Abstract: A method of making a drill bit having the following steps: placing matrix material in a bit body mold; placing a metal blank in the bit body mold; placing a binder material in the bit body mold with the binder material proximate the matrix material and the metal blank; and exposing binder material to microwave radiation, whereby binder material and other constituents is heated to a selected temperature to allow binder material to melt and to infiltrate matrix material. A method of heating selected portions of a drill bit comprising: placing the drill bit in an insulative oven having a wave guide of microwave radiation from a microwave generator; positioning a portion of the drill bit to be heated proximate the wave guide; and exposing the portion of the drill bit to be heated to microwave radiation, wherein the portion of the drill bit is heated without overheating remaining portions of the drill bit.

Abstract: Methods and systems are provided to improve design, manufacture and performance of oilfield equipment and well tools using three dimensional (3D) scanning technology and one or more feedback loops. Manufacturing processes and techniques associated with a well tool may be evaluated based on comparing “as built” 3D data with a design data file for the well tool. Based on differences between “as built” 3D data and the design data file, one or more changes in associated manufacturing procedures and/or techniques may be made. Computational fluid dynamic applications may be used to simulate fluid flow characteristics of a well tool using associated design data file, “as built” 3D data and/or after use 3D data. The associated design data file, manufacturing procedures and/or procedures for use of the well tool may be modified based on comparing simulated fluid flow data with desired fluid flow characteristics for the well tool.

Abstract: Methods and systems are provided to improve design, manufacture and performance of oilfield equipment and well tools using three dimensional (3D) scanning technology and one or more feedback loops. Manufacturing processes and techniques associated with a well tool may be evaluated based on comparing “as built” 3D data with a design data file for the well tool. Based on differences between “as built” 3D data and the design data file, one or more changes in associated manufacturing procedures and/or techniques may be made. Computational fluid dynamic applications may be used to simulate fluid flow characteristics of a well tool using associated design data file, “as built” 3D data and/or after use 3D data. The associated design data file, manufacturing procedures and/or procedures for use of the well tool may be modified based on comparing simulated fluid flow data with desired fluid flow characteristics for the well tool.

Abstract: Methods and systems are provided to improve design, manufacture and performance of oilfield equipment and well tools using three dimensional (3D) scanning technology and one or more feedback loops. Manufacturing processes and techniques associated with a well tool may be evaluated based on comparing “as built” 3D data with a design data file for the well tool. Based on differences between “as built” 3D data and the design data file, one or more changes in associated manufacturing procedures and/or technique may be made. Computational fluid dynamic applications may be used to simulate fluid flow characteristics of a well tool using associated design data file, “as built” 3D data and/or after use 3D data. The associated design data file, manufacturing procedures and/or procedures for use of the well tool may be modified based on comparing simulated fluid flow data with desired fluid flow characteristics for the well tool.

Abstract: Methods and systems are provided to improve design, manufacture and performance of oilfield equipment and well tools using three dimensional (3D) scanning technology and one or more feedback loops. Manufacturing processes and techniques associated with a well tool may be evaluated based on comparing “as built” 3D data with a design data file for the well tool. Based on differences between “as built” 3D data and the design data file, one or more changes in associated manufacturing procedures and/or technique may be made. Computational fluid dynamic applications may be used to simulate fluid flow characteristics of a well tool using associated design data file, “as built” 3D data and/or after use 3D data. The associated design data file, manufacturing procedures and/or procedures for use of the well tool may be modified based on comparing simulated fluid flow data with desired fluid flow characteristics for the well tool.

Abstract: A method of making a drill bit having the following steps: placing matrix material in a bit body mold; placing a metal blank in the bit body mold; placing a binder material in the bit body mold with the binder material proximate the matrix material and the metal blank; and exposing hinder material to microwave radiation, whereby hinder material and other constituents is heated to a selected temperature to allow hinder material to melt and to infiltrate matrix material. A method of heating selected portions of a drill bit comprising: placing the drill bit in an insulative oven having a wave guide of microwave radiation from a microwave generator; positioning a portion of the drill bit to be heated proximate the wave guide; and exposing the portion of the drill bit to be heated to microwave radiation, wherein the portion of the drill bit is heated without overheating remaining portions of the drill bit.

Abstract: A drill bit is designed to achieve optimum performance in a specified drilling application defined by the drilling system, the formation to be drilled and the configuration of the bore hole. A depth of cut versus predicted torque for a basic bit configuration is evaluated for different configurations of the drill bit. A computer modeling program is used to obtain the predicted torque for the basic bit configuration, and its modifications. Features of the bit design are changed to achieve the lowest predicted torque for an optimum depth of cut. Presenting the computer analysis as depth of cut versus predicted torque for the bit design simplifies the design selection process. The formation being drilled may be evaluated by comparing actual torque with predicted torque for a given rate of penetration. The evaluation can be used to conform the computer model and determine formation properties.

Abstract: A fixed-cutter drill bit is optimized so that cutter torques are evenly distributed not only during drilling of homogeneous rock, but also in transitional formations.

Abstract: A fixed-cutter drill bit is optimized so that cutter torques are evenly distributed not only during drilling of homogeneous rock, but also in transitional formations.