Crack Propagation Hypothesis and a Model To Calculate the Optimum Water-Soaking Period in Shale Gas/Oil Wells for Maximizing Well Productivity

IF 1.3 4区 工程技术 Q3 ENGINEERING, PETROLEUM
B. Guo, R. Shaibu, Xuejun Hou
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引用次数: 4

Abstract

Currently, researchers and the industry believe that water invasion into a shale matrix should dominate the process of water soaking before flowback of hydraulic fracturing fluids. Based on laboratory observations with Tuscaloosa marine shale (TMS) cores, we postulate a hypothesis that cracks are formed in shale formations during and after hydraulic fracture stimulation and that they later contribute to improved well productivity. The formation of cracks contributes to improving well inflow performance, while the cracks also draw fracturing fluid from the hydraulic fractures, reduce fracture width, and consequently lower well inflow performance. The trade-off between crack development and fracture closure allows for an optimum water-soaking time, which could potentially maximize well productivity. A mathematical model was developed to describe the dynamic propagation of cracks based on the capillary-viscous force balance. The effect of crack formation on the long-term well productivity was analyzed using a previously published mathematical model for well productivity. A combination of the crack propagation and the well productivity models for the first time provides a technique for predicting the optimum fluid soaking time before flowback of hydraulic fracturing fluids. Sensitivity analyses show that reducing the viscosity of fracturing fluid could potentially speed up the optimum water-soaking time, while lowering the water-shale interfacial tension (IFT) could potentially delay the optimum water-soaking time. Real-time shut-in pressure data can be used in the crack propagation model to “monitor” crack development and identify the optimum water-soaking time before the flowback of hydraulic fracturing fluids for maximizing well productivity and the gas/oil recovery factor.
裂缝扩展假说和页岩气/油井最佳吸水期计算模型
目前,研究人员和业内人士认为,在水力压裂液返排之前,水侵入页岩基质的过程应该占主导地位。根据对Tuscaloosa海相页岩(TMS)岩心的实验室观察,我们假设裂缝是在水力压裂期间和之后在页岩地层中形成的,并且它们后来有助于提高油井产能。裂缝的形成有助于改善井的流入性能,同时裂缝也会从水力裂缝中吸出压裂液,减小裂缝宽度,从而降低井的流入性能。在裂缝发育和裂缝闭合之间进行权衡,可以获得最佳的浸水时间,从而可能最大限度地提高油井产能。建立了基于毛细管-粘性力平衡的裂纹动态扩展数学模型。利用先前发表的井产能数学模型分析了裂缝形成对井长期产能的影响。裂缝扩展和油井产能模型的结合首次为预测水力压裂液返排前的最佳流体浸泡时间提供了一种技术。敏感性分析表明,降低压裂液粘度可能会加快最佳浸水时间,而降低水-页岩界面张力(IFT)可能会延迟最佳浸水时间。实时关井压力数据可用于裂缝扩展模型,以“监测”裂缝发育,并确定水力压裂液返排前的最佳浸水时间,从而最大限度地提高油井产能和油气采收率。
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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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