Force-balanced roller-cone bits, systems, drilling methods, and design methods
First Claim
Patent Images
1. A roller cone drill bit for drilling an earth formation, comprising:
- a bit body;
three roller cones attached to the bit body and able to rotate with respect to the bit body; and
a plurality of cutting elements arranged on each of the roller cones so that cutting elements on adjacent cones intermesh between the adjacent cones, the cutting elements being arranged such that axial force exerted on the bit during drilling is substantially balanced between the cones, wherein the axial force on the cones is determined by selecting bit design parameters, comprising at least a geometry of a cutting element on said bit;
selecting drilling parameters, comprising at least an axial force on said bit;
selecting an earth formation to be represented as drilled;
calculating from said selected drilling parameters, said selected bit design parameters and said earth formation, parameters for a crater formed when one of a plurality of said cutting elements contacts said earth formation;
calculating a bottomhole geometry, wherein said crater is removed from a bottomhole surface;
simulating incrementally rotating said bit, and repeating said calculating of said crater parameters and said bottomhole geometry, based on calculated roller cone rotation speed and geometrical location with respect to rotation of said roller cone drill bit about its axis; and
summing axial force developed by each of said cutting elements in creating said craters.
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Abstract
Roller cone drilling wherein the bit optimization process equalizes the downforce (axial force) for the cones (as nearly as possible, subject to other design constraints). Bit performance is significantly enhanced by equalizing downforce.
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Citations
27 Claims
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1. A roller cone drill bit for drilling an earth formation, comprising:
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a bit body;
three roller cones attached to the bit body and able to rotate with respect to the bit body; and
a plurality of cutting elements arranged on each of the roller cones so that cutting elements on adjacent cones intermesh between the adjacent cones, the cutting elements being arranged such that axial force exerted on the bit during drilling is substantially balanced between the cones, wherein the axial force on the cones is determined by selecting bit design parameters, comprising at least a geometry of a cutting element on said bit;
selecting drilling parameters, comprising at least an axial force on said bit;
selecting an earth formation to be represented as drilled;
calculating from said selected drilling parameters, said selected bit design parameters and said earth formation, parameters for a crater formed when one of a plurality of said cutting elements contacts said earth formation;
calculating a bottomhole geometry, wherein said crater is removed from a bottomhole surface;
simulating incrementally rotating said bit, and repeating said calculating of said crater parameters and said bottomhole geometry, based on calculated roller cone rotation speed and geometrical location with respect to rotation of said roller cone drill bit about its axis; and
summing axial force developed by each of said cutting elements in creating said craters. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9)
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10. A roller cone drill bit, comprising:
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a bit body;
three roller cones attached to said bit body and able to rotate with respect to said bit body; and
a plurality of cutting elements arranged on each of the cones so that cutting elements on adjacent cones intermesh between the adjacent cones, the cutting elements being arranged such that an amount of work performed by each cone during drilling is substantially the same as the work performed by each of the other cones. - View Dependent Claims (11, 12, 13, 14, 15, 16, 17, 18)
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19. A roller cone drill bit, comprising:
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a bit body;
three roller cones attached to said bit body and able to rotate with respect to said bit body;
a plurality of cutting elements arranged on each of the cones so that cutting elements on adjacent cones intermesh between the adjacent cones, the cutting elements being arranged such that a distribution of axial force on the bit is optimized. - View Dependent Claims (20, 21, 22, 23, 24, 25, 26, 27)
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Specification