BACKGROUND1. Field of the Disclosure
The following is directed to cutting elements for use in drill bits for drilling subterranean formations and more particularly, cutting elements utilizing a cutting table comprising a superabrasive layer and an abrasive insert.
2. Description of the Related Art
In the past, rotary drill bits have incorporated cutting elements employing superabrasive materials, including synthetic diamond cutters using polycrystalline diamond compacts, otherwise termed “PDC” cutters. Such PDC cutters have had various shapes and designs, including self-supported cutters, otherwise a monolithic object solely of the made of the desired cutting material, or alternatively, cutters employing a polycrystalline diamond layer or “table” on a substrate made of a hard metal material suitable for supporting the diamond layer.
Despite improvements in PDC cutter designs, certain obstacles remain, including for example, performance degradation and failure of cutters due to mechanical strain, thermal-induced strain, and a combination of such forces. Delamination and fracture of a cutter can occur given the extreme loading and temperatures generated during drilling operations. Furthermore, repetitive heating and cooling of the cutter can amplify damage to the cutter due to differences in thermal expansion coefficient and thermal conductivity of the cutter components. Wear characteristics of cutters have also been studied to mitigate catastrophic damage to the cutter surfaces.
Various different configurations of cutters have been used to overcome some of the above noted obstacles, however, significant shortcomings are still exhibited by conventional cutters, and there remains a need in the art for improvements.
SUMMARYAccording to one aspect, a cutting element for use in a drill bit for drilling subterranean formations includes a substrate having a body having an upper surface extending transversely to a longitudinal axis of the body, a superabrasive layer overlying the upper surface of the substrate, wherein the superabrasive layer comprises an annular shape having a central opening defined by an inner surface, and an abrasive insert overlying the upper surface of the substrate. The abrasive insert can be disposed within the central opening of the superabrasive layer, wherein the abrasive insert comprises an upper surface having a surface roughness (Ra) of greater than about 1 micron.
In another aspect, a cutting element for use in a drill bit for drilling subterranean formations includes a cutting table made of a superabrasive layer comprising an annular shape having a central opening defined by an inner surface, and an abrasive insert overlying the upper surface of the substrate and disposed within the central opening of the superabrasive layer. The abrasive insert includes abrasive grit contained within a matrix material, wherein an upper region of the abrasive insert comprising an upper surface has a different amount of abrasive grit than a lower region of the abrasive insert.
In accordance with still another aspect, a cutting element for use in a drill bit for drilling subterranean formations includes a cutting table made of a superabrasive layer having an annular shape having a central opening defined by an inner surface, and an abrasive insert disposed within the central opening of the superabrasive layer, wherein the abrasive insert comprises an upper surface having a texture comprising protrusions and recesses.
BRIEF DESCRIPTION OF THE DRAWINGSThe present disclosure may be better understood, and its numerous features and advantages made apparent to those skilled in the art by referencing the accompanying drawings.
FIG. 1 includes an illustration of a subterranean drilling operation.
FIG. 2 includes an illustration of a drill bit in accordance with an embodiment.
FIGS. 3A-3C include cross-sectional illustrations and a perspective view of cutter elements in accordance with embodiments.
FIG. 4 includes a cross-sectional illustration of a portion of a cutter element in accordance with an embodiment.
FIG. 5 includes a cross-sectional illustration of a portion of a cutter element in accordance with an embodiment.
FIG. 6 includes a cross-sectional illustration of a portion of a cutter element in accordance with an embodiment.
FIGS. 7A-7C include top view illustrations of cutter elements in accordance with embodiments.
The use of the same reference symbols in different drawings indicates similar or identical items.
DESCRIPTION OF THE PREFERRED EMBODIMENT(S)The following is directed to earth boring drill bits, and more particularly, towards cutting elements used in such drill bits. The terms “bit”, “drill bit”, and “matrix drill bit” may be used in this application to refer to “rotary drag bits”, “drag bits”, “fixed cutter drill bits” or any other earth boring drill bit incorporating the teachings of the present disclosure. Such drill bits may be used to form well bores or boreholes in subterranean formations.
An example of a drilling system for drilling such well bores in earth formations is illustrated inFIG. 1. In particular,FIG. 1 illustrates a drilling system including adrilling rig101 at the surface, serving as a station for a crew of workers to operate adrill string103. Thedrill string103 defines awell bore105 extending into the earth and can include a series ofdrill pipes100 and103 that are coupled together viajoints104 facilitating extension of thedrill string103 for great depths into thewell bore105. Thedrill string103 may include additional components, such as tool joints, a kelly, kelly cocks, a kelly saver sub, blowout preventers, safety valves, and other components known in the art.
Moreover, the drill string can be coupled to a bottom hole assembly107 (BHA) including adrill bit109 used to penetrate earth formations and extend the depth of thewell bore105. The BHA107 may further include one or more drill collars, stabilizers, a downhole motor, MWD tools, LWD tools, jars, accelerators, push and pull directional drilling tools, point stab tools, shock absorbers, bent subs, pup joints, reamers, valves, and other components. Afluid reservoir111 is also present at the surface that holds an amount of liquid that can be delivered to thedrill string103, and particularly thedrill bit109, viapipes113, to facilitate the drilling procedure.
FIG. 2 includes a perspective view of a fixed cutter drill bit according to an embodiment. As shown inFIG. 2, the fixedcutter drill bit200 can include abit body213 which may be connected to ashank portion214 via a weld. Theshank portion214 can include a threadedportion215 for connection of thedrill bit200 to other components of the BHA. Thedrill bit body213 can further include abreaker slot221 extending laterally along the circumference of thedrill bit body213 to aid coupling and decoupling of thedrill bit200 to other components.
Thedrill bit200 can include acrown portion222 coupled to thedrill bit body213. As will be appreciated, thecrown portion222 can be integrally formed with thedrill bit body213 such that they are a single, monolithic piece. Thecrown portion222 can includegage pads224 situated along the sides of protrusions orblades217 that extend radially from thecrown portion222. Each of theblades217 extend from thecrown portion222 and include a plurality of cuttingmembers219 bonded to theblades217 for cutting, scraping, and shearing through earth formations when thedrill bit200 is rotated during drilling. Thecutting members219 may be tungsten carbide inserts, polycrystalline diamond compacts (PDC), milled steel teeth, and particularly those cutting elements described herein. Coatings or hard facings may be applied to thecutting members219 and other portions of thebit body213 orcrown portion222 to reduce wear and increase the life of thedrill bit200.
Thecrown portion222 can further includejunk slots227 or channels formed between theblades217 that facilitate fluid flow and removal of cuttings and debris from the well bore. Notably, thejunk slots227 can further includeopenings223 for passages extending through the interior of thecrown portion222 andbit body213 for communication of drilling fluid through thedrill bit200. Theopenings223 can be positioned at exterior surfaces of thecrown portion222 at various angles for dynamic fluid flow conditions and effective removal of debris from the cutting region during drilling.
FIGS. 3A-3C include cross-sectional illustrations and a perspective view illustration of cutting elements in accordance with an embodiment. Referring toFIG. 3A, a cross-sectional illustration of a cutting element is provided. Thecutting element300 includes asubstrate301 which can have a shape suitable for maintaining a cutting table306 thereon. Thesubstrate301 can have various shapes, for example, a cylindrical shape having a height as defined by alongitudinal axis310 extending through the body of thesubstrate301. Substrates herein can have anupper surface305 that extends transversely to thelongitudinal axis310, and a rear surface opposite and parallel to theupper surface305. It will be appreciated that other geometries may be suitable for thesubstrate301.
Thesubstrate301 can have a hardness suitable for withstanding drilling operations. That is,certain substrates301 can be made of a material having a Mohs hardness of at least about 8, or at least about 8.5, at least about 9.0, or even at least about 9.5. Particular metals or metal alloy materials may be used to form thesubstrate301. For example, thesubstrate301 can be formed of carbides, nitrides, oxides, borides, carbon-based materials, and a combination thereof. Reference herein to carbon-based materials is reference to synthetically-produced molecules made entirely of carbon and the various carbon allotropes, such as carbon nanotubes and the like. In some instances, thesubstrate301 may be made of a cemented material such as a cemented carbide. Some suitable cemented carbides may include metal carbides, and more particularly cemented tungsten carbide such that thesubstrate301 consists essentially of cemented tungsten carbide.
As illustrated, the cuttingelement300 can be formed such that a cutting table306 overlies theupper surface305 of thesubstrate301. The cutting table306 can be formed of two components, notably including asuperabrasive layer302 having an annular shape and comprising acentral opening329 as defined by aninner surface315 of thesuperabrasive layer302. Furthermore, the cutting table306 includes anabrasive insert303 overlying theupper surface305 of thesubstrate301 and disposed within thecentral opening329 of thesuperabrasive layer302 as defined by theinner surface315.
Referring briefly toFIG. 3B, a perspective view illustration provides an alternative view demonstrating the orientation between thesuperabrasive layer302 and theabrasive insert303. Thesuperabrasive layer302 is formed such that it has an annular shape, including acentral opening329 extending radially and axially around a central point at the center of the cutting table306. As further illustrated inFIG. 3B, the cutting table306 is formed such that theabrasive insert303 is configured to fit within thecentral opening329 of thesuperabrasive layer302.
Referring again toFIG. 3A, thesuperabrasive layer302 can be formed such that thecentral opening329, and therein theabrasive insert303, extend through theentire height333 of the cutting table306. However, in other embodiments, the central opening may extend for a fraction of theheight333, and therein theabrasive insert303 extends for only a fraction of theheight333 of the abrasive table306. In such designs, thesuperabrasive layer302 would be formed with a central recess (as opposed to a central opening329) that would contain theabrasive insert303.
Moreover, the cutting table306 can be formed such that thesuperabrasive layer302 comprises abottom surface312 that can directly contact theupper surface305 of thesubstrate301, and more particularly can be bonded to theupper surface305 of thesubstrate301. Theabrasive insert303 of the cutting table306 can be formed such that it comprises arear surface313 that is directly contacting theupper surface305 of thesubstrate301, and more particularly is bonded to theupper surface305 of thesubstrate301. Additionally, the cutting table306 can be formed such that thesuperabrasive layer302 is bonded to theabrasive insert303 at theinner surface315 defining the interface between the components.
Thesuperabrasive layer302 can include superabrasive materials such as diamond, boron nitride (e.g., cubic boron nitride), carbon-based materials, and a combination thereof. Some superabrasive layers may be in the form of polycrystalline materials. For instance, thesuperabrasive layer302 can consist essentially of polycrystalline diamond. With reference to those embodiments using polycrystalline diamond, thesuperabrasive layer302 can be made of various types of diamond including thermally-stable polycrystalline diamond, which can contain a lesser amount of catalyst materials (e.g., cobalt) than other diamond materials, making the material stable at higher temperatures.
The cutting table306 can be formed such that thesuperabrasive layer302 comprises aside surface309 that extends parallel to thelongitudinal axis310, anupper surface307 that extends transversely to thelongitudinal axis310, and achamfered surface308 extending between theside surface309 andupper surface307 at an angle to thelongitudinal axis310. The length and angle of the chamferedsurface308 may be controlled depending on the intended application of the cuttingelement300. It will further be appreciated that embodiments herein may utilize cutting elements having a radiused edge, wherein the edge between the upper surface and the side surface of the cutting element comprises a curved or arcuate surface defined by a radius.
Theabrasive insert303 can be formed such that it includesabrasive grit331 contained within amatrix material332, which may facilitate improved wear characteristics, mechanical integrity, and cutting ability of the cutting table306. As used herein, reference to a matrix material is reference to a solid material for containing abrasive grit therein, such as a polycrystalline material, formed from a metal or cermet material as will be described in more detail. For some cutter designs, theabrasive insert303 can be formed such that theabrasive grit331 is dispersed uniformly throughout the entire volume ofmatrix material332. In accordance with one embodiment, theabrasive insert303 is formed such that it includes at least 10 vol %abrasive grit331 contained within thematrix material332 for the entire volume of theabrasive insert303. In other designs, the amount of abrasive grit can be greater, such as on the order of at least 15 vol %, at least 25 vol %, at least 40 vol %, or even at least about 50 vol % ofabrasive grit331 contained within thematrix material332 for the entire volume of theabrasive insert303. In particular instances, the cutting table306 is designed such that theabrasive insert303 contains an amount of abrasive grit within a range between about 10 vol % and70 vol %, such as between about 15 vol % and60 vol %, and more particularly between about 20 vol % and50 vol %.
Theabrasive grit331 can be contained within amatrix material332 that comprises a metal or metal alloy material. For example, thematrix material332 can be made of a carbide material, such as a metal carbide. One suitable metal carbide material is tungsten carbide, and in fact, some cutter designs utilize amatrix material332 that consists essentially of tungsten carbide. Some other suitable metals or metal alloys may include transition metal elements.
Additionally, theabrasive grit331 can be formed of abrasive material having suitable abrading and cutting capabilities. For example, suitable abrasive materials can include oxides, borides, nitrides, carbides, carbon-containing materials, and a combination thereof. Reference herein to carbon-based materials is reference to synthetically produced molecules made entirely of carbon and various carbon allotropes, such as carbon nanotubes and the like. Certain abrasive materials for use as the abrasive grit can include alumina, silica, silicon carbide, combinations thereof and the like. In certain instances, theabrasive grit331 is formed of a superabrasive material, such as diamond, cubic boron nitride, and a combination thereof. Particular cutting elements are formed such that theabrasive insert303 uses onlyabrasive grit331 consisting of diamond.
With particular reference to embodiments employing diamond abrasive grit, the grit material can have particular multi-faceted shapes providing a plurality of sharp edges suitable for cutting and abrading hard formations. For example, the diamond abrasive grit can be cubo-octahedral, cubic faced, and the like.
Additionally, theabrasive grit331 can employ encapsulated grit, such that each of the particles ofabrasive grit331 are substantially surrounded by an encapsulating material. The encapsulating material may improve the mechanical properties of the abrasive grit (e.g., wear resistance), provide added protection for the abrasive grit during processing, particularly with regard to thermal cycling used in various manufacturing processes, and further improve the bonding characteristics between the abrasive grit and thematrix material332. Additionally, provision of encapsulated grit can facilitate proper spacing and distribution of theabrasive grit331 within thematrix material332. Suitable compositions for use as the encapsulant material can include ceramics, such as oxides, carbides, borides, nitrides, and carbon-based materials. Other encapsulant materials can include refractory metal or refractory metal alloy compositions.
Certain sizes ofabrasive grit331 can be used to aid proper functioning of theabrasive insert303. For example, theabrasive grit331 can have an average grit size of at least about 25 microns, such as at least about 50 microns, at least about 100 microns, or even at least about 200 microns. In certain instances, the abrasive grit has an average grit size within a range between about 25 microns and about 2 millimeters and more particularly between about 100 microns and about 1 millimeters, and even more particularly between about 100 microns and about 0.5 millimeter.
FIG. 3C includes a cross-sectional illustration of a cutting element in accordance with an embodiment. The cuttingelement350 includes a cutting table306 overlying theupper surface305 of thesubstrate301 as previously described in accordance withFIG. 3A. Notably, the cutting table306 ofFIG. 3C demonstrates anabrasive insert303 having a different shape than the abrasive insert of embodiment inFIG. 3A. Theabrasive insert303 and particularly, thesuperabrasive layer302 is formed such that the interface between theabrasive insert303 andsuperabrasive layer303 comprises atapered surface325. Thetapered surface325 extends at an angle to thelongitudinal axis310 such that the diameter of thecentral opening329 at theupper surface307 of thesuperabrasive layer302 is smaller than the diameter of thecentral opening329 at thebottom surface312.
FIG. 4 includes a cross-sectional illustration of a portion of a cutting element in accordance with an embodiment. The cuttingelement400 includes a cutting table406 comprising thesuperabrasive layer302 andabrasive insert303 disposed within a central opening of thesuperabrasive layer302. As illustrated, theabrasive insert303 is formed such that it has anupper surface317 having particular features. That is, in accordance with one embodiment, theabrasive insert303 can be formed such that theupper surface317 has a particular surface roughness, which may be suitable for conducting certain types of cutting operations and improving the wear characteristics of the cutting table406. In accordance with one embodiment, theabrasive insert303 can have a surface roughness (Ra) of greater than about 1 micron. It will be noted that the reference to surface roughness is an arithmetic average of the roughness profile as measured through physical (e.g., a stylus) or optical measuring techniques. In other embodiments, theabrasive insert303 is formed such that theupper surface317 has a greater surface roughness, such as on the order of greater than about 3 microns, greater than about 5 microns, greater than about 10 microns, or even greater than about 15 microns. In particular instances, theabrasive insert303 can be formed such that theupper surface317 has a surface roughness (Ra) within a range between about 1 micron and about 50 microns, such as between about 1 micron and about 30 microns, and more particularly between 1 micron and 20 microns or even more particularly between 1 micron and about 10 microns.
In addition to the characteristics of surface roughness described herein, theabrasive insert303 can be formed with anupper surface317 that has a texture defined byprojections403 and recesses404 extending across theupper surface317. Notably, theprojections403 can be formed byabrasive grit332 protruding through thematrix material332, while therecesses404 can be regions along theupper surface317 that may be absent theabrasive grit332. In particular, therecesses404 can be regions comprising primarily thematrix material332 between theprojections403 formed by theabrasive grit332.
In certain embodiments, the arrangement ofprojections403 along theupper surface317 of theabrasive insert303 can be a random orientation. That is, there is no long range or short range order between the orientation of theprojections403 with respect to each other. Moreover, therecesses404 can have a random arrangement with no short range order or long range order with respect to theprojections403 or each other. However, in other embodiments, theabrasive insert303 can be formed such that theupper surface317 has a pattern ofprojections403 and recesses404 such that they are ordered relative to each other in an array. In such embodiments, theabrasive insert303 may be cast or molded initially to form the pattern ofprojections403 and recesses404.
Embodiments herein may utilize a particular arrangement between the amount of superabrasive layer and the amount of abrasive insert forming the cutting table. For example, in certain designs the abrasive insert is formed such that it comprises at least 10 vol % of the total volume of the cutting table. In fact, certain embodiments may utilize a larger abrasive insert, such that it comprises at least 20 vol %, at least about 30 vol %, or even at least about 40 vol % of the total volume of the cutting table. Still, the size of theabrasive insert303 may be limited such that the abrasive insert comprises between about 10 vol % and60 vol %, and more particularly between about 10 vol % and50 vol % of the total volume of the cutting table.
Additionally, cutting tables of the cutting elements herein may utilize a particular arrangement between thesuperabrasive layer302 andabrasive insert303 such that a certain amount of the upper surfaces of thesecomponents307 and317 is exposed. For example, certain designs utilize a cutting table wherein the upper surface of theabrasive insert303 comprises at least about 10% of the total surface area of the upper surface of the cutting table, which includes theupper surface307 of thesuperabrasive layer302 and theupper surface317 of theabrasive insert303. In other embodiments, the percentage of the surface area occupied by theupper surface317 of theabrasive insert303 is greater, such as on the order of at least 20%, at least about 25%, or even at least 30% of the total surface area of the upper surface of the cutting table. However, the total surface area occupied by theupper surface317 of theabrasive insert303 may be limited such that it may be between about 10% and 75%, such as between about 20% and 60%, and more particularly between about 20% and 50% of the total surface area of the upper surface of the cutting table.
FIG. 5 includes a cross-sectional illustration of a portion of a cutting element in accordance with an embodiment. The cuttingelement500 illustrates a cutting table506 comprising asuperabrasive layer302 and anabrasive insert303 disposed within the central opening of thesuperabrasive layer302. In particular, theabrasive insert303 comprises alower region501 that includes therear surface313, which is bonded to theupper surface305 of thesubstrate301. Additionally, theabrasive insert303 comprises anupper region503 comprising theupper surface317 that is axially spaced apart from therear surface313 along thelongitudinal axis310. Notably, theabrasive insert303 comprises at least two distinct regions; thelower region501 andupper region503, which can represent at least two distinct layers within theabrasive insert303.
In particular cutting elements, theabrasive insert303 can be formed such that theupper region503 includes a different amount ofabrasive grit505 within thematrix material504 than the amount ofabrasive grit509 contained within thematrix material508 of thelower region501. For example, in particular embodiments, the bonding interface at therear surface313 of thelower region501 and theupper surface305 of thesubstrate301 can be substantially free ofabrasive grit509 to facilitate bonding between thelower region501 of theabrasive insert303 and theupper surface305 of thesubstrate301. Such a design may facilitate bonding of thelower region501 to theupper surface305 of thesubstrate301
In certain designs, theupper region503 comprises at least about 10% greater amount (per unit volume) of abrasive grit than thelower region501 of theabrasive insert303. In other embodiments, the amount of abrasive grit in theupper region503 as compared to thelower region501 may be greater, such as on the order of at least about 15% greater, at least about 20% greater, or even at least about 50% greater amount of abrasive grit within theupper region503 than thelower region501. Such a design may facilitate a greater amount of abrasive grit in the upper region for improved cutting and wear resistance and a lower amount of abrasive grit in thelower region501 for improved bonding of theabrasive insert303 to thesubstrate301. In particular embodiments, theupper region503 comprises between about 10% and about 100%, and more particularly between about 15% and about 80% greater amount of abrasive grit than thelower region501 of theabrasive insert503.
In alternative embodiments, theupper region503 can be formed such that it contains a lesser amount of abrasive grit than thelower region501. For instance, particular cutting designs utilize anupper region503 having at least about 10% lesser amount (per unit volume) of abrasive grit than thelower region501 of theabrasive insert303. In other embodiments, the amount of abrasive grit in theupper region503 as compared to thelower region501 may be lesser, such as on the order of at least about 15% less, at least about 20% less, or even at least about 30% less than thelower region501. Such a design can facilitate a greater stiffness of material within thelower region501 for supporting theupper region503.
While the cutting table506 is illustrated as having distinct or discrete layers defining thelower region501 andupper region503, it will be appreciated that such a change in the amount of abrasive grit may not necessarily include a layered structure, but a gradual change in the amount of abrasive grit present within the matrix material over the height of theabrasive insert303.
FIG. 6 includes a cross-sectional illustration of a portion of a cutting element in accordance with an embodiment. The cuttingelement600 includes a cutting table606 having asuperabrasive layer302 of an annular shape and defining a central opening, and further includes anabrasive insert303 disposed within the central opening of thesuperabrasive layer302. In accordance with one particular embodiment, theabrasive insert303 can comprise a graded concentration ofabrasive grit625 through the height of theabrasive insert303 such that the amount ofabrasive grit625 within thematrix material626 is different at different positions along thelongitudinal axis310 from therear surface313 of theabrasive insert303 to theupper surface317 of the abrasive insert.
In particular designs the amount of abrasive grit at theupper surface317 is greater than the amount of abrasive grit at therear surface313 such that the amount of abrasive grains increases along the height of theabrasive insert303 as defined by thelongitudinal axis310. In particular instances, the upper surface. It will be appreciated, that in certain embodiments, theabrasive insert303 can be formed such that theupper surface317 is formed to have a greater amount ofabrasive grit625 thanmatrix material626.
Still, in some alternative embodiments, the direction of abrasive grit concentration grading through the volume of theabrasive insert303 can be alternated in an axial direction, radial direction, or a combination thereof. For example, the graded direction of abrasive grit may be reversed, such that the amount ofabrasive grit625 contained within thematrix material626 decreases at distances along thelongitudinal axis310 away from therear surface313. In still other alternative embodiments, a cutting element can be formed that includes an abrasive insert having a graded amount ofabrasive grit625 contained within thematrix material626, wherein the concentration of abrasive grit increases with proximity to theinner surface605 of thesuperabrasive layer302. That is, the abrasive insert can be formed such that regions in the center of the abrasive insert along thelongitudinal axis310 comprise a lesser amount ofabrasive grit625 than regions within the abrasive insert spaced apart from thelongitudinal axis310 at a radial distance which are closer in proximity to theinner surface605 of thesuperabrasive layer302. Such designs may facilitate the formation of a cutting element capable of maintaining suitable cutting rates when the cutting table606 wears into the abrasive insert.
FIG. 7A-7C provides top view illustrations of cutting elements in accordance with an embodiment. In particular,FIGS. 7A-7C demonstrate various shapes of the abrasive insert that can be formed. In particular,FIG. 7A illustrates anabrasive insert701 contained within a central opening of asuperabrasive layer302, wherein theabrasive insert701 comprises an elliptical shape.FIG. 7B includes anabrasive insert703 having an irregular shapedabrasive insert703 containinglong arm sections704 and705 that are joined byshort arm sections706 and707.FIG. 7B illustrates that various irregular shapes are suitable for use in the abrasive insert.FIG. 7C includes a polygonal shapedabrasive insert709, in particular, an octahedral-shapedabrasive insert703 contained within a central opening of asuperabrasive layer302 for use in a cutting element.
The cutting elements described herein can be formed using one or more particular methods. For example, the superabrasive layer of the cutting table and the substrate can be formed using a high pressure/high temperature (HP/HT) process, wherein the substrate material is loaded into a HP/HT cell with the appropriate orientation and amount of diamond crystal material, typically of a size of 100 microns or less. Furthermore, a metal catalyst powder can be added to the HP/HT cell, which can be provided in the substrate or intermixed with the diamond crystal material. The loaded HP/HT cell is then placed in a process chamber, and subject to high temperatures (approximately between 1450-1600° C.) and high pressures (approximately between 50-70 kilobar), wherein the diamond crystals, stimulated by the catalytic effect of the metal catalyst powder, bond to each other and to the substrate material to form a PDC product.
For certain cutting elements, the PDC product can be further processed to form a thermally stable polycrystalline diamond material (commonly referred to as “TSP”) by leaching out the remaining metal catalyst material in the diamond layer. Alternatively, silicon, which possesses a coefficient of thermal expansion similar to that of diamond, may be used to bond diamond particles to produce a Si-bonded TSP. Such TSP materials are capable of enduring higher temperatures (on the order of 1200° C.).
With regard the to the abrasive insert, in certain processes, the abrasive insert can be formed separately from the superabrasive layer and the substrate. Certain suitable forming methods can include molding, casting, heating, pressing, and a combination thereof to give the abrasive insert the proper shape such that it fits into the cutting table with the superabrasive layer as described in embodiments herein. Notably, for more complex designs of the abrasive insert, such as those having layers or graded compositions of abrasive grit within the matrix material, individual layers or films of the appropriate material may be formed in a molding or casting cell before the final forming process. For example, a series of layers may be formed in a molding cell that includes a first layer having a predetermined amount of abrasive grit, a second layer may be formed on the first layer having a greater content of abrasive grit than the first layer, and a third layer may be formed on the second layer having a greater content of abrasive grit than the second layer, and so on. The layered structure may then be formed in a single process utilizing heat and/or pressure, such as a hot isostatic pressing process to form the abrasive insert.
After forming the abrasive insert, the insert may be fit into the cutting table, and may be particularly bonded to the superabrasive layer and the substrate. Some machining may take place such that the abrasive insert has the proper dimensions for fitting into the cutting table. Suitable processes for bonding of the abrasive insert may include hot pressing, brazing, and the like.
In other alternative processes, the abrasive insert can be formed using a high pressure/high temperature (HP/HT) process, such as the one used to form the superabrasive layer and the substrate. In fact, some forming methods may simultaneously form the superabrasive layer, abrasive insert, and the substrate in the same chamber at the same time. Such a process may require a special HP/HT cell capable of accommodating all of the components and effectively forming said components. Notably, such a process may be suitable for designs utilizing complex geometries between the superabrasive layer and the abrasive insert.
As will be appreciated, after the formation of the cutting element, finishing processes can be undertaken to prepare the surfaces for drilling applications. For example, surfaces of the superabrasive layer may be formed to have chamfers in accordance with the embodiments herein. Moreover, the surfaces of the cutting body may be polished.
The embodiments herein represent a departure from conventional cutting elements. While changes to cutting elements for use in drill bits have been disclosed, such changes generally are directed to the use of different or new materials, combinations of different materials within the cutting table, and different arrangements of the cutting table with the substrate to improve bonding between the components and reduce the likelihood of certain failure mechanisms. The embodiments herein include a combination of features not previously recognized including the provision of a cutting table including a superabrasive layer with an abrasive insert having unique surface features and employing abrasive grit in a matrix material. Such features facilitate the formation of cutting elements using less precious materials, while maintaining cutting ability and having suitable resistance to thermally-induced and mechanically induced failure mechanisms. The cutting elements herein may be particularly suitable for use in impreg drill bits and PDC drill bits. The cutting elements may be suitable for impreg drill bits designed to drill through soft formations transitioning to harder formations. For instance, in transitioning from soft formations to harder formations, the superabrasive portion of the cutting table may be worn in an initial drilling operation and as the surface wears to expose the abrasive insert, the drill bit may be capable of functioning more like an impregnated drill bit capable of moving through the harder formations. PDC drill bits may utilize such cutting elements as backup cutters, or peripheral cutters proximate to the gauge pads. Notably, such cutting elements may be utilized as rubbing or depth of cut limiting devices, strategically positioned on the drill bit at the cone, nose, or shoulder regions.
The above-disclosed subject matter is to be considered illustrative, and not restrictive, and the appended claims are intended to cover all such modifications, enhancements, and other embodiments, which fall within the true scope of the present invention. Thus, to the maximum extent allowed by law, the scope of the present invention is to be determined by the broadest permissible interpretation of the following claims and their equivalents, and shall not be restricted or limited by the foregoing detailed description.
The Abstract of the Disclosure is provided to comply with Patent Law and is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims. In addition, in the foregoing Detailed Description of the Drawings, various features may be grouped together or described in a single embodiment for the purpose of streamlining the disclosure. This disclosure is not to be interpreted as reflecting an intention that the claimed embodiments require more features than are expressly recited in each claim. Rather, as the following claims reflect, inventive subject matter may be directed to less than all features of any of the disclosed embodiments. Thus, the following claims are incorporated into the Detailed Description of the Drawings, with each claim standing on its own as defining separately claimed subject matter.