1. Technical Field
This disclosure relates generally to rotary drill bits. In particular, a drill bit of the present disclosure may be employed, e.g., in a drilling apparatus for drilling a borehole into the earth.
2. Description of Related Art
Often when drilling a borehole into the earth, a down-hole drilling motor is suspended from the lower end of a drill string. A drilling fluid may be transmitted through the drill string and circulated through the drilling motor to induce rotation of a drill bit, and the rotating drill bit engages a subterranean rock formation to produce a borehole therein. In some instances, directional drilling may be desirable, i.e., it may be desirable to produce a borehole that deviates from a vertically oriented path.
Some mechanisms employed for this purpose include a bent subassembly, integrated in the down-hole drilling motor, typically between the power section of the motor and the bearing assembly. A bent subassembly generally includes a bent or bendable structural component that supports the bearing assembly, and a drill bit at its lower end, at a slight angle to the direction of the drill string above the bent subassembly. The bent subassembly may define a fixed angle, or the angle may be adjustable. When it is desired to drill in a generally straight path, the entire drill string may be continuously rotated from the surface, and the motor may or may not be activated. When it is desired to cause the path of the borehole to diverge in a given direction, continuous rotation of the drill string is stopped, and the drill string, bent subassembly, motor and bit are oriented to in the desired direction of divergence. The upper part of the drill string is held in this position and the down-hole motor is started. This causes the borehole to diverge in the desired direction. A minimum turning radius of these mechanisms may be limited in part by a “bit-to-bend” length that may be generally described as the distance from a fulcrum point of the bent subassembly to leading face of the drill bit.
Mother type of drilling apparatus that may be employed for directional drilling is a rotary steerable system (RSS). Generally, a rotary steerable system provides some mechanism for steering the drill bit in a desired direction, usually without requiring continuous rotation of the drill string from the surface to be stopped. Many rotary steerable systems include a mechanism for providing a radial or sideways-direction force relative to the lower end of the drill string to steer the drill bit on a path that diverges from a straight path.
The drill bits employed for vertical drilling and/or directional drilling may need to be replaced for a number of reasons including wear or breakage of the surfaces contacting the subterranean rock formation. Often, drill bits are provided with a threaded interface, or another repeatable coupling, on a shank portion thereof to permit decoupling of a broken or worn drill bit from a lower portion of the motor, and replacement with a new or refurbished bit.
Advancements made in the design and usage of drill bits have made it possible to extend the expected life of a bit beyond the expected need for the bit for a particular application or project. Thus, it is now possible for a user to rent a drill bit for use on a project, and return the bit for subsequent use by another user on another project. This increase in the usable life of drill bits has affected the design considerations made in the manufacture of drill bits for down-hole drilling motors.
In one embodiment of the present disclosure, a down-hole drilling apparatus includes a bearing housing defining a longitudinal axis and upper and lower portions. The upper portion of the bearing housing is configured for connection to a drill string, and at least one annular bearing package is disposed within the bearing housing. A drill bit is coupled to the bearing housing and is rotatable with respect to the longitudinal axis. The drill bit includes a leading body supporting a plurality of cutters thereon for engaging a subterranean rock formation, a shank portion projecting from the leading body, and a mandrel portion engaging the shank portion and defining an inseparable connection therewith. The mandrel portion extends longitudinally into the bearing housing and through the at least one annular bearing package.
According to another embodiment of the present disclosure, a rotary steerable system includes a housing having an upper end and a lower end, wherein the upper end of the housing is configured for connection to a drill string. The rotary steerable system also includes a steering mechanism operable to provide a lateral force relative to the lower end of the housing, and a drill bit disposed at least partially within the housing. The drill bit includes a leading body supporting a plurality of cutters that are configured to engage a subterranean rock formation, and a mandrel portion inseparably coupled with the leading body. The mandrel portion extends longitudinally into the housing.
According to another embodiment of the present disclosure, a drill bit for use in a drilling apparatus includes a leading body supporting a plurality of cutters thereon, and a mandrel portion inseparably coupled with the leading body. The mandrel portion is adapted to extend into a housing of the drilling apparatus and to rotate therein. The mandrel portion includes at least one engagement surface thereon for engaging at least one annular bearing.
The present disclosure is best understood from the following detailed description when read with the accompanying figures. In accordance with the standard practice in the industry, various features may not be drawn to scale.
It is to be understood that the following disclosure provides many different embodiments, or examples, for implementing different features of various embodiments. Specific examples of components and arrangements are described below to simplify the present disclosure. These are, of course, merely examples and are not intended to be limiting.
The bottom-hole assembly 14A includes a bearing section 28, which permits rotary motion of the drill bit 100 with respect to the drill string 16. The bottom-hole assembly 14A also includes a steerable section 30, which may be employed to maintain or change the general heading of the drill bit 100 as the bottom-hole assembly 14A penetrates deeper into the earth. For example, the steerable section 30 may be employed to generate a bend 34 in the borehole 12A such that the borehole 12A deviates from the vertical. To achieve a bend such as bend 34, the steerable section 30 includes radially-extensible, side-force exertion elements 38 that selectively engage a sidewall of the borehole 12A. The side-force exertion elements 38 are described in greater detail in U.S. Pat. No. 7,287,605, the entire content of which is hereby incorporated by reference. It will be recognized that various other steering mechanisms may be employed within the scope of the present disclosure.
The achievable sharpness of the bend 34 generated by the drilling apparatus 10A is in part a function of the geometry and structural characteristics of the bottom-hole assembly 14A. The bottom-hole assembly 14A defines an overall length “L” that generally corresponds indirectly to the achievable sharpness of the bend 34, i.e., a shorter overall length “L” may yield a sharper bend 34 and a longer overall length “L” may yield a bend 34 that is relatively gradual.
The drill bit 100 may be employed in various alternate types drilling systems. For example, referring now to
The drilling apparatus 10B defines a bit-to-bend length “B” that contributes to an achievable sharpness of a deviation in borehole 12B. The bit-to-bend length “B” may be generally described as the distance from a fulcrum point of the bent subassembly 40 to an extreme end of the drill bit 100. Other apparatuses for directional drilling may not employ a bent subassembly, or a rotary steerable system but nevertheless define a length that contributes to the achievable sharpness of a bend in a borehole. Still other drilling apparatuses may be configured for generally vertical drilling. Any of these drilling apparatuses, whether configured for directional drilling or vertical drilling, may employ a drill bit 100 within the scope of the present disclosure.
Referring now to
The transmission section 44 includes a transmission 58 therein that serves to transmit mechanical motion, e.g., rotational motion, from the power section 46 to the drill bit 100. The transmission 58 may comprise, e.g., a fixed or flexible drive shaft operably coupled to the drill bit 100. Power section 46 includes rotor 62, stator 64, optional rotor catch 66, and top sub 68. The top sub 68 provides an interface for the connection of bottom-hole assembly 14 with the drill string 16. As is common with down-hole drilling motors, the power section 46 is configured such that transmission of a drilling fluid therethrough induces rotational motion of the rotor 62 with respect to the stator 64. The induced rotational motion of the rotor 62 may be eccentric or concentric rotational motion with respect to the stator 64.
Referring now to
The leading body 102 includes a plurality of blades 110 protruding from a central core 112. The central core 112 may be constructed of a hardened steel alloy or stainless steel, and the blades 110 may be subsequently affixed to the core 112 by fasteners, welding, molding, etc. A plurality of cutters 114 are mounted to the blades 110. The cutters 114 may comprise surfaces formed of tungsten carbide, PCD or another material suitable for engaging a subterranean rock formation. It will be recognized that other configurations of the leading body 102 are contemplated such as those configurations found in rolling cone bits, or the like. The shank portion 104 protrudes from the leading body and provides mating surfaces for engaging the mandrel portion 106. The shank portion 104 may be formed integrally or monolithically with the core 112 of the leading body 102, e.g., from the same piece of material by forging, rolling, extruding, etc., or coupled to the core 112 by welding or a similar process.
The mandrel portion 106 abuts the shank portion 104 and defines an inseparable connection 118 therewith. As used throughout this specification, the term “inseparable” is intended to mean that the connection 118 may not readily be disassembled without damaging or destroying the connected components. The inseparable connection 118 is depicted as a butt-welded connection established between adjoining faces 120, 122 of the mandrel portion 106 and the shank portion 106 respectively. The butt-welded connection 118 is characterized by a weld 124 wherein the base materials of the shank portion 104 and the mandrel portion 106 have been heated beyond their respective melting temperatures so as to fuse together in a region generally within an outer circumference of both of the adjoining faces 120, 122. The adjoining faces 120, 122 may be constructed in generally the same size and shape so the shank portion 104 and the mandrel portion 106 form a continuous annular shape in the region of the weld 124.
In other embodiments, such as the embodiment depicted in
In still other embodiments, an inseparable connection may be established by mechanisms other than welding wherein the base materials are not melted. For example, a soldered connection may be established wherein a filler material, or solder (usually a tin, lead or silver alloy), is melted and flowed into the joint between the mandrel portion 106 and shank portion 104 without melting the base material of either of the mandrel portion 106 and shank portion 104. Alternatively, a brazed connection may be established. Brazing generally involves melting a filler material (usually brass) at higher temperatures than are employed in soldering (typically more than 450° C.), and flowing the filler material into the joint between the mandrel portion 106 and shank portion 104.
Still other mechanisms might include shrink-fitting, wherein one of the mandrel portion 106 and the shank portion 104 is cooled or frozen to permit engagement with the other, and wherein an interference fit is established by the re-expansion of the cooled or frozen component returning to a nominal temperature. Also, a drill bit 100b may be provided wherein a mandrel portion 106b, shank portion 104b and/or a central core 112b may be integrally or monolithically formed as a single component as depicted in
Other embodiments, as depicted in
Referring again to
In some embodiments, the measurement/logging-while-drilling package 130 includes a magnetometer configured to make measurements of the strength and direction of magnetic fields. A magnetometer may also be provided independently of the measurement/logging-while-drilling package 130. The drill bit 100, 100a, 100b and other housing and drive components in such embodiments may be constructed of non-magnetic or nonferrous material such as aluminum, titanium or a similar alloy. A non-magnetic or nonferrous alloy facilitates measurements of the magnetometer.
It will be appreciated that the bit-to-bend length “B” of the bottom-hole assembly 14B, and/or the overall length “L” of the bottom-hole assembly 14A, is relatively short. For instance, by employing an inseparable connection 118 between the mandrel portion and the shank portion 104, rather than a repeatable coupling, the bit-to-bend length “B,” or overall length “L,” may be about 4 to about 5 inches shorter. Thus, the bottom-hole assemblies 14A and 14B may undergo relatively sharp changes in direction during directional drilling. Also, there may be less expense associated with an inseparable coupling 118 in certain applications such as “factory style” drilling operations where multiple boreholes may be drilled simultaneously with an emphasis on standardization.
The foregoing outlines features of several embodiments so that a person of ordinary skill in the art may better understand the aspects of the present disclosure. Such features may be replaced by any one of numerous equivalent alternatives, only some of which are disclosed herein. One of ordinary skill in the art should appreciate that they may readily use the present disclosure as a basis for designing or modifying other processes and structures for carrying out the same purposes and/or achieving the same advantages of the embodiments introduced herein. One of ordinary skill in the art should also realize that such equivalent constructions do not depart from the spirit and scope of the present disclosure, and that they may make various changes, substitutions and alterations herein without departing from the spirit and scope of the present disclosure.
The Abstract at the end of this disclosure is provided to comply with 37 C.F.R. §1.72(b) to allow the reader to quickly ascertain the nature of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.
Moreover, it is the express intention of the applicant not to invoke 35 U.S.C. §112, paragraph 6 for any limitations of any of the claims herein, except for those in which the claim expressly uses the word “means” together with an associated function.
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