Systems for drilling wellbores into the earth for the recovery of hydrocarbons, such as oil and natural gas, typically include a drill bit mounted on the lower end of a drill string. Several different types of drill bits exist depending on the primary mechanism by which the drill bit advances into the earthen formation. Common drill bits include rotary cone bits, drag bits, and percussion bits. Additionally, conventional drill bits include a plurality of inserts or cutting elements on a face of the drill bit that are configured to engage the earthen formation.
In a percussion drilling operation, a hammer is repeatedly raised and lowered to strike an end of the percussion bit, which strikes the earthen formation and thereby progressively increases the depth of the wellbore into the earthen formation (e.g., by crushing, breaking, and/or loosening the earthen formation). In a rotary cone drilling operation, a rotary cone bit having one or more cones is rotated against an earthen formation. An axial force is also applied to the rotary cone bit to progressively increase the depth of the wellbore into the earthen formation (e.g., by crushing, breaking, and/or loosening the earthen formation).
With conventional drilling systems, the rate of penetration (“ROP”) of the drill bit into the earthen formation is limited, in part, by the energy delivered to the drill bit (e.g., the hammer force applied to the percussion drill bit or the torque applied to the drag bit or the rotary cone drill bit). The ROP of conventional drilling systems is also limited by the geometry and the size of the cutting elements or the portion thereof that engages the earthen formation. For instance, conventional drill bits may include geometric features such that energy delivered to the drill bit during a drilling operation is distributed over a relatively large surface area of the drill bit. Thus, the energy delivered to the drill bit may be dispersed over a relatively large area of the earthen formation, which may limit the ROP of the conventional drilling systems.
Embodiments of ultra-hard cutting elements for use with a drill bit are disclosed. In one embodiment, the ultra-hard cutting element includes a base portion defining a longitudinal axis, an extension portion on an end of the base portion, and a lip on an outer surface of the extension portion. At least a portion of the outer surface of the extension portion includes an ultra-hard abrasive material. The ultra-hard abrasive material may be polycrystalline diamond or polycrystalline cubic boron nitride. At least a portion of the ultra-hard abrasive material may have a hardness of at least approximately 4000 kg/mm2. The outer surface may include a first spherical portion having a first radius of curvature and a second spherical portion having a second radius of curvature less than the first radius of curvature. The lip may be defined between the first spherical portion and the second spherical portion. The lip may extend beyond the first spherical portion or an outer end of the lip may be flush with the first spherical portion. The lip may include cutting face extending between the first spherical portion and the second spherical portion. The cutting face may be substantially perpendicular to the second spherical portion. The cutting face may be canted at an angle from approximately 15 degrees to approximately 60 degrees relative to the second spherical portion. The lip may extend diametrically across the outer surface. The lip may be offset from the longitudinal axis. A height of the lip may between a higher end proximate the longitudinal axis and lower ends proximate an interface edge between the outer surface and a sidewall of the base portion. A height of the lip may be substantially constant along a length of the lip.
The present disclosure is also directed to various embodiments of a drill bit. In one embodiment, the drill bit includes a shank, a bit body on one end of the shank, a series of cutter pockets in the bit body, and a series of ultra-hard cutting elements at least partially received in the cutter pockets. At least one of the ultra-hard cutting elements includes a base portion defining a longitudinal axis, an extension portion on an end of the base portion, and a lip on an outer surface of the extension portion. At least a portion of the outer surface of the extension portion includes an ultra-hard abrasive material. The ultra-hard abrasive material may be polycrystalline diamond or polycrystalline cubic boron nitride. The outer surface may include a first spherical portion having a first radius of curvature and a second spherical portion having a second radius of curvature less than the first radius of curvature. The lip may be defined between the first spherical portion and the second spherical portion. The lip may extend beyond the first spherical portion or an outer end of the lip may be flush with the first spherical portion. The lip may extend diametrically across the outer surface. A height of the lip may between a higher end proximate the longitudinal axis and lower ends proximate an interface edge between the outer surface and a sidewall of the base portion. A height of the lip may substantially constant along a length of the lip. The ultra-hard cutting elements may be oriented on the bit body such that the lips extend radially toward a longitudinal axis of the shank.
This summary is provided to introduce a selection of concepts that are further described below in the detailed description. This summary is not intended to identify key or essential features of the claimed subject matter, nor is it intended to be used in limiting the scope of the claimed subject matter.
These and other features and advantages of embodiments of the present disclosure will become more apparent by reference to the following detailed description when considered in conjunction with the following drawings. In the drawings, like reference numerals are used throughout the figures to reference like features and components. The figures are not necessarily drawn to scale.
The present disclosure is directed to various embodiments of ultra-hard cutting elements for use in a drill bit, such as, for instance, a percussive drill bit, a rotary cone bit, a drag bit, or a reamer, for drilling a wellbore into an earthen formation for the recovery of hydrocarbons. Embodiments of the ultra-hard cutting elements of the present disclosure include geometric features configured to increase the rate of penetration (“ROP”) of the drill bit into the earthen formation compared to conventional drill bits. Embodiments of the ultra-hard cutting elements of the present disclosure may include one or more geometric features configured to concentrate the force of the hammering action of the drill bit onto a localized area of the earthen formation. Embodiments of the cutting elements of the present disclosure may also include one or more geometric features configured to cut into the earthen formation during the rotary action of the drill bit.
With reference now to
With reference now to
The extension portion 107 of the ultra-hard cutting element 105 includes first and second outer formation-engaging surfaces 110, 111. The ultra-hard cutting element 105 also includes a circumferential edge 112 at the interface between the extension portion 107 and the cylindrical sidewall 109 of the base portion 106. In the illustrated embodiment, the outer formation-engaging surfaces 110, 111 of the extension portion 107 are spherical or substantially spherical. The extension portion 107 also defines a pair of apices or crowns 113, 114 on the first and second outer formation-engaging surfaces 110, 111, respectively, that are furthest from the circular base 108 of the base portion 106. The outer formation-engaging surfaces 110, 111 of the extension portion 107 have a maximum height H1, H2, respectively, defined between the apices 113, 114 and a plane that is perpendicular to the longitudinal axis A and extends through the circumferential edge 112. The outer formation-engaging surfaces 110, 111 of the extension portion 107 also have radii of curvature R1, R2, respectively. In one embodiment, the maximum heights H1, H2 of the outer formation-engaging surfaces 110, 111 of the extension portion 107 may be less than the respective radii of curvature R1, R2 of the outer formation-engaging surfaces 110, 111. In one or more alternate embodiments, the maximum heights H1, H2 of the outer formation-engaging surfaces 110, 111 of the extension portion 107 may be equal or substantially equal to the respective radii of curvature R1, R2 of the outer formation-engaging surfaces 110, 111. In one or more embodiments, the outer formation-engaging surfaces 110, 111 of the extension portion 107 may have any other suitable shape, such as, for instance, ellipsoidal or substantially ellipsoidal. Additionally, in one or more embodiments, at least one of the outer formation-engaging surfaces 110, 111 may include a flat or substantially flat segment or portion (e.g., at least one of the outer formation-engaging surfaces 110, 111 may include a straight segment and a curved segment).
Still referring to the embodiment illustrated in
In the illustrated embodiment, the lip 115 includes a cutting face 116 configured cut into the earthen formation when the ultra-hard cutting element 105 is rotated against the earthen formation. In the illustrated embodiment, the cutting face 116 of the lip 115 is canted at an angle a relative to a plane perpendicular to the first and second outer formation-engaging surfaces 110, 111. In one embodiment, the angle a of the cutting face 116 relative to the first and second outer formation-engaging surfaces 110, 111 may be from approximately 15 degrees to approximately 60 degrees. In one or more embodiments, the angle a of the cutting face 116 may be less than approximately 15 degrees or greater than approximately 60 degrees. In one or more alternate embodiments, the cutting face 116 of the lip 115 may be perpendicular or substantially perpendicular to the first and second outer formation-engaging surfaces 110, 111. Additionally, in the illustrated embodiment, an outer end 117 of the cutting face 116 is rounded such that the lip 115 blends into the first outer formation-engaging surface 110 (e.g., the outer end 117 of the cutting face 116 may include a radius). In one or more alternate embodiments, the outer end 117 of the cutting face 116 may define a sharp edge. In one or more alternate embodiments, the outer end 117 of the cutting face 116 may include a chamfer. Opposite sides of the chamfer may be either rounded (e.g., include a radius) or may define sharp edges. Additionally, in one embodiment, an inner end 118 of the cutting face 116 may be rounded such that the lip 115 blends into the second outer formation-engaging surface 111, although in one or more alternate embodiments, the inner end 118 of the lip 115 may define a sharp edge.
A height h of the lip 115 is defined between the inner end 118 and the outer end 117 of the cutting face 116 (i.e., the height h of the lip 115 is defined between the first outer formation-engaging surface 110 and the second outer formation-engaging surface 111). In the illustrated embodiment, the height h of the lip 115 tapers between a highest point proximate the apex 113 of the first outer formation-engaging surface 110 (i.e., the intersection between the longitudinal axis A and the first outer formation-engaging surface 110) and lowest points proximate the circumferential interface edge 112 where the extension portion 107 joins the sidewall 109 of the base portion 106. In one or more embodiments, the highest point of the lip 115 may be at any other suitable location, such as, for instance, proximate the circumferential interface edge 112 or at an intermediate point between the apex 113 and the circumferential interface edge 112. Additionally, in the illustrated embodiment, the height h of the lip 115 at or proximate the circumferential interface edge 112 is zero or substantially zero. In one or more embodiments, the radius of curvature R1 of the first outer formation-engaging surface 110 and/or the radius of curvature R2 of the second outer formation-engaging surface 111 varies such that the height h of the lip 115 tapers toward the circumferential interface edge 112. In one or more alternate embodiments, the height h of the lip 115 may be constant or substantially constant along the length of the lip 115. In one embodiment in which the height h of the lip 115 is constant or substantially constant, the radii of curvature R1, R2 of the first and second outer formation-engaging surfaces 110, 111 may not vary (i.e., the radii of curvature R1, R2 of the first and second outer formation-engaging surfaces 110, 111 may be constant or substantially constant). In one or more embodiments, the lip 115 may include a segment or a portion that has a constant or substantially constant height and a segment that tapers between a higher end and a lower end. In one embodiment, the height h of the lip 115 may not taper uniformly. The lip 115 may have any suitable maximum height h depending, for instance, on the desired performance characteristics of the ultra-hard cutting element 105 and the composition of the earthen formation the ultra-hard cutting element 105 is intended to drill through. In one embodiment, the ratio of the maximum height h of the lip 115 to the diameter D of the cylindrical sidewall 109 of the ultra-hard cutting element 105 may be from approximately 0.01 to approximately 0.4. In one or more embodiments, the ratio of the maximum height h of the lip 115 to the diameter D of the cylindrical sidewall 109 of the ultra-hard cutting element 105 may be from approximately 0.01 to approximately 0.1. In one or more embodiments, the ratio of the maximum height h of the lip 115 to the diameter D of the cylindrical sidewall 109 may be greater than 0.4. In another embodiment, the ratio of the maximum height h of the lip 115 to the diameter D of the cylindrical sidewall 109 may be less than 0.01.
At least a portion of the first outer formation-engaging surface 110, the second outer formation-engaging surface 111, and/or the lip 115 may be formed from any material having highly abrasive and/or wear-resistant properties. In one embodiment, at least a portion of the outer formation-engaging surfaces 110, 111 and the lip 115 may include polycrystalline diamond (“PCD”) or polycrystalline cubic boron nitride (“PCBN”). In one embodiment, the outer formation-engaging surfaces 110, 111 and the lip 115 of the ultra-hard cutting element 105 may include any suitable type of thermally stable polycrystalline diamond (e.g., leached PCD, non-metal catalyst PCD, or catalyst-free PCD) or thermally stable PCBN. In one embodiment, the material of at least a portion of the outer formation-engaging surfaces 110, 111 and the lip 115 of the ultra-hard cutting element 105 may have a hardness greater than or equal to approximately 4000 kg/mm2. In one or more alternate embodiments, the material of at least a portion of the outer formation-engaging surfaces 110, 111 and the lip 115 of the ultra-hard cutting element 105 may have a hardness less than approximately 4000 kg/mm2. Although in one embodiment only the outer formation-engaging surfaces 110, 111 and the lip 115 (or portions thereof) are formed from PCD or PCBN, in one or more embodiments, any other suitable portion of the extension portion 107 may be formed from PCD or PCBN. For instance, in one embodiment, all or substantially all of the extension portion 107 may be formed from PCD or PCBN. Additionally, in one or more embodiments, the material properties of at least one of the outer formation-engaging surfaces 110, 111 and the lip 115 may be different than the material properties of at least one of the other outer formation-engaging surfaces 110, 111 and the lip 115. For instance, in one embodiment, one of the outer formation-engaging surfaces 110, 111 or the lip 115 may have a hardness less than one of the other outer formation-engaging surfaces 110, 111 or the lip 115 by approximately 500 kg/mm2 to approximately 2500 kg/mm2, such as, for instance, by approximately 2200 kg/mm2.
In one embodiment, a remainder of the ultra-hard cutting element 105 (i.e., the portion of the ultra-hard cutting element 105 other than the outer formation-engaging surfaces 110, 111 and the lip 115) may be formed from any suitably hard and durable material, such as, for instance, tungsten carbide or other matrix materials of carbides, nitrides, and/or borides. In one embodiment, the material of the remainder of the ultra-hard cutting element 105 may be selected to facilitate coupling (e.g., by welding or brazing) the ultra-hard cutting element 105 to the percussion drill bit 100 during a process of manufacturing the drill bit 100, as described in more detail below. Additionally, in one embodiment, a portion of the material of the remainder of the ultra-hard cutting element 105 may be infiltrated into interstitial spaces (e.g., pores or voids) defined between a network of interconnected crystals of the PCD or PCBN outer formation-engaging surfaces 110, 111 and/or the PCD or PCBN cutting face 116 of the lip 115.
In one embodiment, the ultra-hard cutting element 105 may include one or more transition layers (e.g., a diamond-tungsten carbide composite material). For instance, in one embodiment, the ultra-hard cutting element 105 may include a transition layer between the PCD or PCBN outer formation-engaging surfaces 110, 111 and the lip 115 and an inner portion of the ultra-hard cutting element 105 formed from tungsten carbide. The material of the transition layer may be selected such that the transition layer has a coefficient of thermal expansion that is between a coefficient of thermal expansion of the PCD or PCBN outer formation-engaging surfaces 110, 111 and the lip 115 and a coefficient of thermal expansion of tungsten carbide of the inner portion of the ultra-hard cutting element 105. In one embodiment, the material of the transition layer may also be selected such that the transition layer has an elastic modulus that is between the elastic modulus of the PCD or PCBN outer formation-engaging surfaces 110, 111 and the lip 115 and the elastic modulus of the tungsten carbide of the inner portion of the ultra-hard cutting element 105. In one embodiment, a portion of the transition layer may be infiltrated into the interstitial spaces defined between the network of interconnected crystals of the PCD or PCBN outer formation-engaging surfaces 110, 111 and/or the PCD or PCBN lip 115 (e.g., cobalt from the transition layer may be infiltrated into the PCD or PCBN on the outer formation-engaging surfaces 110, 111 and/or infiltrated into the PCD or PCBN on the lip 115). Accordingly, in one embodiment, the transition layer may be configured to mitigate the formation of thermal stress concentrations which might otherwise develop when the ultra-hard cutting element 105 is subject to elevated temperatures, such as during a drilling operation, due to the thermal expansion differential between the PCD or PCBN layer and the tungsten carbide (i.e., the one or more transition layers may be configured to mitigate the formation of thermal cracks in the outer formation-engage surfaces 110, 111 and/or the lip 115 due to the thermal expansion differential between the PCD or PCBN on the outer formation-engaging surfaces 110, 111 and the lip 115 and the inner tungsten carbide, which may result in the premature failure of the ultra-hard cutting element 105). The transition layer may also serve to reduce the elastic mismatch between the PCD or PCBN outer formation-engaging surfaces 110, 111 and the lip 115 and the tungsten carbide of the inner portion of the ultra-hard cutting element 105, thereby improving reliability of the ultra-hard cutting element 105, particularly during dynamic loading of the ultra-hard cutting element 105.
With reference now to
The extension portion 202 of the ultra-hard cutting element 200 includes first and second outer formation-engaging surfaces 205, 206. The ultra-hard cutting element 200 also includes a circumferential edge 207 at the interface between the extension portion 202 and the cylindrical sidewall 204 of the base portion 201. In the illustrated embodiment, the outer formation-engaging surfaces 205, 206 of the extension portion 202 are spherical or substantially spherical. The extension portion 202 also defines a pair of apices or crowns 208, 209 on the first and second outer formation-engaging surfaces 205, 206, respectively, that are furthest from the circular base 203 of the base portion 201. The outer formation-engaging surfaces 205, 206 of the extension portion 202 have a maximum height H1′, H2′, respectively, defined between the apices 208, 209 and a plane that is perpendicular to the longitudinal axis A′ and extends through the circumferential edge 207. The outer formation-engaging surfaces 205, 206 of the extension portion 202 also have radii of curvature R1′, R2′, respectively. In one embodiment, the maximum heights H1′, H2′ of the outer formation-engaging surfaces 205, 206 of the extension portion 202 may be less than the respective radii of curvature R1′, R2′ of the outer formation-engaging surfaces 205, 206. In one or more alternate embodiments, the maximum heights H1′, H2′ of the outer formation-engaging surfaces 205, 206 of the extension portion 202 may be equal or substantially equal to the respective radii of curvature R1′, R2′ of the outer formation-engaging surfaces 205, 206. In one or more embodiments, the outer formation-engaging surfaces 205, 206 of the extension portion 202 may have any other suitable shape, such as, for instance, ellipsoidal or substantially ellipsoidal. Additionally, in one or more embodiments, at least one of the outer formation-engaging surfaces 205, 206 may include a flat or substantially flat segment or portion (e.g., at least one of the outer formation-engaging surfaces 205, 206 may include a straight segment and a curved segment).
Still referring to the embodiment illustrated in
In one embodiment, at least a portion of the first and second outer formation-engaging surfaces 205, 206 and the lip 210 may be formed from any material having highly abrasive and/or wear-resistant properties, such as, for instance, PCD, PCBN, and/or any material having a hardness greater than or equal to approximately 4000 kg/mm2. In one or more embodiments, the first and second outer formation-engaging surfaces 205, 206 and the lip 210 may be formed from a material having a hardness less than approximately 4000 kg/mm2. Although in one embodiment only the first and second outer formation-engaging surfaces 205, 206 and the lip 210 (or portions thereof) of the extension portion 202 are formed from PCD or PCBN, in one or more embodiments, any other suitable portion of the extension portion 202 may be formed from PCD or PCBN. For instance, in one embodiment, all or substantially all of the extension portion 202 may be formed from PCD or PCBN. Additionally, in one or more embodiments, the material properties of at least one of the outer formation-engaging surfaces 205, 206 and the lip 210 may be different than the material properties of at least one of the other outer formation-engaging surfaces 205, 206 and the lip 210. For instance, in one embodiment, one of the outer formation-engaging surfaces 205, 206 or the lip 210 may have a hardness less than one of the other outer formation-engaging surfaces 205, 206 or the lip 210 by approximately 500 kg/mm2 to approximately 2500 kg/mm2, such as, for instance, by approximately 2200 kg/mm2.
In the illustrated embodiment, the lip 210 includes a cutting face 211 configured cut into the earthen formation when the ultra-hard cutting element 200 is rotated against the earthen formation. In the illustrated embodiment, the cutting face 211 of the lip 210 is perpendicular or substantially perpendicular to the first and second outer formation-engaging surfaces 205, 206. In one or more embodiments, the cutting face 211 of the lip 210 may canted at an angle relative to a plane perpendicular to the first and second outer formation-engaging surfaces 205, 206. Additionally, in the illustrated embodiment, an outer end 212 of the cutting face 211 is rounded such that the lip 210 blends into the first outer formation-engaging surface 205. In one or more alternate embodiments, the outer end 212 of the cutting face 211 may define a sharp edge. In one or more alternate embodiments, the outer end 212 of the cutting face 211 may include a chamfer. Opposite sides of the chamfer may be either rounded (e.g., include a radius) or may define sharp edges. Additionally, in one embodiment, an inner end 213 of the cutting face 211 may be rounded such that the lip 210 blends into the second outer formation-engaging surface 206, although in one or more alternate embodiments, the inner end 213 of the lip 210 may define a sharp edge.
Accordingly, when the ultra-hard cutting element 200 is used in a rotary hammer or hammer drilling operation, the hammering force is initially concentrated on the lip 210 because the lip 210 projects above the first outer formation-engaging surface 205 (i.e., the hammering force imparted to the ultra-hard cutting element 200 during a drilling operation is initially concentrated on the lip 210, rather than distributed across the area of the first and second outer formation-engaging surfaces 205, 206). The concentration of the hammering force onto the lip 210 may increase the rate of penetration of the drill bit 100 incorporating the ultra-hard cutting element 200 into an earthen formation compared to conventional drill bits (i.e., when the ultra-hard cutting elements 200 of the present disclosure are used in a rotary percussive drilling operation, the geometry of the cutting elements 200 is configured to concentrate the percussive force of the impact on a localized region of the earthen formation corresponding to the size of the lip 210, which serves to advance the drill bit further into the earthen formation). Additionally, in a rotary hammer drilling operation the percussive drill bit 100 is rotated to index the drill bit 100 to a new earthen formation with each impact. Accordingly, when the ultra-hard cutting element 200 is used in a rotary hammer drilling operation, the cutting face 211 of the lip 210 is configured to shear or cut into the earthen formation due to the rotation of the drill bit 100.
A height h′ of the lip 210 is defined between the inner end 213 and the outer end 212 of the cutting face 211. In the illustrated embodiment, the height h′ of the lip 210 tapers between a highest point proximate the apices 208, 209 of the outer formation-engaging surfaces 205, 206 (i.e., the intersection between the longitudinal axis A′ and the outer formation-engaging surface 205, 206) and lowest points proximate the circumferential interface edge 207 where the extension portion 202 joins the sidewall 204 of the base portion 201. In one or more embodiments, the highest point of the lip 210 may be at any other suitable location, such as, for instance, proximate the circumferential interface edge 207 or at an intermediate point between the apices 208, 209 and the circumferential interface edge 207. Additionally, in the illustrated embodiment, the height h′ of the lip 210 at or proximate the circumferential interface edge 207 is zero or substantially zero. In one or more embodiments, the radius of curvature R1′ of the first outer formation-engaging surface 205 and/or the radius of curvature R2′ of the second outer formation-engaging surface 206 varies such that the height h′ of the lip 210 tapers toward the circumferential interface edge 207. In one or more alternate embodiments, the height h′ of the lip 210 may be constant or substantially constant along the length of the lip 210. In one embodiment in which the height h′ of the lip 210 is constant or substantially constant, the radii of curvature R1′, R2′ of the first and second outer formation-engaging surfaces 205, 206 may not vary (i.e., the radii of curvature R1′, R2′ of the first and second outer formation-engaging surfaces 205, 206 may be constant or substantially constant). In one or more embodiments, the lip 210 may include a segment or a portion that has a constant or substantially constant height and a segment that tapers between a higher end and a lower end. In one embodiment, the height h′ of the lip 210 may not taper uniformly. The lip 210 may have any suitable maximum height h′ depending, for instance, on the desired performance characteristics of the ultra-hard cutting element 200 and the composition of the earthen formation the ultra-hard cutting element 200 is intended to drill through. In one embodiment, the ratio of the maximum height h′ of the lip 210 to the diameter D′ of the cylindrical sidewall 204 of the ultra-hard cutting element 200 may be from approximately 0.01 to approximately 0.4. In one or more embodiments, the ratio of the maximum height h′ of the lip 210 to the diameter D′ of the cylindrical sidewall 204 of the ultra-hard cutting element 200 may be from approximately 0.01 to approximately 0.1. In one or more embodiments, the ratio of the maximum height h′ of the lip 210 to the diameter D′ of the cylindrical sidewall 204 may be greater than 0.4. In another embodiment, the ratio of the maximum height h′ of the lip 210 to the diameter D′ of the cylindrical sidewall 204 may be less than 0.01.
In one embodiment, the ultra-hard cutting element 200 may include one or more transition layers (e.g., a diamond-tungsten carbide composite material). For instance, in one embodiment, the ultra-hard cutting element 200 may include a transition layer between the PCD or PCBN outer formation-engaging surfaces 205, 206 and the lip 210 and an inner portion of the ultra-hard cutting element 200 formed from tungsten carbide. The material of the transition layer may be selected such that the transition layer has a coefficient of thermal expansion that is between a coefficient of thermal expansion of the PCD or PCBN outer formation-engaging surfaces 205, 206 and the lip 210 and a coefficient of thermal expansion of tungsten carbide of the inner portion of the ultra-hard cutting element 200. In one embodiment, the material of the transition layer may also be selected such that the transition layer has an elastic modulus that is between the elastic modulus of the PCD or PCBN outer formation-engaging surfaces 205, 206 and the lip 210 and the elastic modulus of the tungsten carbide of the inner portion of the ultra-hard cutting element 200. In one embodiment, a portion of the transition layer may be infiltrated into the interstitial spaces defined between the network of interconnected crystals of the PCD or PCBN outer formation-engaging surfaces 205, 206 and/or the PCD or PCBN lip 210 (e.g., cobalt from the transition layer may be infiltrated into the PCD or PCBN on the outer formation-engaging surfaces 205, 206 and/or infiltrated into the PCD or PCBN on the lip 210).
The ultra-hard cutting elements 105, 200 of the present disclosure may have any suitable arrangement and orientation on the drill bit 100 (see
With reference now to
With continued reference to
With continued reference to
In one embodiment, the forming device 407 is configured to deform the can 402, the solid particulates 401, and the extension portion 406 of the substrate 404 into the shape of the first and second inner surfaces 409, 410 and the depression 411 when the can 402 and the substrate 404 are pressed onto the recess 408 in the forming device 407. In one embodiment, the forming device 407 may be configured not to deform the extension portion 406 of the substrate 404 (e.g., the forming device 407 may be configured to deform only the solid particulates 401 and the deformable can 402). In one or more alternate embodiments, the can 402 may not be deformable and the can 402 may be pre-formed or pre-shaped into the desired shape (or a portion thereof) of the ultra-hard cutting element 105, 200. In the illustrated embodiment, the first and second inner surfaces 409, 410 in the forming device 407 are configured to form first and second outer formation-engaging surfaces of the ultra-hard cutting element 105, 200 (e.g., the first and second outer formation-engaging surfaces 110, 111 in
Pressing the can 402 and the substrate 404 onto the forming device 407 may also cause the solid particulates 401 (e.g., diamond powder) to become a solid mass. Pressing the can 402 and the substrate 404 onto the forming device 407 may also create a connection (e.g., a press-fit connection) between the solid particulate mass 401 and an outer surface 412 of the extension portion 406 of the substrate 404.
Still referring to
A catalyst material may be used to facilitate and promote the inter-crystalline bonding of the diamond crystals. In one or more embodiments, the catalyst material may be mixed into the diamond powder prior to the HPTP sintering process and/or may infiltrate the diamond powder from an adjacent substrate during the HPHT sintering process. The HPHT sintering process creates a polycrystalline diamond structure having a network of intercrystalline bonded diamond crystals, with the catalyst material remaining in interstitial spaces (e.g., voids or gaps) between the bonded diamond crystals. In one embodiment, the catalyst material may be a solvent catalyst metal selected from Group VIII of the Periodic table (e.g., iron), Group IX of the Periodic table (e.g., cobalt), or Group X of the Periodic table (e.g., nickel). Accordingly, the HPHT sintering process forms the ultra-hard cutting element 105, 200 having a substrate 404 and solid particulate mass 401 (e.g., polycrystalline diamond structure) coupled to the outer surface 412 of the substrate 404. The ultra-hard cutting element 105, 200 may be removed from the can 402 and the forming device 407 following the HPHT sintering process.
The method 300 may also include a task 320 of coupling a plurality of the ultra-hard cutting elements 105, 200 to a drill bit (e.g., a percussion drill bit 100, a rotary cone drill bit, a drag bit, or a reamer). In one embodiment, the task 320 of coupling the ultra-hard cutting elements 105, 200 to the drill bit includes brazing the ultra-hard cutting elements 105, 200 in the cutter pockets 104 defined in the bit face 103 of the drill bit 100. In one or more embodiments, the task 320 of coupling the ultra-hard cutting elements 105, 200 to the drill bit may include any other suitable manufacturing technique or process, such as, for instance, welding (e.g., laser beam welding).
While this invention has been described in detail with particular references to embodiments thereof, the embodiments described herein are not intended to be exhaustive or to limit the scope of the invention to the exact forms disclosed. Persons skilled in the art and technology to which this invention pertains will appreciate that alterations and changes in the described structures and methods of assembly and operation can be practiced without meaningfully departing from the principles, spirit, and scope of this invention. Additionally, as used herein, the term “substantially” and similar terms are used as terms of approximation and not as terms of degree, and are intended to account for the inherent deviations in measured or calculated values that would be recognized by those of ordinary skill in the art. Furthermore, as used herein, when a component is referred to as being “on” or “coupled to” another component, it can be directly on or attached to the other component or intervening components may be present therebetween.
This application claims the benefit of U.S. Provisional Application No. 62/098,539, entitled “CUTTING ELEMENTS AND DRILL BITS INCORPORATING THE SAME,” filed Dec. 31, 2014, the disclosure of which is hereby incorporated herein by reference.
Filing Document | Filing Date | Country | Kind |
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PCT/US2015/063919 | 12/4/2015 | WO | 00 |
Number | Date | Country | |
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62098539 | Dec 2014 | US |