Scaling Formulae for the Wellbore Hydraulics Similitude with Drill Pipe Rotation and Eccentricity

Thad Nosar, Pooya Khodaparast, Wei Zhang, A. Mehrabian
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引用次数: 1

Abstract

Equivalent circulation density of the fluid circulation system in drilling rigs is determined by the frictional pressure losses in the wellbore annulus. Flow loop experiments are commonly used to simulate the annular wellbore hydraulics in the laboratory. However, proper scaling of the experiment design parameters including the drill pipe rotation and eccentricity has been a weak link in the literature. Our study uses the similarity laws and dimensional analysis to obtain a complete set of scaling formulae that would relate the pressure loss gradients of annular flows at the laboratory and wellbore scales while considering the effects of inner pipe rotation and eccentricity. Dimensional analysis is conducted for commonly encountered types of drilling fluid rheology, namely, Newtonian, power-law, and yield power-law. Appropriate dimensionless groups of the involved variables are developed to characterize fluid flow in an eccentric annulus with a rotating inner pipe. Characteristic shear strain rate at the pipe walls is obtained from the characteristic velocity and length scale of the considered annular flow. The relation between lab-scale and wellbore scale variables are obtained by imposing the geometric, kinematic, and dynamic similarities between the laboratory flow loop and wellbore annular flows. The outcomes of the considered scaling scheme is expressed in terms of closed-form formulae that would determine the flow rate and inner pipe rotation speed of the laboratory experiments in terms of the wellbore flow rate and drill pipe rotation speed, as well as other parameters of the problem, in such a way that the resulting Fanning friction factors of the laboratory and wellbore-scale annular flows become identical. Findings suggest that the appropriate value for lab flow rate and pipe rotation speed are linearly related to those of the field condition for all fluid types. The length ratio, density ratio, consistency index ratio, and power index determine the proportionality constant. Attaining complete similarity between the similitude and wellbore-scale annular flow may require the fluid rheology of the lab experiments to be different from the drilling fluid. The expressions of lab flow rate and rotational speed for the yield power-law fluid are identical to those of the power-law fluid case, provided that the yield stress of the lab fluid is constrained to a proper value.
考虑钻杆旋转和偏心的井筒水力相似度换算公式
钻机流体循环系统的等效循环密度取决于井筒环空的摩擦压力损失。流动环实验是实验室模拟环空井筒水力学的常用方法。然而,包括钻杆旋转和偏心率在内的实验设计参数的合理标度一直是文献中的薄弱环节。我们的研究利用相似定律和量纲分析得到了一套完整的标度公式,该公式将实验室环空流动的压力损失梯度与井筒尺度联系起来,同时考虑了内管旋转和偏心的影响。对常见的钻井液流变学类型,即牛顿、幂律和屈服幂律进行量纲分析。建立了相关变量的适当的无量纲群来表征具有旋转内管的偏心环空中的流体流动。管壁处的特征剪切应变率由所考虑的环空流动的特征速度和长度尺度得到。实验室尺度和井筒尺度变量之间的关系是通过施加实验室流动环路和井筒环空流动之间的几何、运动学和动力学相似性来获得的。所考虑的标度方案的结果用封闭形式的公式表示,该公式将根据井筒流量和钻杆转速以及问题的其他参数确定实验室实验的流量和内管转速,从而使得到的实验室和井眼尺度环空流动的范宁摩擦系数相同。研究结果表明,对于所有流体类型,实验室流速和管道转速的适宜值与现场条件的适宜值呈线性相关。长度比、密度比、一致性指数比和功率指数决定了比例常数。为了在模拟环空流动和井筒尺度环空流动之间获得完全的相似性,可能需要实验室实验的流体流变学与钻井液不同。屈服幂律流体的实验室流速和转速表达式与幂律流体相同,只要将实验室流体的屈服应力约束在一个适当的值。
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