交替压裂移位/压裂/闭合作业的实际考虑:从地质力学建模和井下诊断中学习

IF 1.3 4区 工程技术 Q3 ENGINEERING, PETROLEUM
Benyamin Yadali Jamaloei
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引用次数: 5

摘要

交替压裂或序外压裂(OOSF)已于2014年在西伯利亚西部进行了现场测试,并于2017年、2018年和2019年在加拿大西部进行了现场测试,取得了成功和良好的生产效果。首先进行第1段(趾部)压裂,然后进行第3段(跟部)压裂,然后在第1段和第3段(外部裂缝)之间进行第2段(中心裂缝)起下钻。在放置中心裂缝时,OOSF可以利用减小的应力各向异性来有效激活薄弱面(天然裂缝、裂缝、断层和节理),从而在几乎所有方向上产生具有不同破裂角度的破坏面。这可能会产生分支裂缝,将水力裂缝与放置外部裂缝时产生的应力释放裂缝连接起来,最终形成复杂的裂缝网络,增强裂缝的连通性。尽管之前有裂缝建模(通过现场测试校准)和地质力学建模的研究,但对OOSF过程中井筒破裂特征和水力裂缝方向的对比分析仍然缺乏。因此,在本研究中,给出了低应力各向异性和高应力各向异性的三维Kirsch方程的解,以分析不同地质力学和处理设计条件下的破裂梯度、破坏角和裂缝方向的差异。考虑了完整岩石从各向同性应力状态到高应力各向异性状态。根据井下测量的压力和温度对结果进行了分析。结果表明,OOSF过程中应力各向异性的减小导致了有利的处理条件:当净裂缝延伸压力大于减小的应力各向异性时,允许裂缝以不同的破坏角度生长可以产生裂缝复杂性。此外,可以在任何倾角或方位角进行钻井和压裂,其有利的破裂梯度为覆盖层梯度的45%至85%。应力各向异性的减小也会引发一些挑战。近井应力集中效应会变得更加明显,从而促进纵向裂缝的形成。对于弯曲度大于应力各向异性的处理,可以产生纵向裂缝而不是横向裂缝,因为弯曲度传递到井筒而不是进入裂缝。在这种情况下,为了启动横向裂缝,要么井筒必须与已有的横向缺口相交,要么近井孔隙流体压力必须超过轴向应力和岩石强度(在环向应力达到拉伸破坏点之前)。此外,裂缝可能会失去方向控制,并沿着任何薄弱的路径运行。因此,在低应力各向异性条件下,岩石织构效应变得更加明显,这意味着在没有横向天然裂缝或缺口的情况下,可以在完整水平井筒的底部和顶部形成纵向裂缝。这是第一次尝试通过地质力学建模和对井下测量压力和温度的分析来确定优化OOSF应该避免的情况,从而揭示在低应力各向异性状态下,在各种地质力学和处理条件下,使用Kirsch方程来揭示破裂特征的差异。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Practical Considerations in Alternate Fracturing with Shift/Fracture/Close Operation: Learnings from Geomechanical Modeling and Downhole Diagnostics
Alternate or out-of-sequence fracturing (OOSF) has been field tested in western Siberia in 2014 and in western Canada in 2017, 2018, and 2019, with operational success and positive well-production performance. It is conducted by fracturing Stage 1 (at the toe) and then fracturing Stage 3 (toward the heel), followed by tripping back to place Stage 2 (center fracture) between Stages 1 and 3 (outside fractures). During placing the center fracture, OOSF can exploit the reduced stress anisotropy to effectively activate the planes of weakness (natural fractures, fissures, faults, and joints) to potentially create failure surfaces with different breakdown angles in virtually all directions. This can potentially lead to branch fractures that can connect the hydraulic fractures to stress-relief fractures that are created while placing the outside fractures, ultimately generating a complex fracture network and enhancing fracture connectivity. Despite prior works on fracture modeling (calibrated by field tests) and geomechanical modeling, a comparative analysis of wellbore-breakdown character and hydraulic-fracture orientation during OOSF is still lacking. Thus, in this study, the solutions to 3D Kirsch equations are provided for both low and high stress anisotropies to analyze the differences in breakdown gradient, failure angle, and fracture orientation under various geomechanical and treatment-design conditions. The consideration is given to an intact rock from an isotropic stress state to high-stress-anisotropy conditions. The results are analyzed in the context of the downhole-measured pressures and temperatures. The results indicate that the reduced stress anisotropy during OOSF leads to favorable treating conditions: With a net fracture-extension pressure greater than the reduced stress anisotropy, fracture complexity can be created by allowing the fracture to grow with different failure angles. Also, a well can be drilled and fractured at any inclination or azimuth with favorable breakdown gradients of 45 to 85% of the overburden gradient. The reduced stress anisotropy can also trigger some challenges. The near-well stress-concentration effects can become more pronounced, promoting longitudinal fracture creation. For treatments with tortuosity greater than the stress anisotropy, longitudinal fractures can be created instead of transverse fractures because the tortuosity is transmitted to the wellbore body and not into the fractures. In this case, to initiate transverse fractures, either the wellbore must intersect the pre-existing transverse notches or the near-well pore-fluid pressure must exceed the axial stress and rock strength (before the hoop stress reaches the tensile failure point). In addition, the fracture might lose directional control and follow any path of weakness. Hence, the rock-fabric effects become more dominant under a low-stress-anisotropy regime, which means that with no pre-existing transverse natural fractures or notches, a longitudinal fracture can be generated at the bottom and top of an intact horizontal wellbore. This is the first attempt in identifying the circumstances that should be avoided for optimizing OOSF through geomechanical modeling and the analysis of the downhole-measured pressures and temperatures to reveal the differences in breakdown character using the Kirsch equations under various geomechanical and treatment conditions during the low-stress-anisotropy regime.
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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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