你能感觉到压力吗?在BC蒙特尼,土桦树断裂几何的DAS应变前沿

G. Ugueto, F. Todea, Talib Daredia, M. Wojtaszek, P. Huckabee, A. Reynolds, C. Laing, J. Chavarria
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引用次数: 28

摘要

分布式声波传感应变前沿技术(DAS-SF)作为一种工具越来越受欢迎,它可以帮助表征水力裂缝的几何形状,并评估非常规油藏远场增产作业的效率。这些应变前沿是由水力压裂增产(HFS)过程中岩石的变形引起的,通过在套管后固井的光纤(FO)电缆上测量井中的玻璃纤维,可以产生一个特征应变特征。该DAS应用程序最初是由壳牌和OptaSense根据在加拿大Groundbirch Montney获得的数据集开发的。在本文中,我们展示了DAS-SF在各种完井系统中的应用实例:桥塞射孔(PnP)、裸眼封隔器滑套(OHPS),以及通过球激活固井单点进入滑套(ba - cspe)和连续油管激活固井单点进入滑套(cta - cspe)完井的数据。通过测量附近邻井在增产过程中的应变前沿,观察到大多数增产阶段在监测井中产生了远场应变梯度响应。当在空间上进行映射时,发现应变响应符合并证实了蒙特尼的主要平面裂缝几何形状,水力裂缝沿垂直于最小应力的方向扩展。然而;在邻井增产过程中,还观察到一些意想不到的、不一致的方位偏离事件,其中在先前阶段已经增产的位置检测到应变前沿。通过对多个数据源的进一步整合和分析,发现这些应变事件与压裂井的分段隔离缺陷相对应,导致原有裂缝“再增产”,资源开发效率低下。在蒙特尼的应变前沿监测为该地层的平面裂缝几何假设提供了更大的信心。DAS-SF提供的远离井筒的高分辨率裂缝几何信息也使我们能够改进分段偏移和井方位角策略。此外,识别在分段隔离不良的情况下发生的再增产和资源损失,也为未来的完井方案提供了改进的机会。反过来,这应该允许我们优化操作决策,以更有效地访问预期的资源量。这些数据集表明,通过FO结合其他数据来监测高分辨率变形,可以提供有关增产效率、裂缝几何形状和井结构缺陷的高可信度见解,这些都是其他方法无法获得的。
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Can You Feel the Strain? DAS Strain Fronts for Fracture Geometry in the BC Montney, Groundbirch
The use of Distributed Acoustic Sensing for Strain Fronts (DAS-SF) is gaining popularity as one of the tools to help characterize the geometries of hydraulic fracs and to assess the far-field efficiencies of stimulation operations in Unconventional Reservoirs. These strain fronts are caused by deformation of the rock during hydraulic fracture stimulation (HFS) which produces a characteristic strain signature measurable by interrogating a glass fiber in wells instrumented with a fiber optic (FO) cable cemented behind casing. This DAS application was first developed by Shell and OptaSense from datasets acquired in the Groundbirch Montney in Canada. In this paper we show examples of DAS-SF in wells stimulated for a variety of completion systems: plug-and-perforating (PnP), open hole packer sleeves (OHPS), as well as, data from a well completed via both ball-activated cemented single point entry sleeves (Ba-cSPES) and coil-tubing activated cemented single point entry sleeves (CTa-cSPES). By measuring the strain fronts during stimulation from nearby offset wells, it was observed that most stimulated stages produced far-field strain gradient responses in the monitor well. When mapped in space, the strain responses were found to agree with and confirm the dominant planar fracture geometry proposed for the Montney, with hydraulic fractures propagating in a direction perpendicular to the minimum stress. However; several unexpected and inconsistent off-azimuth events were also observed during the offset well stimulations in which the strain fronts were detected at locations already stimulated by previous stages. Through further integration and the analysis of multiple data sources, it was discovered that these strain events corresponded with stage isolation defects in the stimulated well, leading to "re-stimulation" of prior fracs and inefficient resource development. The strain front monitoring in the Montney has provided greater confidence in the planar fracture geometry hypothesis for this formation. The high resolution frac geometry information provided by DAS-SF away from the wellbore in the far-field has also enabled us to improve stage offsetting and well azimuth strategies. In addition, identifying the re-stimulation and loss of resource access that occurs with poor stage isolation also shows opportunities for improvement in future completion programs. This in turn, should allow us to optimize operational decisions to more effectively access the intended resource volumes. These datasets show how monitoring high-resolution deformation via FO combined with the integration of other data can provide high confidence insights about stimulation efficiency, frac geometry and well construction defects not available via other means.
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