2017
DOI: 10.1002/rnc.3759
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Nonlinear output‐feedback control of torsional vibrations in drilling systems

Abstract: Summary This paper considers the design of a nonlinear observer‐based output‐feedback controller for oil‐field drill‐string systems aiming to eliminate (torsional) stick–slip oscillations. Such vibrations decrease the performance and reliability of drilling systems and can ultimately lead to system failure. Current industrial controllers regularly fail to eliminate stick–slip vibrations under increasingly challenging operating conditions caused by the tendency towards drilling deeper and inclined wells, where … Show more

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Cited by 36 publications
(22 citation statements)
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“…When masses are non zero, they belong to the class of so-called "juggling systems" whose structure is particular [140,131]. It is noteworthy that so-called play operators of hysteresis (as in Figure 2.3 (b) [440,149,85], and naturally yields Lur'e set-valued systems [20,561]. Two-dimensional Coulomb's friction is represented in the tangent direction, by the mapping…”
Section: Compliant Contact/impact Modelsmentioning
confidence: 99%
“…When masses are non zero, they belong to the class of so-called "juggling systems" whose structure is particular [140,131]. It is noteworthy that so-called play operators of hysteresis (as in Figure 2.3 (b) [440,149,85], and naturally yields Lur'e set-valued systems [20,561]. Two-dimensional Coulomb's friction is represented in the tangent direction, by the mapping…”
Section: Compliant Contact/impact Modelsmentioning
confidence: 99%
“…The same objective is set in [5], where a PI controller to damp the first resonance mode based on feedback of the top drive velocity only is used. Other control methods, including torsional rectification [25], observer-based output feedback [7], [28], [29], feedback linearization [30], impedance matching [31], adaptive output-feedback for infinite dimensional drill-string models [23], backstepping control [32], sliding mode control [33], model predictive control [34], weight-on-bit (WOB) control [35], and robust control [6], [14], have been developed. A nonlinear observer-based approach for stick-slip mitigation is presented in [29], which uses a similar approach to model the drilling dynamics as employed in this paper.…”
Section: Mitigation Of Torsional Vibrations In Drillingmentioning
confidence: 99%
“…Other control methods, including torsional rectification [25], observer-based output feedback [7], [28], [29], feedback linearization [30], impedance matching [31], adaptive output-feedback for infinite dimensional drill-string models [23], backstepping control [32], sliding mode control [33], model predictive control [34], weight-on-bit (WOB) control [35], and robust control [6], [14], have been developed. A nonlinear observer-based approach for stick-slip mitigation is presented in [29], which uses a similar approach to model the drilling dynamics as employed in this paper. Such an observer-based state-feedback approach requires information about the bit-rock interaction in the observer, which is typically not available in practice.…”
Section: Mitigation Of Torsional Vibrations In Drillingmentioning
confidence: 99%
“…erefore, the torsional vibrations of the system cannot be interpreted rationally, neither from electrical nor from mechanical aspect. It is important to establish an accurate model of the electromechanical coupling system to further analyze the torsional vibration dynamic characteristics in the semidirect transmission system of the shearer and control the torsional vibration from the aspect of motor [21]. Gustavsson and Aidanpää [22] established the model of electromagnetic excitation produced by the uniform magnetic field, and the influence of nonlinear magnetic pull on rotor vibration of the hydrogenerator unit was discussed.…”
Section: Introductionmentioning
confidence: 99%
“…21 is coefficient vector corresponding to u 2 u.F 21 � F 21,1 F 21,2 0 F 21,4 0 , F 21,1 � c φ 2 H 11,4 + φ 2 H 20,4 + φ 4 H 11,2 + φ 4 H 20,2 � 0.0022 + 0.0015i, F 21,2 � f φ 1 H 11,4 + φ 1 H 20,4 + φ 4 H 11,1 + φ 4 H 20,1…”
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