A radial bearing having a wear surface with improved wear characteristics comprises a steel support, to which is bonded a metal carbide composite wear surface made by first arranging, within a cavity defined between a steel mold and the steel support, tiles made of microwave sintered, cemented metal carbide, closely packing the voids between the tiles with metal carbide powder, and infiltrating the mold cavity with a metal brazing alloy by subjecting the filled mold to rapid heating. The brazing alloy fills voids between the metal carbide particles, the microwave sintered metal carbide tiles, and the metal support, thereby relatively rapidly consolidating the carbide into a wear layer bonded with the steel support without substantially damaging the properties of the microwave-sintered metal carbide tiles.

Embodiments disclosed herein are directed to bearing assemblies, related bearing apparatuses, and related methods. An example of a bearing assembly disclosed herein may include a support structure having a first end and a second end. The bearing assembly also includes a superhard bearing element secured to the first end of the support structure. The superhard bearing element includes a superhard sealing surface that may be configured to contact a sealing surface of an opposing bearing element, a base surface contacting the support structure and opposing the superhard sealing surface, and at least one lateral surface extending between the superhard sealing surface and the base surface. The support structure and the superhard bearing element may both include at least one conduit extending therethrough through which a fluid may flow.

A ground drilling device with a drivetrain for rotating a drill string, wherein at least one section of the drivetrain is configured to form a channel between a force transmission element of the drivetrain and the drill string, wherein the channel projects through the force transmission element and the force transmission element may be driven radially in the drivetrain.

Disclosed herein are embodiments of a pressure compensation piston and embodiments of rotary seal assemblies. In one embodiment, a pressure compensation piston for use with a rotary seal assembly includes a stepped piston having an opening extending there through for positioning the stepped piston about a rotatable shaft of a rotary seal assembly. In accordance with this embodiment, the pressure compensation piston further includes a rotary seal positioned along a radial surface of the opening for sealing the stepped piston relative to the rotatable shaft.

Provided herein is a motor or mud lubricated motor for use with horizontal directional drilling equipment as part of a trenchless drilling system. The motor has a hollow body with proximal and distal open ends and a compartment recessed into a top surface thereof between the proximal open end and the distal open end. A sonde housing with a removable cap secured to the housing is disposed within the compartment and contains a sonde transmitter and a battery operably connected to the sonde transmitter.

Provided herein is a motor or mud lubricated motor for use with horizontal directional drilling equipment as part of a trenchless drilling system. The motor has a hollow body with proximal and distal open ends and a compartment recessed into a top surface thereof between the proximal open end and the distal open end. A sonde housing with a removable cap secured to the housing is disposed within the compartment and contains a sonde transmitter and a battery operably connected to the sonde transmitter.

A lubricator for receiving a reciprocating plunger has (a) an elongate lubricator body with an inner bore, a lower inlet passage and a side outlet port; (b) an upper lubricator assembly capping an upper end of the lubricator body; and (c) a sleeve extending the length of the lubricator body, and having an outside diameter smaller than an inside diameter of the inner bore, defining an annular flow passage which is in fluid communication with the side outlet port. The sleeve defines an upper hole allowing fluid communication between an inner volume of the sleeve and the annular flow passage, and a lower hole allowing fluid communication between an inner volume of the sleeve and the annular flow passage.

The present application pertains to an injector chain control system for a coiled tubing unit. The system may comprise real time data received from sensors monitoring depth, pressure, force and other aspects of the well bore. The amount of hydraulic, electric, or pneumatic pressure allocated to the chain system may control both tension and traction system using the pressure as an indicator or trigger for the electronic feeding of information. A return feedback of the chain system may preset operating limits provided by well profile depths, pressures, temperatures, and/or composition of well contents in fluid, gaseous, and/or solid based. An injector chain system with or without a chain lubrication system may have a chain which is lubricated via an automated or manual system which can be triggered via a predetermined chain footage travel or timed interval, based on factors such a traction and/or tension pressure.

A full-metal dynamic-sealed concentrically-centered downhole displacement motor includes an outer tube, a stator fixed in the outer tube, a rotor rotatably connected in the stator, and a flow distribution shaft suspended in the rotor. When the rotor rotates, the plurality of circulation ports is alternately communicated with the flow distribution holes, and an accommodation space for flowing the drilling fluid is formed among the plurality of rotor copper rods; each of the circulation ports has a notch on the side of the rotor copper rod that is in communication with the accommodation space; the stator is provided with pressure relief ports for allowing the annular chamber and the accommodation space to communicate with each other, and the flow distribution hole and the pressure relief port are circumferentially arranged in a staggered manner.

A rotary transfer mechanism is disclosed for a motor, pump, or other downhole tool that accommodates the eccentric motion of a rotor without the need for a flex shaft, articulating joint or CV joint. In one configuration, the rotor is coupled to the drive shaft at a radial offset from the drive shaft axis. The orbiting motion of the rotor, rather than rotation of the rotor about its own axis, generates a torque on the drive shaft, by applying a tangential force to the drive shaft at the location of the radial offset. The radial offset may be set equal to the orbital radius so that no radial movement or flex is required at the drive shaft to accommodate the eccentric rotor movement.