Modeling of micro-annulus propagation along cementing interface in stimulated horizontal wellbore

IF 1.5 Q3 GEOSCIENCES, MULTIDISCIPLINARY

Geosystem Engineering Pub Date : 2021-09-23 DOI:10.1080/12269328.2021.1978109

Yan Yan, Z. Guan, Weijun Yan

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Abstract

ABSTRACT Once there are micro-annulus at cementing interfaces in the process of reservoir stimulation, it is easy to form fluid channeling in the later development. Fluid channeling reduces the efficiency of reservoir development and even the service life of oil and gas wells. Based on the characteristics of ‘multi-stage’ in stimulated reservoir volume, a mathematical model was set up to calculate the interface debonding length driven by hydraulic pressure. The propagation process of micro-annulus in stimulated reservoir volume was also analyzed. The results show that the propagation speed of the micro-annulus gradually slows down with the progress of fracturing. Meanwhile, the debonding azimuth of the micro-annulus and the cement elastic modulus have dominant effects on the propagation length. It is recommended that the setting position of the packer be outranged from the debonding area of the cementing interface in the design of the stimulated reservoir volume scheme to avoid fluid channeling between the stages. This study can predict the unsealing length of cement sheath during hydraulic fracturing as a reference for the optimization of fracturing parameters.

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受激水平井微环空沿固井界面传播的建模

摘要在储层增产过程中，固井界面一旦出现微环空，在后期开发中很容易形成流体窜动。流体窜动降低了油藏开发效率，甚至降低了油气井的使用寿命。根据模拟储层体积“多级”的特点，建立了水力驱动下界面脱胶长度的数学模型。分析了微环空在受激储层体积中的传播过程。结果表明，随着压裂的进行，微环空的传播速度逐渐减慢。同时，微环空的脱粘方位角和水泥弹性模量对传播长度有主要影响。在模拟储层体积方案的设计中，建议封隔器的设置位置偏离固井界面的脱胶区域，以避免各阶段之间的流体窜流。该研究可以预测水力压裂过程中水泥环的解封长度，为优化压裂参数提供参考。

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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来源期刊

Geosystem Engineering GEOSCIENCES, MULTIDISCIPLINARY-

CiteScore

2.70

自引率

0.00%

发文量