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: Matrix drill bits and other downhole tools may be formed with one or more layers of hard materials disposed on exterior portions thereof. Exterior portions of used rotary drill bits or other downhole tools may be measured using three dimensional (3D) scanning techniques or other techniques to determine specific locations of undesired abrasion, erosion and/or wear. During the design of a new rotary drill bit or other downhole tool, computational flow analysis techniques may be used to determine potential locations for excessive erosions, abrasion, wear, impact and/or fatigue on exterior portions of the rotary drill bit or other downhole tools. One or more layers of hard material may be disposed at such locations on exterior portions of matrix bit bodies and other matrix bodies based on analyzing exterior portions of used downhole tools and/or computational flow analysis.

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: According to one embodiment, a rotary drill bit comprises a bit body with a bit rotational axis extending through the bit body; blades disposed outwardly from exterior portions of the bit body; and cutting elements disposed outwardly from exterior portions of each blade. At least one blade has a substantially arched configuration. Each blade comprises a leading surface and a trailing surface, where the leading surface is disposed on the side of the blade toward the direction of rotation of the rotary drill bit, and the trailing surface is disposed on the side of the blade opposite to the direction of rotation of the rotary drill bit. The rotary drill bit also comprises junk slots. Each junk slot is disposed between an adjacent leading surface and an adjacent trailing surface of associated blades.

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: Matrix drill bits and other downhole tools may be formed with one or more layers of hard materials disposed on exterior portions thereof. Exterior portions of used rotary drill bits or other downhole tools may be measured using three dimensional (3D) scanning techniques or other techniques to determine specific locations of undesired abrasion, erosion and/or wear. During the design of a new rotary drill bit or other downhole tool, computational flow analysis techniques may be used to determine potential locations for excessive erosions, abrasion, wear, impact and/or fatigue on exterior portions of the rotary drill bit or other downhole tools. One or more layers of hard material may be disposed at such locations on exterior portions of matrix bit bodies and other matrix bodies based on analyzing exterior portions of used downhole tools and/or computational flow analysis.