Dynamic modeling and load transfer prediction of drill-string axial vibration in horizontal well drilling

A three-dimensional finite element dynamics model of drill-string is established considering dynamic friction model and buckling effect. The modified dynamics model is proved to have higher computational accuracy by laboratory experiment. A parameters study is conducted based on the dynamics model. Results show that the exciting force amplitude, drilling fluid density, axial force, friction coefficient, and drill-string dimension have significant effects on the friction reduction performance and effective propagation distance of axial vibration. A prediction model for vibration propagation distance is established, which facilitates efficient optimization of the axial vibration parameters in horizontal well drilling. This study can provide theoretical guidance for axial vi-bration to safely and efficiently reduce the sliding friction in exploitation of unconventional oil-gas reservoirs.

Automated summary

In this study, a three-dimensional finite element dynamics model of the drill-string is established, taking into consideration the dynamic friction model and buckling effect. The modified dynamics model is verified to have higher computational accuracy through laboratory experiments. A parameter study is conducted based on the dynamics model, revealing significant effects of the exciting force amplitude, drilling fluid density, axial force, friction coefficient, and drill-string dimension on the friction reduction performance and effective propagation distance of axial vibration. A prediction model for vibration propagation distance is established, enabling efficient optimization of axial vibration parameters in horizontal well drilling. This study can provide theoretical guidance for safely and efficiently reducing sliding friction in the exploitation of unconventional oil and gas reservoirs.