In modeling passage of an elongate well tool through a well, a computing system receives inputs representing a plurality of geometric characteristics of the well tool including three dimensional surface data characterizing the shape of outwardly facing, lateral surfaces of the well tool. The computi
In modeling passage of an elongate well tool through a well, a computing system receives inputs representing a plurality of geometric characteristics of the well tool including three dimensional surface data characterizing the shape of outwardly facing, lateral surfaces of the well tool. The computing system also receives inputs representing a plurality of geometric characteristics of the well. The computing system determines a prediction of the force to pass the well tool through at least a portion of the well based on a comparison of the three dimensional surface data of the well tool and the plurality of geometric characteristics of the well.
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1. A computer-implemented method for modeling passage of an elongate well tool through a well, the method comprising: receiving, with a computing system, inputs representing a plurality of geometric characteristics of the well tool including three dimensional surface data characterizing the shape of
1. A computer-implemented method for modeling passage of an elongate well tool through a well, the method comprising: receiving, with a computing system, inputs representing a plurality of geometric characteristics of the well tool including three dimensional surface data characterizing the shape of outwardly facing, lateral surfaces of the well tool;receiving, with the computing system, inputs representing a plurality of geometric characteristics of the well;determining, with the computing system, a radial position of the well tool within the well and relative to a radial surface of the well due to loads on the well tool; anddetermining, with the computing system, a prediction of the force to pass the well tool through at least a portion of the well based on a comparison of the three dimensional surface data of the well tool, the radial position of the well tool relative to the well, and the plurality of geometric characteristics of the well. 2. The computer-implemented method of claim 1, further comprising determining, with the computing system, whether the well tool will pass through the at least a portion of the well based on the comparison of the three dimensional surface data of the well tool and the plurality of geometric characteristics of the well. 3. The computer-implemented method of claim 1, wherein determining, with the computing system, the radial position of the well tool comprises determining radial deflection of the well tool. 4. The computer-implemented method of claim 1, wherein the loads comprise fluid imposed loads, thermal imposed loads, gravitationally imposed loads, and loads imposed due to interaction between the well tool and the well as the well tool moves axially through the well. 5. The computer-implemented method of claim 1, wherein the plurality of geometric characteristics of the well include three dimensional surface data characterizing one or more inwardly facing, lateral surfaces of the well that will pass directly adjacent one or more outwardly facing, lateral surfaces of the well tool as the well tool attempts to pass through the at least a portion of the well. 6. The computer-implemented method of claim 1, further comprising generating, with the computing system, an image of the well tool and the well depicting contacting surfaces of the well tool and the well. 7. The computer-implemented method of claim 1, further comprising receiving, with the computing system, inputs representing a current location of the well tool in the well; and where generating, with the computing system, an image of the well tool and the well depicting contacting surfaces of the well tool and the well comprises generating a current image based on the current location. 8. The computer-implemented method of claim 1, where determining, with the computing system, a prediction of the force to pass the well tool through at least a portion of the well comprises determining, with the computing system, a prediction of the force to pass the well tool from a location proximate the surface to a specified location in the well. 9. The computer-implemented method of claim 1, further comprising receiving, with the computing system, inputs representing a plurality of geometric characteristics of a tubing string having the well tool, the inputs including three dimensional surface data characterizing the shape of outwardly facing, lateral surfaces of the well tool; and where determining, with the computing system, a prediction of the force to pass the well tool through at least a portion of the well comprises determining, with the computing system, a prediction of the force to pass the well tool through at least a portion of the well based on a comparison of the three dimensional surface data of the well tool and three dimensional surface data of the tubing string with the plurality of geometric characteristics of the well. 10. The computer-implemented method of claim 1, further comprising receiving, with the computing system, inputs representing characteristics of a line supporting the well tool in the well; and where determining, with the computing system, a prediction of the force to pass the well tool through at least a portion of the well comprises determining, with the computing system, a prediction of the force to pass the well tool through at least a portion of the well based on a comparison of the three dimensional surface data of the well tool and characteristics of the line supporting the well tool in the well with the plurality of geometric characteristics of the well. 11. An apparatus comprising instructions embodied on a tangible, non-transitory computer-readable media, the instructions operable when executed to cause a computing system to perform operations comprising: receiving, with the computing system, inputs representing a plurality of geometric characteristics of a well tool including three dimensional surface data characterizing the shape of outwardly facing, lateral surfaces of the well tool;receiving, with the computing system, inputs representing a plurality of geometric characteristics of a well;determining, with the computing system, a radial position of the well tool within the well and relative to a radial surface of the well due to loads on the well tool; anddetermining, with the computing system, a prediction of the force to pass the well tool through at least a portion of the well based on a comparison of the three dimensional surface data of the well tool, the radial position of the well tool relative to the well, and the plurality of geometric characteristics of the well. 12. The apparatus of claim 11, where the plurality of geometric characteristics of the well include three dimensional surface data characterizing the inwardly facing, lateral surfaces of the well that will pass directly adjacent the outwardly facing, lateral surfaces of the well tool as the well tool attempts to pass through the at least a portion of the well. 13. The apparatus of claim 11, where the operations further comprise generating, with the computing system, an image of the well tool and the well depicting contacting surfaces of the well tool and the well. 14. The apparatus of claim 11, where the operations further comprise determining, with the computing system, whether the well tool will pass through the at least a portion of the well based on the comparison of the three dimensional surface data of the well tool and the plurality of geometric characteristics of the well. 15. A computing system for modeling passage of an elongate well tool through a well, comprising a memory, a processor, and instructions stored in the memory and executable by the processor to perform operations comprising: receiving, with the computing system, inputs representing a plurality of geometric characteristics of the well tool including three dimensional surface data characterizing the shape of outwardly facing, lateral surfaces of the well tool;receiving, with the computing system, inputs representing a plurality of geometric characteristics of the well;determining, with the computing system, a radial position of the well tool within the well and relative to a radial surface of the well due to loads on the well tool; anddetermining, with the computing system, a prediction of the force to pass the well tool through at least a portion of the well based on a comparison of the three dimensional surface data of the well tool, the radial position of the well tool relative to the well, and the plurality of geometric characteristics of the well. 16. The computing system of claim 15, where the operations further comprise generating, with the computing system, an image of the well tool and the well depicting contacting surfaces of the well tool and the well. 17. The computing system of claim 15, where the plurality of geometric characteristics of the well include three dimensional surface data characterizing one or more inwardly facing, lateral surfaces of the well that will pass directly adjacent one or more outwardly facing, lateral surfaces of the well tool as the well tool attempts to pass through the at least a portion of the well. 18. The computing system of claim 15, where the operations further comprise determining, with the computing system, whether the well tool will pass through the at least a portion of the well based on the comparison of the three dimensional surface data of the well tool and the plurality of geometric characteristics of the well. 19. The computing system of claim 15, where the operations further comprise receiving, with the computing system, inputs representing characteristics of a line supporting the well tool in the well; and where determining, with the computing system, a prediction of the force to pass the well tool through at least a portion of the well comprises determining, with the computing system, a prediction of the force to pass the well tool through at least a portion of the well based on a comparison of the three dimensional surface data of the well tool and characteristics of the line supporting the well tool in the well with the plurality of geometric characteristics of the well.
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이 특허에 인용된 특허 (11)
McLaughlin, Stuart, Downhole intelligent impact jar and method for use.
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