注水和生产过程中井筒轴向和径向温度的计算流体动力学建模与分析

SPE Journal Pub Date : 2024-02-01 DOI:10.2118/219467-pa
Jie Zheng, Zhihao Hu, Weixiao Wang, Yihua Dou, Jiahui Li, Xu Yang, Yarong Zhang, Yinping Cao
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摘要

为解决油气藏压裂生产过程中环流温度变化引起的油管/套管附加载荷、套管变形、封隔器失效等问题,基于油气藏的井身结构和过渡瞬态传热机理,提出了油管主流体域温度场、油管固体域温度场、环流域温度场和套管固体域温度场的四场耦合模拟模型。考虑到流体温度、压力和物理参数的耦合,根据储层特征、井筒传热特征以及压裂和生产条件建立了边界条件,并通过用户自定义函数(UDF)方法编译到 Fluent 软件中进行模拟。研究了注入压裂液和产出油气的温度和流量对井筒温度场分布和温度梯度的影响。研究结果表明,将 D14-1 和 D5-5 气井应用到模型中,模拟温度与实测井筒温度吻合良好,两口不同气井模拟值的最大误差分别为 6.4% 和 4.3%。随着注采作业时间的延长,井筒与地层之间的传热逐渐趋于稳定。此时,注采流量对井筒温度场的影响较小,而注采温度对井筒温度场的影响较大。注入和生产温度会引起环状温度和温度梯度的变化,导致有限环状体积内压力的增减,从而对油管和套管产生局部应力。研究成果可为压裂和油气生产过程中井筒温度场和压力场的分析提供理论依据,确保压裂和生产的安全性和稳定性。
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Computational Fluid Dynamics Modeling and Analysis of Axial and Radial Temperature of Wellbore during Injection and Production Process
To solve problems such as additional tubing/casing load, casing deformation, and packer failure caused by changes in annular temperature during oil and gas reservoir fracturing and production, based on the well structure of oil and gas reservoirs and transition transient heat transfer mechanism, a four-field coupling simulation model of the temperature field in the main fluid domain of the tubing, the temperature field in the solid domain of the tubing, the temperature field in the annular fluid domain, and the temperature field in the solid domain of the casing is proposed. Considering the coupling of fluid temperature, pressure, and physical parameters, boundary conditions are established based on reservoir characteristics, wellbore heat transfer characteristics, and fracturing and production conditions, and are compiled into Fluent software for simulation through the user-defined function (UDF) method. The effects of the temperature and flow rate of injected fracturing fluid and produced oil and gas on the distribution of the wellbore temperature field and temperature gradient are studied. The research results show that by applying D14-1 and D5-5 gas wells to the model, the simulated temperature is in good agreement with the measured wellbore temperature, and the maximum errors of the simulated values of the two different wells are 6.4% and 4.3%, respectively. As the injection and production operation time increase, the heat transfer between the wellbore and the formation gradually stabilizes. At this time, the injection and production flow rate have little impact on the wellbore temperature field, while the injection and production temperature have a greater impact on the wellbore temperature field. The injection and production temperature will cause changes in annular temperature and temperature gradient, leading to an increase or decrease in pressure within a limited annular volume, resulting in local stress on the tubing and casing. The research results can provide a theoretical basis for the analysis of the temperature field and pressure field of the wellbore during fracturing and oil and gas production, ensuring the safety and stability of fracturing and production.
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