DRILL BITS AND OTHER DOWNHOLE DRILLING TOOLS WITH NON-CYLINDRICAL CUTTER POCKETS

Abstract

Embodiments of the present invention may encompass downhole tools that may include a body comprising a face and an axis of rotation. The tools may include a plurality of blades disposed on the face of the body. Each of the plurality of blades may define a plurality of cutter pockets. At least one cutter pocket of the plurality of cutter pockets may include a non-circular cross-section. The tools may include a plurality of cutters. A portion of each cutter may be disposed within a respective cutter pocket of the plurality of cutter pockets. The portion of each cutter may have a cross-sectional shape that matches a cross-sectional shape of the respective pocket.

Description

TECHNICAL FIELD

The present disclosure generally relates to drill bits having blades with improved cutters. In particular, the disclosure relates to drill bits and other downhole drilling having cutter pockets and cutters having non-circular cross-sections that enable the cutter pockets to self-align cutters inserted therein.

BACKGROUND

Downhole drilling tools, drill bits (such as rotary drag bits), reamers, and similar downhole tools for boring or forming holes in subterranean rock formations are well-known. When drilling oil and natural gas wells, geothermal wells, and mining boreholes, and other boreholes into the earth, rotary drag bits utilize discrete cutting elements, referred to as “cutters,” mounted in fixed locations on the body of the tool against the formation. As the cutters are dragged against the formation by rotation of the tool body, the cutters fail the formation through a shearing action. This shearing action forms small chips that are evacuated hydraulically or pneumatically by drilling fluid pumped through nozzles in the tool body. Conventional cutters are formed from cylindrical bodies. However, such cylindrical bodies may present limitations into the design of downhole tools. For example, where the cutters include a discrete cutting tip, it may be difficult to align the cutting tip in a desired orientation due to the manual brazing process for securing the cutter to the downhole tool. Additionally, the size and shape of the cylindrical bodies may limit the number of cutters on a blade, as well as the customizability of a cutting profile of a drill bit. Therefore, improvements in cutters and downhole tools including such cutters are desired.

SUMMARY

Embodiments of the present invention may encompass downhole tools that may include a body comprising a face and an axis of rotation. The tools may include a plurality of blades disposed on the face of the body. Each of the plurality of blades may define a plurality of cutter pockets. At least one cutter pocket of the plurality of cutter pockets may include a non-circular cross-section. The tools may include a plurality of cutters. A portion of each cutter may be disposed within a respective cutter pocket of the plurality of cutter pockets. The portion of each cutter may have a cross-sectional shape that matches a cross-sectional shape of the respective pocket.

In some embodiments, the downhole tool may be a drill bit. The downhole tool may include a reamer. The at least one pocket may have a generally rectangular cross-section. The generally rectangular cross-section may include two orthogonal linear sides and a rounded corner coupling the two orthogonal linear sides. A width of each rounded corner may be between 5 degrees and 45 degrees as measured from a central axis of the cutter pocket. The blade may include a plurality of knuckles. Each of the plurality of knuckles may protrude from a top surface of one of the plurality of blades and may be in alignment with a respective one of the plurality of cutter pockets and may support a portion of a base of one of the plurality of cutters seated within the respective one of the plurality of cutter pockets. Each of the plurality of knuckles may have a shape and size that substantially corresponds to a size and shape of a portion of the one of the plurality of cutters that extends above the top surface of a respective one of the plurality of blades on which the one of the plurality of cutters is mounted. A top surface of each of the plurality of knuckles may taper downward toward the top surface of a respective one of the plurality of blades in a direction away from the one of the plurality of cutters. Each of the plurality of knuckles may be axially aligned with a respective one of the plurality of cutters. The body may include a plurality of channels. Each channel may be formed between adjacent blades of the plurality of blades. The body may include a plurality of nozzles. Each nozzle may be disposed within one of the plurality of channels. An outlet of each nozzle may be aligned with one of the plurality of cutters that faces the respective channel. At least one of the plurality of cutters may include a diamond table having a non-cylindrical outer periphery that is configured to be rotated about a central axis of the at least one of the plurality of cutters at an angle of between 60 degrees and 300 degrees in the respective cutter pocket to expose a new cutting edge of point loading ability that is greater than a point loading ability of a conventional cylindrical cutter of similar size while maintaining a braze gap thickness of 0.015″ or less across 85% or more of a brazeable surface area of the conventional cylindrical cutter of similar size. A shape and orientation of the at least one cutter pocket and a respective one of the cutters disposed within the at least one cutter pocket may be selected such that when the respective one of the cutters is inserted into the at least one cutter pocket, the respective one of the cutters is oriented with a cutting tip of the respective one of the cutters protruding beyond a top surface of a respective one of the plurality of blades.

Some embodiments of the present technology may encompass cutters for a downhole tool. The cutters may include a substrate comprising a brazing surface. At least a portion of the brazing surface may include a first non-circular cross-section. The cutters may include a diamond table. The diamond table may include a bottom surface joined to the substrate. The diamond table may include a cutting face opposite the bottom surface. The cutting face may include a second non-circular cross-section.

In some embodiments one or both of the first non-circular cross-section and the second non-circular cross-section may include one or more concave and/or convex regions. The cutting face may be non-planar. The cutting face may include multiple discrete cutting tips. One or both of the first non-circular cross-section and the second non-circular cross-section may include a generally quadrilateral shape. The cutter may be symmetrical about two perpendicular planes that extend through both the substrate and the diamond table. One or both of the first non-circular cross-section and the second non-circular cross-section may include two or more linear sides that are connected via a plurality of curved corners. A ratio of a length of the linear sides to a length of the curved corners may be at least 0.5:1. One or both of the first non-circular cross-section and the second non-circular cross-section may include a generally rectangular shape. The generally rectangular shape may include four linear sides and four rounded corners. One or both of the first non-circular cross-section and the second non-circular cross-section may include a generally triangular shape. The generally triangular shape may include three linear sides and three rounded corners. One or both of the first non-circular cross-section and the second non-circular cross-section may include a stadium shape. The diamond table may include a chamfered edge that extends from the cutting face to a lateral side of the diamond table. An angle of the chamfered edge relative to the cutting face may vary along a periphery of the cutting face. The angle of the chamfered edge relative to the cutting face may be greater at a cutting region of the cutting face than at a medial region of the cutting face. The angle of the chamfered edge relative to the cutting face may be lower at a cutting region of the cutting face than at a medial region of the cutting face. A depth of the chamfered edge may vary along a periphery of the cutting face. The depth of the chamfered edge may be greater at a cutting region of the cutting face than at a medial region of the cutting face. The depth of the chamfered edge may be lower at a cutting region of the cutting face than at a medial region of the cutting face. The substrate may include a non-planar interface that protrudes from the substrate in a direction of the diamond table. The non-planar interface may include a non-circular cross-section. A shape of an outer periphery of the non-planar interface may match a shape of an outer periphery of a topmost planar surface of the substrate. A thickness of the non-planar interface may vary across a surface area of the non-planar interface. A thickness of the diamond table may vary across a surface area of the diamond table. A variation in the thickness of the non-planar interface may correspond to a variation in the thickness of the diamond table across the surface area of the diamond table. The diamond table may include a protruding feature. A thickness of the non-planar interface may increase in a region that corresponds to the protruding feature. The diamond table may include a recessed feature. A thickness of the non-planar interface may decrease in a region that corresponds to the recessed feature. A distance from a peripheral edge of the non-planar interface to a peripheral edge of the diamond table may be consistent within 20% of a greatest distance from the peripheral edge of the non-planar interface to the peripheral edge of the diamond table across an entire periphery of the diamond table. The first non-circular cross-section and the second non-circular cross-section may be a same shape.

Some embodiments of the present technology may encompass cutters for a downhole tool that may include a diamond table having a non-cylindrical outer periphery that is configured to be rotated about a central axis of diamond table at an angle of between 60 degrees and 300 degrees within a cutter pocket of a downhole tool to expose a new cutting edge of point loading ability that is greater than a point loading ability of a conventional cylindrical cutter of similar size while maintaining a braze gap thickness of 0.015″ or less across 85% or more of a brazeable surface area of the conventional cylindrical cutter of similar size.

Some embodiments of the present technology may encompass cutters for a downhole tool that may include a body having a central axis. A radial distance between an outer surface of the cutter and the central axis may vary about an outer periphery of the body along at least 50% of the outer periphery of the cutter and along at least 50% of a length of the body.

Some embodiments of the present technology may encompass methods of bonding a cutter to a downhole tool. The methods may include inserting a cutter having a non-circular cross-section into a non-cylindrical pocket formed into a downhole tool such that a gap is formed between an outer face of the cutter and a wall of the pocket. The methods may include providing a metal-containing substance into the gap. The methods may include setting the cutter in the pocket such that the cutter is joined to the downhole tool.

In some embodiments, the metal-containing substance may include a brazing alloy. The pocket and the cutter may each have a generally rectangular cross-section. The pocket and the cutter may each have a generally triangular cross-section. The pocket and the cutter each may have a generally stadium-shaped cross-section The pocket and the cutter may each have a generally pentagonal cross-section. The pocket and the cutter may each have a generally hexagonal cross-section. The pocket may be formed within a blade that extends outward from a face of the downhole tool. A shape and orientation of the cutter and the pocket may be selected such that when the cutter is inserted into the pocket, the cutter is oriented with a cutting tip of the cutter protruding beyond a top surface of the blade.

Some embodiments of the present technology may encompass methods of manufacturing a downhole tool. The methods may include forming a mold of a body of the downhole tool. The methods may include inserting a plurality of cutter pocket displacements within the mold. The plurality of cutter pocket displacements may have non-circular cross-sections. The plurality of cutter pocket displacements may be aligned within the mold such that the cutter pocket displacements define a size and orientation of cutter pockets. The methods may include filling the mold with a carbide matrix material and a binder material. The methods may include heating the filled mold to form the body of the downhole tool. The plurality of cutter pocket displacements may form the cutter pockets within the body of the downhole tool. At least one of the cutter pockets may include a non-circular cross-section that is configured to automatically orient a cutter in a cutting position. The methods may include removing the body of the downhole tool from the mold. The methods may include inserting a cutter into at least one of the cutter pockets. At least one of the cutters may have a non-circular cross-section that substantially matches the non-circular cross-section of a respective one of the cutter pockets.

In some embodiments, inserting the plurality of cutter pocket displacements within the mold may include inserting each cutter pocket displacement into a trough formed in the mold. Each the plurality of cutter pocket displacements may be aligned within a respective one of the cutter pockets manually. Each of the plurality of cutter pocket displacements may be aligned within a respective one of the cutter pockets using an indexing feature formed in one or both of the mold and the respective cutter pocket displacement. One of the trough and a respective cutter pocket displacement may include a ridge and the other of the trough and a respective cutter pocket displacement may define a groove. Insertion of the ridge into the groove may align the respective cutter pocket displacement within the trough. One of the trough and a respective cutter pocket displacement may include a convexity and other of the trough and a respective cutter pocket displacement may define a concavity. Interfacing the concavity with the convexity may align the respective cutter pocket displacement within the trough. Each of the trough and a respective cutter pocket displacement may define a slot. A key may be inserted within both of the slots to align the respective cutter pocket displacement within the trough. The methods may include removing the cutter pocket displacements from the body of the downhole tool prior to inserting the cutters. The methods may include brazing each cutter within a respective cutter pocket. The body of the downhole tool may include a plurality of blades that extend away from the body of the downhole tool. A shape and orientation of each cutter pocket and a respective one of the cutters disposed within the cutter pocket may be selected such that when the respective one of the cutters is inserted into the cutter pocket, the respective one of the cutters is oriented with a cutting tip of the respective one of the cutters protruding beyond a top surface of a respective one of the plurality of blades.

Some embodiments of the present technology may encompass methods of manufacturing a downhole tool that may include forming a body of a downhole tool. The body may include a plurality of blades. Each blade may include a plurality of cutter pockets. At least one of the plurality of cutter pockets may include a non-circular cross-section. The methods may include hardfacing the body of the downhole tool. The methods may include inserting a cutter into each of the plurality of cutter pockets. At least one cutter may include a non-circular cross-section that substantially matches the non-circular cross-section of a respective one of at least one of the plurality of cutter pockets. The methods may include brazing each cutter into the respective one of the cutter pockets.

In some embodiments, forming the body of the downhole tool may include machining the body from a steel blank. Hardfacing may include fusing a carbide material and a binder onto at least a portion of the body of the downhole tool. A shape and orientation of each cutter pocket and a respective one of the cutters disposed within the cutter pocket may be selected such that when the respective one of the cutters is inserted into the cutter pocket, the respective one of the cutters is oriented with a cutting tip of the respective one of the cutters protruding beyond a top surface of a respective one of the plurality of blades. Forming the body of the downhole tool may include machining each of the plurality of cutter pockets into the body of the downhole tool. Forming the body of the downhole tool may include forming each of the plurality of cutter pockets with a circular cross-section. Forming the body of the downhole tool may include welding a shim into the circular cross-section to form the non-circular cross-section.

Some embodiments of the present technology may encompass methods of re-orienting a cutter to a downhole tool. The methods may include determining that a first cutting tip of a cutter on blade of a downhole tool is excessively worn. The first cutting tip may be in a cutting position in which the first cutting tip protrudes above a top surface of the blade. The cutter may include a plurality of discrete cutting tips. The cutter may include a non-circular cross-section that corresponds with a cross-section of a cutter pocket in which the cutter is secured. The methods may include determining that a second cutting tip of the plurality of discrete cutting tips is in sufficient condition to be utilized in the cutting position. The methods may include removing the cutter from the cutter pocket. The methods may include rotating the cutter and inserting the cutter into the cutter pocket with the second cutting tip oriented into the cutting position. The methods may include securing the cutter within the cutter pocket. In some embodiments, securing the cutter within the cutter pocket may include brazing the cutter to the cutter pocket. A shape and orientation of the cutter pocket the cutter may be selected such that when the cutter is inserted into the cutter pocket, the cutter is oriented with one of the plurality of discrete cutting tips in the cutting position. Determining that a first cutting tip of a cutter on blade of a downhole tool is excessively worn may be done by grading the first cutting tip based on one or more predetermined criteria. Determining that a second cutting tip of the plurality of discrete cutting tips is in sufficient condition to be utilized in the cutting position may be done by grading the second cutting tip based on one or more criteria.

Some embodiments of the present technology may encompass drill bits that may include a body having a face for engaging a bottom of a well bore. The body may include an axis of rotation that extends along a length of the body. The drill bits may include a plurality of blades formed on the body. The drill bits may include a plurality of cutters mounted on each blade of the plurality of blades. The plurality of cutters may include pairs of cutters. Each pair of cutters may include a first cutter and a second cutter at a same radial distance from the axis of rotation. One or both of the first cutter and the second cutter of each pair of cutters may include a plurality of discrete cutting tips. Each cutter may be mounted on a respective blade with a single cutting tip extending beyond a top surface of the respective blade.

In some embodiments, at least some of the pairs of cutters may be on a same blade. At least some of the pairs of cutters may be on different blades. One of the first cutter and the second cutter of each pair of cutters may include a cylindrical cutter. The first cutter and the second cutter of each pair of cutters may include identical cutting tips. The first cutter and the second cutter of each pair of cutters may include different cutting tips. The first cutter and the second cutter of each pair of cutters may include different cross-sectional shapes.

Some embodiments of the present technology may encompass drill bits to advance a borehole. The drill bits may include a body having a face for engaging a bottom of a well bore. The body may include an axis of rotation that extends along a length of the body. The drill bits may include a plurality of blades formed on the body. The drill bits may include a plurality of cutters mounted on each blade of the plurality of blades. At least one of the blades may be an offset blade having an inner region supporting an inner set of cutters of the plurality of cutters along a first leading edge portion of the offset blade and an outer region supporting an outer set of cutters along a second leading edge portion of the offset blade. The second leading edge portion may be rotationally offset from the first leading edge portion. At least some cutters of the plurality of cutters may include a plurality of discrete cutting tips. Each cutter may be mounted on a respective blade with a single cutting tip of the plurality of discrete cutting tips extending beyond a top surface of the respective blade.

In some embodiments, the at least some cutters may include the inner set of cutters. The at least some cutters may include the outer set of cutters. The at least some cutters may include both the inner set of cutters and the outer set of cutters.

BRIEF DESCRIPTION OF THE DRAWINGS

A further understanding of the nature and advantages of various embodiments may be realized by reference to the following figures. In the appended figures, similar components or features may have the same reference label. Further, various components of the same type may be distinguished by following the reference label by a set of parentheses containing a second label that distinguishes among the similar components. If only the first reference label is used in the specification, the description is applicable to any one of the similar components having the same first reference label irrespective of the second reference label.

FIG. 1 is an isometric view of a drill bit according to embodiments of the present invention.

FIG. 2 is an isometric view of a drill bit according to embodiments of the present invention.

FIG. 3 is an isometric view of a reamer according to embodiments of the present invention.

FIGS. 4A-4D illustrate different views of a generally rectangular cutter according to embodiments of the present invention.

FIGS. 5A-5D illustrate different views of a generally triangular cutter according to embodiments of the present invention.

FIGS. 6A-6D illustrate different views of a generally pentagonal cutter according to embodiments of the present invention.

FIGS. 7A-7D illustrate different views of a generally stadium-shaped cutter according to embodiments of the present invention.

FIGS. 8A-8D illustrate different views of a generally hexagonal cutter according to embodiments of the present invention.

FIGS. 9A-9D illustrate different views of a generally rectangular cutter according to embodiments of the present invention.

FIGS. 10A-10D illustrate different views of a generally rectangular cutter with a non-planar diamond table according to embodiments of the present invention.

FIGS. 11A-11D illustrate different views of a generally rectangular cutter with a non-planar diamond table according to embodiments of the present invention.

FIGS. 12A-12D illustrate different views of a generally rectangular cutter with a non-planar diamond table according to embodiments of the present invention.

FIGS. 13A-13D illustrate different views of a generally rectangular cutter with a non-planar diamond table according to embodiments of the present invention.

FIGS. 14A-14C illustrate different views of a generally rectangular cutter with a variable chamfer according to embodiments of the present invention.

FIG. 15 illustrates different views of a generally rectangular cutter with a shaped non-planar interface according to embodiments of the present invention.

FIG. 16 illustrates different views of a generally rectangular cutter with a shaped non-planar interface according to embodiments of the present invention.

FIG. 17 is an isometric view of a drill bit according to embodiments of the present invention.

FIGS. 18A-18C illustrate different views of non-cylindrical cutters and pockets according to embodiments of the present invention.

FIG. 19 illustrates a blade with a cutter pocket including a keyway according to embodiments of the present invention.

FIG. 20 illustrates a keyed shim according to embodiments of the present invention.

FIG. 21 illustrates a non-keyed shim according to embodiments of the present invention.

FIG. 22 illustrates the blade with the keyed shim and the non-keyed shim according to embodiments of the present invention.

FIG. 23 illustrates a spacer with a non-keyed shim according to embodiments of the present invention.

FIG. 24 illustrates the blade with a spacer and two non-keyed shims according to embodiments of the present invention.

FIG. 25 illustrates a blade with a number of non-cylindrical cutters according to embodiments of the present invention.

FIG. 26 is a flowchart illustrating operations of a method for bonding a cutter to a cutter pocket according to embodiments of the present invention.

FIG. 27 is a flowchart illustrating operations of a method for manufacturing a drill bit according to embodiments of the present invention.

FIG. 28 is a flowchart illustrating operations of a method for manufacturing a drill bit according to embodiments of the present invention.

FIG. 29 is a flowchart illustrating operations of a method for re-orienting a cutter within a cutter pocket according to embodiments of the present invention.

FIG. 30 is a flowchart illustrating operations of a method for operating a downhole tool according to embodiments of the present invention.

Several of the figures are included as schematics. It is to be understood that the figures are for illustrative purposes and are not to be considered of scale unless specifically stated to be of scale. Additionally, as schematics, the figures are provided to aid comprehension and may not include all aspects or information compared to realistic representations and may include exaggerated material for illustrative purposes.

DETAILED DESCRIPTION

The subject matter of embodiments of the present invention is described here with specificity to meet statutory requirements, but this description is not necessarily intended to limit the scope of the claims. The claimed subject matter may be embodied in other ways, may include different elements or steps, and may be used in conjunction with other existing or future technologies. This description should not be interpreted as implying any particular order or arrangement among or between various steps or elements except when the order of individual steps or arrangement of elements is explicitly described.

Embodiments of the present invention are directed to non-cylindrical cutters (e.g., cutters having a non-circular cross-sectional shape) and downhole tools that include such cutters. The use of such cutters may provide numerous benefits over conventional cylindrical cutters. For example, use of non-cylindrical cutters may enable better point loading. More specifically, non-cylindrical cutters may include one or more discrete cutting tips (rather than a continuous circular cutting edge) that enables higher pressures to be exerted on the rock formation, as a same amount of force is delivered through a smaller surface area than in conventional cylindrical cutters, which enables drilling efficiency to be increased. Additionally, the geometry of non-cylindrical cutters and cutter pockets may enable the cutters to be self-aligning within the cutter pockets, such that the cutting tip is positioned at a desired orientation (e.g., cutting position) upon the cutter being inserted into the cutter pocket. This may reduce or eliminate alignment errors associated with manual orientation (e.g., by eye or using a measurement tool) during brazing of the cutters within the cutter pockets. Additionally, the presence of multiple discrete cutting tips may enable worn cutters to be removed from the cutter pockets, rotated, and re-brazed into the cutter pockets with a new cutting tip positioned above a top surface of a respective blade. This may enable the cutters to be reused for two or more cycles and may cut down on material waste. Additionally, some or all cutting tips of an individual cutter with multiple discrete cutting tips may have a different chamfer or bevel size, which may reduce overall cutter inventory for the organization, further reducing operating costs.

In some embodiments, the downhole tools described herein may include drill bits, such as rotary drag bits, hybrid drill bits, which can include a variety of fixed cutters, with or without rotating cutters that can fail formation through a shearing or plowing action, and/or rolling elements that fail formations through a crushing action. FIG. 1 illustrates an example of a rotary drill bit 100 according to embodiments of the present disclosure. The rotary drill bit 100 of FIG. 1 is intended to be a representative example of drill bits, e.g., drag bits, for drilling formations. Rotary drill bit 100 is designed to be rotated around its central axis 102. Drill bit 100 may include a bit body 104 connected to a shank 106 having a tapered threaded coupling 108 for connecting the bit to a drill string (not shown). Drill bit 100 may further include a bit breaker surface 111 for cooperating with a wrench to tighten and loosen the coupling to the drill string. The exterior surface of bit body 104 is intended to face generally in the direction of boring and is referred to as bit face. The face generally lies in a plane perpendicular to central axis 102 of drill bit 100. In some embodiments, bit body 104 is made from an abrasion-resistant composite material or “metal matrix composite” that includes, for example, a ceramic component (such as a powdered tungsten carbide) that reinforces a metal matrix, such as a copper alloy matrix. In other embodiments, bit body 104 may be formed from a metal alloy, such as a steel alloy. In some embodiments, all or a portion of a steel alloy bit body 104 may include a hardfacing material, such as a carbide material that has been fused to a surface of the steel alloy to provide additional strength to bit body 104. It will be appreciated that other materials may be used to form bit body 104 in various embodiments.

During drilling operations, drill bit 100 may be coupled to the drill string. As drill bit 100 is rotated within the wellbore via the drill string, drilling fluid may be pumped down the drill string, through the internal fluid plenum and fluid passageways within bit body 104 of drill bit 100, and out from drill bit 100 through nozzles 117. Formation cuttings generated by cutters 112 of bit body 104 may be carried with the drilling fluid through the fluid courses (e.g., “junk slots”), around drill bit 100, and back up the wellbore through the annular space within the wellbore outside the drill string.

Bit body 104 may include one or more raised blades 110 that extend from the face of bit body 104. In some embodiments, blades 110 extend radially along the bit face and are circumferentially spaced structures extending along the leading end or formation engaging portion of bit body 104. Each blade 110 may extend generally in a radial direction, outwardly to the periphery of bit body 104. For example, blades 110 may generally extend from the cone region proximate the longitudinal axis, or central axis 102, of the bit, upwardly to the gauge region, or maximum drill diameter of bit. In some embodiments, blades 110 may be substantially equally spaced around central axis 102 of drill bit 100 and each blade 110 may sweep or curve backward in the direction of rotation indicated by arrow 115. In other embodiments, one or more of blades 110 may have zero sweep (e.g., do not curve in the direction of arrow 115). Channels formed between adjacent blades may form the junk slots that provide paths for drilling fluid and formation cuttings to be carried up the wellbore.

As noted above, bit body 104 further includes a plurality of superabrasive cutters 112. Cutters 112 may be, for example, polycrystalline diamond compact (“PDC”) cutting elements, disposed on front and/or top facing surfaces of each blade 110. For example, a plurality of discrete cutters 112 may be mounted on each blade 110. Cutters 112 may be arranged in a forward spiral, reverse spiral, skip spiral, and/or other cutter arrangement that defines a radial and angular position of each cutter 112. For example, a skip spiral may be differentiated from a forward or reverse spiral in that radially adjacent cutters are not always on angularly adjacent blades, even on the nose and shoulder where all of the secondary blades are present. On a reverse spiral, five bladed bit, cutters 15 through 19 might appear on blades 1, 5, 4, 3, 2, respectively. Whereas on a skip spiral, five bladed bit of similar size and cutter count, cutters 15 through 19 might appear on blades 1, 4, 5, 2, 3 respectively. There are many other ways to arrange a skip spiral layout.

Each discrete cutter 112 may be disposed within a recess or pocket formed in a given blade 110. Cutters 112 may be mounted to drill bit 100 either by press-fitting or otherwise locking the stud (e.g., substrate portion of cutting element) of the respective cutter 112 into a pocket or receptacle on a drag bit, or by brazing a portion of the respective cutter 112 directly into a preformed pocket, socket or other receptacle on a given blade 110. Cutters 112 may be provided in one or more rows along each blade 110. For example, in some embodiments, a given blade 110 may include one or more primary cutters 112 that extend through a leading edge of the blade 110 and one or more backup cutters 112 that are positioned on the blade 110 behind the primary cutters 112. In some embodiments, each cutter 112 may have a unique radial position (i.e., radial distance from central axis 102), while in other embodiments multiple cutters 112 (e.g., two or more, three or more, four or more, etc.) cutters may be positioned at a given radial position. Cutters at a same radial position may be mounted on a same blade 110 or on different blades 110 in various embodiments. In some embodiments, an outlet of some or all nozzles 117 may be aligned with a cutting face of one of the cutters that faces the respective channel, with the axis of each nozzle 117 being aimed slightly away (e.g., between 1 degree and 10 degrees) of parallel with respect to the front surface of the respective blade 110. This may enable the drilling fluid to more effectively wash cuttings away from cutters 112 while helping reduce erosion of the area of the blade 110 surrounding the cutter pockets.

FIG. 2 represents a view of the face of another embodiment of a drill bit 200. Drill bit 200 may be similar to drill bit 100 and may include any of the features described in relation to drill bit 100. Drill bit 200 has a plurality of cutters (PDC or other types) mounted on a plurality of blades. This particular embodiment has six blades, three of which are primary blades 226. The other three are secondary blades 236. The primary blades extend from near the center of the axis of rotation 202, through the cone, nose and shoulder regions, to the gauge of bit 200. In this example, each primary blade 226 is an offset blade. Each secondary blade 236 extends from the nose region of bit 200, through the shoulder region, and then to the gauge of bit 200. Secondary blades 236 are not offset. In alternative embodiments, one or more of the blades may be conventional, non-offset blades. The various features or aspects of the improvements disclosed herein are not limited to a bit with a particular size or number of cutters or blades unless otherwise specifically stated.

The leading edge of a traditional blade, where front wall of the blade transitions to the top surface of the blade and along which the primary cutters are mounted, is curvilinear. However, each offset blade has a leading edge with a pronounced step or set back where it transitions from a first inner region to a second outer region. The distal end of the leading edge of the inner region is rotationally or angularly offset from the proximal end of the leading edge of the outer region, forming a step or offset such that the difference between the angular position of a last cutter (most radially distant) on the inner region and the angular position of the first cutter on the outer region is much greater than the differences in angular positions of the last two cutters on the inner region and the difference in the angular positions of the first two cutters on the outer region. In the illustrated embodiment, each offset blade 226 is continuous, without a gap in the wall of the blade where the offset occurs. However, in alternative embodiments, a small gap between the inner and outer regions may be formed.

As illustrated each offset blade 226 has seven cutters 212-224 (although other numbers of cutters are possible in various embodiments), which are primary cutters. Cutters 212-224 are mounted along a leading edge of the offset blade, adjacent to one of the channels or “junk slots” 234 that extends along the length of the offset blade. The offset blades 226 may also have cutters in the gauge area of drill bit 200, which are not visible in this view of this embodiment. Each offset blade 226 in this example is one continuous blade that has an offset in the blade geometry along the face or front wall of the blade. The offset is, in this embodiment, between cutter 216 and cutter 218. The offset creates two blade regions, a first (or inner) blade region closer to the centerline or axis of rotation 202 of drill bit 200 that extends through the cone region of drill bit 200 to the offset, and a second (or outer) region that extends from the offset, through the nose and shoulder regions, to the gauge of drill bit 200. A proximal end of the outer region is displaced radially (outwardly from the axis of rotation) and angularly from a distal end of the inner region. In this example, the offset in offset blade 226 occurs approximately where the cone region of the bit transitions to the nose region of drill bit 200. However, in other embodiments, the offset may occur in or near other regions of drill bit 200, such in the nose or shoulder, or at the transition of the nose to the shoulder. Furthermore, alternative embodiments of drill bits may have one or more, or all, of the offset blades with more than one offset and different numbers of offsets. For example, an offset blade could have three portions: a first, a second and third, with a first offset between the first two portions and a second offset between the second and third portions. Furthermore, one or more of the offset blades on a bit could have one offset; and one or more of the other offset blades could have two offsets. One or more additional offset blades on the bit could have three or more offsets.

Secondary blades 236 may be used to increase the cutter density of the bit in the nose and shoulder of a bit. Cutters in these regions typically perform much of the work forming a wellbore. As the bit progresses downhole, more material must be removed from the borehole in these regions relative to the cone region because the wider radius of these regions, relative to the cone region, results in a greater surface area of rock that must be removed. The secondary blades allow for balancing the amount of exposed cutter in a region to the area of rock that must be removed from that region. Each of the secondary blades has four primary cutters 238-244 that are visible in this view and may have cutters in the gauge region of drill bit 200 that are occluded from view. Cutters 238-244 each have a fixed position on drill bit 200. The fixed position of a particular cutter being defined by the blade on which the cutter is mounted, the axial distance from the center of rotation of drill bit 200, and the relative radial position of the cutter on the face of drill bit 200.

Drill bit 200 may include a plurality of nozzles 228-232 which are located in a plurality of channels or junk slots 234. Junk slots 234 may be located in front of each of the blades and are defined by the back wall of the blade and a front wall of the following blade (based on a rotational direction of drill bit 200). Nozzles 228-232 direct drilling fluid being pumped through the drill string, which is not shown, toward the cutters to flush cuttings from the face of drill bit 200. Junk slots 234 create room for collecting and evacuating cuttings, with the junk slots direction the flow of drilling fluid and cuttings radially outwardly and then up through the gauge region and into an annulus between the wellbore side wall and the drilling string (not shown.)

Nozzles 230 are in front of the inner region of offset blade 226. The drilling fluid flowing from each nozzle 230 is primarily intended to clear cuttings coming off of primary cutters mounted along a leading of the inner region of each offset blade 226, which in this example are cutters 212, 214, and 216. The drilling fluid flowing from each nozzle 230 is secondarily intended to provide cooling and manage the operating temperature of primary cutters mounted along a leading edge of the inner region of each offset blade 226, which in this example are cutters 212, 214, and 216. Nozzles 230 are therefore directed so that drilling fluid flows across the face of these cutters 212-215 and down junk slot 234 that is between the front of the offset blade 226 and the back side of the secondary blade 236 in front of the offset blade 226.

Nozzles 228 are each tucked into the corner formed in the front wall of the blade formed by the offset in offset blade 226. Each nozzle 228 directs drilling fluid along the outer region of each of offset blades 226, toward faces of cutters 218, 220, 222, and 224, which are primary cutters mounted along a leading edge of the outer region of offset blade 226.

Nozzles 228 are rotationally offset rearwardly with respect to nozzle 230 and radially outwardly. Because each nozzle 228 is rotationally displaced with respect to nozzle 230, fluid flowing from each nozzle 228 tends not to interfere with fluid flow from nozzle 230 or interferes much less than it would if it were not rotationally displaced. Nozzle 230 is aimed so that the drilling fluid from nozzle 230, after flowing across the face of cutters 212, 214, and 218 in the inner region of offset blade 226, tends for flow with the cuttings produced by those cutters primarily through the area between the back of secondary blade 236 and nozzle 228. Fluid flowing from nozzle 228 primarily flows across the face of cutters 218, 220, 222, and 224 and then continues along the front wall or leading edge of the second blade portion of the offset blade 226 into the annular space of the borehole.

Offset blades 226 and secondary blades 236 of drill bit 200 may include sloped surfaces 246 and 248, respectively, on the back of the blades, behind the cutters that are arranged along the leading edge of the blades. The cutting face of the body of drill bit 200, in particular the top surfaces of the blade, act to limit the penetration of the cutters into the formation. The primary cutters extend above the top of the blades or other feature or aspect of the bit that limits how far the cutters can penetrate into rock, which is referred to as cutter exposure. Generally, higher exposures will allow the primary cutters to penetrate deeper into the formation, which can increase the rate that the bit penetrates the formation (the rate of penetration or ROP) to advance the bore hole. On the other hand, if the primary cutter exposure is too high, other problems may arise that might retard rate of penetration or lead to premature failure of cutters and eventual damage or destruction of the drill bit. Therefore, exposure is chosen to optimize ROP while maintaining an acceptable degree of reliability. At high ROP the back part of the top surface of the blades might contact the formation before the front part of the top surface contacts the formation, resulting in added friction and possibly also a shallower penetration than the bit is otherwise capable of. Sloped surfaces 246 and 248 remove some of the blade without substantially weakening it where the back of each blade might otherwise contact the formation during high ROP. Instead of a sloped surface, a step or series of steps could be substituted, but possibly at the cost of added fabrication difficulties and/or a weaker blade.

In some embodiments, the downhole tools described herein may include reamers. FIG. 3 illustrates a reamer 300 for earth boring operations, according to certain embodiments. Reamer 300 may include an upper shaft 302a, a lower shaft 302b, a body 304, and blades 314a-c disposed about body 304. Each blade 314a-c may be separated by channels or “junk slots.” Each blade 314a-c may include one or more cutters 316, which may be PDC cutters in some embodiments. For example, each cutter 316 may include a substrate and a diamond table. The substrate may be formed from a carbon and metal containing material, such as a carbide containing titanium, iron, tungsten, and other suitable metals. The diamond table may include a polycrystalline diamond surface as described above. Each cutter 316 may be inserted into a hollow pocket included in a respective blade 314. The hollow pocket (or “pocket”) may be machined, cast, and/or otherwise formed into reamer 300 during manufacture of reamer 300. Each cutter 316 may be configured such that it corresponds to a specific pocket included in the respective blade 314. For example, a size and shape of each cutter 316 may substantially match (e.g., within about 0.025 inches or less to provide a braze gap for receiving a brazing alloy that joins the cutters with the blade) a size and shape a corresponding pocket that receives the cutter 316.

Reamer 300 may be used, at least in part, to widen a pre-existing hole or bore. For example, the pre-existing hole or bore may be created at a first width by a drill bit similar to drill bits 100 and 200. Reamer 300 may then be inserted into the pre-existing hole or bore to widen the pre-existing hole or bore. As reamer 300 is rotated within the pre-existing hole or bore, cutters 316 may cause material (e.g., earth, rock, etc.) to be removed from the hole or bore.

Although reamer 300 is shown with blades 314a-c disposed vertically between upper shaft 302a and lower shaft 302b, rotated axially with respect to reamer 300, other configurations are possible. For example, blades 314a-c may be disposed vertically between upper shaft 302a and lower shaft 302b with no rotation (parallel to a vertical axis of reamer 300). In another example, blades 314a-c may be arranged about a circumference of reamer 300. Reamer 300 may be a fluted reamer, a winged back reamer, an eccentric reamer, a barrel reamer, and/or any other suitable reamer.

In yet another example, reamer 300 may be an expandable reamer. In such embodiments, blades 314a-c may be enclosed in a housing. During operation, the housing may open and blades 314a-c may extend radially outward from the reamer 300, thus engaging cutters 316 with the formation. In still another example, during periods of non-operation, blades 314a-c may be in a first position in which cutters 316 are not exposed to the formation. During operation, blades 314a-c may rotate and/or extend to a second position in which cutters 316 engage the formation. One of ordinary skill in the art would recognize many different possibilities and configurations.

As disclosed above, the downhole tools described herein may include cutters that are utilized to engage and remove a portion the drilling formation. Each cutter may include a highly wear resistant cutting or wear surface comprised of a polycrystalline diamond (PDC) or similar highly wear resistant material. PDC cutters are typically made by forming a layer of polycrystalline diamond, sometimes called a crown or diamond table, on substrate carbide substrate, such as a tungsten carbide substrate that may include one more additional metal additives in some embodiments. The PDC wear surface may be formed from sintered polycrystalline diamond (either natural or synthetic) exhibiting diamond-to-diamond bonding. Polycrystalline cubic boron nitride, wurtzite boron nitride, aggregated diamond nanotubes (ADN) or other hard, crystalline materials are known substitutes and/or additives and may be useful in some drilling applications. A compact may be made by mixing a diamond grit material in powder form with or without one or more powdered metal catalysts and other materials/additives, forming the mixture into a compact, and then sintering the compact, typically with a tungsten carbide substrate using high heat and pressure. Sintered compacts of polycrystalline cubic boron nitride, wurtzite boron nitride, ADN and similar materials are, for the purposes of description contained below, equivalents to polycrystalline diamond compacts and, therefore, a reference to “PDC” in the detailed description should be construed, unless otherwise explicitly indicated or context does not allow, as a reference to a sintered compacts of polycrystalline diamond, cubic boron nitride, wurtzite boron nitride and other highly wear resistant materials. References to “PDC” are also intended to encompass sintered compacts of these materials with other materials or structure elements that might be used to improve its properties and cutting characteristics. Furthermore, PDC encompasses thermally stable varieties in which a metal catalyst has been partially or entirely removed after sintering. Such PDC cutters can also include “twice-pressed” cutters which involves sintering a diamond table onto a substrate, either planar or non-planar as will be discussed in greater detail below.

Substrates for supporting a PDC wear surface or layer are typically made, at least in part, from cemented metal carbide, with tungsten carbide being the most common. Cemented metal carbide substrates may be formed by sintering powdered metal carbide with a metal alloy binder. The composite of the PDC and the substrate may be fabricated in a number of different ways. The composite may also, for example, include transitional layers in which the metal carbide and diamond are mixed with other elements for improving bonding and reducing stress between the PDC and substrate.

Each PDC cutter may be fabricated as a discrete piece, separate from the downhole tool. Because of the processes used for fabricating them, the polycrystalline diamond layer and substrate typically have a cylindrical shape, with a relatively thin disk of polycrystalline diamond bonded to a taller or longer cylinder of substrate material. The resulting composite can be used as a conventional cutter in a cylindrical shape or may be machined or otherwise formed to a desired non-cylindrical shape. In other embodiments, the substrate and/or diamond table may be pressed or otherwise formed in a non-cylindrical shape and may or may not require machining to have a desired non-cylindrical shape.

By incorporating non-cylindrical cutters into downhole tools, such as drill bits and reamers, may provide several benefits over conventional cylindrical cutters. For example, non-cylindrical cutters may include multiple discrete cutting tips that enable better point loading and may enable drilling efficiency to be increased. Furthermore, the non-cylindrical carbide substrate may reduce or eliminate substrate rubbing on downhole formation at moderate to high depths-of-cut, eliminating the substrate bearing surface that can lead to loss of rate of penetration and/or premature cutter failure due to thermal breakdown. Additionally, the geometry of non-cylindrical cutters and cutter pockets may enable the cutters to be self-aligning within the cutter pockets, such that the cutting tip is positioned at a desired orientation (e.g., cutting position) upon the cutter being inserted into the cutter pocket. Additionally, the presence of multiple discrete cutting tips may enable worn cutters to be removed from the cutter pockets, rotated, and re-brazed into the cutter pockets with a new cutting tip positioned above a top surface of a respective blade. This may enable the cutters to be reused for two or more cycles and may cut down on material waste.

FIGS. 4A-16 illustrate embodiments of non-cylindrical cutters in accordance with the present invention. The non-cylindrical cutters may be used as some or all cutters 112 and 212-224 in drill bits 100 and 200 and/or cutters 316 in reamer 300. Each non-cylindrical cutter may be a PDC cutter and may include a substrate that is used to mount the cutter within a pocket of a downhole tool and a diamond table that is used to engage the cutting formation. FIGS. 4A-4D illustrate a non-cylindrical cutter 400 according to certain embodiments. Cutter 400 may include a body formed from a substrate 402 and a diamond table 404 that is coupled with substrate 402. Cutter 400 may include a central axis 410, which may extend along a length of cutter 400. Substrate 402 may include a base 406, a top surface (not shown) on which diamond table 404 may be mounted, and one or more lateral surfaces 408 that extend between base 406 and the top surface. Similarly, diamond table 404 may include a base (not shown), a top cutting face 412, and one or more lateral surfaces 414 that extend between the base and cutting face 412. As illustrated, cutting face 412 is planar and parallel to base 406, however in some embodiments cutting face 412 may include one or relief features and/or may be angled relative to base 406 as will be described in greater detail below.

Substrate 402 may include a brazing surface, which may include base 406 and all or part of one or more of the lateral surfaces 408. The brazing surface may include a portion of an exterior surface of substrate 402 that may be brazed to a cutter pocket of a downhole tool, such as the portion of the lateral surfaces 408 and/or base 406 that contact and/or are received within the cutter pocket. In other words, the brazing surface or brazeable surface area may include all surfaces that correspond to and/or directly face the walls defining the cutter pocket. In some embodiments, as least a portion of the brazing surface, substrate 402, and/or diamond table 404 may have a non-circular cross-section. For example, a radial distance between the lateral surfaces 408 and/or 414 and the central axis 410 may vary about an outer periphery of the body of cutter 400. The radial distance between the lateral surfaces 408 and/or 414 of cutter 400 and central axis 410 may vary along at least 50% of the outer periphery of cutter 400, at least 60% of the outer periphery, at least 70% of the outer periphery, at least 80% of the outer periphery, at least 90% of the outer periphery, or more. The radial distance between the lateral surfaces 408 and/or 414 of cutter 400 and central axis 410 may vary along at least 75% of a length of the body and/or substrate 402, at least 80% of the length of the body and/or substrate 402, at least 85% of the length of the body and/or substrate 402, at least 90% of the length of the body and/or substrate 402, at least 95% of the length of the body and/or substrate 402, or more. In other words, the cross-section of substrate 402 and/or the body of cutter 400 may be non-circular for at least 75% of a length of the body and/or substrate 402. In some embodiments, only substrate 402 (or a portion thereof) has a non-circular cross-section, while in other embodiments both substrate 402 and diamond table 404 (or portions of one or both components) may have a non-circular cross-section. As used herein, the term cross-sectional shape is understood to mean the cross-sectional shape of a given cutter or cutter pocket taken along a plane that extends through a width of the cutter or cutter pocket and that is normal to a longitudinal axis of the cutter or cutter pocket.

To produce the non-circular cross-sections, rather than having one lateral surface having an arc of constant radius relative to central axis 410, cutter 400 may include multiple distinct lateral surfaces 408 and/or 414, with at least one lateral surface 408 and/or 414 not having an arc of constant radius relative to central axis 410. For example, cutter 400 may include one or more lateral surfaces 408 and/or 414 that are planar and that are joined by one or more corners, which may be sharp or rounded in various embodiments. In other embodiments, one or more lateral surfaces may be rounded, such as convex or concave surfaces. In the illustrated embodiment, lateral surfaces 408 and 414 each include four planar or linear lateral surfaces 408a and 414a that are joined at four corners 408b and 414b to form a generally quadrilateral shape (e.g., a quadrilateral with rounded corners). As illustrated, linear lateral surfaces 408a and 414a are arranged as two pairs of parallel surfaces, with the two pairs being orthogonal relative to one another to form a generally rectangular shaped cross-section, although in other embodiments linear lateral surfaces 408a and/or 414a may be at other angles, such as to form diamond shapes, trapezoids, parallelograms, and/or other quadrilaterals. In some embodiments, each linear lateral surface 408a and 414a may have a same length to create a square-shaped cutter 400. In other embodiments, one opposing pair of linear lateral surface 408a and 414a may be longer than the other pair of linear lateral surface 408a and 414a, which may enable rectangular and/or diamond-shaped cutters 400. In other embodiments, a single linear lateral surface 408a and 414a from one or both opposing pairs may have a different length, enabling asymmetrical cutters 400 to be formed.

As illustrated, corners 408b and 414b are rounded, which may help reduce the amount of pressure applied to corners 408b and 414b as cutter 400 engages a cutting formation. A radius of each corner 408b and 414b may be variable or may be constant. For example, a constant radius may be utilized such that each corner 408b and/or 414b has a same radius through the entire corner 408b and/or 414b. In some embodiments, the radius of each corner 408b and 414b may match that of a circle having a diameter extending between opposing corners 408b and 414b, although larger or smaller radii may be utilized in various embodiments to make softer or sharper corners.

A width of each corner 408b and 414b may vary based on the desired point loading and drilling efficiency, while ensuring that cutter 400 is sufficiently durable to withstand conditions in downhole operations. For example, narrower and/or sharper corners 408b and 414b may increase the point loading and drilling efficiency of cutter 400. However, a minimum width is required to ensure that cutter 400 is strong enough to survive a given number of downhole operations, such as drilling or reaming operations. In a particular embodiment, a width of each corner 408b and 414b may be between 5 degrees and 45 degrees as measured relative to central axis 410.

Each corner 414b of diamond table 404 may form a discrete cutting tip of cutting face 412 that may be positioned on a blade of a downhole tool in a cutting position such that the cutting tip protrudes beyond a top surface of the blade. This positions a corner 414b of diamond table 404 such that corner 414b engages a cutting formation prior to a portion of the blade and enables corner 414b to fail the rock or other material forming the cutting formation as the downhole tool rotates within a borehole. Additionally, the presence of one or more lateral surfaces 408 that have non-constant circular arcs (e.g., are linear and/or having variable and/or concave arcs) may enable such lateral surfaces 408 to serve as indexing features that are usable to orient cutter 400 in a corresponding cutter pocket in a cutting position in which a cutting tip of cutter 400 protrudes beyond a top surface of the blade at a desired angle relative to a top and/or front surface of the blade.

Diamond table 404 may include a chamfered edge 416 that extends from cutting face 412 to lateral sides 414 of diamond table 404. For example, chamfered edge 416 may extend from cutting face 412 to lateral sides 414 at an angle of between 20 degrees to 60 degrees relative to cutting face 412. Chamfered edge 416 may reduce the pressure exerted on diamond table 404 by the cutting formation and may help increase the durability of cutter 400. The angle of chamfered edge 416 may be selected to control the aggressiveness of cutting and/or durability of cutter 400.

While FIGS. 4A-4D illustrate non-cylindrical cutters that have generally quadrilateral cross-sections, it will be appreciated that other shapes of non-cylindrical cutters are possible in various embodiments. For example, the diamond table and/or each non-cylindrical cutter may have two or more linear lateral surfaces (and/or concave sides), three or more linear lateral surfaces, four or more linear lateral surfaces, five or more linear lateral surfaces, or more. For example, FIGS. 5A-5D illustrate a non-cylindrical cutter 500 having a generally triangular cross-section. Other than the general cross-sectional shape, cutter 500 may include similar features as cutter 400. For example, cutter 500 may include a body formed from a substrate 502 and a diamond table 504 that is coupled with substrate 502. Cutter 500 may include a central axis 510, which may extend along a length of cutter 500. Substrate 502 may include a base 506, a top surface (not shown) on which diamond table 504 may be mounted, and lateral surfaces 508 that extend between base 506 and the top surface. Similarly, diamond table 504 may include a base (not shown), a top cutting face 512, and three lateral surfaces 514 that extend between the base and cutting face 512. In the illustrated embodiment, lateral surfaces 508 and 514 each include three planar or linear lateral surfaces 508a and 514a that are joined at three corners 508b and 514b to form a generally triangular shape (e.g., a triangle with rounded corners). As illustrated, corners 508b and 514b are rounded, which may help reduce the amount of pressure applied to corners 508b and 514b as cutter 500 engages a cutting formation. A radius of each corner 508b and 514b may be variable or may be constant. For example, a constant radius may be utilized such that each corner 508b and/or 514b has a same radius through the entire corner 508b and/or 514b. In some embodiments, the radius of each corner 508b and 514b may match that of a circle having a diameter extending between opposing corners 508b and 514b, although larger or smaller radii may be utilized in various embodiments to make softer or sharper corners. Diamond table 504 may include a chamfered edge 516 that extends from cutting face 512 to lateral sides 514 of diamond table 504. For example, chamfered edge 516 may extend from cutting face 512 to lateral sides 514 at an angle of between 20 degree and 60 degrees relative to cutting face 512.

Each corner 514b of diamond table 504 may form a discrete cutting tip of cutting face 512 that may be positioned on a blade of a downhole tool in a cutting position such that the cutting tip protrudes beyond a top surface of the blade. This positions a corner 514b of diamond table 504 such that corner 514b engages a cutting formation prior to a portion of the blade and enables corner 514b to fail the rock or other material forming the cutting formation as the downhole tool rotates within a borehole. Additionally, the presence of one or more lateral surfaces 408 that have non-constant circular arcs (e.g., are linear and/or having variable and/or concave arcs) may enable such lateral surfaces 508 to serve as indexing features that are usable to orient cutter 500 in a corresponding cutter pocket in a cutting position in which a cutting tip of cutter 500 protrudes beyond a top surface of the blade at a desired angle relative to a top and/or front surface of the blade.

FIGS. 6A-6D illustrate a non-cylindrical cutter 600 having a generally pentagonal cross-section. Other than the general cross-sectional shape, cutter 600 may include similar features as cutters 400 and 500. For example, cutter 600 may include a body formed from a substrate 602 and a diamond table 604 that is coupled with substrate 602. Cutter 600 may include a central axis 610, which may extend along a length of cutter 600. Substrate 602 may include a base 606, a top surface (not shown) on which diamond table 604 may be mounted, and five lateral surfaces 608 that extend between base 606 and the top surface. Similarly, diamond table 604 may include a base (not shown), a top cutting face 612, and lateral surfaces 614 that extend between the base and cutting face 612. In the illustrated embodiment, lateral surfaces 608 and 614 each include five planar or linear lateral surfaces 608a and 614a that are joined at five corners 608b and 614b to form a generally pentagonal shape (e.g., a pentagon with rounded corners). As illustrated, corners 608b and 614b are rounded, which may help reduce the amount of pressure applied to corners 608b and 614b as cutter 600 engages a cutting formation. A radius of each corner 608b and 614b may be variable or may be constant. For example, a constant radius may be utilized such that each corner 608b and/or 614b has a same radius through the entire corner 608b and/or 614b. In some embodiments, the radius of each corner 608b and 614b may match that of a circle having a diameter extending between opposing corners 608b and 614b, although larger or smaller radii may be utilized in various embodiments to make softer or sharper corners. Diamond table 604 may include a chamfered edge 616 that extends from cutting face 612 to lateral sides 614 of diamond table 604. For example, chamfered edge 616 may extend from cutting face 612 to lateral sides 614 at an angle of between 20 degrees and 60 degrees relative to cutting face 612.

Each corner 614b of diamond table 604 may form a discrete cutting tip of cutting face 612 that may be positioned on a blade of a downhole tool such that the cutting tip protrudes beyond a top surface of the blade. This positions a corner 614b of diamond table 604 such that corner 614b engages a cutting formation prior to a portion of the blade and enables corner 614b to fail the rock or other material forming the cutting formation as the downhole tool rotates within a borehole. Additionally, the presence of one or more lateral surfaces 608 that have non-constant circular arcs (e.g., are linear and/or having variable and/or concave arcs) may enable such lateral surfaces 608 to serve as indexing features that are usable to orient cutter 600 in a corresponding cutter pocket in a cutting position in which a cutting tip of cutter 600 protrudes beyond a top surface of the blade at a desired angle relative to a top and/or front surface of the blade.

FIGS. 7A-7D illustrate a non-cylindrical cutter 700 having a generally stadium shaped cross-section. In some embodiments, cutter 700 may have a true stadium shape, with two semicircular regions separated by a central rectangular region having a width that matches a diameter of the semicircular regions. In such embodiments, a transition between the semicircular regions and the rectangular region may be seamless. In other embodiments, cutter 700 may have a generally stadium shape, with two arcuate regions, each having less than 180 degrees of a circle, separated by a central rectangular region having a width that is less than a diameter of the semicircular regions. In such embodiments, a transition between the semicircular regions and the rectangular region may result in a corner, which may be rounded or sharp. Other than the general cross-sectional shape, cutter 700 may include similar features as cutters 400, 500, and 600. For example, cutter 700 may include a body formed from a substrate 702 and a diamond table 704 that is coupled with substrate 702. Cutter 700 may include a central axis 710, which may extend along a length of cutter 700. Substrate 702 may include a base 706, a top surface (not shown) on which diamond table 704 may be mounted, and lateral surfaces 708 that extend between base 706 and the top surface. Similarly, diamond table 704 may include a base (not shown), a top cutting face 712, and lateral surfaces 714 that extend between the base and cutting face 712. In the illustrated embodiment, lateral surfaces 708 and 714 each include two planar or linear lateral surfaces 708a and 714a that are each joined by two rounded ends 708b and 714b to form a stadium shape. A radius of each rounded end 708b and 714b may be variable or may be constant. For example, a constant radius may be utilized such that each rounded end 708b and/or 714b has a same radius through the entire rounded end 708b and/or 714b. In some embodiments, the radius of each rounded end 708b and 714b may match that of a circle having a diameter extending between the two rounded ends 708b and 714b, although larger or smaller radii may be utilized in various embodiments to make softer or sharper ends. Diamond table 704 may include a chamfered edge 716 that extends from cutting face 712 to lateral sides 714 of diamond table 704. For example, chamfered edge 716 may extend from cutting face 712 to lateral sides 714 at an angle of between 20 degrees and 60 degrees relative to cutting face 712.

Each rounded end 714b of diamond table 704 may form a discrete cutting tip of cutting face 712 that may be positioned on a blade of a downhole tool such that the cutting tip protrudes beyond a top surface of the blade. This positions a rounded end 714b of diamond table 704 such that rounded end 714b engages a cutting formation prior to a portion of the blade and enables rounded end 714b to fail the rock or other material forming the cutting formation as the downhole tool rotates within a borehole. Additionally, the presence of one or more lateral surfaces 408 that have non-constant circular arcs (e.g., are linear and/or having variable and/or concave arcs) may enable such lateral surfaces 408 to serve as indexing features that are usable to orient cutter 400 in a corresponding cutter pocket in a cutting position in which a cutting tip of cutter 400 protrudes beyond a top surface of the blade at a desired angle relative to a top and/or front surface of the blade.

FIGS. 8A-8D illustrate a non-cylindrical cutter 800 having a generally hexagonal cross-section. Other than the general cross-sectional shape, cutter 800 may include similar features as cutters 400, 500, 600, and 700. For example, cutter 800 may include a body formed from a substrate 802 and a diamond table 804 that is coupled with substrate 802. Cutter 800 may include a central axis 810, which may extend along a length of cutter 800. Substrate 802 may include a base 806, a top surface (not shown) on which diamond table 804 may be mounted, and lateral surfaces 808 that extend between base 806 and the top surface. Similarly, diamond table 804 may include a base (not shown), a top cutting face 812, and lateral surfaces 814 that extend between the base and cutting face 812. In the illustrated embodiment, lateral surfaces 808 and 814 each include six planar or linear lateral surfaces 808a and 814a that are joined at six corners 808b and 814b to form a generally hexagonal shape (e.g., a hexagon with rounded corners). As illustrated, corners 808b and 814b are rounded, which may help reduce the amount of pressure applied to corners 808b and 814b as cutter 800 engages a cutting formation. A radius of each corner 808b and 814b may be variable or may be constant. For example, a constant radius may be utilized such that each corner 808b and/or 814b has a same radius through the entire corner 808b and/or 814b. In some embodiments, the radius of each corner 808b and 814b may match that of a circle having a diameter extending between opposing corners 808b and 814b, although larger or smaller radii may be utilized in various embodiments to make softer or sharper corners. Diamond table 804 may include a chamfered edge 816 that extends from cutting face 812 to lateral sides 814 of diamond table 804. For example, chamfered edge 816 may extend from cutting face 812 to lateral sides 814 at an angle of between 20 degrees and 60 degrees relative to cutting face 812.

Each corner 814b of diamond table 804 may form a discrete cutting tip of cutting face 812 that may be positioned on a blade of a downhole tool such that the cutting tip protrudes beyond a top surface of the blade. This positions a corner 814b of diamond table 804 such that corner 814b engages a cutting formation prior to a portion of the blade and enables corner 814b to fail the rock or other material forming the cutting formation as the downhole tool rotates within a borehole. Additionally, the presence of one or more lateral surfaces 808 that have non-constant circular arcs (e.g., are linear and/or having variable and/or concave arcs) may enable such lateral surfaces 808 to serve as indexing features that are usable to orient cutter 800 in a corresponding cutter pocket in a cutting position in which a cutting tip of cutter 800 protrudes beyond a top surface of the blade at a desired angle relative to a top and/or front surface of the blade.

FIGS. 9A-9D illustrate a non-cylindrical cutter 900 having a generally rectangular cross-section with concave, rather than linear lateral surfaces. Other than the general cross-sectional shape, cutter 900 may include similar features as cutters 400, 500, 600, 700, and 800. For example, cutter 900 may include a body formed from a substrate 902 and a diamond table 904 that is coupled with substrate 902. Cutter 900 may include a central axis 910, which may extend along a length of cutter 900. Substrate 902 may include a base 906, a top surface (not shown) on which diamond table 904 may be mounted, and lateral surfaces 908 that extend between base 906 and the top surface. Similarly, diamond table 904 may include a base (not shown), a top cutting face 912, and lateral surfaces 914 that extend between the base and cutting face 912. In the illustrated embodiment, lateral surfaces 908 and 914 each include four concave lateral surfaces 908a and 914a that are joined at four corners 908b and 914b to form a generally rectangular shape (e.g., a rectangular with inwardly curved sides and rounded corners). Each concave lateral surface 908a and 914a may have a constant radius or a variable radius in some embodiments. It will further be appreciated that in some embodiments, rather than having concave lateral surfaces, cutter 900 may have convex lateral surfaces. As illustrated, corners 908b and 914b are rounded, which may help reduce the amount of pressure applied to corners 908b and 914b as cutter 900 engages a cutting formation. A radius of each corner 908b and 914b may be variable or may be constant. For example, a constant radius may be utilized such that each corner 908b and/or 914b has a same radius through the entire corner 908b and/or 914b. In some embodiments, the radius of each corner 908b and 914b may match that of a circle having a diameter extending between opposing corners 908b and 914b, although larger or smaller radii may be utilized in various embodiments to make softer or sharper corners. Diamond table 904 may include a chamfered edge 916 that extends from cutting face 912 to lateral sides 914 of diamond table 904. For example, chamfered edge 916 may extend from cutting face 912 to lateral sides 914 at an angle of between 20 degrees and 60 degrees relative to cutting face 912.

Each corner 914b of diamond table 904 may form a discrete cutting tip of cutting face 912 that may be positioned on a blade of a downhole tool such that the cutting tip protrudes beyond a top surface of the blade. This positions a corner 914b of diamond table 904 such that corner 914b engages a cutting formation prior to a portion of the blade and enables corner 914b to fail the rock or other material forming the cutting formation as the downhole tool rotates within a borehole. Additionally, the presence of one or more lateral surfaces 908 that have non-constant circular arcs (e.g., are linear and/or having variable and/or concave arcs) may enable such lateral surfaces 908 to serve as indexing features that are usable to orient cutter 900 in a corresponding cutter pocket in a cutting position in which a cutting tip of cutter 900 protrudes beyond a top surface of the blade at a desired angle relative to a top and/or front surface of the blade.

While shown with each cutter having a cross-section of a regular shape, it will be appreciated that cutters having irregular shaped cross-sections may be utilized in various embodiments. Additionally, cutters in accordance with the present invention may include circular cross-sections along a portion of a length of the cutter, with the cross-section transitioning to one or more non-circular shapes that collectively extend for at least 75% of the length of the cutter. Similarly, a cross-sectional shape of all or a portion of the diamond table may be different than a cross-sectional shape of some or all of a substrate of the cutter in some embodiments. Oftentimes, a cross-sectional shape of a cutter (or portion thereof) may be formed from two or more linear lateral surfaces that are connected to one another via a number of rounded corners or ends. In such embodiments, a ratio of a length of the linear lateral surfaces to a length of the rounded corners/ends (e.g., a ratio of the outer periphery of the non-circular cross section that is formed from straight surfaces to curved surfaces) may be between 0.5:1 and 10:1, between 0.5:1 and 5:1, between 0.5:1 and 4:1, between 0.5:1 and 3:1, between 0.5:1 and 2.5:1, between 0.5:1 and 2:1, between 0.5:1 and 1.5:1, between 0.5:1 and 1:1, or between 0.5:1 and 0.75:1. In some embodiments, the non-cylindrical cutters described herein may be symmetrical about one or more planes or axes. For example, the cutters may be is symmetrical about two perpendicular planes that extend through both the substrate and the diamond table. This may be the case, for example, with rectangular cutters such as cutter 400, hexagonal cutters such as cutter 800, rectangular cutters with concave sides such as cutter 900 and stadium shaped cutters such as cutter 700. In particular, cutter 400 may be symmetrical about two perpendicular planes that each bisect different pairs of opposing lateral surfaces 408a and 414a and/or about two perpendicular planes that each bisect different pairs of opposing corners 408b and 414b. In other embodiments, the cutters may be asymmetric and/or symmetric about two or more planes that are not orthogonal to one another, such as with triangular cutter 500 and pentagonal cutter 600.

In some embodiments, rather than having diamond tables with planar cutting surfaces as shown in FIGS. 4A-9D, cutters may include diamond tables with non-planar cutting surfaces. For example, the cutting surfaces may include one or more relief features, such as protruding features that extend in a direction opposite the substrate and/or recessed features that extend toward the substrate. The inclusion of relief features may serve different purposes. For example, protruding relief features may increase the thickness of the diamond table to add strength to the cutter, while also improving the point loading of the cutter, as the cutting tip protrudes away from the rest of the diamond table to engage the formation before any other portion of the cutter. Recessed relief features on areas near, but not extending through a cutting tip, may similarly improve the point loading by making the cutting tip extend away from the surrounding portion of the diamond table. FIGS. 10A-12D illustrate different embodiments of cutters having non-planar cutting surfaces in accordance with the present technology. Turning to FIGS. 10A-10D, a rectangular cutter 1000 is illustrated. Cutter 1000 may be similar to rectangular cutter 400 and may include any of the features described in relation to cutter 400. For example, cutter 1000 may include a body that is formed from a substrate 1002 and a diamond table 1004 that is coupled with the substrate 1002. Diamond table 1004 may include a cutting surface that is configured to engage a cutting formation during a downhole operation. Cutting surface 1012 of diamond table 1004 may include one or more relief features that protrude away from and/or are recessed toward substrate 1002. For example, as illustrated diamond table 1004 include a ridge 1020 that extends from one corner of cutting surface 1012 to an opposing corner of cutting surface 1012. Ridge 1020 may have a flat apex, an angled apex, and/or a curved apex in various embodiments. Ridge 1020 is a protruding feature that extends a direction opposite substrate 1002, thereby increasing a thickness of diamond table 1004 at the corners through which ridge 1020 extends. A thickness of diamond table 1004 may taper or otherwise change from a thinnest point proximate the corners that do not include ridge 1020 to a thickest point at an apex of ridge 1020. The taper may be linear as shown here, or may be curved and/or stepped in some embodiments. A difference in thickness between the thickest and thinnest regions of diamond table 1004 may be between 0.005 inch and 0.300 inch, with a total thickness of diamond table 1004 being between 0.050 inch and 0.350 inch.

FIGS. 11A-11D illustrate an embodiment of a rectangular cutter 1100 having multiple relief features. Cutter 1100 may be similar to rectangular cutters 400 and 1000 and may include any of the features described in relation to cutters 400 and 1000. For example, cutter 1100 may include a body that is formed from a substrate 1102 and a diamond table 1104 that is coupled with the substrate 1102. Diamond table 1104 may include a cutting surface that is configured to engage a cutting formation during a downhole operation. Cutting surface 1112 of diamond table 1104 may include one or more relief features that protrude away from and/or are recessed toward substrate 1102. For example, as illustrated diamond table 1104 include two ridges 1120 that 5 each extend from one corner of cutting surface 1112 to an opposing corner of cutting surface 1112. Each ridge 1120 is a protruding feature that extends a direction opposite substrate 1102, thereby increasing a thickness of diamond table 1104 at the corners through which each ridge 1120 extends. The two ridges 1120 may intersect at a center of cutting surface 1112 and may form a thickest region of diamond table 1104. For example, a thickness of diamond table 1104 may taper or otherwise change from a thinnest point proximate midpoints of linear lateral surfaces that extend between adjacent corners of diamond table 1104 to a thickest point at an apex of each ridge 1120. The taper may be linear and may create V-shaped valleys between each pair of adjacent corners of diamond table 1104 as shown here, or may be curved and/or stepped in some embodiments. A difference in thickness between the thickest and thinnest regions of diamond table 1104 may be between 0.005 inch and 0.300 inch, with a total thickness of diamond table 1104 being between 0.050 inch and 0.350 inch.

While shown here with ridges or other protruding relief features extending through the corners/cutting tips of a given cutter, it will be appreciated that some embodiments of cutters may include recessed relief features instead of or in addition to protruding relief features. Such recessed relief features may produce areas of lower thickness of the diamond table and may make the cutting tips more pronounced to improve point loading. Oftentimes, recessed relief features may be positioned between two or more protruding relief features to create a deeper or more pronounced valley between the protruding relief features. Additionally, the presence of one or more recessed relief features may make the cutting tips more pronounced and may improve the point loading and drilling efficiency of the cutter.

In some embodiments, rather than having distinct relief features such as ridges, grooves, and the like, cutters may include sloped surfaces that effectively impart forward rake on the cutting surface. FIGS. 12A-13D illustrate cutters having forward rake in accordance with embodiments of the present invention. For example, FIGS. 12A-12D illustrate a rectangular cutter 1200 having forward rake. Cutter 1200 may be similar to rectangular cutter 400 and may include any of the features described in relation to cutter 400. For example, cutter 1200 may include a body that is formed from a substrate 1202 and a diamond table 1204 that is coupled with the substrate 1202. Diamond table 1204 may include a cutting tip 1222 that is configured to engage a cutting formation during a downhole operation. Cutting surface 1212 of diamond table 1204 may be tapered or otherwise sloped such that diamond table 1204 is thickest at the cutting tip 1222 of diamond table 1204. For example, as illustrated diamond table 1204 slopes from a thinnest point proximate a corner of diamond table 1204 opposite the cutting tip 1222 to a thickest point at cutting tip 1222. The slope may be linear as shown here or may be curved and/or stepped in some embodiments. A difference in thickness between the thickest and thinnest regions of diamond table 1204 may be between 0.005 inch and 0.300 inch, with a total thickness of diamond table 1204 being between 0.050 inch and 0.350 inch. The increased thickness at cutting tip 1222 may impart forward rake on cutter 1200 when cutter 1200 is installed in a pocket of a downhole tool in a cutting position with cutting tip 1222 protruding beyond a top surface of a blade of the downhole tool. The forward rake ensures that cutter 1200 is tilted forward in the direction of bit rotation such that an angle between cutting face 1212 and the formation in front of cutting face 1212 is greater than 90°. Front rake may enable cutter 1200 to penetrate deeper into the cutting formation.

In some embodiments, a cutter having forward rake may be dual-sided. FIGS. 13A-13D illustrate a dual-sided rectangular cutter 1300 having forward rake. Cutter 1300 may be similar to rectangular cutters 400 and 1000 and may include any of the features described in relation to cutters 400 and 1000. For example, cutter 1300 may include a body that is formed from a substrate 1302 and a diamond table 1304 that is coupled with the substrate 1302. Diamond table 1304 may include a cutting surface 1312 having two cutting tips 1322 that are each configured to engage a cutting formation during a downhole operation. Cutting tips 1322 may be positioned on opposite corners of diamond table 1304 such that only one cutting tip 1322 is used to fail the cutting formation at a given time, which enables cutter 1300 to be rotated after use to expose a different cutting tip 1322 after a first cutting tip 1322 has been worn. Cutting surface 1312 of diamond table 1304 may be tapered or otherwise sloped such that diamond table 1304 is thickest at cutting tips 1322 of diamond table 1304. For example, as illustrated diamond table 1304 slopes from a thinnest point proximate a centerline of diamond table 1304 that extends through corners of diamond table 1304 that do not form cutting tips 1322 to a thickest point at each cutting tip 1322. The slope may be linear as shown here or may be curved and/or stepped in some embodiments. A difference in thickness between the thickest and thinnest regions of diamond table 1304 may be between 0.005 inch and 0.300 inch, with a total thickness of diamond table 1304 being between 0.050 inch and 0.350 inch. The increased thickness at each cutting tip 1322 may impart forward rake on cutter 1300 when cutter 1300 is installed in a pocket of a downhole tool in a cutting position with one cutting tip 1322 protruding beyond a top surface of a blade of the downhole tool. The forward rake ensures that cutter 1300 is tilted forward in the direction of bit rotation such that an angle between cutting face 1322 and the formation in front of cutting face 1312 is greater than 90°. Front rake may enable cutter 1300 to penetrate deeper into the cutting formation.

While FIGS. 10A-12D illustrate relief features formed on the cutting surfaces of rectangular cutters, it will be appreciated that similar relief features may be incorporated into cutters having other non-circular cross-sectional shapes. Additionally, cutters may be formed with any number of relief features. For example, each cutting tip of a given cutter may include a protruding feature in some embodiments. The relief features may be distinct elements that are separated by regions of different diamond table thickness and/or may be continuous regions that have a greater or lesser thickness than other regions of the diamond table. It will be appreciated that protruding features are not limited to being positioned at cutting tips of a cutter and that areas of the diamond table that are not intended as cutting tips may include protruding features.

As described above, the cutters described herein may include a chamfered edge that extends from a cutting surface of a diamond table to a lateral surface of the diamond table. The chamfered edge may increase the surface area of the cutting tip and eliminate sharp angles that may result in high force concentrations that may prematurely damage the cutter. In some embodiments, the chamfered edge may be uniform about an entire outer periphery of the cutting face, with an angle and depth of the chamfered edge being consistent about the entire outer periphery of the cutting face. In other embodiments, the angle and/or depth of the chamfered edge may vary along the outer periphery of the cutting face. FIGS. 14A-14C illustrate embodiments of a cutter 1400 that includes a chamfered edge 1416 that extends from a cutting surface 1414 of a diamond table 1404 to a lateral surface 1414 of diamond table 1404. As illustrated in FIG. 14A, chamfered edge 1416a is widest proximate two corners and narrows toward two opposing corners. The change in width may be controlled by changes to a depth (e.g., distance from cutting surface 1412 to lateral surface 1414) of the chamfer and/or angle of the chamfer. In some embodiments, transitions from one chamfer width to another may be done along a lateral surface 1414 and/or along a corner of cutting surface 1412. Transitions in width may be linear and/or arc shaped. As shown in FIG. 14B, chamfered edge 1416b is widest proximate a first pair of opposing corners and thinnest at the other pair of opposing corners. In the illustrated embodiment, transitions between the wide chamfer region and the narrow chamfer region are linear. FIG. 14C illustrates a similar chamfered edge 1416c in which transitions between wide chamfer regions and narrow chamfer regions are arc shaped, with the arc being concave relative to cutting surface 1412c. In some embodiments, the wider regions of chamfered edge 1416 may be used at cutting tips, while in other embodiments the narrower regions of chamfered edge 1416 may be used as cutting tips. In some embodiments, different cutting tips on a single cutter 1400 may have different geometries of chamfered edge 1416 to enable cutter 1400 to be oriented with a particular cutting tip in the cutting position to meet the needs of a particular downhole operation, enabling a single cutter 1400 to provide different cutting parameters.

In some embodiments, a width of chamfered edge 1416 may be between about 0.005 inches and 0.040 inches, with differences between widest and narrowest regions often being between 0.005 inches and 0.035 inches and more commonly between 0.010 inches and 0.025 inches. An angle of chamfered edge 1416 may be between 20 and 60 degrees relative to cutting surface 1412, although the angle is more commonly between 30 degrees and 50 degrees. Chamfered edge 1416 may extend through cutting surface 1412 and/or lateral surface 1414 at angles to form sharp corners and/or may be formed with a radius to soften the corners. Oftentimes, chamfered edge 1416 is at least partially formed using laser grinding techniques, which may enable chamfered edge 1416 to include a mixture of geometries.

In some embodiments, an angle of the chamfered edge relative to the cutting face may vary along a periphery of the cutting face. For example, the angle of the chamfered edge relative to the cutting face may be greater at a cutting region of the cutting face than at a medial region of the cutting face. In other embodiments, the angle of the chamfered edge relative to the cutting face may be lower at a cutting region of the cutting face than at a medial region of the cutting face. In some embodiments, a depth of the chamfered edge may vary along a periphery of the cutting face. For example, the depth of the chamfered edge may be greater at a cutting region of the cutting face than at a medial region of the cutting face. In other embodiments, the depth of the chamfered edge may be lower at a cutting region of the cutting face than at a medial region of the cutting face.

As described above, each cutter may include a substrate and a diamond table that is coupled with the substrate. The substrate may include an interface formed into a surface of the substrate that faces the diamond table. The interface may be formed by pressing, molding, and/or etching the substrate such that the interface protrudes from the top surface of the substrate in a direction of the diamond table. The interface may generally correspond to a peripheral shape of the top surface of the substrate and/or a peripheral shape of the diamond table. For example, in a conventional cylindrical substrate, a cylindrical interface may protrude upward from the top surface of the substrate. The diamond table may therefore include a corresponding (e.g., substantially same size and shape) recess, such that the substrate and the diamond table may be connected via insertion of the cylindrical interface into the recess of the diamond table. In non-cylindrical cutters, such as those described above, the interface may be a non-planar interface (NPI) that has a non-circular cross-section, which may match a cross-sectional shape of the substrate and/or diamond table. In other words, a shape of an outer periphery of the non-planar interface may match a shape of an outer periphery of a topmost planar surface of the substrate and/or an outer periphery of the diamond table. This may enable force being transmitted through the cutter to be more evenly distributed across the interface between diamond table and substrate and/or to prevent weak spots from being formed within the diamond table.

FIG. 15 illustrates one embodiment of a non-cylindrical cutter 1500 with a non-cylindrical non-planar interface 1530. Cutter 1500 may be similar to cutters 400-1400 described herein and may include any of the features described in relation to those cutters. Additionally, each of cutters 400-1400 may incorporate non-planar interfaces such as those described herein. Cutter 1500 may include a substrate 1502 and a diamond table 1504. Cutter 1500 may have a generally rectangular cross-section similar to cutter 400. NPI 1530 may include an outer periphery having a shape that substantially matches an outer periphery of the perimeter of the top surface 1515 of diamond table 1504 such that spacing between edges of NPI 1530 and an edge of substrate 1502 and/or diamond table 1504 is substantially consistent (e.g., within 20%, within 15%, within 10%, within 5%, within 3%, within 1%, or less) about an entire periphery of substrate 1502 and/or diamond table 1504. A top surface of NPI 1530 may be planar or non-planar. For example, as illustrated NPI 1530 includes ridges 1532 and grooves 1534, with each ridge 1532 having a same size and shape and each groove 1534 having a same size and shape. In other embodiments, NPI 1530 may include a lattice pattern, honeycomb pattern, ridges, rings, etc. that enable a portion of the diamond table to be pressed into voids formed within the pattern. Additionally, in some embodiments, the ridges, grooves, and/or other non-planar features may have different sizes and/or shapes across the length and/or width of NPI 1530.

FIG. 16 illustrates multiple views of one embodiment of a shaped cutter 1600 with an NPI 1630 having a variable thickness across a surface area of NPI 1630. Cutter 1600 may be similar to cutters 400-1500 described herein and may include any of the features described in relation to those cutters. Cutter 1600 may include a substrate 1602 and diamond table 1604 that have non-circular cross-sections at a top surface of substrate 1602 and about all of diamond table 1604. Diamond table 1604 may include a relief feature, such as protruding ridge 1620. As illustrated, ridge 1620 may extend across a diameter of diamond table 1604, extending from a depression 1619 in substrate 1602 to another depression 1619 on an opposing side of substrate 1602, although other orientations are possible in various embodiments. Although only one relief feature in diamond table 1604 is shown, diamond table 1604 may include any number of relief features of various shapes and sizes. As illustrated, a thickness of NPI 1630 may vary in accordance with the thickness of diamond table 1604. For example, where diamond table 1604 includes protruding ridge 1620, a thickness of NPI 1630 may increase in a region that corresponds to (e.g., is below and supporting) protruding ridge 1620. In some embodiments, a change in thickness of NPI 1630 within the region below ridge 1620 may be the same as a protrusion distance of ridge 1620, while in other embodiments the protrusion distance may be greater or less than the change in thickness of NPI 1630. Similarly, where diamond table 1604 includes a recessed relief feature, a thickness of NPI 1630 may decrease in a region that corresponds to (e.g., is below and supporting) the recessed relief feature. In some embodiments, a change in thickness of NPI 1630 within the region below the recessed relief feature may be the same as a depth of the recessed relief feature, while in other embodiments the depth may be greater or less than the change in thickness of NPI 1630.

As discussed above, each cutter may be received within a pocket formed within a blade of a downhole tool, such as a drill bit or a reamer. For non-cylindrical cutters, the corresponding pockets may also have non-cylindrical shapes (i.e., do not consist solely of circular or partial circular cross-sections). In particular, a size and shape of each pocket may substantially match that of at least a portion of the cutter that is being inserted into the pocket. This may enable the non-cylindrical cutters to be securely received within the cutter pocket without permitting rotation of the cutter within the pocket. Outer dimensions of the pocket may be slightly larger than the outer dimensions of the cutter, such as by between 0.01 inch and 0.025 inch. This may provide sufficient a gap for braze material that is used to join the cutter to walls defining the pocket, while still limiting the ability of the cutter to rotate within the pocket. Insertion of the cutter into the pocket may therefore completely or substantially orient the cutter in a proper position relative to the blade. More specifically, due to the non-circular cross-section of the pocket and cutter, insertion of the cutter into the blade may result in a cutting tip of the cutter being at a desired angle and projection distance beyond a top surface of the blade (e.g., in a cutting position), with little to no alignment effort by an installer due to the small size of the braze gap. Additionally, for cutters having multiple discrete cutting tips, any number of cutting tips may be placed in the cutting position, enabling the cutter to be removed from the pocket after some use, rotated, and inserted with a different cutting tip in the cutting position, thereby increasing the usable life of the cutter.

While described as being non-cylindrical or as having non-circular cross-sections, it will be appreciated that the pockets described herein may not fully surround the lateral surfaces of a given cutter. For example, a given pocket may only surround between 40% and 95% of the length of the outer periphery of a cutter, with the remaining portion of the cutter being exposed beyond a top surface of the blade on which the pocket is formed. Thus, as used herein, a cylindrical pocket or pocket having a circular cross-section is meant to refer to a pocket in which for greater than 25% of the length of the pocket, a cross-section of the pocket is defined by a single sidewall of a constant radius (possibly with some of the circle missing as the pocket may be open at the top surface of the blade). In contrast, a non-cylindrical pocket or pocket having a non-circular cross-section is meant to refer to a pocket in which at least 10% a non-circular cross-section of the pocket is defined by one or more sidewalls having a variable radius, one or more sidewalls with curvature that is not concentric with the central axis of the cutter pocket, and/or one or more sidewalls including one or more linear and/or convex features, with the non-circular cross-section extending for at least the forwardmost 10% of a length of the cutter pocket, at least the forwardmost 20% of the length, at least the forwardmost 30% of the length, at least the forwardmost 40% of the length, at least the forwardmost 50% of the length, at least the forwardmost 60% of the length, at least the forwardmost 70% of the length, at least the forwardmost 75% of the length, at least the forwardmost 80% of the length, at least the forwardmost 85% of the length, at least the forwardmost 90% of the length, at least the forwardmost 95% of the length, or more, possibly including the entire length. This may enable a front end of the cutter pocket and a front end of the corresponding cutter to index the cutter within a proper orientation relative to the cutter pocket and blade. Embodiments in which the non-circular cross-section extends for all or a majority of the length of the cutter pocket may be beneficial in improving the drilling efficiency, as corresponding cutters will have lower volumes of the substrate extending beyond the top surface of the blade and may therefore provide less resistance to rotation than conventional cylindrical cutters when engaged with the formation.

Moreover, when a cutter pocket is referred to as having a specific cross-sectional shape, it is meant that the cutter pocket is created as a void formed in a blade by a portion of the recited shape such that a cutter having a same cross-sectional size and shape would be able to fit in the pocket without modification. For example, where a pocket is described as having a rectangular cross-section, the pocket may only define between 40% and 95% of a rectangular cross-section and may therefore appear more triangular, pentagonal, or otherwise non-rectangular. However, a rectangular cutter may be inserted into the pocket and enable a discrete cutting tip of the cutter to protrude beyond the top surface of the blade.

The non-cylindrical pockets may be manufactured into the drill bit and/or reamer in non-cylindrical form, or an existing pocket (e.g., cylindrical or a different non-cylindrical shape) may be modified into a non-cylindrical pocket. For example, one or more shims may be inserted into an existing pocket such that the existing pocket is now non-cylindrical. The non-cylindrical pocket may then accept a corresponding non-cylindrical cutter, such as those as described above. In some embodiments, each shim may be inserted into the pocket, then brazed with the corresponding cutter. In other embodiments, each shim may first be brazed, welded, or otherwise attached within the existing pocket prior to a cutter being inserted.

FIG. 17 illustrates a drill bit 1700 without any cutters. Drill bit 1700 may be similar to drill bits 100 and 200 and may include any features described in relation to drill bits 100 and 200. For example, drill bit 1700 may include a bit body 1704 that is designed to be rotated about a central bit axis 1702. Bit body 1704 may include one or more raised blades 1710 that extend from the face of bit body 1704. In some embodiments, blades 1710 extend radially along the bit face and are circumferentially spaced structures extending along the leading end or formation engaging portion of bit body 1704. Each blade 1710 may extend generally in a radial direction, outwardly to the periphery of bit body 1704. For example, blades 1710 may generally extend from the cone region proximate the longitudinal axis, or central axis 1702, of the bit, upwardly to the gauge region, or maximum drill diameter of bit. Channels formed between adjacent blades may form the junk slots that provide paths for drilling fluid and formation cuttings to be carried up the wellbore. As drill bit 1700 is rotated within the wellbore via the drill string, drilling fluid may be pumped down the drill string, through the internal fluid plenum and fluid passageways within bit body 1704 of drill bit 1700, and out from drill bit 1700 through nozzles 1717.

Each blade 1710 may define a number of cutter pockets 1720, with each cutter pocket being configured to receive a cutter, such as cutters 112, 212-224, 316, and 400-1600. Some or all cutter pockets 1720 may include a non-circular cross-section. For example, cutter pockets 1720a may have cross-sections that are rectangular, triangular, pentagonal, stadium-shaped, and/or other non-circular shapes. Each cutter pocket 1720a may be configured to receive a non-cylindrical cutter, such as cutters 400-1600 described herein. For example, each cutter pocket 1720a may have a generally rectangular cross-section, such as with at least two orthogonal linear sides and a rounded corner coupling the two orthogonal linear sides. In some embodiments, one or more additional corners and/or linear sides may be included, such as where a given cutter pocket 1720a surrounds greater than 50% of the perimeter of a corresponding cutter. Some or all of the pockets may surround different amounts of a cutter. In some embodiments, a width of each rounded corner may be between 5 degrees and 45 degrees as measured from a central axis of the cutter pocket.

In some embodiments, drill bit 1700 may also include one or rows of backup cutter pockets 1722 disposed on one or more blades 1710. For example, some blades 1710 may include two rows of cutter pockets 1720 (and subsequently cutters), with one row being substantially behind a first row of primary cutter pockets 1720 that extend through a leading edge of the respective blade 1710. In some embodiments, the backup cutter pockets 1722 may be at a same radial position as a corresponding cutter pocket 1720, while in other embodiments backup cutter pockets 1722 may be at different radial positions than the primary cutter pocket 1720.

In some embodiments, drill bit 1700 may include a number of conventional, cylindrical cutter pockets 1720b, which may be configured to receive conventional cylindrical cutters. For example, as illustrated, cutter pockets 1720b within the nose region of drill bit 1700 include cylindrical cutter pockets 1720b, with the non-cylindrical cutter pockets 1720a being disposed radially outward of cylindrical cutter pockets 1720b. It will be appreciated that other variations are possible and that cylindrical cutter pockets 1720b may be at other radial positions and/or may be entirely omitted in some embodiments.

In some embodiments, each blade 1710 may include one or more knuckles 1730 that protrude from a top surface of blade 1710 and are in alignment with a respective cutter pocket 1720 or 1722. Each knuckle 1730 may support a portion of a base of a cutter that is seated within the respective cutter pocket 1720 or 1722. In some embodiments, each knuckle 1730 may have a size and shape that substantially corresponds to a size and shape of a portion of the cutter that extends above the top surface of the blade 1710 on which the cutter is mounted. For example, if a portion of a rectangular cutter that protrudes above the top surface of blade 1710 is generally triangular in shape, a front surface of knuckle 1730 may have a generally triangular shape. Thus, the base of each cutter pocket 1720 or 1722 and the front face of a corresponding knuckle 1730 may collectively extend behind a full base of a cutter received within the cutter pocket 1720 or 1722 and may provide additional support to the cutter against a direction of rotation during downhole operations. In some embodiments, a cross-sectional size and shape of each knuckle 1730 may substantially match and/or be smaller than a cross-sectional area of the portion of the cutter that protrudes beyond the top surface of blade 1710. Such a design may ensure that knuckle 1730 does not engage the cutting formation and may help reduce wear to knuckle 1730. A top surface of each knuckle 1730 may taper downward toward the top surface of blade 1710 in a direction away from cutter pocket 1720 or 1722. In other embodiments, the transition from the front surface of knuckle 1730 to the top surface of blade 1710 may be stepped. A cross-sectional shape of each knuckle 1730 may remain constant throughout the transition or may vary.

While shown with only rectangular cutter pockets and cylindrical cutter pockets, it will be appreciated that any arrangement of cutter pockets of different shapes may be incorporated into a single drill bit. For example, each cutter shape may create a cutting tip having different cutting characteristics. Cutter pockets and cutters of a drill bit may be selected to create a specific cutting profile that delivers a given performance result.

FIGS. 18A-18C illustrate non-cylindrical cutter pockets with non-cylindrical cutters inserted therein and demonstrate possible cutting positions for non-cylindrical cutters. Cutter pockets 1800 may represent cutter pockets formed on a blade of a downhole tool, such as drill bits 100, 200, and 1700 and reamer 300. For example, FIG. 18A illustrates a generally rectangular cutter pocket 1800a and a generally rectangular cutter 1802a. Cutter 1802a may be similar to cutter 400 and may include four linear lateral surfaces that are arranged as two pairs of parallel surfaces and joined by four corners, with the two pairs of linear lateral surfaces being orthogonal relative to one another to form a generally rectangular shaped cross-section. Each corner of cutter 1802a may form a discrete cutting tip that may protrude above a top surface of cutter pocket 1800a and the blade within which cutter pocket 1800a is formed. In some embodiments, cutter pocket 1800a may be sized such that only two orthogonal linear surfaces and a single corner are provided. In other embodiments, two or three corners may be included, possibly with portions of one or two additional linear surfaces. Where more than 50% of a perimeter of cutter 1802a is constrained, cutter 1802a may be front loaded into pocket 1800a, which may help retain cutter 1802a within pocket 1800a during downhole operations, as the only direction cutter 1802a may be removed is in the direction of rotation of the downhole tool. In some embodiments, a knuckle 1804a may be provided behind pocket 1800a. Knuckle 1804a may have a generally triangular shape such that a base of cutter pocket 1802a and a front face of knuckle 1804a may collectively extend behind a full base of cutter 1802a to provide additional support to cutter 1802a in a direction of rotation during downhole operations. Due to the size and shape of cutter pocket 1800a and cutter 1802a, cutter 1802a may be inserted into cutter pocket 1800a in four different orientations, with each orientation aligning a different cutting tip of cutter 1802a in the cutting position. In some embodiments, each cutting tip maybe identical, while in other embodiments one or more cutting tips may include different relief features and/or chamfered edges as described herein. This may enable a single cutter 1802a to be inserted in different orientations to provide a consistent result (in the event of identical cutting tips) or tailored results (in the event of cutting tips with different characteristics) and may enable cutter 1802a to be reused even after one cutting tip has been damaged.

FIG. 18B illustrates a generally triangular cutter pocket 1800b and a generally triangular cutter 1802b. Cutter 1802b may be similar to cutter 500 and may include three linear lateral surfaces that are arranged at 120 degree angles with respect to one another and joined by three corners to form a generally rectangular shaped cross-section. Each corner of cutter 1802b may form a discrete cutting tip that may protrude above a top surface of cutter pocket 1800b and the blade within which cutter pocket 1800b is formed. Cutter pocket 1800b may be sized to include a linear bottom surface, two corners, and portions of two linear sidewalls that are at 60 degrees (in opposing directions) with respect to the linear bottom surface. and a single corner are provided. Such a design may help lock cutter 1802b into cutter pocket 1800b. For example, cutter 1802b may be front loaded into pocket 1800b, which may help retain cutter 1802b within pocket 1800b during downhole operations. In some embodiments, a knuckle 1804b may be provided behind pocket 1800b. Knuckle 1804b may have a generally triangular shape such that a base of cutter pocket 1802b and a front face of knuckle 1804b may collectively extend behind a full base of cutter 1802b to provide additional support to cutter 1802b in a direction of rotation during downhole operations. Due to the size and shape of cutter pocket 1800b and cutter 1802b, cutter 1802b may be inserted into cutter pocket 1800b in four three orientations, with each orientation aligning a different cutting tip of cutter 1802b in the cutting position. In some embodiments, each cutting tip maybe identical, while in other embodiments one or more cutting tips may include different relief features and/or chamfered edges as described herein. This may enable a single cutter 1802b to be inserted in different orientations to provide a consistent result (in the event of identical cutting tips) or tailored results (in the event of cutting tips with different characteristics) and may enable cutter 1802b to be reused even after one cutting tip has been damaged.

FIG. 18C illustrates a generally stadium-shaped cutter pocket 1800c and a generally stadium-shaped cutter 1802c. Cutter 1802c may be similar to cutter 700 and may include two parallel linear lateral surfaces that are joined by two rounded ends. Each rounded end of cutter 1802c may form a discrete cutting tip that may protrude above a top surface of cutter pocket 1800c and the blade within which cutter pocket 1800c is formed. In some embodiments, cutter pocket 1800c may be sized such that only two parallel linear side surfaces and a single arcuate bottom surface are provided. A depth of cutter pocket 1800c may be between 25% and 75% of a length of cutter 1802c in various embodiments. In some embodiments, a knuckle 1804c may be provided behind pocket 1800c. Knuckle 1804c may have a generally semi-stadium shape such that a base of cutter pocket 1802c and a front face of knuckle 1804c may collectively extend behind a full base of cutter 1802c to provide additional support to cutter 1802c in a direction of rotation during downhole operations. Due to the size and shape of cutter pocket 1800c and cutter 1802c, cutter 1802c may be inserted into cutter pocket 1800c in two different orientations, with each orientation aligning a different cutting tip of cutter 1802c in the cutting position. In some embodiments, each cutting tip maybe identical, while in other embodiments one or more cutting tips may include different relief features and/or chamfered edges as described herein. This may enable a single cutter 1802c to be inserted in different orientations to provide a consistent result (in the event of identical cutting tips) or tailored results (in the event of cutting tips with different characteristics) and may enable cutter 1802c to be reused even after one cutting tip has been damaged.

In some embodiments, a cylindrical or largely cylindrical cutter pocket may be formed within a blade of a downhole tool and later modified to be non-cylindrical. FIGS. 19-24 illustrate techniques for modifying cylindrical or largely cylindrical cutter pockets into non-cylindrical cutter pockets in accordance with the present invention. FIG. 19 illustrates a cutter pocket 1902 formed in a blade 1900 of a downhole tool, with the cutter pocket 1902 having a substantially circular cross-section. A sidewall 1904 of cutter pocket 1902 defines a keyway 1980, according to certain embodiments. Sidewall 1904 and/or a base 1906 of cutter pocket 1902 may at least partially correspond to the cross-sectional shape of a non-cylindrical cutter, such as those described herein. For example, base 1906 may extend upward beyond a top surface of the blade of a downhole tool and form a knuckle 1930, such as those described in relation to FIGS. 17 and 18. As just one example, for a rectangular cutter, base 1906 and knuckle 1930 may collectively form a generally rectangular shape. As illustrated, base 1906 and knuckle 1930 collectively form a teardrop shape, with knuckle 1930 having a generally triangular cross-section that corresponds to a portion of a rectangular cutter that protrudes above the top surface of the blade. Knuckle 1930 may provide additional support for a cutter and may also serve as a reference edge 1920 that may be used to indicate a predetermined orientation of the cutter. Prior to modification, cutter pocket 1902 may be configured to accept a cylindrical cutter with a single scribe point. Knuckle 1930 and reference edge 1920 may indicate a preferred orientation of the scribe point. Thus, knuckle 1930 and reference edge 1920 may indicate a predetermined orientation of the non-cylindrical cutter with the scribe point.

Sidewall 1904 of cutter pocket 1902 may define include a keyway 1908. Keyway 1908 may be formed into cutter pocket 1902 during manufacture of the downhole tool or may be later formed (e.g., by drilling keyway 1908 into cutter pocket 1902). Keyway 1908 may be concave, including a largely round groove, and/or may be angular. As used herein, angular may mean polygonal, triangular, other shape with linear sides, etc. Keyway 1908 may be substantially symmetrical or may be asymmetrical. Although only one keyway 1908 is shown, cutter pocket 1902 may include any number of keyways 1908.

FIG. 20 illustrates a keyed shim 2000, according to certain embodiments. Keyed shim 2000 may include a protrusion 2002, a shim body 2006 having an arcuate outer surface 2012, a support surface 2004, a first end 2008, and a second end 2010. Keyed shim 2000 may be manufactured from steel, tungsten carbide, bronze, brass, Inconel, composites, ceramics, or any other suitable material. Protrusion 2002 may be substantially cylindrical and/or include angular features, as described above. Protrusion 2002 may extend from first end 2008 to second end 2010 or may only extend some portion of the distance between first end 2008 and second end 2010. Protrusion 2002 may be configured to substantially fill the groove of a keyway, such as the keyway 1908. For example, after protrusion 2002 is in keyway 1908, there may be space such that brazing material may be provided to secure protrusion 2002 into keyway 1908. In some embodiments, the protrusion 2002 may substantially fill a width of the groove of the keyway, but not a length of the groove of the keyway.

Support surface 2004 may be configured to alter a shape of a cutter pocket (e.g., cutter pocket 1902) to accept a non-cylindrical cutter. For example, as shown in FIG. 21, support surface 2004 may be substantially planar. When inserted into cutter pocket 1902, support surface 2004 may therefore alter the shape of cutter pocket 1902 to include at least partially planar sidewall. Furthermore, support surface 2004 may also correspond to the shape of at least one lateral surface of a non-cylindrical cutter. For example, the non-cylindrical cutter may include a planar surface at least partially matching the surface 2004. When the non-cylindrical cutter is inserted into the hollow pocket, the surface 2004 may at least partially orient the non-cylindrical cutter within the hollow pocket according to a predetermined orientation.

Although support surface 2004 is shown as substantially planar, support surface 2004 may include any number of indentations and/or protrusions. Furthermore, keyed shim 2000 may have a variable thickness, such as being thicker at one end as compared to the other. For example, keyed shim 2000 may be thicker at second end 2010. Thus, support surface 2004 may be sloped between first end 2006 and second end 2010 at a first angle. Alternatively, second end 2010 may be thicker than first end 2008, causing support surface 2004 to be sloped at a different angle. Furthermore, support surface 2004 may be curved. For example, cutter pocket 1902 may include keyway 1908, but a cylindrical cutter may be inserted into cutter pocket 1902. Then, support surface 2004 may substantially correspond to a sidewall of cutter pocket 1902, such that a cylindrical cutter may be accepted, and keyway 1908 substantially filled. One of ordinary skill in the art would recognize many different possibilities and configurations.

FIG. 21 illustrates a non-keyed shim 2100, according to certain embodiments. Non-keyed shim may include a pocket surface 2102, a support surface 2104, a first end 2108, and a second end 2110. Non-keyed shim 2100 may be manufactured from steel, tungsten carbide, or any other suitable metal, ceramic, composite, or other material. Pocket surface 2102 may be configured to correspond to a sidewall of a hollow pocket, such as the cutter pocket 1902. Pocket surface 2102 may be substantially round and/or may be angular or planar. Similarly, support surface 2104 may be configured to correspond to a surface of a cutter, such as a non-cylindrical cutter. Support surface 2104 may include any number of protrusions and/or grooves, such that support surface 2104 matches the surface of the cutter. Similar to keyed shim 2000, non-keyed shim 2100 may be thicker at one end or another, creating an angle or slope between first end 2108 and second end 2110. Support surface 2104 may also be curved, as described above in relation to keyed shim 2000.

When inserted into the hollow pocket, non-keyed shim 2100 may at least partially alter the shape of cutter pocket 1902 such that cutter pocket 1902 can accept a non-cylindrical cutter. For example, a non-cylindrical cutter may be inserted into a substantially cylindrical hollow pocket. Consequentially, a space may be defined between the non-cylindrical cutter and a sidewall of the hollow pocket. Non-keyed shim 2100 may be inserted in the space, such that the space is substantially filled.

FIG. 22 illustrates the portion of the blade 1900 with keyed shim 2000 and non-keyed shim 2100, according to certain embodiments. As described above in relation to FIG. 19, the cutter pocket 1902 may have been originally manufactured to accept a cylindrical cutter. Thus, sidewall 1904 may be cylindrical. Keyed shim 2000 may be inserted into cutter pocket 1902 such that protrusion 2002 substantially fills keyway 1908. Similarly, non-keyed shim 2100 may be inserted into cutter pocket 1902. Both support surface 2004 and support surface 2104 may at least partially orient a non-cylindrical cutter within the hollow pocket 1902. For example, the non-cylindrical cutter may be a rectangular cutter. Support surface 2004, support surface 2104, knuckle 1930, and reference edge 1920 may assist in orienting (or indexing) the non-cylindrical cutter such that a corner or cutting tip of the rectangular cutter is aligned with reference edge 1920 according to a predetermined orientation.

Keyed shim 2000 and/or non-keyed shim 2100 may be attached to cutter pocket 1902 and/or a non-cylindrical pocket during a brazing process. For example, a brazing process may be started to attach the non-cylindrical cutter to cutter pocket 1902. At some point during the brazing process, one or both of keyed shim 2000 and non-keyed shim 2100 may be inserted into cutter pocket 1902, at least partially to align the non-cylindrical cutter according to a predetermined orientation. Keyed shim 2000 and non-keyed shim 2100 may then also be brazed, such that keyed shim 2000 and non-keyed shim 2100 are attached to cutter pocket 1902 and/or the non-cylindrical cutter, and the non-cylindrical cutter is attached to and/or secured within cutter pocket 1902. Although only one keyed shim 2000 and one non-keyed shim 2100 are shown in FIG. 22, any number of shims, both keyed and non-keyed, may be present (e.g., 2, 3, 4, 5, etc.). While shown with each shim including a single support surface, it will be appreciated that a single shim may include multiple distinct support surfaces, which may be at angles relative to one another. For example, a single shim may be used to provide two lateral surfaces to support corresponding lateral surfaces of a rectangular (or other non-cylindrical) cutter.

In other embodiments, keyed shim 2000 and/or non-keyed shim 2100 may be attached to cutter pocket 1902 by welding (such as tack welding), chemical bonding, or any other suitable method. Keyed shim 2000 and/or non-keyed shim 2100 may be inserted and attached to cutter pocket 1902 at some point prior to the insertion of the non-cylindrical cutter or may be attached at some point after the insertion of the non-cylindrical cutter.

FIG. 23 illustrates a spacer 2300 with non-keyed shim 2100, according to certain embodiments. Spacer 2300 may be configured to at least partially align a non-cylindrical cutter in a predetermined orientation. Spacer 2300 and/or non-keyed shim 2100 may be manufactured from steel, bronze, brass, tungsten carbide, Inconel, ceramics, composites, or any other suitable material. In some embodiments, spacer 2300 may be configured such that a hollow pocket of an earth boring tool can accept non-cylindrical cutters of various lengths. Additionally, or alternatively, spacer 2300 may also be configured to support the non-cylindrical cutter such that the non-cylindrical cutter extends beyond a hollow pocket of an earth boring tool (e.g., cutter pocket 1902 in FIG. 19).

Although the spacer 2300 is shown as substantially flat, spacer 2300 may be configured to tilt the non-cylindrical cutter within the hollow pocket. For example, a thickness of the spacer 2300 may be greater at a backside of spacer 2300 (e.g., where non-keyed shim 2100 is attached). Thus, when a non-cylindrical cutter is placed on spacer 2300 within cutter pocket 1902, the non-cylindrical cutter may be angled away from non-keyed shim 2100. Furthermore, although spacer 2300 is shown attached to non-keyed shim 2100, any number of keyed and/or non-keyed shims may be present. For example, spacer 2300 may be attached to a keyed shim, but not non-keyed shim 2100. In other examples, two non-keyed shims and a keyed shim may be present. One of ordinary skill in the art would recognize may different possibilities and configurations. In some embodiments, the spacer 2300 and the non-keyed shim 2100 may be one unitary piece.

FIG. 24 illustrates blade 1900 with spacer 2300 and two non-keyed shims 2100a-b, according to certain embodiments. Cutter pocket 1902, as illustrated in FIG. 24, may not include a keyway (as is shown in FIG. 19). As described above in relation to FIG. 19, cutter pocket 1902 may have been originally manufactured to accept a cylindrical cutter. Thus, sidewall 1904 may be cylindrical. Non-keyed shims 2100a-b may be inserted into cutter pocket 1902. Both surfaces 2104a and 2104b may at least partially orient a non-cylindrical cutter within cutter pocket 1902. For example, the non-cylindrical cutter may be a rectangular cutter that may be oriented with a corner or cutting tip facing upward in a predetermined orientation based on the positioning of surfaces 2104a and 2104b and reference edge 1920.

Furthermore, spacer 2300 may also be inserted into a predetermined orientation. Spacer 2300 may be inserted into a predetermined orientation prior to a brazing process for attaching a non-cylindrical cutter into a predetermined orientation. Spacer 2300 may be attached prior to the brazing process or may be attached during the brazing process. In some embodiments, spacer 2300 may be attached to a predetermined orientation via welding (e.g., tack welding), chemical bonding, or any other suitable method.

Non-keyed shims 2100a-b may be attached to a predetermined orientation and/or a non-cylindrical cutter during a brazing process. For example, a brazing process may be started to attach the non-cylindrical cutter to a predetermined orientation. At some point during the brazing process, one or both non-keyed shims 2100a-b may be inserted into a predetermined orientation, at least partially to align the non-cylindrical cutter according to a predetermined orientation. Non-keyed shims 2100a-b may then also be brazed, such that non-keyed shims 2100a-b are attached to a predetermined orientation and/or the non-cylindrical cutter, and the non-cylindrical cutter is attached to and/or secured within a predetermined orientation. In some embodiments, non-keyed shims 2100a-b may be attached to a predetermined orientation via welding (e.g., tack welding), chemical bonding, or any other suitable method.

While shown with rectangular, triangular, and stadium-shaped cutter pockets and cutters, it will be appreciated that other shapes of cutters and cutter pockets may be utilized in various embodiments. In some embodiments, the cutter may include a diamond table having a non-cylindrical outer periphery that is configured to be rotated about a central axis of the cutter at an angle of between 60 degrees and 300 degrees in the respective cutter pocket to expose a new cutting edge or tip of similar point loading ability while maintaining a braze gap thickness of 0.015″ or less across 85% or more of a brazeable surface area of a conventional cylindrical cutter of similar size (e.g., a cylindrical cutter having a same maximum outer diameter or other maximum lateral dimension as the non-cylindrical cutter). In other words, the new cutting tip may have less cross-sectional area than a corresponding portion of a conventional cylindrical cutter that protrudes beyond a top surface of the blade, thus enabling higher force concentration on the exposed cutting tip than with conventional cylindrical cutters. For example, a rectangular cutter may be rotated relative to the cutter pocket/blade in 90 degree increments to expose a new cutting tip (e.g., put a new cutting tip into a cutting position). Similarly, triangular cutters may be rotated relative to the cutter pocket/blade in 120 degree increments to expose a new cutting tip, stadium-shaped cutters may be rotated relative to the cutter pocket/blade in 180 degree increments to expose a new cutting tip, pentagonal cutters may be rotated relative to the cutter pocket/blade in 72 degree increments to expose a new cutting tip, and hexagonal cutters may be rotated relative to the cutter pocket/blade in 60 degree increments to expose a new cutting tip. Other variations are possible. A shape and orientation of the cutter pocket and respective cutter may be selected such that when the cutter is inserted into the cutter pocket, the cutter is oriented with a cutting tip protruding beyond a top surface of a respective one of the plurality of blades. In other words, the cutting tip protruding above the top surface of the cutter pocket/blade is in a cutting position. The position and orientation of each cutter pocket within a given blade of a downhole tool may be selected to control various parameters of the cutter. For example, the position of the cutter pocket may control the depth of cut of the cutter, as well as the amount of forward rake, back rake, and/or side rake of the cutter, which may impact the effectiveness of the downhole tool as will be described in greater detail below.

The use of non-cylindrical cutters and cutter pockets may enable a greater number of cutters to be provided on a given blade relative to the use of cylindrical cutters. For example, the non-cylindrical cutters may have more pronounced cutting tips than the constant arcs of cylindrical cutters. Additionally, the constant radius of cylindrical cutters requires a significant amount of space within the blade to form each cutter pocket. In contrast, some non-cylindrical cutter shapes may provide a sufficiently large cutting tip while requiring less space within the blade, which may enable a greater number of cutters, and subsequently cutting surface area, to be provided. As just one example, FIG. 25 illustrates a portion of a blade 2500 having a number of generally stadium-shaped cutters 2502 received in cutter pockets of blade 2500. Cutters 2502 may be similar to cutter 700 and may include any feature described in relation to cutter 700. Given the reduced lateral dimensions (e.g., width between opposing faces of the central rectangular region) of cutters 2502, less distance is needed between adjacent cutters 2502, which enables a greater number of cutters 2502 to be included on blade 2500. For example, the dotted circular lines 2504 illustrate the size of a comparable cylindrical cutter. As shown, lines 2504 of adjacent cutters overlap, which would mean that if cylindrical cutters were utilized, the cutters would need to be spaced further apart and fewer cutters would be included. By increasing the number of cutters on a blade, the size of the bit profile may be reduced while still enabling the drill bit to fail the same amount of material in a given rotation. Additionally, a rate of penetration may be increased. In some embodiments, a greater number of cutters per blade may enable the number of blades on the drill bit to be reduced, which may promote better washing by drilling fluids.

FIG. 26 is a flowchart illustrating operations of a method 2600 for bonding a cutter to a downhole tool according to some embodiments of the present invention. Method 2600 may be used to secure a non-cylindrical cutter, such as cutters 400-1600, into a corresponding non-cylindrical cutter pocket, such as cutter pockets 1720, 1722, 1600, and 1902. Method 2600 may begin at operation 2602 by inserting a cutter having a non-circular cross-section into a non-cylindrical pocket formed into a downhole tool. A small gap, such as between about 0.010 inch and 0.025 inch, may be formed between an outer face of the cutter and a wall defining the pocket. This gap may provide a volume for receiving a metal-containing substance, such as a brazing alloy, that is used to bond the cutter to the walls of the pocket. In some embodiments, prior to inserting the cutter, the pocket may be preheated, such as by using a welding torch, to get the pocket heated to a temperature sufficiently high to accept and bond to a braze material.

At operation 2604, the metal-containing substance may be provided into the gap. For example, a brazing alloy may be melted and delivered to the gap such that the brazing alloy is disposed between all or substantially all of the wall defining the pocket and the adjacent portion of the cutter, including a base of the cutter/pocket and at least a portion of one or more lateral sidewalls or other surfaces of the cutter/pocket. A flux compound may be supplied to the braze joint before, during, and/or after applying the brazing alloy. The flux compound may help prevent the formation of oxides at the braze joint and may help promote higher quality braze joints by helping the brazing alloy flow more freely within the gap between the cutter and pocket. At operation 2606, the cutter may be set within the pocket, such as by allowing the brazing alloy to cool and bond to both the cutter and pocket, thereby joining the cutter with the downhole tool.

FIG. 27 is a flowchart illustrating operations of a method 2700 for manufacturing a downhole tool according to some embodiments of the present invention. Method 2700 may be used to manufacture downhole tools (such as drill bits 100, 200, 1500, reamer 300, and/or other downhole tools) that include non-cylindrical cutters (such as cutters 400-1600). In particular, method 2700 may be used to manufacture cast matrix downhole tools. Method 2700 may begin at operation 2702 by forming a mold of a body of the downhole tool. The mold may be formed of a rigid, machinable, and heat resistant material, such as (but not limited to) graphite or other carbon-based materials. For example, a graphite log may be cut into pucks that are slightly larger than the size of the final mold. Forming the mold may include, for example, machining the mold using a computer numerical control (CNC) mill and/or other machining tool. The mold may create voids that represent features of the body of the downhole tool, including the face and a number of blades. Locating features or troughs for displacements may be machined into each blade to represent cutter locations on the final downhole tool. At least some of the locating features for the displacements may have non-cylindrical cross-sections or otherwise include one or more sidewalls that do not include a single arc of a constant radius. In some embodiments, such locating for non-cylindrical displacements may include one or more indexing features, such as ridges, grooves, visible markings, and/or other features that may enable a displacement to be properly aligned within the pocket. Additional locating features may be provided for other features of the downhole tool, such as nozzles. Different locating features may have different sizes and shapes. For example, locating features for front loaded cutter pockets may have different sizes and shapes than locating features for top loaded cutter pockets, which may be required where the primary blades meet in the middle, or in double row positions. The lack of clearance in front of the pocket requires that the cutter be loaded into the pocket from the top of the blade rather than the front. The size, shape, and orientation of each cutter locating feature may define a final shape, size, and orientation (e.g., forward rake, back rake, side rake, cutting tip rotation, etc.) of the final cutter pocket and cutter.

Once the mold has been formed, a number of displacements, including cutter pocket displacements, may be inserted into the mold, such as into the locating features at operation 2704. Each displacement may be formed from a material suitable for casting metals, such as graphite and/or resin bonded sand. Each displacement may be oriented in a respective locating feature to ensure that the final cutter pocket and cutter are properly positioned on a blade of the downhole tool. In some embodiments, this alignment may be done manually. For example, a visual indicator, such as a notch, groove, or other indexing feature may be formed in the displacement and/or locating feature that may help an installer properly insert and align the displacement within a respective locating feature. In other embodiments, the locating feature and corresponding displacement may have non-cylindrical cross-sections or other geometry that force the displacement to be properly oriented within the locating feature. In some embodiments, a ridge may be formed in the displacement or the locating feature, with a corresponding groove being formed in the other component. Insertion of the ridge into the groove may align the displacement within the locating feature. In some embodiments, a concavity may be formed in the displacement or the locating feature, with a corresponding convexity being formed in the other component. Insertion of the convexity into the concavity may align the displacement within the locating feature. In some embodiments, the locating feature and the cutter may each define a slot. A key may be inserted into both slots simultaneously to align the displacement within the locating feature. In some embodiments, a hole may be drilled through the junk slot into the hemispherical void, a hole may be drilled into/through the displacement, and a pin may be inserted through both holes to orient the displacement within the locating feature. In some embodiments, a shallow hole may be drilled into the trough of the locating feature at an angle that is not parallel to the axis of rotation of the displacement. A corresponding hole may be drilled into or through the displacement and a pin may be inserted within the holes of both the mold and the displacement to align the displacement within the locating feature. Other techniques for aligning the displacements within the locating feature are possible in various embodiments. The displacements may also include displacements for nozzles and a central bore that may be used to deliver a drilling fluid to the nozzles. The various displacements may be adhered to the locating features using an adhesive material.

Once the displacements have been secured to the mold, a steel head blank (such as a blank for later welding the shank, bit breaker surface, and connectors for connecting the drill bit to a drill string) may be positioned partially within the mold. At this point, the mold may be filled with a granular carbide material and a binder material at operation 2706. For example, the carbide material may include a tungsten carbide (or other hard metal, such as titanium carbide and/or tantalum carbide) powder. In some embodiments, the tungsten carbide powder may include between about 80%-95% tungsten, 3%-15% carbon, and may include trace elements of iron, nickel, molybdenum, titanium, tantalum, and/or niobium, however other formulations are possible in various embodiments. The binder material may be provided as a number of metallic chunks or other pieces that may be roughly on the order of 0.5 in² to 2.0 in², although other sizes are possible in various embodiments. In some embodiments, the binder material may include copper, nickel, silver, and/or alloys thereof, such as in the form of a copper-based alloy binder. For example, the binder material may include between about 40%-60% copper, 20%-30% manganese, 10%-20% nickel, and may include trace elements of zinc, iron, lead, silicon, and/or tin.

At operation 2708, the mold may be placed into a furnace that exposes the filled mold to temperatures of between about 1500° F. and 2500° F. for a period of between about 2 hours and five hours. The heat causes the binder material to melt and flow downward into the tungsten carbide powder which, upon cooling, will form a body of the downhole tool from a carbide reinforced matrix composite. For example, the melted binder material may flow into and fill voids between individual particles of the tungsten carbide powder to form a cast matrix body of the downhole tool. In some embodiments, more binder material than is needed to form the body may be placed into the mold to enable pressure infiltration to form the carbide reinforced matrix composite. For example, once melted, the excess binder material applies downward pressure that forces the liquid binder to flow in between particles of the carbide material to form a matrix. In a particular example, the tungsten carbide particles may reinforce a copper alloy matrix. The mold and body may be removed form the furnace and allowed to cool. At operation 2710, the body of the downhole tool may be removed from the mold. For example, the mold may be cut or otherwise damaged to expose the body of the downhole tool. The shank, bit breaker surface, and connectors for connecting the drill bit to a drill string may be welded into the steel head blank. The displacements may be removed from the body of the downhole tool, which may form cutter pockets on the blades of the downhole tool.

The cutter pockets may be cleaned up via one or more tools to be sized and shaped to each receive a respective cutter. At operation 2712, a cutter may be inserted into each of the cutter pockets. At least some of the cutters may have a non-circular cross-section that substantially matches a non-circular cross-section of a respective one of the cutter pockets. In some embodiments, a shape and orientation of each cutter pocket and a respective one of the cutters disposed within the cutter pocket are selected such that when the respective one of the cutters is inserted into the cutter pocket, the respective one of the cutters is oriented with a cutting tip of the respective one of the cutters protruding beyond a top surface of a respective one of the plurality of blades. The cutter pocket may define the shape, size, and orientation (e.g., forward rake, back rake, side rake, cutting tip rotation, etc.) of the cutter positioned therein. Once inserted in a pocket, each cutter may be brazed to the downhole tool, such as using a process similar to method 2600.

FIG. 28 is a flowchart illustrating operations of a method 2800 for manufacturing a downhole tool according to some embodiments of the present invention. Method 2800 may be used to manufacture downhole tools (such as drill bits 100, 200, 1500, reamer 300, and/or other downhole tools) that include non-cylindrical cutters (such as cutters 400-1600). In particular, method 2800 may be used to manufacture steel body downhole tools. Method 2800 may begin at operation 2802 by forming a body of a downhole tool. Forming the body of the downhole tool may be performed, for example, by machining the body from a steel blank using a computer numerical control (CNC) mill and/or other machining tool. The body may include a plurality of blades, with each blade defining a plurality of cutter pockets. At least some of the cutter pockets may have a non-circular cross-section as described herein. Machining such non-cylindrical pockets may be done by producing radiused corners, using a one-sided undercut, a two-sided undercut, and/or other machining techniques for generating square or otherwise non-circular voids. In some embodiments, the cutter pockets may have features parallel to the axis of the cutter with a radius less than 0.1″ or a chamfer and/or sharp corner. In other embodiments, a cylindrical pocket may be formed and a shim may later be welded into the pocket to change the cross-sectional shape of the pocket.

At operation 2804, the body of the downhole tool may be hardfaced. For example, heat may be applied to at least a portion of the body of the downhole tool the body and to a hardfacing material to fuse the hardfacing material to at least a portion of the body, such as the blades. The hardfacing material may include a carbide material and a binder that, when fused to the body, harden the body and make the body more resistant to wear. At operation 2806, a cutter may be inserted into each of the cutter pockets. At least some of the cutters may have a non-circular cross-section that substantially matches a non-circular cross-section of a respective one of the cutter pockets. In some embodiments, a shape and orientation of each cutter pocket and a respective one of the cutters disposed within the cutter pocket are selected such that when the respective one of the cutters is inserted into the cutter pocket, the respective one of the cutters is oriented with a cutting tip of the respective one of the cutters protruding beyond a top surface of a respective one of the plurality of blades. The cutter pocket may define the shape, size, and orientation (e.g., forward rake, back rake, side rake, cutting tip rotation, etc.) of the cutter positioned therein. Once inserted in a pocket, each cutter may be brazed to the downhole tool at operation 2808, such as using a process similar to method 2600.

As noted above, the use of non-cylindrical cutters that include multiple discrete cutting tips may enable the cutters to be reused. For example, oftentimes, only one cutting tip will see substantial wear during drilling or reaming operations. This may result in other cutting tips, such as those recessed within the blade, being in suitable condition to be utilized. FIG. 29 is a flowchart illustrating operations of a method 2900 for reorienting a cutter in a downhole tool according to some embodiments of the present invention. Method 2900 may be used with any of the drill bits and/or cutters describe herein, such as those with a number of discrete cutting tips and that have non-circular cross-sections that correspond with a cross-section of a cutter pocket in which the cutter is secured. Method 2900 may begin at operation 2902 by determining that a first cutting tip of a cutter on blade of a downhole tool is excessively worn. The first cutter tip may be protruding above a top surface of the blade and be in a cutting position. The determination may be made, for example, by grading the first cutting tip based on one or more predetermined criteria. For example, one or more wear scars and/or wear flats may be compared to standards set by the International Association of Drilling Contractors (IADC), an evaluation may be made as to whether any chips, cracks, or flinting extend beyond a threshold percentage of a length of the cutter, an evaluation may be made as to whether there is any cobalt leaching on the diameter of the cutter/cutting tip, whether there is any cobalt denuding proximate the cutting tip, an evaluation may be made as to whether there is graphitization, spalling, chipping, diamond pull, cracking, and/or other wear of the cutting tip, and/or other grading techniques may be utilized. If the first cutting tip is damaged/worn beyond use, method 2900 may include determining that a second cutting tip of the discrete cutting tips is in sufficient condition to be utilized in the cutting position at operation 2904. To do so, a similar evaluation of the one or more grading criteria may be performed for the second cutting tip.

If the second cutting tip passes the grading criteria, the cutter may be removed from the cutter pocket at operation 2906. For example, heat may be applied to the cutter and blade, such as using a torch, to remelt the brazing alloy used to secure the cutter within the pocket. The cutter may be pulled out of engagement from the pocket. At operation 2908 the cutter may be rotated and inserted within the cutter pocket with the second cutting tip oriented into the cutting position. The cutter may be secured within the pocket at operation 2910, such as by re-brazing the cutter into the pocket using a process similar to method 2600. A shape and orientation of the cutter pocket the cutter may be selected such that when the cutter is inserted into the cutter pocket, the cutter is oriented with one of the discrete cutting tips in the cutting position. This may eliminate the need for the installer to manually align the cutting tip in a desired orientation.

FIG. 30 illustrates operations of a method 3000 of using a downhole tool in accordance with the present invention. The downhole tool may be a drill bit, reamer, or other rotatable tool (such as drill bits 100, 200, 1500, reamer 300, and/or other downhole tools) as described herein and may include non-cylindrical cutters (such as cutters 400-1600) on a number of blades. At operation 3002, the downhole tool may be rotated to shear and/or clean out a subterranean formation and/or to advance the well bore. The downhole tool may be rotated in any number of ways. For example, the downhole tool may be coupled with a drill string that is rotated with a top drive or a table drive (not shown) or with a downhole motor that is part of a bottom hole assembly. The downhole tool may be surrounded by a sidewall of the well bore. At operation 3004, as the downhole tool is rotated within the well bore via the drill string, a drilling fluid may be pumped down the drill string through the internal passageways within the downhole tool and out through openings, nozzles or ports. Formation cuttings generated by the one or more PDC cutters of the downhole tool may be carried with the drilling fluid through the channels, around the downhole tool, and back up the well bore through an annular space within the well bore outside the drill string.

It should be noted that the methods, systems, and devices discussed above are intended merely to be examples. It must be stressed that various embodiments may omit, substitute, or add various procedures or components as appropriate. Also, features described with respect to certain embodiments may be combined in various other embodiments. Different aspects and elements of the embodiments may be combined in a similar manner. Also, it should be emphasized that technology evolves and, thus, many of the elements are examples and should not be interpreted to limit the scope of the invention. Some embodiments were described as processes depicted as flow diagrams or block diagrams. Although each may describe the operations as a sequential process, many of the operations can be performed in parallel or concurrently. In addition, the order of the operations may be rearranged. A process may have additional steps not included in the figure.

Specific details are given in the description to provide a thorough understanding of the embodiments. However, it will be understood by one of ordinary skill in the art that the embodiments may be practiced without these specific details. For example, well-known structures and techniques have been shown without unnecessary detail in order to avoid obscuring the embodiments. This description provides example embodiments only, and is not intended to limit the scope, applicability, or configuration of the invention. Rather, the preceding description of the embodiments will provide those skilled in the art with an enabling description for implementing embodiments of the invention. Various changes may be made in the function and arrangement of elements without departing from the spirit and scope of the invention.

Also, the words “comprise”, “comprising”, “contains”, “containing”, “include”, “including”, and “includes”, when used in this specification and in the following claims, are intended to specify the presence of stated features, integers, components, or steps, but they do not preclude the presence or addition of one or more other features, integers, components, steps, acts, or groups.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly or conventionally understood. As used herein, the articles “a” and “an” refer to one or to more than one (i.e., to at least one) of the grammatical object of the article. By way of example, “an element” means one element or more than one element. “About” and/or “approximately” as used herein when referring to a measurable value such as an amount, a temporal duration, and the like, encompasses variations of ±20% or ±10%, ±5%, or +0.1% from the specified value, as such variations are appropriate to in the context of the systems, devices, circuits, methods, and other implementations described herein. “Substantially” as used herein when referring to a measurable value such as an amount, a temporal duration, a physical attribute (such as frequency), and the like, also encompasses variations of ±20% or ±10%, ±5%, or +0.1% from the specified value, as such variations are appropriate to in the context of the systems, devices, circuits, methods, and other implementations described herein. As used herein in the context of shapes, the terms “generally” and “substantially” are understood to mean that a large percentage of the shape of a component (e.g., greater than 70%, greater than 80%, greater than 90%, or more) has the described shape, however some smaller percentage of the component may stray from the shape described. For example, the component may include a number of protrusions, cutouts, and/or small components that prevent the component from perfectly matching the described shape.

Where a range of values is provided, it is understood that each intervening value, to the smallest fraction of the unit of the lower limit, unless the context clearly dictates otherwise, between the upper and lower limits of that range is also specifically disclosed. Any narrower range between any stated values or unstated intervening values in a stated range and any other stated or intervening value in that stated range is encompassed. The upper and lower limits of those smaller ranges may independently be included or excluded in the range, and each range where either, neither, or both limits are included in the smaller ranges is also encompassed within the technology, subject to any specifically excluded limit in the stated range. Where the stated range includes one or both of the limits, ranges excluding either or both of those included limits are also included.

As used herein, including in the claims, “and” as used in a list of items prefaced by “at least one of” or “one or more of” indicates that any combination of the listed items may be used. For example, a list of “at least one of A, B, and C” includes any of the combinations A or B or C or AB or AC or BC and/or ABC (i.e., A and B and C). Furthermore, to the extent more than one occurrence or use of the items A, B, or C is possible, multiple uses of A, B, and/or C may form part of the contemplated combinations. For example, a list of “at least one of A, B, and C” may also include AA, AAB, AAA, BB, etc.

Claims

1. A downhole tool, comprising: a body comprising a face and an axis of rotation;a plurality of blades disposed on the face of the body, each of the plurality of blades defining a plurality of cutter pockets, wherein at least one cutter pocket of the plurality of cutter pockets comprises a non-circular cross-section; anda plurality of cutters, a portion of each cutter being disposed within a respective cutter pocket of the plurality of cutter pockets, wherein the portion of each cutter has a cross-sectional shape that matches a cross-sectional shape of the respective pocket.

2. The downhole tool of claim 1, wherein: the downhole tool comprises a drill bit.

3. The downhole tool of claim 1, wherein: the downhole tool comprises a reamer.

4. The downhole tool of claim 1, wherein: the at least one pocket has a generally rectangular cross-section.

5. The downhole tool of claim 4, wherein: the generally rectangular cross-section comprises two orthogonal linear sides and a rounded corner coupling the two orthogonal linear sides.

6. The downhole tool of claim 5, wherein: a width of each rounded corner is between 5 degrees and 45 degrees as measured from a central axis of the cutter pocket.

7. The downhole tool of claim 1, wherein: the blade comprises a plurality of knuckles; andeach of the plurality of knuckles protrudes from a top surface of one of the plurality of blades and is in alignment with a respective one of the plurality of cutter pockets and supports a portion of a base of one of the plurality of cutters seated within the respective one of the plurality of cutter pockets.

8. The downhole tool of claim 7, wherein: each of the plurality of knuckles has a shape and size that substantially corresponds to a size and shape of a portion of the one of the plurality of cutters that extends above the top surface of a respective one of the plurality of blades on which the one of the plurality of cutters is mounted.

9. The downhole tool of claim 7, wherein: a top surface of each of the plurality of knuckles tapers downward toward the top surface of a respective one of the plurality of blades in a direction away from the one of the plurality of cutters.

10. The downhole tool of claim 7, wherein: each of the plurality of knuckles is axially aligned with a respective one of the plurality of cutters.

11. The downhole tool of claim 1, wherein: the body comprises a plurality of channels, each channel being formed between adjacent blades of the plurality of blades;the body comprises a plurality of nozzles, each nozzle being disposed within one of the plurality of channels; andan outlet of each nozzle is aligned with one of the plurality of cutters that faces the respective channel.

12. The downhole tool of claim 1, wherein: at least one of the plurality of cutters comprises a diamond table having a non-cylindrical outer periphery that is configured to be rotated about a central axis of the at least one of the plurality of cutters at an angle of between 60 degrees and 300 degrees in the respective cutter pocket to expose a new cutting edge of point loading ability that is greater than a point loading ability of a conventional cylindrical cutter of similar size while maintaining a braze gap thickness of 0.015″ or less across 85% or more of a brazeable surface area of the conventional cylindrical cutter of similar size.

13. The downhole tool of claim 1, wherein: a shape and orientation of the at least one cutter pocket and a respective one of the cutters disposed within the at least one cutter pocket are selected such that when the respective one of the cutters is inserted into the at least one cutter pocket, the respective one of the cutters is oriented with a cutting tip of the respective one of the cutters protruding beyond a top surface of a respective one of the plurality of blades.

14. A cutter for a downhole tool, the cutter comprising: a substrate comprising a brazing surface, wherein at least a portion of the brazing surface comprises a first non-circular cross-section; anda diamond table further comprising: a bottom surface joined to the substrate; anda cutting face opposite the bottom surface, the cutting face comprising a second non-circular cross-section.

15. The cutter for a downhole tool of claim 14, wherein: one or both of the first non-circular cross-section and the second non-circular cross-section comprises one or more concave and/or convex regions.

16. The cutter for a downhole tool of claim 14, wherein: the cutting face is non-planar.

17. The cutter for a downhole tool of claim 14, wherein: the cutting face comprises multiple discrete cutting tips.

18. The cutter for a downhole tool of claim 14, wherein: one or both of the first non-circular cross-section and the second non-circular cross-section comprises a generally quadrilateral shape.

19. The cutter for a downhole tool of claim 14, wherein: the cutter is symmetrical about two perpendicular planes that extend through both the substrate and the diamond table.

20. The cutter for a downhole tool of claim 14, wherein: one or both of the first non-circular cross-section and the second non-circular cross-section comprises two or more linear sides that are connected via a plurality of curved corners.

21. The cutter for a downhole tool of claim 20, wherein: a ratio of a length of the linear sides to a length of the curved corners is at least 0.5:1.

22. The cutter for a downhole tool of claim 14, wherein: one or both of the first non-circular cross-section and the second non-circular cross-section comprises a generally rectangular shape.

23. The cutter for a downhole tool of claim 22, wherein: the generally rectangular shape comprises four linear sides and four rounded corners.

24. The cutter for a downhole tool of claim 14, wherein: one or both of the first non-circular cross-section and the second non-circular cross-section comprises a generally triangular shape.

25. The cutter for a downhole tool of claim 24, wherein: the generally triangular shape comprises three linear sides and three rounded corners.

26. The cutter for a downhole tool of claim 14, wherein: one or both of the first non-circular cross-section and the second non-circular cross-section comprises a stadium shape.

27. The cutter for a downhole tool of claim 14, wherein: the diamond table comprises a chamfered edge that extends from the cutting face to a lateral side of the diamond table.

28. The cutter for a downhole tool of claim 27, wherein: an angle of the chamfered edge relative to the cutting face varies along a periphery of the cutting face.

29. The cutter for a downhole tool of claim 28, wherein: the angle of the chamfered edge relative to the cutting face is greater at a cutting region of the cutting face than at a medial region of the cutting face.

30. The cutter for a downhole tool of claim 28, wherein: the angle of the chamfered edge relative to the cutting face is lower at a cutting region of the cutting face than at a medial region of the cutting face.

31. The cutter for a downhole tool of claim 27, wherein: a depth of the chamfered edge varies along a periphery of the cutting face.

32. The cutter for a downhole tool of claim 31, wherein: the depth of the chamfered edge is greater at a cutting region of the cutting face than at a medial region of the cutting face.

33. The cutter for a downhole tool of claim 31, wherein: the depth of the chamfered edge is lower at a cutting region of the cutting face than at a medial region of the cutting face.

34. The cutter for a downhole tool of claim 14, wherein: the substrate comprises a non-planar interface that protrudes from the substrate in a direction of the diamond table, the non-planar interface comprising a non-circular cross-section.

35. The cutter for a downhole tool of claim 34, wherein: a shape of an outer periphery of the non-planar interface matches a shape of an outer periphery of a topmost planar surface of the substrate.

36. The cutter for a downhole tool of claim 34, wherein: a thickness of the non-planar interface varies across a surface area of the non-planar interface.

37. The cutter for a downhole tool of claim 36, wherein: a thickness of the diamond table varies across a surface area of the diamond table; anda variation in the thickness of the non-planar interface corresponds to a variation in the thickness of the diamond table across the surface area of the diamond table.

38. The cutter for a downhole tool of claim 34, wherein: the diamond table comprises a protruding feature; anda thickness of the non-planar interface increases in a region that corresponds to the protruding feature.

39. The cutter for a downhole tool of claim 34, wherein: the diamond table comprises a recessed feature; anda thickness of the non-planar interface decreases in a region that corresponds to the recessed feature.

40. The cutter for a downhole tool of claim 34, wherein: a distance from a peripheral edge of the non-planar interface to a peripheral edge of the diamond table is consistent within 20% of a greatest distance from the peripheral edge of the non-planar interface to the peripheral edge of the diamond table across an entire periphery of the diamond table.

41. The cutter for a downhole tool of claim 34, wherein: the first non-circular cross-section and the second non-circular cross-section comprise a same shape.