Analysis of the flow and thermal-fluid–solid coupling of crude oil in circular pipe caused by variable pressure gradient

Zeitschrift für Naturforschung A Pub Date : 2024-05-09 DOI:10.1515/zna-2023-0293

Jinxia Jiang, Mengqi Liu, Yan Zhang, Zhen Huang

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Abstract

Globally, enhanced oil recovery (EOR) has become a pressing issue as the demand for crude oil continues to increase. This study investigates the flow and thermal-fluid–solid coupling of crude oil in a rod pump during hot water recovery and obtains the maximum recovery of crude oil in a vertical pipeline through numerical analysis. The pressure gradient in the pump barrel was first developed and deduced based on the ideal gas state equation and Bernoulli’s equation. According to the rheological experiment results, it was proven that the light crude oil conforms to the Newtonian constitutive equation. Subsequently, the momentum equation of crude oil flowing in the pipeline and fluid–solid coupling heat transfer equations were established and solved using the finite difference method. The effects of the thermal recovery temperature T w , wall thickness c, and stroke time n of the rod pump on flow Q are discussed. In particular, the flow Q within 1 min first increases and then slows down with the increase in stroke time n and reaches its maximum value at n = 7 r/min. Furthermore, flow Q decreases with an increase in c but increases as T w increases; c = 1.2 cm, T w = 363 K is the best oil recovery scheme.

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变压梯度引起的原油在圆管中的流动和热-流-固耦合分析

在全球范围内，随着原油需求的持续增长，提高石油采收率（EOR）已成为一个紧迫的问题。本研究通过数值分析，研究了热水采油过程中原油在有杆泵中的流动和热-流-固耦合，并获得了垂直管道中原油的最大采收率。首先根据理想气体状态方程和伯努利方程建立并推导了泵筒内的压力梯度。根据流变实验结果，证明轻质原油符合牛顿构成方程。随后，建立了原油在管道中流动的动量方程和流固耦合传热方程，并采用有限差分法进行了求解。讨论了有杆泵的热回收温度 T w、壁厚 c 和冲程时间 n 对流量 Q 的影响。其中，随着冲程时间 n 的增加，1 分钟内的流量 Q 值先增大后减小，并在 n = 7 r/min 时达到最大值。此外，流量 Q 随 c 的增大而减小，但随 T w 的增大而增大；c = 1.2 cm，T w = 363 K 是最佳采油方案。

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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Zeitschrift für Naturforschung A

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