COATING SYSTEM FOR TUBULAR GRIPPING COMPONENTS

BACKGROUND

In oilfield exploration and production operations, various oilfield tubular members are used to perform important tasks, including, but not limited to, drilling the wellbore and casing a drilled wellbore. For example, a long assembly of drill pipes, known in the industry as a drill string, may be used to rotate a drill bit at a distal end to create the wellbore. Furthermore, after a wellbore has been created, a casing string may be disposed downhole into the wellbore and cemented in place to stabilize, reinforce, or isolate (among other functions) portions of the wellbore. As such, strings of drill pipe and casing and/or completion tubulars may be connected together, such as end-to-end by welding or by threaded connections, in which a male “pin” member of a first tubular member is configured to threadably engage a corresponding female “box” member of a second tubular member. Alternatively, a casing string may be made-up of a series of male-male ended casing joints coupled together by female-female couplers. The process by which the threaded connections are assembled is called “making-up” a threaded connection, and the process by which the connections are disassembled is referred to “breaking-out” the threaded connection. As would be understood by one having ordinary skill, individual pieces (or “joints”) of oilfield tubular members may come in a variety of weights, diameters, configurations, and lengths.

Referring to FIG. 1, a perspective view is shown of an example of a drilling rig 101 used to run one or more tubular members 111 (e.g., casing, drill pipe, completion tubulars etc.) downhole into a wellbore. As shown, the drilling rig 101 includes a frame structure known as a “derrick” 102, from which a traveling block 103 (which may include a top drive) suspends a lifting apparatus 105 (e.g., an elevator or a tubular (e.g., casing) running tool connected to the quill of a top drive) and a gripping apparatus 107 (e.g., slip assembly or “spider”) at the rig floor may be used to manipulate (e.g., raise, lower, rotate, hold, etc.) a tubular member 111. The traveling block 103 is a device that is suspended from at or near the top of the derrick 102, in which the traveling block 103 may move up-and-down (i.e., vertically as depicted) to raise and/or lower the tubular member 111. The traveling block 103 may be a simple “pulley-style” block and may have a hook from which objects below (e.g., lifting apparatus 105 and/or top drive) may be suspended. Drilling rig 101 can be a land or offshore rig (e.g., drill ship).

Additionally, the lifting apparatus 105 may be coupled below the traveling block 103 (and/or a top drive if present) to selectively grab or release a tubular member 111 as the tubular member 111 is to be raised and/or lowered within and from the derrick 102. As such, the top drive may include one or more guiding rails and/or a track disposed adjacent to the top drive, in which the guiding rails or track may be used to support and guide the top drive as the top drive is raised and/or lowered within the derrick.

Typically, a lifting apparatus 105 includes movable gripping members (e.g., slip assemblies) attached thereto and movable between a retracted (e.g., disengaged) position and an engaged position. In the engaged position, the lifting apparatus 105 supports the tubular member 111 such that the tubular member 111 may be lifted and/or lowered, and rotated if so equipped. In the retracted position, the lifting apparatus 105 may release the tubular member 111 and move away therefrom to allow the tubular member 111 to be engaged with or removed from the lifting apparatus 105 and/or the gripping apparatus 107. For example, the lifting apparatus 105 may release the tubular member 111 after the tubular member 111 is threadably connected to a tubular string 115 supported by the gripping apparatus 107 (e.g., slip assembly or “spider”) at the rig floor at the floor of the drilling rig 101.

Further, in an embodiment in which the drilling rig 101 includes a top drive and a tubular running tool, the tubular member 111 may be supported and gripped by the tubular running tool connected to the quill of the top drive. For example, the tubular running tool may include one or more gripping members that may move radially inward and/or radially outward or have a radial displacement component. In such embodiments, the gripping members or radial displacement components of a tubular running tool may move radially outward to grip an internal surface of the tubular member 111, such as with an internal gripping device, and/or the gripping members or radial displacement components of the tubular running tool may move radially inward to grip an external surface of the tubular member 111, such as with an external gripping device, however so equipped.

As such, the gripping apparatus 107 of the drilling rig 101 may be used to support and suspend the tubular string 115, e.g., by gripping, from the drilling rig 101, e.g., supported by the rig floor 109 or by a rotary table thereof. The gripping apparatus 107 may be disposed within the rig floor 109, such as flush with the rig floor 109, or may extend above the rig floor 109, as shown. As such, the gripping apparatus 107 may be used to suspend the tubular string 115, e.g., while one or more tubular members 111 are connected or disconnected from the tubular string 115.

FIGS. 2A and 2B show an example of a gripping device 201 that includes a bowl 203 with a plurality of slip assemblies 205 movably disposed therein. Specifically, the slip assemblies 205 may be connected to a ring 207, in which the ring 207 may be connected to the bowl 203 through an actuator (e.g., actuator rods) 209. Actuator may be actuated, such as electrically actuated and/or fluidly (e.g., hydraulically) actuated, to move up and/or down with respect to the bowl 203, in which the slip assemblies 205 connected to the ring 207 may correspondingly move up and/or down with respect to the bowl 203.

The illustrated slip assemblies 205 are designed to engage and contact the inner tapered surface of the bowl 203 when moving with respect to the bowl 203. Bowl 203 is shown as a continuous surface but may comprise non-continuous surfaces (e.g., a surface adjacent to the rear of each slip assembly 205). Thus, as the slip assemblies 205 move up or down with respect to the bowl 203, the slip assemblies 205 may travel down along an inner surface of the bowl 203. With this movement, an inner surface (e.g., die or insert) of the slip assemblies 205 will grip a tubular member 211 disposed within the gripping device 201. The slip assemblies 205 may have a gripping surface (e.g., teeth) on the inner surface to facilitate the gripping of the tubular member 211. After the tubular member 211 is supported by the gripping device 201, additional tubular members may be connected or disconnected from the tubular member 211.

As shown with respect to FIGS. 2A and 2B, the gripping device 201 may be used to grip tubular members 211 having multiple outer diameters. For example, as shown in FIG. 2A, the slip assemblies 205 may be positioned within the bowl 203 of the gripping device 201 to grip a tubular member 211A having a first diameter D1. As discussed, the slip assemblies 205 may be positioned using the ring 207 that may be vertically moveable, e.g., through the actuator rods 209. FIG. 2B shows gripping device 201, in which the slip assemblies 205 are positioned vertically higher within the bowl 203 with respect to the positioning of the slip assemblies 205 shown in FIG. 2A. As such, this positioning of the slip assemblies 205 in FIG. 2B enables the gripping device 201 to grip another tubular member 211B, in which the tubular member 211B has a second outer diameter D2 larger than the first outer diameter D1 of the tubular member 211A (for example, where D1 and D2 are on a tubular body itself and not a connector portion thereof). Thus, gripping device 201 may grip tubular members 211 having a large range of outer diameters without the need of reconfiguration and/or adding supplemental equipment to the gripping device 201. However, in some gripping devices, various sizes of inserts and/or slip assemblies may be interchanged.

From time-to-time, drillstring, casing, completion tubing, etc. must be raised or “tripped” out of the hole, such as when changing the drill bit at the end of the string. As the drillstring, casing, or completion tubing is brought out of the hole, the various tubular members are removed from the string and set aside in or around the drilling rig. However, when doing this, the tubular members may have drilling fluids and/or debris deposited thereon, such as oil or water-based mud and cuttings from the drilled underground formations.

Further, generally a pipe string may be disposed and suspended within a borehole from a drilling rig using a pipe handling apparatus, such as a spider, in which the pipe string may be lengthened step-wise by threadably joining or welding a tubular segment to the proximal end of the pipe string at the rig. The pipe string may be suspended within the drilling rig using a second type of pipe handling apparatus, such as an elevator, that is movably supported from a draw works and a derrick above the spider. As the load of the pipe string is transferred between the spider and the elevator, the spider may be unloaded and then disengaged from the pipe string by retraction of the slips within the spider. The lengthened pipe string may then be lowered further into the borehole using the draw works controlling the elevator. The spider may then again engage and support the pipe string within the borehole and an additional tubular segment may be joined to the new proximal end of the pipe string to further lengthen the pipe string.

SUMMARY

Embodiments of the disclosure include a gripping tool for gripping oilfield tubulars that includes a gripping element having a substrate, and at least one gripping surface configured to engage an oilfield tubular, the at least one gripping surface being formed on the gripping element. The at least one gripping surface includes a coating on an outer surface of the substrate, the coating includes a carrier and a plurality of particles at least partially embedded in the carrier. The particles each have a hardness that is greater than a hardness of the carrier and a base metal of the gripping element, and the particles extend outward from the carrier and are configured to engage a structure that is gripped by the gripping tool.

Embodiments of the disclosure further include a method for manufacturing a gripping tool. The method includes forming a gripping surface on at least a portion of a substrate without creating a heat-affected zone in the substrate by applying a coating comprising a carrier and a plurality of particles onto the substrate. The plurality of particles have a hardness that is greater than a hardness of a base metal of the substrate and greater than a hardness of the carrier. The plurality of particles extend at least partially outward from the carrier and are configured to at least partially embed into a material that is at least as hard as the base metal of the substrate.

Embodiments of the method also include a method for manufacturing a gripping tool. The method includes, using electroless deposition, forming a coating on a gripping surface comprising at least a portion of the outer surface of the substrate, without creating a heat-affected zone in the substrate. The coating includes a carrier comprising nickel-phosphorous and having a thickness of between about 14 μm and about 20 μm, and a plurality of particles at least partially embedded in the carrier and having an average particle size of about 10 μm to about 60 μm, and having a surface density on the gripping surface ranging from about 10% to about 50%. The plurality of particles are configured to at least partially embed into a material that is at least as hard as a base metal of the substrate such that the gripping tool grips the material.

Other aspects and advantages of the invention will be apparent from the following description and the appended claims.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a schematic view of a drilling rig.

FIGS. 2A and 2B show perspective views of a gripping apparatus.

FIGS. 3A and 3B show a perspective view and a cross-sectional view, respectively, of a gripping tool according to embodiments of the present disclosure.

FIG. 4 shows a picture of a gripping surface under 25× magnification according to embodiments of the present disclosure.

FIG. 5 shows a cross sectional view of a pipe handling system including a collar-support-type elevator and a slip-type gripping tool at the rig floor elevation according to embodiments of the present disclosure.

FIG. 6 shows a cross sectional view of a pipe handling system including a slip-type elevator and a slip-type gripping tool at the rig floor elevation according to embodiments of the present disclosure.

FIG. 7 illustrates a conceptual, cross-sectional view of a gripping tool, according to embodiments of the present disclosure.

FIG. 8 illustrates a conceptual, cross-sectional view of a gripping tool, according to embodiments of the present disclosure.

FIG. 9 illustrates a flowchart of a method for manufacturing a gripping tool, according to embodiments of the present disclosure.

FIG. 10A illustrates a perspective view of a gripping tool, according to embodiments of the present disclosure.

FIG. 10B illustrates a perspective view of another gripping tool, according to embodiments of the present disclosure.

DETAILED DESCRIPTION

Embodiments of the present disclosure relate generally to surface processing methods. Surface processing methods of the present disclosure may be used, for example, on tongs, dies, backups, removable inserts and dies as well as slips or jaws with teeth, dies or slips integrally formed to a gripping tool, inserts, slip assemblies or dies used with spiders or elevators, gripping tools that can grip from the inner diameter of a tubular member, gripping tools that can grip from the outer diameter of a tubular member, or other tools that may be used to grip corrosion resistant alloy (“CRA”) tubulars. Further, surface processing methods of the present disclosure may be used on gripping elements that grip using transverse or rotational loading, longitudinal loading, or any other type or combination of directional loading. Other embodiments of the present disclosure relate to gripping tools formed of non-ferrous materials that do not need surface processing.

CRA tubulars may be formed of stainless steels or other materials having high alloy contents of elements, such as chromium and nickel, to prevent corrosion. Such materials, for example, 13-chrome stainless steels, may have a hard outer layer, which conventional gripping tools have difficulty penetrating, and thus, may lead to slippage and damage to the tubular. For example, CRA tubulars may have an outer layer hardness ranging from about 55 to 65 HRC, or 50 to 75 HRC equivalent (e.g., 600 HV-830 HV or 510 HV-1500 HV). Conventional gripping tools, however, such as case carburized gripping tools, have an outer gripping surface that is softer than CRA tubular outer layers. For example, an outer gripping surface of a conventional case carburized gripping tool may have a hardness no greater than about 62 HRC equivalent (e.g., 750 HV), which decreases along the depth of the gripping surface to the core hardness of the substrate. Thus, although conventional case carburized gripping tools may initially penetrate CRA tubular outer layers, they quickly blunt and wear down to such an extent that repetitive gripping is inhibited. Further, the conventional gripping tools may be formed of a ferrous material, such as carburizing steel, which may transfer to the CRA tubular being gripped and may eventually lead to corrosion. By providing inserts, dies, or other gripping tools with a surface processing system of the present disclosure, the gripping tool may be provided with strength sufficient to penetrate the outer surface of a tubular and properly grip the tubular with reduced slippage while also reducing or preventing the transfer of ferrous or deleterious material and maintaining sufficient ductility to resist fracture. Further, treatments disclosed herein may provide the gripping surface with sufficient hardness to penetrate oxide layers on 13-Cr alloys, reduce friction, thereby reducing potential for slip crush and facilitating penetration, and also provide improved wear resistance.

Surface processing methods described below may be used to treat the outer surface of a gripping tool to tie up residual free iron at the outer surface, thereby reducing or preventing its transfer to the CRA material. However, some embodiments disclosed herein having a gripping surface formed of non-ferrous material that may or may not be surface processed. Material treatments disclosed herein may be applied to both ferrous and non-ferrous alloys, and non-ferrous alloys can be used with or without material treatment, as disclosed herein, depending on the application of the non-ferrous alloy. The use of non-ferrous alloys may reduce or eliminate iron transfer potential and may require a treatment to prevent wear depending on the alloy chosen.

Referring now to FIGS. 3A and 3B, a perspective view and cross-sectional view, respectively, of a gripping tool 300 according to embodiments of the present disclosure are shown. The gripping tool 300 may be used within tubular handling and/or gripping equipment, such as a slip assembly or die used with a spider or an elevator, or other tool used to grip corrosion resistant alloy (“CRA”) tubulars. The gripping tool 300 has a body 310 and a gripping surface 320, in which the gripping surface 320 includes a plurality of teeth 330 extending from the body 310. According to embodiments of the present disclosure, the gripping surface 320 may be subjected to either a first surface coating or a first diffusion layer and may be followed by at least one additional coating or diffusion layer. For example, in some embodiments, teeth of a gripping surface may be carburized to form a carburized layer extending from the teeth outer surface to the body. An additional diffusion layer, e.g., a boronized layer or a nitridized layer, may then be formed on the carburized layer, or a coating may be applied to the carburized layer. According to embodiments of the present disclosure, a first inner layer may provide structural support to a second outer layer, and the second outer layer may provide enhanced gripping ability and wear resistance and act as a buffer from transfer of ferrous or other deleterious material.

As shown in FIG. 3B, each of the teeth 330 has side surfaces 332 transitioning to an apex 334, in which the apex 334 has a curvature sufficient to penetrate and grip a CRA material. The cross sectional shape of an apex may include, for example, triangular or parabolic shapes. Further, the teeth 330 may be uniformly or non-uniformly positioned along the gripping surface 320, as measured between points at the same position on the apexes 334 of adjacent teeth 330. For example, in some embodiments, teeth 330 may be spaced uniformly along a gripping surface 320 such that the distance 336 between the apexes of adjacent teeth 330 range from about 0.05 to about 0.8 inches apart. In some embodiments, the distance 336 between uniformly spaced teeth 330 may range from about 0.06 to about 0.20 inches apart. According to some embodiments of the present disclosure, teeth may be micro-sized, for example, ranging less than 0.06 inches apart. However, in other embodiments, larger sized teeth may be used, for example, teeth having a pitch ranging from 0.06 to 0.2 inches, or teeth having a pitch greater than 0.2 inches. In some embodiments, teeth may be uniformly spaced along a gripping surface, where the teeth have a pitch ranging from 0.08 inches to 0.2 inches and a height ranging from 0.03 inches to 0.1 inches. For example, a gripping surface may have uniformly spaced teeth with a pitch ranging from 0.09 to 0.12 and a height ranging from 0.035 to 0.04 inches, or a pitch ranging from 0.17 to 0.19 inches and a height ranging from 0.06 to 0.09 inches. Advantageously, gripping surface treatments disclosed herein may provide enhanced gripping performance for teeth sizes disclosed above, as well as other size and shape combinations. Uniformly spaced teeth on a gripping surface may allow for easier cleaning and manufacturing of the gripping surface, while still maintaining effective grip. Further, fine-point teeth (teeth having a pointed tip, either angular or tight radius of curvature) along a gripping surface may facilitate penetration into a surface to be gripped by virtue of the high contact pressure generated at the tips of the teeth.

Each tooth 330 may also have a uniform or non-uniform profile. For example, as shown in FIG. 3B, each tooth 330 may have a uniform profile, in which the angle of separation 338 formed between side surfaces of adjacent teeth may be equal among all adjacent teeth along the gripping surface 320. An angle of separation 338 formed between the side surfaces 332 of adjacent teeth 330 may range, for example, from about 30 degrees to about 100 degrees, depending on the size and amount of teeth formed on the gripping surface 320. For example, a gripping surface 320 having a relatively high amount of teeth 330 formed thereon may have smaller angles of separation 338 than a gripping surface of the same length with a relatively smaller amount of teeth formed thereon. By forming one or more layers on a gripping surface having uniform angles of separation between the teeth of the gripping surface, loads from gripping may be more uniformly distributed along the gripping surface.

As used herein, a “surface processing” method refers to a method of coating or chemically altering a surface. As used herein, “coating” a surface refers to attachment of at least one material to the surface (e.g., applying a coating to the surface), and “chemically altering” a surface refers to chemical treatment of the surface. Thus, although coatings may be chemically attached to a surface (e.g., via metallurgical bonding), “coating” a surface is distinct from chemically altering a surface. Various different ways of coating a gripping surface and/or chemically altering the gripping surface are disclosed herein and may be used individually or in any combination, as will be described below.

For example, in some embodiments, a surface processing method may include chemically altering a surface by diffusing a chemical (a chemical element and/or chemical composition) a depth into a material. As described more below, diffusing a chemical into the material may result in the formation of a diffusion layer extending the depth into the material, in which the formed layer has a distinct microstructure from the original surface material. Using one or more diffusion processes to treat the outer surface of a gripping tool may avoid adhesion problems that can be experienced with other methods of treating a surface, such as grit-facing or brazing an outer layer to the gripping tool. Further, in chemical diffusion treatments, the chemical diffuses into an outer surface of the material a depth into the material to form the diffusion layer. Thus, upon formation of the diffusion layer, the outer surface of the pre-diffused material becomes the outer surface of the diffusion layer, i.e., the outer surface remains the same surface but with a different material composition. Accordingly, the term “outer surface” is used herein to refer to the outermost surface of a region being described in its current processing state. For example, an outer surface of a pre-treated material may be referred to as an outer surface of a carburized layer once the material has been carburized and may be referred to as an outer surface of a boronized layer once the carburized layer has been boronized.

In contrast, the outer surface of a material does not become the outer surface of layers that are coated on or attached to the material. For example, in some embodiments, a surface processing method may include altering a surface by applying one or more coatings over the outer surface of a material body, in which the outermost surface of the coating forms a new outer surface of the material body. According to some embodiments of the present disclosure, a first coating may be applied to a base material, and a second coating may be applied to the first coating, in which the first coating may act as a support and transition region for the outer second coating. In some embodiments, a single coating may be applied to a base material. Further, in some embodiments, one or more coatings may be applied to a diffusion layer.

Diffusion Surface Processing

According to embodiments of the present disclosure, a base material, such as the gripping surface of a gripping tool, may be diffused with a diffusion material to alter the composition of the surface, which may be referred to herein as diffusion processing. As described more below, diffusion materials may include, for example, carbon, boron, nitrogen, aluminum, silicon, chromium, titanium or combinations thereof. Diffusion processing is a type of surface processing that may include providing the gripping surface in an environment with a diffusion material source and under conditions sufficient for the diffusion material to diffuse a depth into the gripping surface, thereby forming a diffusion layer. For example, some diffusion processes may include providing the gripping surface in an environment with a diffusion material and heating the gripping surface at a temperature and a time to diffuse the diffusion material a depth into the gripping surface to form a diffusion layer. Some diffusion processes may also include quenching or cooling the gripping surface. One or more diffusion processes may be used to surface process a gripping element. Further, one or more additional processing methods disclosed herein, e.g., other surface processing methods such as coating, may be used in combination with diffusion processing.

Various diffusion processes are described below in more detail, including, for example, carburizing, boronizing, and nitridizing. However, diffusion materials other than or in addition to carbon, boron and nitrogen may be used to form one or more diffusion layers in a gripping tool of the present disclosure using diffusion processes similar to those described with respect to carburizing, boronizing and nitridizing below. Generally, an outer surface of a gripping element may be subjected to an environment containing a diffusion material source sufficient for the diffusion material to diffuse a depth into the gripping element. One or more subsequent diffusion processes may be conducted on a gripping element to form multiple diffusion layers. For example, according to embodiments of the present disclosure, a gripping tool may include a gripping element with a plurality of teeth extending from the gripping element and a diffusion layer extending a depth from an outer surface of the gripping element to a base material of the gripping element. The diffusion layer may include, for example, a carburized layer, nitrided layer, a nitrocarburizing layer, a boronitrided layer, an aluminized layer, a nitroaluminized layer, a siliconized layer, a borochromatized layer, or a borochromtitanized layer, or a boronized layer. One or more subsequent diffusion layers may then be formed on the first diffusion layer. In embodiments having more than one diffusion layer formed thereon, the diffusion processes may be controlled to have each subsequent diffusion layer extend a depth less than the previously formed diffusion layer, such that the last diffusion layer formed extends a depth from the outer surface of the gripping element and the first diffusion layer formed is adjacent to the base material.

For example, according to embodiments of the present disclosure, a base material, such as the gripping surface of a gripping tool, may be carburized to form a carburized layer. In one or more embodiments, treatments that are part of the base material or base metal (e.g., carburization) may be more resilient than coatings/platings and may be more difficult to remove than coatings/platings. The carburized layer may act as a support and/or transition layer for one or more outer layers or the carburized layer may form the outer layer. For example, in some embodiments, a carburized layer may act as a support and/or transition layer for an outer layer having a hardness greater than the carburized layer. As described more below, an outer layer formed on a carburized layer may include using a chemical surface processing method, such as forming a diffusional layer on the carburized layer, or may include using other surface processing methods, such as applying a coating to the carburized layer.

Materials that may be carburized include relatively low carbon content materials, such as steel having a carbon content ranging from about 0.08 percent by weight to about 0.35 percent by weight. Carburizing materials with low carbon content may include, for example, plain carbon steel, mild steel, resulfurized steel, low carbon steel, medium carbon steel, low alloy steel, chromium alloy steel, chromium-molybdenum alloy steel, chromium-nickel-molybdenum alloy steel, other steels having corrosion resistant additives added thereto, nickel chromium alloys, nickel molybdenum alloys and special alloys. As used herein, “carburizing steel” refers to steel having carbon content low enough to have carbon diffused therein during a carburization process. Further, carburizing steel may include steel phases of pearlite, ferrite, cementite, and/or austenite phases, carbide, boride, bainite, and martensite. One skilled in the art may appreciate that depending on the particular composition of carburizing steel and processing conditions, such as heating and cooling rates, various phases of steel may be present, as referenced, for example, in steel phase diagrams known in the art.

According to embodiments of the present disclosure, carburizing steel may be subjected to a carburization process. Various carburizing processes are known in the art, which include heating a relatively low carbon-containing base material in a carbon rich environment for a sufficient time to allow carbon to diffuse into the base material. For example, during a carburization process, a carburizing steel may be heated in a carbon rich atmosphere such that carbon diffuses into the carburizing steel. In some embodiments, the carburizing environment may have a vacuum applied thereto (referred to as vacuum carburizing). As carbon diffuses into the carburizing steel, various alloy carbides, such as those in the form of MC, M3C, M23C, etc., may result. The depth of a carburized layer may range, for example, from about 0.01 inches to about 0.2 inches. In some embodiments, a carburized layer may have a depth ranging from about 0.03 inches to about 0.125 inches. The depth of carburization may depend on, for example, the initial amount of carbon content in the gripping surface (i.e., the carbon content of the gripping surface before the carburizing process), the composition of the gripping surface (including, for example, amount and type of metal additives), the geometry of the gripping surface, and the processing conditions, such as the duration, temperature, pressure, and heating and cooling rates.

Upon completing a carburization process (i.e., increasing the amount of carbon in a base material by diffusing carbon therein to form a carburized layer), the carburized layer may subsequently be quench hardened. For example, upon carburizing steel, the carburized steel may be quenched to a temperature sufficient to initiate transformation of at least part of the carburized steel into martensite. In such embodiments, a carburized layer of relatively high carbon content martensitic steel results from quenching the carburized steel and extends substantially the depth of carbon diffusion from the carburization process, depending on, for example, temperature and cooling rate parameters. For example, an outer layer of steel or other iron alloy may be heated to form austenite and may have carbon diffused into the surface, where upon quenching the outer layer, a hardened outer layer of plate and/or lath martensite extending a depth into the base material may be formed. Quenching may include cooling the carburized steel at a constant rate. Further, quenching may include cooling the carburized steel in a gas, e.g., nitrogen, helium, and hydrogen, or liquid, e.g., oil or salt bath. Optionally, furnace cooling may be performed prior to quenching.

A carburized layer may have various features that are distinct from a base material that has not undergone carburization. For example, a carburized layer is formed by diffusing carbon into a relatively low carbon content material, and thus may have a diffusion-type carbon gradient through the thickness of the layer. The diffusion-type carbon gradient may have relatively higher carbon content at the outer surface of the layer and a decreasing carbon content moving toward the interior of the layer to the interface between the carburized layer and the base material. Because the diffusion-type gradient may gradually transition to the base material, the interface between the carburized layer and base material may be approximately determined by measuring the hardness at various radial positions along the carburized layer and base material. Further, because diffusion includes treating a base material rather than bonding a separate material to the base material, a diffusion layer may be less likely to delaminate or crack off. A carburized layer may have a carbon content ranging from about 0.5 percent by weight to about 1.25 percent by weight, depending on the composition of the base material and the carburization parameters used. Further, a carburized layer may have a hardness greater than the base material, which may gradually decrease corresponding to a diffusion-type gradient formed through the thickness of the layer. For example, a carburized layer may have a hardness ranging from about 50 HRC to about 65 HRC (e.g., 510 HV-830 HV), while the base material may have a hardness ranging from about 20 HRC to about 45 HRC (e.g., 240 HV-450 HV).

A carburized layer may also have improved corrosion resistance compared with the base material. For example, in some embodiments, a carburized layer may be free from carbide precipitates, which may allow a sufficient amount of free chromium or other corrosion resistant additives such as molybdenum, and niobium for corrosion protection. In other embodiments, corrosion resistant additives may form carbides in the carburized layer. Whether a carburized layer includes carbides or free carbon depends on, for example, carburization processing time and temperature and base material composition.

According to one or more embodiments, the outer surface of a gripping element may be carburized to form a carburized outer layer. In other embodiments, a carburized layer formed in a gripping element may be surface processed with one or more additional methods disclosed herein, such as by one or more subsequent diffusion processes and/or by one or more coating processes.

According to embodiments of the present disclosure, the outer surface of a gripping element may be boronized, or diffused with a boronizing variant, such as a boron chromium compound, boron aluminum compound, boron titanium compound, or boron nitrogen compound, or any combination thereof. The boronizing process may include heating the surface material in the presence of a boron source such that boron diffuses into the surface material. Boron sources may include, for example, a pack or paste, salt, gas, etc. Further, boron sources may include variants of boron, including, for example, boron chromium and boron nitride, wherein the boron variants are diffused a depth into the outer surface of the gripping element during the diffusion process. Depending on the process being used, boronizing temperatures may range, for example, between approximately 1300° F. and 1830° F. As the boron diffuses into the surface material, boron may react with the surface material to form borides of the surface material, such as iron and alloying elements in a steel surface material. For example, in some embodiments, carburized steel may be boronized, and as boron diffuses into the carburized steel, FeB and/or Fe2B is formed from reaction between iron in the steel and boron. However, in some embodiments, a boronized layer, or a boronizing variant diffusion layer may be formed directly on a gripping element base material.

In embodiments having a boronized layer formed on a carburized layer, the boronizing process is performed on the carburized layer prior to quenching. In other embodiments, a boronized layer may be formed on a surface material that has not been carburized. The thickness of the boronized layer, or boronizing variant diffusion layer, depends on, for example, the temperature, treatment time, the boron potential used in the boronizing process, and diffusion gradient between the boron source and surface (alloying content). Referring now to FIG. 4, a picture of a gripping surface 400 having a carburized layer 430 and/or a boronized layer 420 formed thereon under 25× magnification is shown. As shown, the gripping surface 400 is formed on a gripping tool body 405, in which the gripping surface 400 includes a plurality of teeth 410 extending from the body 405. The boronized layer 420 extends a depth 425 from an outer surface 402 of the gripping surface 400. The depth 425 may be less than about 0.001 inches. However, in some embodiments, a boronized layer may have a depth greater than about 0.001 inches, for example, ranging between about 0.003 inches and about 0.010 inches. The carburized layer 430 extends a depth 435 from the boronized layer 420 to the body 405. The carburized layer 430 has a carbon content that is greater than the body 405.

Further, as shown, the carburized layer 430 may transition to the body 405 at an interface 440, in which the thickness of the carburized layer 430 is measured from the outer surface 402 to the interface 440. As described above, the interface 440 may be generally determined by measuring the position at which the material hardness substantially equals the hardness of the base material of the body. The interface 440 of the embodiment shown in FIG. 4 may be non-planar, such as to approximately correspond with the non-planar outer surface 402 of the teeth 410. Particularly, as shown, the interface 440 has apexes substantially corresponding with the apexes of the teeth 410, in which the radius of curvature of the interface apexes are larger than the radius of curvature of the teeth apexes. As described above, such an interface may be formed from a carburization process by the diffusion of carbon through an outer surface to a thickness into the body or other diffusion process. As used herein, the term “thickness” may refer to a dimension extending from an outer surface of a material towards the interior of the material. For example, the thickness of the gripping surface 400 shown in FIG. 4 may be measured from the outer surface 402 to the interface 440. When carburizing gripping surfaces having teeth formed thereon, carbon may diffuse through the outer surface of the teeth. As carbon diffuses through the outer surface of the teeth, the diffusion paths from opposite sides of each tooth may overlap, thus creating a non-planar interface having apexes with a relatively larger radius of curvature than each corresponding tooth. According to embodiments of the present disclosure, an interface between a carburized layer and body may be planar or non-planar and/or substantially correspond with the outer surface of the carburized layer.

Referring still to FIG. 4, the hardness of the carburized layer 430 may be greater than the hardness of the body 405. For example, the carburized layer 430 may be formed of a carburized steel having a hardness ranging from about 50 HRC to about 65 HRC (e.g., 510 HV-830 HV), and the body may be formed of a steel having a hardness ranging from about 20 HRC to about 45 HRC (e.g., 240 HV-450 HV). According to embodiments of the present disclosure, the difference in hardness between a carburized layer and the body may range from about 10 HRC to about 40 HRC (e.g., 100 HV-450 HV), when measured at the hardest points of the carburized layer and the body. The boronized layer 420 may have a hardness ranging from about 900 HV-2200 HV. As used herein, the hardness of layers in a gripping tool may be determined by taking micro-hardness measurements along the material layer.

According to some embodiments of the present disclosure, a gripping element may be borochromatized to form a borochromatized outer layer. In such embodiments, a boron and chromium source may be packed around the outer surface of a gripping element and subjected to heat for a time sufficient to allow boron and chromium to diffuse a depth into the surface. According to one or more embodiments, multi-component boriding processes may include boroaluminizing, borosiliconizing, borochromizing, and borochromtitanized structural steel alloy. Boroaluminizing may involve boriding followed by aluminizing (e.g., a compact layer formed in steel parts), which may provide wear resistance and corrosion resistance, including in humid environments. Borosiliconizing may result in the formation of FeSi in a surface layer, which may enhance a corrosion-fatigue strength of treated parts. Borochromizing may involve chromizing after boriding and may provide oxidation resistance. The most uniform layer (which, e.g., may include a solid-solution boride containing iron and chromium) may provide improved wear resistance and enhanced corrosion-fatigue strength. A post-heat-treatment operation may be safely accomplished without a protective atmosphere. Borochromtitanized structural alloy steel may provide high resistance to abrasive wear and corrosion as well as extremely high surface hardness (e.g., up to 5000 HV). The microstructure of borochromtitanized constructional alloy steel may exhibit titanium boride in the outer layer and iron-chromium boride beneath it. Further, one or more embodiments disclosed herein may include borovanadized and/or borochromvanadized layers, which may be ductile and may have a hardness exceeding 3000 HV, which may reduce the danger of spalling under impact loading conditions. As such, the diffusion layer, according to one or more embodiments disclosed herein, may include any of these aforementioned layers.

In some embodiments, the outer surface of a gripping element may be subjected to a nitriding diffusion process. Nitriding is a surface processing method that includes the diffusion of nitrogen into the surface at a temperature for a period of time. Depending on the material being nitridized, environment and other processing conditions, nitriding temperatures may range, for example, from about 450° C. to about 700° C. Nitrogen sources may include, for example, ammonia, liquid salt baths, nitrogen plasma sources. In embodiments using liquid salt baths as a nitrogen source, nitriding temperatures may be higher than 550° C.

According to embodiments of the present disclosure, a gripping surface may have a carburized layer formed thereon and an additional diffusion layer formed on the carburizing layer. For example, as described above, a boronized layer may be formed on a carburized layer of a gripping surface. However, in some embodiments, a carburized layer may have a nitridized layer formed thereon. A nitridized layer may be formed by a nitriding process known in the art, which includes, generally, heating the surface in a nitrogen rich environment at a temperature and time sufficient for the nitrogen to infiltrate the surface. For example, a carburized layer may have a nitridized layer formed thereon by subjecting the carburized layer to a gas nitriding, salt bath nitriding, or plasma nitriding process.

Advantageously, forming one or more diffusional layers on the teeth of a gripping surface may provide adequate support for additional outer layers and increased hardness, while also avoiding adhesion problems present in various coating methods. Alternatively, a diffusion layer may form the outer layer of a gripping element, without subsequent surface processing.

Additionally, carburizing teeth of a gripping surface according to embodiments of the present disclosure may provide a support for additional layers either formed or attached to the teeth. For example, in embodiments having a gripping surface carburized and subsequently boronized, the depth and gradual transition to the hardness of the body in the carburized layer may provide support for the boronized layer. Further, a boronized outer layer may provide a reduction in the friction coefficient of the teeth on a gripping surface, thereby decreasing the force required to penetrate the material being gripped, and thus reducing the potential for slip crush, such as when one or more slip assemblies deforms or crushes a tubular being gripped. Diffusion layers formed on a gripping surface according to embodiments of the present disclosure may also provide improved wear resistance and buffer benefits.

By providing the carburized layer as a support layer for additional outer layers, such as described herein, teeth of a gripping surface may have increased hardness while also being able to better withstand highly loaded or compressive applications. Additional layers formed or disposed on a carburized layer may include a diffusion layer, such as a boronized or nitridized layer described above, or an outer layer attached to the carburized layer, such as described below. In some embodiments, a surface material may have a single diffusion layer, which may or may not be a carburized layer. For example, in some embodiments, a gripping surface may have a boronized layer with an outer layer attached or coated to the boronized layer.

As mentioned above, treating a gripping surface with one or more diffusion processes may provide the gripping surface with enhanced gripping capabilities and decreased iron transfer, while also being less likely to delaminate or crack than coating or plating processes, as the diffusion process results in a layer formed from the base material. During the diffusion processes, atoms are diffused into a base material to alter the microstructure and material properties of the base material in the resulting diffusion layer. Thus, the diffusion layer is formed as part of the base material, where the diffused atoms are diffused into the base material rather than applied as a surface layer that can more easily be worn or chipped away.

Other Surface Processing

According to embodiments of the present disclosure, one or more outer layers may be coated or otherwise applied on a gripping surface of the present disclosure, which may or may not also have a diffusion layer formed therein. For example, at least one outer layer may be applied on a gripping surface by methods including electro-deposition, laser metal deposition, laser sintering, physical vapor deposition (PVD), chemical vapor deposition (CVD), plasma-assisted processes, ion implantation, or any powder metallurgy process. Further, coatings may be formed of non-ferrous material, including, for example, cobalt alloys, tungsten and tungsten alloys such as doped tungsten, molybdenum alloys, titanium alloys, nickel alloys, and copper alloys or may include diamond-like coatings. In some embodiments, diamond, cubic boron nitride, polycrystalline cubic boron nitride and/or other ultrahard material may be impregnated into an outer layer. Such ultrahard material particles impregnated into a coating may range in size from nano-scale to micro-scale.

In some embodiments, one or more layers may be coated or otherwise applied on a gripping surface (whether on a case-hardened/diffusion layer or not) using an electroless deposition process. Also known as chemical or auto-catalytic plating, electroless deposition refers to a non-galvanic plating method that involves several simultaneous reactions in an aqueous solution, which occur without the use of external electrical power.

One or more embodiments may include a diamond impregnated coating according to embodiments of the present disclosure. In one or more embodiments, diamond particles may be impregnated within a coating material, which may include, for example, at least one of nickel, cobalt, tungsten, molybdenum, iron, ceramics, nickel-phosphorus, and/or polymers. Diamond particles may have a size ranging from a lower limit selected from any of 1 nm, 10 nm, 100 nm, 1,000 nm, 10 microns, and 100 microns to an upper limit selected from any of 100 nm, 10 microns, 100 microns and 800 microns. The size of diamond particles imbedded into a coating material may be selected depending on the thickness of the coating being applied as an outer layer on a gripping surface. Further, as shown, diamond particles may be exposed at the outer surface of the coating material, or diamond particles may be entirely immersed in the coating material. The diamond impregnated coating may be deposited on the outer surface of a gripping element that has already undergone one or more of the processing methods disclosed herein, such as on a diffusion layer formed in the outer surface of the gripping element. In other embodiments, the diamond impregnated coating may be deposited directly to a base material of a gripping element, i.e., a gripping surface that has not already undergone a surface processing method. In some embodiments, the diamond impregnated coating may be deposited to an outer surface of a gripping element formed by additive manufacturing, which is described more below.

The thickness of a coating applied to the gripping surface of a gripping tool may vary depending on the type of material being coated and the method of application to the gripping surface. For example, in some embodiments, a coating applied as an outer layer to a gripping surface by a thin film deposition method, such as chemical vapor deposition, physical vapor deposition, electro-deposition, or atomic layer deposition, may have a thickness ranging from about 10 nanometers to about 1.5 mm. In some embodiments, a coating applied as an outer layer to a gripping surface may have a thickness greater than about 1.5 mm.

Further, one or more coatings may be applied as an outer layer to a gripping surface to provide increased hardness. For example, in some embodiments, a gripping surface may have two or more layers formed thereon, in which the two or more layers may be formed on the gripping surface in an order of increasing hardness i.e., the outer layer forming the outer surface of the gripping surface has a hardness greater than an adjacent layer formed distal from the outer surface. In some embodiments, a coating may be applied to a carburized layer formed on the gripping surface, in which the coating has a hardness greater than the carburized layer, and the carburized layer has a diffusion-type gradient of decreasing hardness that transitions to the body of the gripping tool. In some embodiments, a second coating may be applied to a first coating (applied to a gripping surface prior to having the second coating applied thereto), in which the second coating forms the outer surface of the gripping surface and has a hardness greater than the hardness of the first coating, and in which the first coating has a hardness greater than the base material of the gripping surface.

According to embodiments of the present disclosure, one or more coatings, such as described above, may be applied to a carburized layer formed on a gripping surface. For example, a gripping surface of the present disclosure may include a plurality of teeth extending from a gripping tool body. The teeth may include side surfaces transitioning to an apex to penetrate and grip another material, such as CRA tubulars. Penetrating and gripping another material may induce compressive loads, among others, on the teeth. By providing the teeth with a carburized layer to support additional outer layers (such as those described above, including diffusion layers and coatings), the outer layers may have improved retention to the teeth, while also providing the teeth with increased hardness, wear resistance, lubricity, etc.

Gripping elements according to embodiments of the present disclosure may have an outer surface that is surface processed using one or more of the surface processing methods disclosed herein. For example, the outer surface of a gripping element may be subjected to one or more diffusion processes such that the outer surface of the gripping element is formed from a diffusion layer. In some embodiments, the outer surface of a gripping element may be subjected to one or more diffusion processes and subsequently coated using one or more other surface processing methods disclosed herein, such as applying one or more coatings to the outer surface. In yet other embodiments, the outer surface of a gripping element may be subjected to one or more surface processing methods disclosed herein that does not include a diffusion process. For example, in some embodiments, a gripping element that has not been subjected to a diffusion process may have one or more coatings applied to the outer surface of the gripping element. The one or more coatings may include, for example, diamond impregnated coating, diamond like carbon coating, and/or coating applied by CVD or PVD. Further, in any of the methods of surface processing described herein, the outer surface of the gripping element may undergo one or more cleaning processes, which are known in the art, prior to being surface processed.

In some embodiments, gripping elements may have a gripping surface formed of non-ferrous material, such as one or more of cobalt alloys, tungsten, tungsten alloys, molybdenum alloys, titanium alloys, nickel alloys, and copper alloys. For example, a gripping element may be formed with a non-ferrous material by extrusion, swaging, rolling, machining, forging, bulk powder metallurgy, additive manufacturing, such as described below, or any other bulk manufacturing process. Gripping elements may be entirely formed of non-ferrous material, or partially formed of non-ferrous material, wherein at least the gripping surface is made of non-ferrous material. Further, gripping elements having a gripping surface formed of non-ferrous material may be surface processed according to methods disclosed herein, or may not be surface processed.

Gripping elements formed according to embodiments disclosed herein may have a life span longer than conventionally formed gripping elements. For example, upon testing gripping elements formed according to embodiments of the present disclosure and conventionally formed gripping elements, the gripping elements formed according to embodiments described herein incurred less wear than the conventionally formed gripping elements.

Additive Manufacturing

According to one or more embodiments, a gripping element may be formed by additive manufacturing, which includes building up the gripping element layer by layer. For example, a gripping tool may include a gripping element with at least one gripping surface formed on the gripping element, wherein the gripping surface includes a plurality of teeth extending from the gripping element, an outer layer formed of a first material, and at least one inner layer formed between the outer layer and a base. In some embodiments, the first material may be a non-ferrous material. The base may be formed of a second material, different from the first material, and may be a ferrous or non-ferrous material.

Further, a gripping tool may include one, two, three or greater than three layers formed on a base of the gripping element using additive manufacturing. For example, a gripping element may be formed by applying sequential layers of the same or different materials by extruding each layer on top of the previous layer. In some embodiments, one or more layers may be applied by heating or fusing a layer of powdered material to the previous layer. Materials used to form one or more layers in additive manufacturing a gripping element may include ferrous and/or non-ferrous materials, such as one or more types of steels, titanium alloys, cobalt alloys, nickel chromium alloys, molybdenum alloys, or other alloys. For example, in some embodiments, a gripping element may be formed entirely of non-ferrous material by additive manufacturing. In other embodiments, a gripping element may be formed of ferrous material layers and non-ferrous material layers, wherein one or more non-ferrous material layers form the gripping surface of the gripping element.

Additive manufacturing may be used to create a gripping element having layers of materials with varying hardness. For example, in some embodiments, one or more inner layers of a gripping element may be formed with one or more materials having an average hardness that is less than the average hardness of the material forming the outer layer of the gripping element. In some embodiments, additive manufacturing may be used to create a gripping element having layers of materials with varying amounts of iron. For example, a gripping element may have one or more inner layers formed with one or more materials having an iron content greater than the iron content of the material forming the outer layer of the gripping element. Various combinations of materials may be used to form a gripping element layer by layer. Advantageously, by using additive manufacturing to form a gripping element, the gripping element may include varying material properties throughout the thickness of the gripping element. For example, gripping elements formed layer by layer having different average hardness values for each layer may have a harder outer layer and relatively tougher inner layers.

Gripping elements formed by additive manufacturing may or may not be surface processed according to methods described herein. For example, a gripping element formed layer by layer may be chemically surface processed by a diffusion process, such as one or more of a carburizing process, boronizing process, or nitridizing process, and/or may be coated by one or more coating methods described above. As referred to herein, layers formed during additive manufacturing are different from layers formed from coating processes. Additive manufacturing layers are layers that are formed during the manufacturing of the gripping element, while coating layers are applied to an already formed gripping element. Additive manufacturing layers may be thicker than coating layers. For example, in some embodiments, additive manufacturing layers may have thicknesses in a macro-level range, such as a millimeter or more, while coating layers may have thicknesses in a micro level range, such as in the micron or nanometer range. Further, in some embodiments, additive manufacturing layers may be formed with a common or integral material shared throughout two or more layers, while coating layers are applied separate or non-integrally with adjacent layers. For example, in some embodiments, a gripping element may be formed by additive manufacturing that includes layering two or more types of powdered materials and infiltrating the layers of powdered materials with a binder. In such embodiments, the layers may have varying compositions that are integrally formed and bonded with a single binder. After forming such gripping elements, they may be coated or otherwise surface processed according to methods disclosed herein.

Methods described herein used to surface process teeth of a gripping surface according to embodiments of the present disclosure may reduce or prevent the transfer of residual free iron otherwise present at the surface of a non-treated gripping surface to the material being gripped, such as CRA tubulars. For example, a non-treated gripping surface may transfer an amount of ferrous material to a CRA material being gripped. The transferred ferrous material may result in, among other things, eventual corrosion of the CRA material. However, by forming one or more layers (e.g., a diffusion layer and/or a coating) on the teeth of a gripping surface according to embodiments of the present disclosure, the layers may act as a buffer, thereby preventing transfer of ferrous material beyond the maximum allowable limit to the CRA material.

Further, one or more embodiments of the present disclosure may be used in combination with other embodiments of the present disclosure. For example, one or more layers (e.g., a diffusion layer and/or a coating) may be formed on the teeth of a gripping surface used in a first component for gripping tubular members, while a second component used in combination with the first component for gripping tubular members may have a either the same or different layers formed on its teeth. FIGS. 5 and 6 show cross-sectional views of examples of different gripping components that may be used in slip assemblies according to embodiments of the present disclosure; however, other combinations or components used alone may be used to grip tubular members with gripping surfaces having teeth formed as described above. As shown in FIG. 5, a tubular member 600 may be supported with a side-door elevator 610 and a slip-type gripping spider 620, where the elevator supports the tubular member 600 by supporting the tubular 600 via the lower load face of the coupling 611 attached to the upper extremity of the tubular member, and where the spider 620 includes a slip assembly 622 and a gripping surface 624 according to embodiments described herein. In one or more embodiments, the gripping surface 624 may be manufactured or treated according to any of the methods discussed above. As shown in FIG. 6, a tubular member 700 may be gripped with a slip type elevator 710 and a slip type spider 720, where both the elevator slip assembly 712 and the spider slip assembly 722 have an insert 714, 724, respectively, with a gripping surface according to embodiments of the present disclosure. The gripping surface used in the elevator insert 714 may be the same or different than the gripping surface used in the spider insert 724. For example, one or more gripping surfaces may be non-metallic or may include one or more coatings over a carbon steel substrate material. Further, in one or more embodiments, one or more gripping surfaces may be formed from other materials other than carbon steel and may include ferrous and/or non-ferrous alloys with or without inserts. In one or more embodiments, one or more of the material treatments discussed above may also apply to the use for tong dies.

FIG. 7 illustrates a conceptual, cross-sectional view of a portion of a gripping tool 750, according to an embodiment. The gripping tool 750 may form a part of a slip, rotary slip, tong jaw, or any other axial, radial, or torque loading device configured to grip another material, e.g., a corrosion resistant oilfield tubular, as discussed above. As shown, in this embodiment, the gripping tool 750 generally includes a substrate 752 and a coating 754. The coating 754 includes a “carrier” 758 (e.g., a metal matrix or another binding material, as will be discussed below) with particles 756 at least partially embedded therein. As shown, the particles 756 extend outward from the carrier 758, such that they are configured to be additionally embedded (e.g., on the upper side) into a structure or material that is gripped by the gripping tool 750, e.g., in lieu of or in addition to teeth or other marking structures.

The substrate 752 generally includes a base metal, which may be ferrous (e.g., a steel alloy) or non-ferrous. The substrate 752 may also define an outer surface 760, onto which the coating 754 may be formed. It will be appreciated that the substrate 752 may define other surfaces (e.g., inner and/or side surfaces) which may or may not be coated with the coating 754.

The coating 754 may be a metal deposition applied to the substrate 752, e.g., with the particles 756 impregnated in the carrier 758. The carrier 758 may include ferrous material or non-ferrous materials such as nickel alloys, copper alloys, cobalt alloys, tungsten and tungsten alloys, molybdenum alloys, titanium alloys, nickel-phosphorous, and/or polymers.

The coating 754 extends outward from the outer surface 760 by a thickness 762. The thickness 762 may be uniform or may vary, but generally refers to the distance between a point on an outer surface 764 formed by the carrier material 758 of the coating 754 and a point on the outer surface 760 of the substrate 752 along a line drawn normal to the outer surface 720. The thickness of the coating 754 may be determined based on a number of factors, e.g., based on characteristics of the substrate 752, the particles 756, the carrier 758, and/or the process by which the coating 754 is formed on the substrate 752.

As noted above, examples of such deposition processes include electro deposition, laser metal deposition, laser sintering, physical vapor deposition, chemical vapor deposition, plasma assisted processes, ion implantation, powder metallurgy processes, and/or electroless deposition. For example, the thickness may range from about 10 nm to about 1.5 mm. Some specific embodiments may range from about 10 μm to about 60 μm or from about 14 μm to about 20 μm.

The particles 756 may be formed from a material that is harder than the substrate 752, e.g., so as to facilitate embedding into and thereby gripping a structure made of a material that is nearly as hard, as hard, or harder than the substrate 752. The particles 756 may also be harder than the carrier 758. Examples of such material may include diamond, cubic boron nitride, polycrystalline cubic boron nitride, silicon carbide, and/or other material. The size (e.g., average cross-sectional diameter) of the particles 756 may range from about 1 μm to about 100 μm, e.g., about 10 μm to about 40 μm, including 10 μm, 20 μm, 35 μm, 40 μm, as specific examples. Further, the surface density of particles 756 (e.g., the amount of the total surface area occupied by the particles 756) may range from about 10% to about 50% of the gripping surface area. For example, diamond particles may have a surface density typically between 25% and 35% and silicon carbide particles may have a particle surface density of between 40% and 50%.

Table 1 provides a summary of the potential carrier material, deposition process, and particle material. Potentially any combination of one option from each column may be used in order to form the coating. In other embodiments, other materials/processes may be used.

TABLE 1

Carrier Material
Deposition Process
Particle Material

Nickel Alloys
Electro Deposition
Diamond

Nickel Phosphorous
Laser Metal
Cubic boron nitride

Deposition

Copper Alloys
Laser Sintering
Polycrystalline cubic

boron nitride

Cobalt Alloys
Physical Vapor
Silicon carbide

Deposition (PVD)

Tungsten
Chemical Vapor

Deposition (CVD)

Tungsten Alloys
Plasma Assisted

Processes

Molybdenum Alloys
Ion Implantation

Titanium Alloys
Powder Metallurgy

Processes

Polymers
Electroless Deposition

Iron

FIG. 8 illustrates a conceptual, cross-sectional view of a portion of another gripping tool 800, according to an embodiment. The gripping tool 800 may be similar to the gripping tool 750 shown in FIG. 7, except that it may additionally include a hardened layer 802. The hardened layer 802 may be formed from the base metal 804 of the substrate 752, so as to form distinct layers within the substrate 752. For example, the hardened layer 802 may extend inwards from the outer surface 760 of the substrate 752 by a thickness 806, which may depend on the hardening process.

Such hardening processes may include diffusion surface treatments, as discussed above. For example, such surface treatments include carburizing, boronizing, and nitridizing. The resulting hardened layer 802 may thus represent a case-hardened layer, having a hardness that exceeds the hardness of the base metal 804 of the substrate 752. In some embodiments, the hardened layer 802 may have a hardness that is less than a hardness of the particles 756.

FIG. 9 illustrates a flowchart of a method 900 for manufacturing a gripping tool, such as the gripping tools 750 and/or 800, according to an embodiment. The method 900 may optionally begin by surface treating a base metal of a substrate to form a hardened layer extending a depth inward from an outer surface of the substrate, as at 902. For example, such surface treating may include applying a diffusion surface treatment, such as carburizing, boronizing, and/or nitridizing.

The method 900 may also include forming a coating on a gripping surface of the substrate, without creating a heat-affected zone in the substrate, as at 904. In embodiments including surface treating at 902, the gripping surface is at least partially provided by the hardened layer, and thus the coating is applied at least partially to the hardened layer.

Forming the coating at 904 may include using electroless deposition. Other deposition processes for forming the coating may also or instead be used, for example, electro-deposition, laser-metal deposition, laser sintering, physical vapor deposition, chemical vapor deposition, plasma-assisted processing, ion implantation, or powder metallurgy processing. As discussed above, the coating may include a carrier (e.g., nickel-phosphorous) and a plurality of particles (e.g., silicon carbide) partially embedded therein.

In some embodiments, forming the coating at 904 may include at least partially immersing the gripping tool in a bath of the carrier with the particles suspended in the carrier, as at 906. The gripping tool may remain immersed for a predetermined amount of time. The predetermined amount of time may be calculated such that a coating of a certain thickness is formed. As mentioned above, for example, the coating thickness may be determined as a function of the average size of the particles (e.g., between about 30% and about 60% thereof, more particularly, e.g., about 50%), or a specific thickness determined by other factors. Furthermore, the carrier in the bath may be held at ambient or nearly ambient temperatures, as at 908, e.g., to avoid creating a heat-affected zone (i.e., a volume of the substrate where the properties of the metal forming the substrate are modified by heat during the application of the coating). Once the predetermined time has elapsed, the gripping tool may be removed from the bath, as at 910. In some embodiments, optionally, a sealant may then be applied to the coating, as at 912. It will be appreciated that actions 906-908 are representative of only one specific embodiment, and other processes for forming the coating 904, as described above, are within the scope of the present disclosure.

FIGS. 10A and 10B illustrate perspective views of two gripping tools 1000, 1050, which may be provided at least partially by the gripping tools 750 and/or 800 discussed above, according to an embodiment. Specifically, the gripping tools 1000, 1050 are inserts for slips that engage and support the weight of a tubular string, e.g., in a spider, elevator, and/or the like. It will be appreciated, however, that the gripping tools 750, 800 may also be employed as tong dies, or any other radial, axial, and/or torque loading device.

Referring specifically to FIG. 10A, the illustrated gripping tool 1000, which is a slip, includes a slip body 1002 and an insert 1004 coupled thereto. The insert 1004 includes a gripping surface 1006, which is coated by a coating including a carrier and a plurality of particles, as discussed above.

Referring specifically to FIG. 10B, the illustrated gripping tool 1050, which is a rotary slip, includes a slip body 1052 and a plurality of inserts 1054 that are spaced circumferentially apart. One, some, or each of the inserts 1054 may include a gripping surface 1056, which is coated by a coating including a carrier and a plurality of particles, as discussed above.

While the invention has been described with respect to a limited number of embodiments, those skilled in the art, having benefit of this disclosure, will appreciate that other embodiments can be devised which do not depart from the scope of the invention as disclosed herein. Accordingly, the scope of the invention should be limited only by the following claims.

Number	Date	Country
61856420	Jul 2013	US
61835976	Jun 2013	US
61829029	May 2013	US

	Number	Date	Country
Parent	14292748	May 2014	US
Child	15482151		US

	Number	Date	Country
Parent	15482151	Apr 2017	US
Child	16237199		US

COATING SYSTEM FOR TUBULAR GRIPPING COMPONENTS

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CROSS-REFERENCE TO RELATED APPLICATIONS

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