A depth of cut control (DOCC) assembly includes a DOCC element positioned in a retainer pocket along a drill bit blade to limit a depth of cut of one or more fixed cutters. A retention member initially retains the DOCC element within the retainer pocket at a first exposure position. The retention member is configured to release the DOCC element downhole to allow one-way movement of the DOCC element to a second exposure position.

A depth of cut control (DOCC) assembly includes a DOCC element positioned in a retainer pocket along a drill bit blade to limit a depth of cut of one or more fixed cutters. A retention member initially retains the DOCC element within the retainer pocket at a first exposure position. The retention member is configured to release the DOCC element downhole to allow one-way movement of the DOCC element to a second exposure position.

The disclosure provides a drill bit including a bit body and a blade extending form the bit body. The blade includes a first element protruding from a surface of the blade and a second element protruding from the surface of the blade. The first element and the second element are each configured to extend or retract relative to the surface of the blade and are coupled to each other such that when the second element retracts relative to the surface of the blade, the first element extends relative to the surface of the blade. The first element is disposed within a first pocket formed in the surface of the blade, and the second element is disposed within a second pocket formed in the surface of the blade. A communication channel is formed between the first pocket and the second pocket.

Embodiments relate to a polycrystalline diamond compact (“PDC”) including a polycrystalline diamond (“PCD”) table bonded to a cemented carbide substrate including tungsten carbide grains having a fine average grain size to provide one or more of enhanced wear resistance, corrosion resistance, or erosion resistance, and a PDC with enhanced impact resistance. In an embodiment, a PDC includes a cemented carbide substrate having a cobalt-containing cementing constituent cementing tungsten carbide grains together exhibiting an average grain size of about 1.5 μm or less. The substrate includes an interfacial surface and a depletion zone depleted of the cementing constituent that extends inwardly from the interfacial surface to a depth of, for example, about 30 μm to about 60 μm. The PDC includes a PCD table bonded to the interfacial surface of the substrate. The PCD table includes diamond grains bonded together exhibiting an average grain size of about 40 μm or less.

A drill bit having reinforced binder zones and method of forming same are disclosed. The method includes the steps of mixing reinforcing particles with a binder-reinforcing material, placing the mixture of reinforcing particles and binder-reinforcing material in a mold used in forming a body of the drill bit, placing a universal binder in the mold, and heating the mold. The binder-reinforcing material is infiltrated with the universal binder which thereby forms reinforced binder zones.

A drill bit having reinforced binder zones and method of forming same are disclosed. The method includes the steps of mixing reinforcing particles with a binder-reinforcing material, placing the mixture of reinforcing particles and binder-reinforcing material in a mold used in forming a body of the drill bit, placing a universal binder in the mold, and heating the mold. The binder-reinforcing material is infiltrated with the universal binder which thereby forms reinforced binder zones.

A method for designing lithology-specific drill bits. The method creates an experimentally verified multiphysics model to predict drilling into site-specific rock formations. A physics-based, Eulerian-Lagrangian computational modeling framework to predict particle flow and tribological phenomena. The method uses this multiphysics model to generate virtual drilling data and then generates a machine learning enabled surrogate model of the physics-based model using the data from virtual drilling to provide design charts for drill bits.

A method for designing lithology-specific drill bits. The method creates an experimentally verified multiphysics model to predict drilling into site-specific rock formations. A physics-based, Eulerian-Lagrangian computational modeling framework to predict particle flow and tribological phenomena. The method uses this multiphysics model to generate virtual drilling data and then generates a machine learning enabled surrogate model of the physics-based model using the data from virtual drilling to provide design charts for drill bits.

A drilling assembly is disclosed for drilling a borehole in a rock body and inserting a rock bolt within the borehole in a single pass. The drilling assembly includes an elongated drill string having a downhole end. A drill bit is detachably joined to the downhole end of the drill string, with the drill bit having an external screw thread extending in an axial direction of the drill string. The drill string is surrounded by a rock bolt sleeve that has a thread engaging formation at or near its downhole end and that is arranged to cooperate with the external screw thread of the drill bit so that the drill bit is able to be screwed into the rock bolt sleeve.

A drilling assembly is disclosed for drilling a borehole in a rock body and inserting a rock bolt within the borehole in a single pass. The drilling assembly includes an elongated drill string having a downhole end. A drill bit is detachably joined to the downhole end of the drill string, with the drill bit having an external screw thread extending in an axial direction of the drill string. The drill string is surrounded by a rock bolt sleeve that has a thread engaging formation at or near its downhole end and that is arranged to cooperate with the external screw thread of the drill bit so that the drill bit is able to be screwed into the rock bolt sleeve.