Active Control of Stick-Slip Torsional Vibrations of Drill-Strings using Non-Switching Sliding Mode Controller

A. Baz
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Abstract

Torsional vibrations of drill-strings are actively controlled using a non-switching sliding mode strategy. The controller is intended also to reject the effect of the interaction between the drill-bit and rock formation which induces non-linear stick-slip friction torque while tracking a desirable constant angular velocity of the drill-string. In order to demonstrate the merits of the proposed control algorithm, it is integrated with a simple two degrees-of-freedom model of the drill-string which is considered as a benchmark model for studying stick-slip induced torsional vibrations. Details of the development of the individual components making up the entire control action of the sliding mode controller (SMC) are presented. These components aim at rejecting the effect of the external disturbance of the stick-slip disturbance and tracking a reference angular velocity of the drill-string. Such development of the control action components is established using Lyapunov stability criterion. Numerical examples are presented to demonstrate the effectiveness of the SMC controller as influenced by the weight-on-bit (WOB), the drill-string rotational speed, and the main parameters of the controller. The stick-slip sensitivity (SSS) maps are developed to illustrate the performance characteristics of the active system for different operating conditions and important design parameters of the SMC. The presented active control approach is envisioned to present an invaluable and practical means for effectively mitigating the undesirable effects of stick-slip frictional disturbances on drill-stings.
基于非切换滑模控制器的钻柱粘滑扭振主动控制
采用非切换滑模策略主动控制钻柱扭振。该控制器还旨在抑制钻头与岩层之间相互作用的影响,这种相互作用会在跟踪钻柱的理想恒定角速度时产生非线性粘滑摩擦扭矩。为了证明所提出的控制算法的优点,将其与钻柱的简单二自由度模型相结合,该模型被认为是研究粘滑诱导扭转振动的基准模型。详细介绍了构成滑模控制器(SMC)整个控制动作的各个元件的开发。这些组件的目的是抵制粘滑干扰的外部干扰的影响,并跟踪钻柱的参考角速度。利用李亚普诺夫稳定性判据建立了控制作用分量的发展。数值算例表明,在钻压(WOB)、钻柱转速和控制器主要参数的影响下,SMC控制器是有效的。为了说明主动系统在不同工况和SMC重要设计参数下的性能特征,建立了粘滑灵敏度(SSS)图。所提出的主动控制方法有望为有效减轻粘滑摩擦扰动对钻柱的不良影响提供宝贵而实用的手段。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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