Simulating Drillstring Dynamics Motion and Post-Buckling State with Advanced Transient Dynamics Model

IF 1.3 4区 工程技术 Q3 ENGINEERING, PETROLEUM
Wei Chen, Yuelin Shen, Rongbing Chen, Zhengxin Zhang, S. Rawlins
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引用次数: 3

Abstract

As drilling sections become deeper and longer, transferring more weight downhole to improve rate of penetration is the primary concern for the operator. Drillstring dynamics and buckling are some primary limiters for drilling efficiency. Aggressive drilling parameters may lead to severe downhole dynamics, which leads to cutter breakage and tool damage. When axial compression exceeds a certain threshold, the drillstring buckles sinusoidally inside the wellbore first, followed by helical buckling. Buckling leads to accelerated joint wear, tool fatigue failures, and lower drilling efficiency. To better manage drillstring dynamics and buckling, we propose a method of simulating drillstring dynamics motion and postbuckling state using an advanced transient dynamics model. An analysis methodology was developed on the basis of the finite element transient dynamics model. The model captures the enriched physics of drillstring dynamics and loading: the large deformation of buckled drillstring, the strong nonlinearity of contact and friction forces, and the dynamically triggered instability caused by drilling rotation. Transient dynamics simulations are conducted for drillstring with the actual well trajectory and rotation speed. The weight on bit (WOB) is ramped up gradually, and the drillstring deformation is monitored to detect the onset of buckling or dynamics instability. To conduct the model validation, the buckling inception loads predicted by the model are compared against the analytical equation of critical buckling loads. A field extended reach drilling (ERD) job was simulated by the model. The downhole weight and torque data from the measurement-while-drilling (MWD) tool was used to validate the weight transfer prediction by the model. Most existing buckling theories use the analytical equations of critical buckling load, which were normally derived on the basis of the idealized assumptions, such as perfect wellbore shape and uniform tubular geometry. The proposed method simulates the drillstring behaviors in the field drilling conditions and aims to capture effects of wellbore friction and string rotation. The transient dynamics model is capable of simulating drillstring dynamics movement (whirling and snaking) and weight lockup under severe helical buckling. An automatic method is proposed to interpret the drillstring behaviors from the simulation results. Using the transient dynamics model, the procedure presented in this article can simulate the dynamics and buckling behaviors of drillstring and help mitigate associated risks in well-planning and execution phases.
利用先进的瞬态动力学模型模拟钻柱动态运动和后屈曲状态
随着钻井段越来越深、越来越长,向井下转移更多的重量以提高钻速是操作员最关心的问题。钻井动力学和屈曲是钻井效率的一些主要限制因素。激进的钻井参数可能导致严重的井下动力学,从而导致刀具断裂和工具损坏。当轴向压缩超过一定阈值时,钻柱首先在井筒内正弦屈曲,然后是螺旋屈曲。屈曲会导致接头磨损加速、工具疲劳失效和钻井效率降低。为了更好地管理钻柱动力学和屈曲,我们提出了一种使用先进的瞬态动力学模型模拟钻柱动力学运动和屈曲后状态的方法。在有限元瞬态动力学模型的基础上,提出了一种分析方法。该模型捕捉到了钻柱动力学和载荷的丰富物理特性:屈曲钻柱的大变形、接触力和摩擦力的强非线性,以及钻井旋转引起的动态触发不稳定性。利用实际井眼轨迹和旋转速度对钻柱进行了瞬态动力学模拟。钻头上的重量(WOB)逐渐增加,并监测钻柱变形,以检测屈曲或动力学不稳定性的开始。为了进行模型验证,将模型预测的屈曲起始载荷与临界屈曲载荷的解析方程进行比较。利用该模型模拟了油田大位移钻井作业。利用随钻测量工具的井下重量和扭矩数据验证了该模型的重量传递预测。大多数现有的屈曲理论都使用临界屈曲载荷的解析方程,这些方程通常是在理想化假设的基础上推导出来的,例如完美的井筒形状和均匀的管几何形状。该方法模拟了现场钻井条件下的钻柱行为,旨在捕捉井筒摩擦和钻柱旋转的影响。瞬态动力学模型能够模拟严重螺旋屈曲下的钻柱动力学运动(旋转和蛇形)和重量锁定。提出了一种从模拟结果中自动解释钻柱行为的方法。使用瞬态动力学模型,本文中提出的程序可以模拟钻柱的动力学和屈曲行为,并有助于减轻井规划和执行阶段的相关风险。
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来源期刊
SPE Drilling & Completion
SPE Drilling & Completion 工程技术-工程:石油
CiteScore
4.20
自引率
7.10%
发文量
29
审稿时长
6-12 weeks
期刊介绍: Covers horizontal and directional drilling, drilling fluids, bit technology, sand control, perforating, cementing, well control, completions and drilling operations.
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