged in their respective grooves such that movement of the retainers in multiple directions is required to remove the retainers from the grooves. The retainers may be wedged into the retainer grooves to prohibit movement of the retainers in at least one of the required directions in operation.
The embodiments of the present disclosure describe rolling element assemblies that can be secured within corresponding cavities provided on a drill bit. Each rolling element assembly includes a cylindrical rolling element strategically positioned and secured to the drill bit so that the rolling element is able to engage the formation during drilling. In response to drill bit rotation, and depending on the selected positioning (orientation) of the rolling element with respect to the body of the drill bit, the rolling element may roll against the underlying formation, cut against the formation, or may both roll against and cut the formation. The rolling elements of the presently disclosed rolling element assemblies are retained within corresponding cavities on the bit body using an arcuate retainer received within a retainer slot defined in the cavity.
The orientation of each rolling element with respect to the bit body is selected to produce a variety of different functions and/or effects. The selected orientation includes, for example, a selected side rake and/or a selected back rake. In some cases while drilling, the rolling element may be configured as a rolling cutting element that both rolls along the formation (e.g., by virtue of a selected range of side rake) and cuts the formation (e.g., by virtue of the selected back rake and/or side rake). More particularly, the rolling cutting element may be positioned to cut, dig, scrape, or otherwise remove material from the formation using a portion of the rolling element (e.g., a polycrystalline diamond table) that is positioned to engage the formation.
In some example embodiments, the rolling element assemblies described herein can be configured as rolling cutting elements. The rolling cutting elements may be configured to rotate freely about a rotational axis and, as a result, the entire outer edge of the rolling cutting element may be used as a cutting edge. Consequently, rather than only a limited portion of the cutting edge being exposed to the formation during drilling, as in the case of conventional fixed cutters, the entire outer edge of the rolling cutting element will be successively exposed to the formation as it rotates about its rotational axis during drilling. This results in a more uniform cutting edge wear, which may prolong the operational lifespan of the rolling cutting element as compared to conventional cutters.
In other example embodiments, the rolling element assemblies described herein can be configured as rolling depth of cut control (DOCC) elements that roll along the formation as the drill bit rotates. In a rolling DOCC element configuration, the orientation of the rolling element may be selected so that a full axial span of the rolling element bears against the formation. As with rolling cutting elements, rolling DOCC elements may exhibit enhanced wear resilience and allow for additional weight-on-bit without negatively affecting torque-on-bit. This may allow a well operator to minimize damage to the drill bit, thereby reducing trips and non-productive time, and decreasing the aggressiveness of the drill bit without sacrificing its efficiency. The rolling DOCC elements described herein may also reduce friction at the interface between the drill bit and the formation, and thereby allow for a steady depth of cut, which results in better tool face control.
In yet other example embodiments, the rolling element assemblies described herein may operate as a hybrid between a rolling cutting element and a rolling DOCC element. This may be accomplished by orienting the rotational axis of the rolling element on a plane that does not pass through the longitudinal axis of the drill bit nor is the plane oriented perpendicular to a plane that does pass through the longitudinal axis of the drill bit. Those skilled in the art will readily appreciate that the presently disclosed embodiments may improve upon hybrid rock bits, which use a large roller cone element as a depth of cut limiter by sacrificing diamond volume. In contrast, the presently disclosed rolling element assemblies are small in comparison and its enablement will not result in a significant loss of diamond volume on a fixed cutter drag bit.
The drill bit 100 has a bit body 102 that includes radially and longitudinally extending blades 104 having leading faces 106. The bit body 102 may be made of steel or a matrix of a harder material, such as tungsten carbide. The bit body 102 rotates about a longitudinal drill bit axis 107 to drill into underlying subterranean formation under an applied weight-on-bit. Corresponding junk slots 112 are defined between circumferentially adjacent blades 104, and a plurality of nozzles or ports 114 can be arranged within the junk slots 112 for ejecting drilling fluid that cools the drill bit 100 and otherwise flushes away cuttings and debris generated while drilling.
The bit body 102 further includes a plurality of cutters 116 secured within a corresponding plurality of cutter pockets sized and shaped to receive the cutters 116. Each cutter 116 in this example comprises a fixed cutter secured within its corresponding cutter pocket via brazing, threading, shrink-fitting, press-fitting, snap rings, or any combination thereof. The fixed cutters 116 are held in the blades 104 and respective cutter pockets at predetermined angular orientations and radial locations to present the fixed cutters 116 with a desired back rake angle against the formation being penetrated. As the drill string is rotated, the fixed cutters 116 are driven through the rock by the combined forces of the weight-on-bit and the torque experienced at the drill bit 100. During drilling, the fixed cutters 116 may experience a variety of forces, such as drag forces, axial forces, reactive moment forces, or the like, due to the interaction with the underlying formation being drilled as the drill bit 100 rotates.
Each fixed cutter 116 may include a generally cylindrical substrate made of an extremely hard material, such as tungsten carbide, and a cutting face secured to the substrate. The cutting face may include one or more layers of an ultra-hard material, such as polycrystalline diamond, polycrystalline cubic boron nitride, impregnated diamond, etc., which generally forms a cutting edge and the working surface for each fixed cutter 116. The working surface is typically flat or planar, but may also exhibit a curved exposed surface that meets the side surface at a cutting edge.
Generally, each fixed cutter 116 may be manufactured using tungsten carbide as the substrate. While a cylindrical tungsten carbide “blank” can be used as the substrate, which is sufficiently long to act as a mounting stud for the cutting face, the substrate may equally comprise an intermediate layer bonded at another interface to another metallic mounting stud. To form the cutting face, the substrate may be placed adjacent a layer of ultra-hard material particles, such as diamond or cubic boron nitride particles, and the combination is subjected to high temperature at a pressure where the ultra-hard material particles are thermodynamically stable. This results in recrystallization and formation of a polycrystalline ultra-hard material layer, such as a polycrystalline diamond or polycrystalline cubic boron nitride layer, directly onto the upper surface of the substrate. When using polycrystalline diamond as the ultra-hard material, the fixed cutter 116 may be referred to as a polycrystalline diamond compact cutter or a “PDC cutter,” and drill bits made using such PDC fixed cutters 116 are generally known as PDC bits.
As illustrated, the drill bit 100 may further include a plurality of rolling element assemblies 118, shown as rolling element assemblies 118a and 118b. The orientation of a rotational axis of each rolling element assembly 118a,b with respect to a tangent to an outer surface of the blade 104 may dictate whether the particular rolling element assembly 118a,b operates as a rolling DOCC element, a rolling cutting element, or a hybrid of both. As mentioned above, rolling DOCC elements may prove advantageous in allowing for additional weight-on-bit (WOB) to enhance directional drilling applications without over engagement of the fixed cutters 116. Effective DOCC also limits fluctuations in torque and minimizes stick-slip, which can cause damage to the fixed cutters 116.
If, for example, the rotational axis A of the rolling element 122 is substantially parallel to a tangent to the outer surface 119 of the blade profile, the rolling element assembly 118a,b may generally operate as a rolling DOCC element. Said differently, if the rotational axis A of the rolling element 122 passes through or lies on a plane that passes through the longitudinal axis 107 (
Accordingly, as depicted in
Traditional load-bearing type cutting elements for DOCC unfavorably affect torque-on-bit (TOB) by simply dragging, sliding, etc. along the formation, whereas a rolling DOCC element, such as the presently described rolling element assemblies 118b, may reduce the amount of torque needed to drill a formation because it rolls to reduce friction losses typical with load bearing DOCC elements. A rolling DOCC element will also have reduced wear as compared to a traditional bearing element. As will be appreciated, however, one or more of the rolling element assemblies 118b can also be used as rolling cutting elements, which may increase cutter effectiveness since it will distribute heat more evenly over the entire cutting edge and minimize the formation of localized wear flats on the rolling cutting element.
For example, the bit face profile 128 may include a first gage zone 130a located opposite a second gage zone 130b, a first shoulder zone 132a located opposite a second shoulder zone 132b, a first nose zone 134a located opposite a second nose zone 134b, and a first cone zone 136a located opposite a second cone zone 136b. The fixed cutters 116 included in each zone may be referred to as cutting elements of that zone. For example, the fixed cutters 116a included in gage zones 130a,b may be referred to as gage cutting elements, the fixed cutters 116b included in shoulder zones 132a,b may be referred to as shoulder cutting elements, the fixed cutters 116c included in nose zones 134a,b may be referred to as nose cutting elements, and the fixed cutters 116d included in cone zones 136a,b may be referred to as cone cutting elements.
Cone zones 136a,b may be generally concave and may be formed on exterior portions of each blade 104 (
The blade profile 138 includes an inner zone 142 and an outer zone 144. The inner zone 142 extends outward from the longitudinal axis 107 to a nose point 146, and the outer zone 144 extends from the nose point 146 to the end of the blade 104. The nose point 146 may be a location on the blade profile 138 within the nose zone 134 that has maximum elevation as measured by the bit longitudinal axis 107 (vertical axis) from reference line 140 (horizontal axis). A coordinate on the graph in
Depending on how the rotational axis A (
Depending on how they are oriented with respect to the longitudinal axis 107, each rolling element assembly 118a,b (
Back rake can be defined as the angle subtended between the Z-axis of a given rolling element 122 and the Z-R plane. More particularly, as the Z-axis of a given rolling element 122 rotates offset backward or forward from the Z-R plane, the amount of offset rotation is equivalent to the measured back rake. If, however, the Z-axis of a given rolling element 122 lies on the Z-R plane, the back rake for that rolling element 122 will be 0°.
In some embodiments, one or more of the rolling element assemblies 118a,b may exhibit a side rake that ranges between 0° and 45° (or 0° and −45°), or alternatively a side rake that ranges between 45° and 90° (or −45° and −90°). In other embodiments, one or more of the rolling element assemblies 118a,b may exhibit a back rake that ranges between 00 and 45° (or 0° and −45°). The selected side rake will affect the amount of rolling versus the amount of sliding that a rolling element 122 included with the rolling element assembly 118a,b will undergo, whereas the selected back rake will affect how a cutting edge of the rolling element 122 engages the formation (e.g., the first and second formations 124, 126 of
Referring again to
Strategic placement of the first and second rolling element assemblies 118a,b may further allow them to be used as either primary and/or secondary rolling cutting elements as well as rolling DOCC elements, without departing from the scope of the disclosure. For instance, in some embodiments, one or more of the rolling element assemblies 118a,b may be located in a kerf forming region 120 located between adjacent fixed cutters 116. During operation, the kerf forming region 120 results in the formation of kerfs on the underlying formation being drilled. One or more of the rolling element assemblies 118a,b may be located on the bit body 102 such that they will engage and otherwise extend across one or multiple formed kerfs during drilling operations. In such an embodiment, the rolling element assemblies 118a,b may also function as prefracture elements that roll on top of or otherwise crush the kerf(s) formed on the underlying formation between adjacent fixed cutters 116. In other cases, one or more of the rolling element assemblies 118a,b may be positioned on the bit body 102 such that they will proceed between adjacent formed kerfs during drilling operations. In yet other embodiments, one or more of the rolling element assemblies 118a,b may be located at or adjacent the apex of the drill bit 100 (i.e., at or near the longitudinal axis 107). In such embodiments, the drill bit 100 may fracture the underlying formation more efficiently.
In some embodiments, as illustrated, the rolling element assemblies 118a,b may each be positioned on a respective blade 104 such that the rolling element assemblies 118a,b extend orthogonally from the outer surface 119 (
The blade 104 is depicted in
The rolling element assembly 200 includes a rolling element 204 that comprises a generally cylindrical or disk-shaped body having a first axial end 208a and a second axial end 208b opposite the first axial end 208a. The distance between the first and second axial ends 208a,b is referred to herein as the axial width 210 of the rolling element 204.
The rolling element 204 includes a substrate 212 and opposing diamond tables 214a and 214b arranged at the first and second axial ends 208a,b, respectively, and otherwise coupled to opposing axial ends of the substrate 212. The substrate 212 may be formed of a variety of hard or ultrahard materials including, but not limited to, steel, steel alloys, tungsten carbide, cemented carbide, any derivatives thereof, and any combinations thereof. Suitable cemented carbides may contain varying proportions of titanium carbide (TiC), tantalum carbide (TaC), and niobium carbide (NbC). Additionally, various binding metals may be included in the substrate 212, such as cobalt, nickel, iron, metal alloys, or mixtures thereof In the substrate 212, the metal carbide grains are supported within a metallic binder, such as cobalt. In other cases, the substrate 212 may be formed of a sintered tungsten carbide composite structure or a diamond ultra-hard material, such as polycrystalline diamond (PCD) or thermally stable polycrystalline diamond (TSP).
The diamond tables 214a,b may be made of a variety of ultrahard materials including, but not limited to, polycrystalline diamond (PCD), thermally stable polycrystalline diamond (TSP), cubic boron nitride, impregnated diamond, nanocrystalline diamond, ultra-nanocrystalline diamond, and zirconia. Such materials are extremely wear-resistant and are suitable for use as bearing surfaces, as herein described.
The rolling element 204 may comprise and otherwise include one or more cylindrical bearing portions. More particularly, in this example, the entire rolling element 204 is cylindrical and made of hard, wear-resistant materials, and thus any portion of the rolling element 204 may be considered as a cylindrical bearing portion to the extent it slidingly engages a bearing surface of the cavity 202 or another component of the rolling element assembly 200 when rolling, such as would be expected during drilling operations. In some embodiments, for instance, one or both of the diamond tables 214a,b may be considered cylindrical bearing portions for the rolling element 204. In other embodiments, one or both of the diamond tables 214a,b may be omitted from the rolling element 204 and the substrate 212 may alternatively be considered as a cylindrical bearing portion. In yet other embodiments, the entire cylindrical or disk-shaped rolling element 204 may be considered as a cylindrical bearing portion and may be made of any of the hard or ultra-hard materials mentioned herein, without departing from the scope of the disclosure.
It should be noted that the features of the rolling element 204 are shown for illustrative purposes only and may or may not be drawn to scale. Consequently, the rolling element 204 as depicted should not be considered as limiting the scope of the present disclosure. For example, the thickness or axial extent of both the diamond tables 214a,b may or may not be the same. In at least one embodiment, one of the diamond tables 214a,b may be thicker than the other. Moreover, in some embodiments, one of the diamond tables 214a,b may be omitted from the rolling element 204 altogether. In yet other embodiments, the substrate 212 may be omitted and the rolling element 204 may instead be made entirely of the material of the diamond tables 214a,b.
The rolling element assembly 200 also includes a retainer 206 used to help secure or retain the rolling element 204 in the cavity 202 during use. More particularly, the cavity 202 provides and otherwise defines an opening 216 large enough to receive the rolling element 204. When seated within the cavity 202, an arcuate portion of the rolling element 204 extends out of cavity 202 to expose the full axial width 210 of the rolling element 204. The retainer 206 may subsequently be inserted into the cavity 202, and the cavity 202 and the retainer 206 cooperatively retain the rolling element 204 within the cavity 202. This is accomplished as portions of the cavity 202 and the retainer 206 jointly encircle more than 180° of the circumference of the rolling element 204, but less than 360°, so that the full axial width 210 of the rolling element 204 remains exposed for external contact with a formation during operation.
During drilling operations, the rolling element 204 is able to rotate within the cavity 202 about a rotational axis A of the rolling element 204. As the rolling element 204 rotates about the rotational axis A, the arcuate portion of the rolling element 204 extending out of the cavity 202 and otherwise exposed through the opening 216 engages (i.e., cut, roll against, or both) the underlying formation. This allows the full axial width 210 of the rolling element 204 across the entire outer circumferential surface to progressively be used as the rolling element 204 rotates during use.
As illustrated, the cavity 202 may provide or otherwise define a retainer slot 302 configured to receive and seat the retainer 206. More specifically, the cavity 202 may provide a first arcuate portion 304a that extends from one side of the opening 216 and a second arcuate portion 304b that extends from the opposing side of the opening 216. The first arcuate portion 304a exhibits a first radius R1 and the second arcuate portion 304b exhibits a second radius R2 that is greater than first radius R1, and an end wall 306 provides a transition between the first and second arcuate portions 304a,b. With a larger second radius R2, the second arcuate portion 304b is sized to accommodate the retainer 206 within the cavity 202. Accordingly, the retainer slot 302 is defined, at least in part, by the second arcuate portion 304b and the end wall 306.
The retainer 206 provides an inner arcuate surface 308a and an outer arcuate surface 308b opposite the inner arcuate surface 308a. With the retainer 206 received within the retainer slot 302, the outer arcuate surface 308b will be disposed against or otherwise adjacent the second arcuate portion 304b and the inner arcuate surface 308a will be disposed against or otherwise adjacent the outer circumferential surface of the rolling element 204. Moreover, the retainer 206 is sized such that the curvature of the first arcuate portion 304a will transition smoothly to the curvature of the inner arcuate surface 308a to enable the rolling element 204 to bear against a continuously (uniformly) curved surface at all angular locations within the cavity 202 during operation.
The retainer 206 can be made of any of the hard or ultra-hard materials mentioned above for the substrate 212 and the diamond tables 214a,b. More specifically, the retainer 206 may be made of a material such as, but not limited to, steel, a steel alloy, tungsten carbide, a sintered tungsten carbide composite structure, cemented carbide, polycrystalline diamond (PCD), thermally stable polycrystalline diamond (TSP), cubic boron nitride, impregnated diamond, nanocrystalline diamond, ultra-nanocrystalline diamond, zirconia, any derivatives thereof, and any combinations thereof Alternatively, or in addition thereto, the retainer 206 may be made of an engineering metal, a coated material (i.e., using processes such as chemical vapor deposition, plasma vapor deposition, etc.), or other hard or abrasion-resistant materials.
The retainer 206 may be secured within the cavity 202 (e.g., the retainer slot 302) using a variety attachment means or techniques such as, but not limited to, brazing, welding, an industrial adhesive, press-fitting, shrink-fitting, one or more mechanical fasteners (e.g., screws, bolts, snap rings, pins, a ball bearing retention mechanism, a locking wire, etc.), or any combination thereof In at least one embodiment, as illustrated, a set screw 312 (shown in dashed lines) or the like may be used to secure the retainer 206 within the retainer slot 302. In the illustrated embodiment, the set screw 312 may be extended through a hole 314a defined in the blade 104, such as a trailing face of the blade 104, and threaded into a correspondingly aligned hole 314b defined in the retainer 206. It will be appreciated, however, that the set screw 312 may be used to secure the retainer 206 within the retainer slot 302 via alternately defined holes provided in other locations, without departing from the scope of the disclosure.
In some embodiments, the retainer 206 may define or otherwise provide an extraction feature 316 used to help extract the retainer 206 from the cavity 202 when desired. The extraction feature 316 may comprise any negative or positive alteration in the geometrical shape of the retainer 206 that provides a location where the retainer 206 may be gripped or otherwise engaged to pry (rotate) the retainer 206 out of the retainer slot 302. Negative alterations, for example, comprise material removal from the geometrical shape of the retainer 206, while positive alterations comprise material additions to the geometrical shape. In some embodiments, as illustrated, the extraction feature 316 may comprise a groove, depression, or channel (i.e., a negative alteration) defined on the outer arcuate surface 308b of the retainer 206. In other embodiments, however, the extraction feature 316 may alternatively be provided on one or both of the sidewalls of the retainer 206, without departing from the scope of the disclosure.
When it is desired to remove the retainer 206 from the cavity 202, a user may access and engage the extraction feature 316 with a rigid contrivance (e.g., a pick, a screwdriver, a rigid rod, etc.) and pry (rotate) the retainer 206 out of the retainer slot 302. In at least one embodiment, as illustrated, an access groove 318 may be defined in the upper surface of the blade 104 to provide a location where a user can access the extraction feature 316 and gain leverage over the retainer 206 to pry it out of the cavity 202. In the illustrated embodiment, where the extraction feature 316 is provided on the outer arcuate surface 308b of the retainer 206, the access groove 318 will be defined in the upper surface of the blade 104 adjacent the outer arcuate surface 308b of the retainer 206. In embodiments where the extraction feature 316 is alternatively provided on one or both of the sidewalls of the retainer 206, as mentioned above, the access groove 318 will be defined in the upper surface of the blade 104 adjacent one or both of the sidewalls of the retainer 206. In embodiments where the retainer 206 is brazed into the cavity 202, the braze may first be melted prior to extracting the retainer 206.
The rolling element assembly 200 may be arranged on the blade 104 such that the rolling element 204 will rotate about the rotational axis A in a first direction 320 during operation. As the rolling element 204 engages an underlying subterranean formation and rotates about the rotational axis A, a weight on bit (WOB) force F1 and a friction force F2 will act on the rolling element 204. The WOB force F1 is the weight force applied to the rolling element 204 in the direction of advancement of the drill bit 100 (
F
R
2
=F
1
2
+F
2
2 Equation (1)
And the resultant force FR vector will be directed at an angle θ offset from the WOB force F1. The angle θ may be determined as follows:
If the direction of the resultant force FR ector intersects the retainer 206 as positioned within the retainer slot 302, then the retainer 206 may not only be used to help retain the rolling element 204 in the cavity 202, but may also prove useful as a bearing element that assumes at least a portion of the resultant force FR of the rolling element 204 during drilling operations. If, however, the direction of the resultant force FR vector does not intersect the retainer 206, then the retainer 206 will primarily serve as a structure that helps retain the rolling element 204 in the cavity 202.
In the illustrated embodiment, an arc length L of the retainer 206 is long enough such that the resultant force FR vector will intersect the retainer 206, which allows the retainer 206 to operate as a retaining structure and a bearing element. In other embodiments, however, and depending on known or predicted drilling parameters, the arc length L of the retainer 206 may be increased or decreased to allow the retainer 206 to operate as a retaining structure and a bearing element, or only as a retaining element. As will be appreciated, the respective arc lengths of the first and second arcuate surfaces 304a,b and the location of the end wall 306 will correspondingly be altered to accommodate the change to the arc length L. Moreover, because of the arcuate shape of the retainer 206, the maximum arc length L will be limited to the size of the opening 216.
Accordingly, the retainer 206 not only helps secure the rolling element 204 in the cavity 202, but can also serve as a bearing surface that supports and guides the rolling element 204 and may assume most (if not all) of the load exerted on the rolling element 204. In contrast, the first arcuate surface 304a may see only minimal loads under normal operation conditions. Given the design of the rolling element assembly 200, the force exerted on the retainer 206 during operation may be primarily compressive in nature. Having the retainer 206 made of a hard or ultra-hard material may help reduce the amount of friction and wear between the rolling element 204 and the retainer 206 as the rolling element 204 bears and slides against the inner arcuate surface 308a. Consequently, the hard or ultra-hard materials of the support bearing 206 may reduce or eliminate the need for lubrication between the retainer 206 and the rolling element 204. In at least one embodiment, however, the inner arcuate surface 308a may be polished so as to reduce friction between the opposing surfaces. The inner arcuate surface 308a may be polished, for example, to a surface finish of about 40 micro-inches or better.
Moreover, as the rolling element 204 rotates in the first direction 320, it inherently urges the retainer 206 to remain secured in the cavity 202. More particularly, the friction generated between the outer circumference of the rolling element 204 and the inner arcuate surface 304a of the retainer 206 will continuously provide a force that urges the retainer 206 against the end wall 306 and otherwise deeper into the cavity 202. Consequently, minimal retention means (i.e., brazing, welding, industrial adhesives, press-fitting, shrink-fitting, mechanical fasteners, etc.) may be required to maintain the retainer 206 within the cavity 202.
It should be noted that, although the rolling element assembly 200 has been described as retaining one rolling element 204, embodiments of the disclosure are not limited thereto and the rolling element assembly 200 (or any of the rolling element assemblies described herein) may include and otherwise use two or more rolling elements 204, without departing from the scope of the disclosure. In such embodiments, the multiple rolling elements 204 may be retained within the cavity 202 using the retainer 206 or each rolling element 204 may be supported by individual retainers 206.
In some embodiments, as shown in
In some embodiments, the transition corners 408 between the second end 404b and the first and second sidewalls 406a, b and of the retainer 206 may be chamfered or radiused. Chamfered or radiused transition corners 408 may help with ease of installation of the retainer into the retainer slot 302 (
The hardfacing material 504 can be applied to the depressions 502 via a variety of hardfacing techniques including, but not limited to, oxyacetylene welding (OXY), atomic hydrogen welding (ATW), welding via tungsten inert gas (TIG), gas tungsten arc welding (GTAW), shielded metal arc welding (SMAW), gas metal arc welding (GMAW—including both gas-shielded and open arc welding), oxyfuel welding (OFW), submerged arc welding (SAW), electroslag welding (ESW), plasma transferred arc welding (PTAW—also called powder plasma welding), additive/subtractive manufacturing, thermal spraying, cold polymer compounds, laser cladding, hardpaint, and any combination thereof.
One suitable hardfacing material 504 comprises sintered tungsten carbide particles in a steel alloy matrix. The tungsten carbide particles may include grains of monotungsten carbide, ditungsten carbide and/or macrocrystalline tungsten carbide. Spherical cast tungsten carbide may typically be formed with no binding material. Examples of binding materials used to form tungsten carbide particles may include, but are not limited to, cobalt, nickel, boron, molybdenum, niobium, chromium, iron and alloys of these elements. Other hard constituent materials include cast or sintered carbides consisting of chromium, molybdenum, niobium, tantalum, titanium, vanadium and alloys and mixtures thereof.
In some embodiments, one or more of the depressions 502 may alternatively be used to retain and otherwise receive a bearing element 506. The bearing element 506 may comprise, for example, a TSP or another ultra-hard material secured within a corresponding depression 502, cast into the inner arcuate surface 308a of the retainer 206, or otherwise secured thereto. Although the bearing element 506 is illustrated as having a generally circular cross-section, it will be appreciated that the bearing element 506 may alternatively exhibit any suitable shape, such as oval, polygonal, etc., without departing from the scope of the disclosure. In at least one embodiment, the entire inner arcuate surface 308a of the retainer 206 may comprise the bearing element 506 or may otherwise be coated with an ultra-hard material that acts as a bearing element or bearing surface, without departing from the scope of the disclosure.
In
In some embodiments, one or more material cavities 508 (two shown) may be defined or otherwise provided on the outer arcuate surface 308b of the retainer 206. The material cavities 508 may be used to retain a locking material (e.g., braze paste, solder, etc.) used to secure the retainer 206 within the cavity 202 (
Exemplary assembly of the rolling element assembly 200 in a blade 104 of a drill bit 100 (
In
In
In some embodiments, the first and second side surfaces 702a,b may form integral parts of the blade 104 and, therefore, may be made of the same materials as the bit body 102 (
In yet other embodiments, or in addition thereto, one or both of the side surfaces 702a,b may have a bearing element 704 positioned thereon to be engageable with an adjacent diamond table 214a,b of the rolling element 204. The bearing element 704 may comprise, for example, a TSP or another ultra-hard material cast into the particular side surface 702a,b or otherwise secured thereto. Although the bearing element 704 is illustrated as having a generally circular cross-section, it will be appreciated that the bearing element 704 may alternatively exhibit any suitable shape, such as oval, polygonal, etc., that may be engageable with the opposing diamond tables 214a,b, without departing from the scope of the disclosure. In at least one embodiment, the entire side surface 702a,b may comprise a bearing element 704 or may otherwise be coated with an ultra-hard material that acts as a bearing element or bearing surface, without departing from the scope of the disclosure.
Those skilled in the art will readily appreciate that other designs and configurations of the cavity 202 and the retainer slot 302 may be employed. For instance, a combination of rounded and polygonal features may define the retainer slot 302, without departing from the scope of the disclosure.
As illustrated, the rolling element assembly 900 includes a rolling element 902 and a retainer 904 used to help retain the rolling element 902 within a cavity. The rolling element 902 comprises a generally cylindrical body having a first axial end 906a and a second axial end 906b opposite the first axial end 906a. While not specifically shown, in some embodiments, diamond tables (i.e., diamond tables 214a and 214b of
Unlike the rolling element 204 of
While the rolling element 902 and the retainer 904 are depicted in
As illustrated, the rolling element assembly 1000 includes a rolling element 1002 and a retainer 1004 used to help retain the rolling element 1002 within a cavity. The rolling element 1002 comprises a generally cylindrical body having a first axial end 1006a and a second axial end 1006b opposite the first axial end 1006a. While not specifically shown, in some embodiments, diamond tables (i.e., diamond tables 214a and 214b of
Similar to the rolling element 902 of
As illustrated, the rolling element assembly 1100 includes a rolling element 1102 and a two-piece retainer 1104 used to help retain the rolling element 1102 within a cavity. The rolling element 1102 is illustrated in dashed linetype as comprising a generally cylindrical body having a first axial end 1106a and a second axial end 1106b opposite the first axial end 1106a. The rolling element 1102 is illustrated with a constant diameter between the first and second axial ends 1106a,b, and in other embodiments, the rolling element may exhibit a variable diameter as illustrated, e.g. in 9A-10B. While not specifically shown, in some embodiments, diamond tables (i.e., diamond tables 214a and 214b of
The two-piece retainer 1104 includes a first retainer piece 1104a and a second retainer piece 1104b disposed within a retainer slot 1132 defined within a cavity 1134 of blade 104. The interior of the cavity 1134 also provides and otherwise defines a first side surface 1134a and a second side surface 1134b opposite the first side surface 1134a within the cavity 1134. As illustrated, the side surfaces 1134a,b may be substantially parallel to the opposing second axial ends 1106a,b of the rolling element 1102 when the rolling element 1102 is installed in the cavity 1134. An opening 1138 to the cavity 1134 defines an axial width 1140 thereacross, which, in the illustrated embodiment, extends over the retainer slot 1132. During operation, the rolling element 1102 may or may not extend across the axial width 1140 such that the first and second axial ends 1106a,b of the rolling element 1102 may or may not always engage or contact the opposing side surfaces 1134a,b of the cavity 1134. Respective first ends 1144a 1146a of the first and second retainer pieces 1104a, 1104b together define an axial width 1150 of the two-piece retainer 1104. Due to an axial taper in one or both of the retainer pieces 1104a,b, the axial width 1150 changes as the second retainer piece 1104b is rotated into the retainer slot 1132. For example, an axial taper is provided on a helically shaped side of the second retainer piece 1104b that engages the first retainer piece 1104a. Thus, in the configuration illustrated, with the second retainer piece 1104b partially inserted into the retainer slot 1132 (as illustrated in
The retainer slot 1132 includes an optional axial offset 1152 with respect to the side surface 1134a and the opening 1138. The axial offset 1152 permits a second end 1154a of the first retainer piece 1104a within the retainer slot 1132 to be axially offset from the first end 1144a of the first retainer piece 1104a. As illustrated, the axial offset 1152 is formed from an offset region 1158 of the retainer slot 1132 that extends helically from the side surface 1134a and receives a correspondingly-shaped protruding portion 1160 of the first retainer piece 1104a. In other embodiments, an axial offset may include a notch, slot or keyhole shaped to receive a correspondingly shaped protrusion of a first retainer piece therein. With the protruding portion 1160 extending into the offset region 1158 of the retainer slot 1132, the retainer slot 1132 may receive the second retainer piece 1104b therein. The second retainer piece 1104b optionally includes a helical ridge 1162 defined on an axial side thereof. The helical ridge 1162 is arranged to engage and interlock with a helical groove 1164 defined on an axial side of the first retainer piece. The helical ridge 1162 may guide the second retainer piece 1104b into the proper position within the retainer slot 1132. Installation of the second retainer piece 1104b into the retainer slot 1132 prohibits axial withdrawal of the protruding portion 1160 of the first retainer piece 1104a from the offset region 1158 of the retainer slot 1132.
In other embodiments, some clearance 1170 may be maintained where the axial width 1150 of the retainer is less than the axial width 1140 of the cavity 1134. Where the clearance 1170 is less than the axial offset 1152, the protruding portion 1160 will extend at least a partially into the offset potion 1158 of the retainer slot 1132 even when the first and second retainer pieces 1104a,b are shifted axially in the direction of arrow 1182 toward the second side surface 1134b. The protruding portion 1160 thereby helps to retain the two-piece retainer 1104 within the retainer slot 1132 at least by preventing simultaneous removal of the first and second retainer pieces 1104a,b from the retainer slot 1132. For example, embodiments are contemplated in which the first and second retainer pieces 1104a,b may be functionally joined to one another (by friction, ratchet mechanism, a third retainer piece (see
In some embodiments, an axial width 1180 defined by the second ends 1154a,b of the first and second retainer pieces 1104a, 1104b is greater than the axial width 1140 defined by the opening 1138 of the cavity 1134. In these embodiments, the first and second retainer pieces 1104a, 1104b may not be removed simultaneously from the retainer slot 1132. To remove the two-piece retainer 1104 from the retainer slot, the second retainer piece 1104b may first be moved in a circumferential direction 1184 (
The clearance 1236 in the retainer slot 1234 may be filled with a biasing material 1244, such as a braze material, an epoxy or other filler to prohibit movement of the retainer 1204 in a lateral direction 1248. In this manner, the retainer 1204 may be maintained in the retainer slot 1234 with the protruding portion 1210 and an offset region 1212 of the cavity 1216. When it is necessary to remove the retainer 1204, the biasing material 1244 may be removed from the retainer slot 1234 (by melting the braze material, drilling or otherwise mechanically removing the filler). Thereafter, the retainer 1204 may be moved in the axial direction 1248 to permit removal of the retainer 1204 from the retainer slot 1234, e.g. in a circumferential direction as described above.
Embodiments disclosed herein include:
A. A drill bit that includes a bit body having one or more blades extending therefrom, a plurality of cutters secured to the one or more blades, and a rolling element assembly positioned within a cavity defined on the bit body, the rolling element assembly including a rolling element rotatable within the cavity about a rotational axis, and a retainer extendable within a retainer slot defined in the cavity to secure the rolling element within the cavity, wherein the retainer and the cavity cooperatively encircle more than 180° but less than 360° of a circumference of the rolling element while leaving a full axial width of the rolling element exposed.
B. A rolling element assembly that includes a rolling element rotatable about a rotational axis when positioned within a cavity defined on a bit body of a drill bit, and a retainer extendable within a retainer slot defined in the cavity to secure the rolling element within the cavity, wherein the retainer and the cavity cooperatively encircle more than 180° but less than 360° of a circumference of the rolling element while leaving a full axial width of the rolling element exposed.
Each of embodiments A and B may have one or more of the following additional elements in any combination: Element 1: wherein the cavity is defined on the one or more blades. Element 2: wherein the cavity comprises an opening to receive the rolling element, a first arcuate portion that extends from one side of the opening and exhibits a first radius, a second arcuate portion that extends from an opposing side of the opening and exhibits a second radius greater than first radius; and an end wall that provides a transition between the first and second arcuate portions, wherein the retainer slot is defined in part by the second arcuate portion and the end wall. Element 3: wherein the cavity provides a first side surface and a second side surface opposite the first side surface, and wherein a bearing element is positioned on one or both of the first and second side surfaces. Element 4: wherein the retainer comprises a material selected from the group consisting of steel, a steel alloy, tungsten carbide, a sintered tungsten carbide composite, cemented carbide, polycrystalline diamond, thermally stable polycrystalline diamond, cubic boron nitride, impregnated diamond, nanocrystalline diamond, ultra-nanocrystalline diamond, zirconia, any derivatives thereof, and any combination thereof. Element 5: wherein the retainer is secured within the retainer slot using at least one of brazing, welding, an industrial adhesive, press-fitting, shrink-fitting, and a mechanical fastener. Element 6: further comprising an extraction feature defined on the retainer. Element 7: further comprising an access groove defined in the bit body to access the extraction feature. Element 8: wherein the retainer comprises an arcuate body having a polygonally symmetric or polygonally asymmetric cross-sectional shape. Element 9: further comprising one or more depressions defined in an inner arcuate surface of the retainer, and a hardfacing material received within at least one of the one or more depressions. Element 10: further comprising one or more material cavities defined in an outer arcuate surface of the retainer to retain a locking material used to secure the retainer within the cavity. Element 11: wherein the rolling element assembly is oriented on the bit body to exhibit a side rake angle ranging between 0° and 45°. Element 12: wherein the rolling element assembly is oriented on the bit body to exhibit a side rake angle ranging between 45° and 90° and thereby operates as a depth of cut controller. Element 13: wherein the rolling element assembly is oriented on the bit body to exhibit a back rake angle ranging between 0° and 45°, thereby allowing the rolling element to operate as a cutter. Element 14: wherein the rotational axis of the rolling element lies on a plane that passes through a longitudinal axis of the bit body. Element 15: wherein the rotational axis of the rolling element lies on a plane that is perpendicular to a longitudinal axis of the bit body. Element 16: wherein the rolling element exhibits a variable diameter between a first axial end and a second axial end. Element 17: wherein the retainer provides an inner arcuate surface that is concave to receive the rolling element with the variable diameter.
Element 18: wherein the retainer comprises an arcuate body having a first end and a second end opposite the first end, an arcuate inner surface extending between the first and second ends, an arcuate outer surface opposite the inner arcuate surface and extending between the first and second ends, a first sidewall extending radially between the inner and outer arcuate surfaces, and a second sidewall opposite the first sidewall and extending radially between the inner and outer arcuate surfaces. Element 19: further comprising an extraction feature defined in the outer arcuate surface. Element 20: further comprising one or more depressions defined in the inner arcuate surface, and a hardfacing material received within at least one of the one or more depressions. Element 21: further comprising one or more material cavities defined in the outer arcuate surface to retain a locking material used to secure the retainer within the cavity.
By way of non-limiting example, exemplary combinations applicable to A and B include: Element 6 with Element 7; Element 16 with Element 17; and Element 18 with Element 19.
Therefore, the disclosed systems and methods are well adapted to attain the ends and advantages mentioned as well as those that are inherent therein. The particular embodiments disclosed above are illustrative only, as the teachings of the present disclosure may be modified and practiced in different but equivalent manners apparent to those skilled in the art having the benefit of the teachings herein. Furthermore, no limitations are intended to the details of construction or design herein shown, other than as described in the claims below. It is therefore evident that the particular illustrative embodiments disclosed above may be altered, combined, or modified and all such variations are considered within the scope of the present disclosure. The systems and methods illustratively disclosed herein may suitably be practiced in the absence of any element that is not specifically disclosed herein and/or any optional element disclosed herein. While compositions and methods are described in terms of “comprising,” “containing,” or “including” various components or steps, the compositions and methods can also “consist essentially of” or “consist of” the various components and steps. All numbers and ranges disclosed above may vary by some amount. Whenever a numerical range with a lower limit and an upper limit is disclosed, any number and any included range falling within the range is specifically disclosed. In particular, every range of values (of the form, “from about a to about b,” or, equivalently, “from approximately a to b,” or, equivalently, “from approximately a-b”) disclosed herein is to be understood to set forth every number and range encompassed within the broader range of values. Also, the terms in the claims have their plain, ordinary meaning unless otherwise explicitly and clearly defined by the patentee. Moreover, the indefinite articles “a” or “an,” as used in the claims, are defined herein to mean one or more than one of the elements that it introduces. If there is any conflict in the usages of a word or term in this specification and one or more patent or other documents that may be incorporated herein by reference, the definitions that are consistent with this specification should be adopted.
As used herein, the phrase “at least one of” preceding a series of items, with the terms “and” or “or” to separate any of the items, modifies the list as a whole, rather than each member of the list (i.e., each item). The phrase “at least one of” allows a meaning that includes at least one of any one of the items, and/or at least one of any combination of the items, and/or at least one of each of the items. By way of example, the phrases “at least one of A, B, and C” or “at least one of A, B, or C” each refer to only A, only B, or only C; any combination of A, B, and C; and/or at least one of each of A, B, and C.
The Abstract of the disclosure is solely for providing the United States Patent and Trademark Office and the public at large with a way by which to determine quickly from a cursory reading the nature and gist of technical disclosure, and it represents solely one or more examples.
While various examples have been illustrated in detail, the disclosure is not limited to the examples shown. Modifications and adaptations of the above examples may occur to those skilled in the art. Such modifications and adaptations are in the scope of the disclosure.
The present application claims priority to International Patent Application No. PCT/US2016/037991, entitled Rolling Element with Half Lock, filed Jun. 17, 2016.
Filing Document | Filing Date | Country | Kind |
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PCT/US2017/038005 | 6/16/2017 | WO | 00 |