Patent Publication Number: US-7717199-B2

Title: Cutting elements and bits incorporating the same

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
   This application is a continuation of U.S. application Ser. No. 10/954,122, filed on Sept. 29, 2004 and issued as U.S. Pat. No. 7,287,610 on Oct. 30, 2007. 

   BACKGROUND OF THE INVENTION 
   This invention relates to cutting elements and bits incorporating the same and more specifically to cutting elements having a non-uniform interface between their substrate and cutting layer of ultra hard material. 
   Typically, cutting elements are cylindrical in shape. They have a cemented tungsten carbide substrate having an upper surface. On the upper face is sintered an ultra hard material such as diamond or cubic boron nitride forming a polycrystalline ultra hard material cutting layer. 
   Common problems that plague cutting elements and specifically cutting elements having an ultra hard material layer bonded on a cemented carbide substrate, are chipping, spalling, partial fracturing, cracking or delamination of the ultra hard material layer. These problems result in the early failure of the cutting layer (i.e., the ultra hard material layer) and thus, in a shorter operating life for the cutting element. Typically, these problems may be the result of peak (high magnitude) stresses generated on the ultra hard material cutting layer at the region in which the ultra hard material layer makes contact with the earth formations during drilling. 
   One way to attempt to overcome these problems is to increase the thickness of the ultra hard material. Theoretically, an increase in the ultra hard material layer results in increased cutting element impact and wear resistance. However, an increase in the thickness of the ultra hard material layer may result in delamination of the ultra hard material layer from the substrate. Moreover, as the ultra hard material layer thickness increases, the edges and surfaces of the ultra hard material furthest away from the substrate (e.g., the ultra hard material layer upper surface circumferential edge) are starved for cobalt during the sintering process. Consequently, the strength and ductility of these edges are decreased. Thus, the ultra hard material edges subjected to the highest impact loads will be brittle and have lower impact and wear resistance resulting in the early failure of the cutting layer. 
   Another problem associated with increasing the thickness of the ultra hard material layer is that, as the ultra hard material volume increases, there is an increase in the residual stresses formed on the ultra hard material due to the thermal coefficient mismatch between the ultra hard material layer and the substrate. The cemented carbide substrate has a higher coefficient of thermal expansion than the ultra hard material. During sintering, both the cemented carbide body and ultra hard material layer are heated to elevated temperatures expanding and forming a bond between the ultra hard material layer and the cemented carbide substrate. The heating causes the substrate to expand more than the ultra hard material. As the ultra hard material layer and substrate cool down, the substrate shrinks more than the ultra hard material because of its higher coefficient of thermal expansion. Consequently, thermally induced compressive stresses are formed on the ultra hard material layer and tensile stresses are formed on the substrate. These stresses may reduce the operating life of a cutting element. 
   Furthermore, an increase in the volume of the ultra hard material also results in the build-up of residual stresses on the ultra hard material layer/substrate interface due to the difference in shrinkage between the ultra hard material and the substrate caused by the consolidation of the ultra hard material and the consolidation of the substrate after sintering. These residual stresses may also reduce the operating life of a cutting element. 
   Accordingly, there is a need for a cutting element having an ultra hard material table with improved impact and wear resistance, as well as improved cracking, chipping, fracturing, and exfoliating characteristics and thereby an enhanced operating life. 
   SUMMARY OF THE INVENTION 
   In one exemplary embodiment, a cutting element is provided having a substrate having an interface surface and a periphery. A plurality of generally trapezoidal spaced apart peripheral lands are defined on the interface surface, each of the plurality of lands extending to the periphery. A plurality of depressions are formed on a surface of each land. An ultra hard material layer is formed over the interface surface. In another exemplary embodiment, the plurality of depressions are generally polygonal in plan view. In a further exemplary embodiment, the plurality of depressions are generally hexagonal in plan view. In yet another exemplary embodiment, each of the peripheral lands has a side surface aligned with the periphery. The peripheral lands may be arranged around the interface surface. In a further exemplary embodiment, a central land is defined on the interface surface spaced apart from the plurality of peripheral lands, such that the peripheral lands are arranged around the central land. In an exemplary embodiment, the central land is generally hexagonal in plan view. In yet a further exemplary embodiment, the central land has depression formed on its surface. In one exemplary embodiment, a generally hexagonal depression is formed on the center of the central land. Six generally trapezoidal depressions are also formed on the central land extending from the sides of the generally hexagonal depression, such that each generally trapezoidal depression abuts two other generally trapezoidal depressions. 
   In another exemplary embodiment, a cutting element is provided having a substrate having an interface surface and a periphery. A main depression is formed on the interface surface. The main depression has a generally polygonal annular depression in plan view and a radially extending depression extending from each vertex of the generally polygonal annular depression to the periphery, such that a plurality of lands are defined by the main depression. A plurality of secondary depressions are formed on the lands and are shallower than the main depression. An ultra hard material layer is formed over the interface surface. In an exemplary embodiment, the generally polygonal annular depression is formed surrounding a center of the interface surface. 
   In another exemplary embodiment, the generally polygonal annular depression is generally hexagonal in plan view. The land defined within the generally polygonal annular depression in another exemplary embodiment has a plurality of secondary depressions. In a further exemplary embodiment, the plurality of secondary depressions formed on the land defined within the generally polygonal annular depression include a generally hexagonal central secondary depression surrounded by a plurality of generally trapezoidal secondary depressions. 
   In yet a further exemplary embodiment, a cutting element is provided having a substrate having an interface surface. A plurality of spaced apart lands are formed on the interface surface. A plurality of abutting depressions are formed on the lands. Each abutting depression has a generally hexagonal shape in plan view such that the plurality of abutting depressions define a honeycomb pattern on each land. An ultra hard material layer is formed over the interface surface. In an exemplary embodiment, each land has height, and each of the abutting depressions formed on each land has a depth that is smaller than this height. In yet another exemplary embodiment, the interface surface has a main depression defining the lands. The main depression may define at least six lands. 
   In further exemplary embodiments, bits are provided incorporating any of the aforementioned exemplary embodiment cutting elements. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is a perspective view of an exemplary embodiment cutting element of the present invention. 
       FIG. 2  is a perspective view of a substrate of an exemplary embodiment cutting element of the present invention. 
       FIG. 3  is a perspective view of a bit incorporating exemplary embodiment cutting elements of the present invention. 
       FIG. 4  is a cross-sectional view of an exemplary cutting element and bit taken along arrows  4 - 4  shown in  FIG. 3 . 
       FIG. 5  is a top view of an exemplary embodiment cutting element of the present invention with portions of the cutting element worn off. 
   

   DETAILED DESCRIPTION OF THE INVENTION 
   In an exemplary embodiment, cutting elements  10  are provided each having a substrate  12  over which is formed an ultra hard material layer  14  such as a polycrystalline diamond (“PCD”) or a polycrystalline cubic boron nitride (“PCBN”) ultra hard material layer as for example shown in  FIG. 1 . It should be noted that the term “substrate” as used herein refers to the portion or layer of the cutting element interfacing with the ultra hard material layer. For example, if a transition layer is incorporated between the ultra hard material layer and a body of the cutting element, the transition layer will be deemed a “substrate.” In addition, the body will also be deemed a substrate. It should also be noted that the Figures herein are used for illustrative purposes and are not to scale. 
   In an exemplary embodiment, the substrate is formed from tungsten carbide. In an exemplary embodiment, the substrate has an end surface  16  defining an interface surface for interfacing with the ultra hard material layer, as for example shown in  FIGS. 1 and 2 . A main depression  18  is formed on the interface surface defining a path having in plan view a generally hexagonal portion  20  and radial portions  22  extending from each vertex  23  of the hexagonal portion to the periphery  24  of the substrate. Consequently six equidistantly spaced protrusions or lands  26  are defined on the interface surface and extend to the periphery  24  of the substrate. These lands are referred to herein for convenience as the “peripheral lands.” Also defined is a central generally hexagonal protrusion or land  26  surrounded by the generally hexagonal portion of the path and referred to herein for convenience as the “central land.” 
   The peripheral lands  26  are “generally trapezoidal” in plan view. The base  28  of each peripheral land which is defined by the periphery  24  of the substrate has the curvature of the substrate. In the exemplary embodiment as shown in  FIG. 2 , in order to minimize residual stresses that tend to form on the interface surface, all the angles of the main depression are rounded. Consequently, the corners  30  of the peripheral lands opposite their base  28  are rounded. Similarly, the vertices  32  of the central land are rounded. Furthermore, in the exemplary embodiment, the edges  34  of the peripheral and central lands defined by the main depression and interfacing with the upper surfaces  36  of the lands are also curved to minimize residual stresses. It should be noted, the plan shape of the peripheral lands is referred to as “generally trapezoidal” since at least one side defining the trapezoid, i.e., the base, has a curvature and/or since at least some of the vertices of the trapezoid may be rounded, thus not defining a true trapezoid. Consequently, the phrase “generally trapezoidal” as used herein in relation to an element encompasses elements that are true trapezoids as well as trapezoidal elements that have one or more curved sides and/or one or more rounded corners. 
   It should also be noted that the terms “upper” and “lower” as are used herein to describe relative positions and not exact positions of elements. Thus, an “upper” surface may be lower than a “lower” surface. 
   In a further exemplary embodiment, depressions that are shallower than the main depression are formed on the upper surfaces of the lands. In the exemplary embodiment, shown in  FIG. 2 , these shallow depressions  38  are generally hexagonal in plan view and abut each other defining a honeycomb-like pattern  40  on the upper surfaces of the peripheral lands. In the exemplary embodiment, a shallow hexagonal depression  42  is formed at the center of the central land. Six generally trapezoidal and almost triangular shallow depressions  44  extend radially outward from each side  46  of the central shallow depression to the periphery  48  of the central land. Each generally trapezoidal shallow depression abuts two other generally trapezoidal shallow depressions, one on each side. In the exemplary embodiment, the shallow depressions formed on the central land form an axisymmetric pattern. The shallow depressions are defined as being “generally” hexagonal or “generally” trapezoidal because some of their vertices may be rounded consequently not forming true hexagons or triangles. Consequently, the phrases “generally” as used herein in relation to a polygonal element, as for example a hexagonal, triangular, or trapezoidal element encompass elements that are true polygons as well as polygonal elements that have one or more curved sides and/or one or more rounded corners. 
   In the exemplary embodiment shown in  FIG. 2 , the upper surfaces  36  of the lands, notwithstanding the shallow depressions, generally extend along a planar surface. In an alternate exemplary embodiment, the upper surfaces, notwithstanding the shallow depressions, may extend along a concave surface or a convex surface, as for example a dome shaped surface. 
   When the ultra hard material layer is formed over the interface surface, the surface of the ultra hard material layer interfacing with the interface surface of the substrate is complementary in shape to the interface of the substrate. As such, the ultra hard material layer surface interfacing with the interface surface of the substrate will include a main protrusion having a hexagonal portion and radial portions or ribs  52  complementary to the main depression hexagonal and radial portions. 
   In one exemplary embodiment, an exemplary embodiment cutting element is mounted on a bit pocket  51  of a bit  50  such as a drag bit, as for example, shown in  FIG. 3 . The cutting element is mounted on the bit such that a radially extending rib  52  of the ultra hard material layer is aligned with the edge  54  of the ultra hard material layer that would make contact with the earth formation during drilling, as for example shown in  FIG. 4 . In this regard the volume of the ultra hard material making contact with the earth formation is increased in the immediate locality of the impact, whereas the overall volume of the ultra hard material layer is not significantly increased. Consequently, the residual stresses as well as the risk of delamination and other problems, which are common with an increase in the volume of ultra hard material, are not significantly increased. 
   Moreover, as an exemplary embodiment cutting element cuts the earth formations, the cutting element ultra hard material layer and the substrate material on either side of the rib  52  wear off such that a narrowing of the cutting element is formed defining a point  56  which enables the cutter to become more aggressive in cutting, as for example shown in  FIG. 5 . This pointing or arrowing effect of the cutting element is maintained as the cutting element continues to cut and as the cutting element wears off. Consequently, the cutting efficiency of the cutting element is maintained even when the cutting element is worn. 
   As the exemplary embodiment cutting elements wear off, they can be rotated within the bit pocket such that a new radial ultra hard material projection  52  is aligned to make contact with the earth formation during drilling. 
   Applicants believe that the honeycomb pattern defined by the shallower depressions on the peripheral lands and the axisymmetric pattern of the shallower depressions formed on the central land of the exemplary embodiment cutting element better distribute, and reduce the magnitude, of the residual stresses generated during sintering of the ultra hard material. Thus, cutting elements of the present invention should have longer operating lives than conventional cutting elements. 
   The substrates of the exemplary embodiment cutting elements may be formed using well-known methods. For example, tungsten carbide particles may be mixed with a cobalt binder, wax and solvent and placed in a mold for forming a substrate having the desired geometry. In the exemplary embodiment, a mold may be used that will produce the desired pattern on the interface of the substrate. The mold with mixture of material are heated and held to a predetermined temperature to “dewax” the mixture. The temperature is then further raised and held to another predetermined value causing the cobalt binder to cement the tungsten carbide particles together forming the substrate. 
   In another exemplary embodiment, the substrate may be formed to have a cylindrical shape. The interface pattern may then be machined on the interface using well-known methods such as electro-discharge machining (“EDM”) and grinding. Other known methods for forming the substrate may also be used. 
   To form the cutting element of the present invention, the substrate with the desired geometry interface is placed in a can made from a material such as niobium. Ultra hard material powder such as diamond or cubic boron nitride and a binder are then placed over the substrate interface surface in the can. The can is covered and subjected to high pressure and high temperature whereby the ultra hard material becomes polycrystalline and bonds to the substrate. 
   Although specific exemplary embodiments are disclosed herein, it is expected that persons skilled in the art can and will design alternative cutting elements and methods to produce the cutting elements that are within the scope of the following claims either literally or under the Doctrine of Equivalents.