水平注水井:注入裂缝的注入能力和密封

Jongsoo Hwang, M. Sharma, Maria-Magdalena Chiotoroiu, T. Clemens
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摘要

与直井相比,水平注水井能够注入更大体积的水,并且占地面积更小。我们对水平井注入能力、注入方案(基质与压裂)和裂缝封闭性进行了新的定量分析。为了准确预测注入器的性能并描述安全的操作条件,我们模拟了多层油藏中的颗粒堵塞、热孔隙弹性应力变化、热对流和热传导以及裂缝生长/封闭。模拟结果表明,水平井注入基质的持续时间比垂直注入更长,因为颗粒沉积在水平井更大的表面积上发生得更慢。同时,热损失在较长的井筒长度上均匀发生,从而减少热应力,延迟裂缝萌生。因此,水平井长度和注入速度是控制水平井裂缝起裂和长期注入能力的关键因素。为了准确预测裂缝的封闭性,盖层的热传导和相关的热应力是关键因素。我们发现忽略这些因素低估了裂缝高度的增长。根据我们的模拟分析,我们提出了通过控制注入速度、温度和水质来保持高注入能力和延迟裂缝起裂的策略。我们还提供了几种设计水平注水器的方法,以考虑相对于局部应力方向的井筒方向来改善裂缝封闭性。在局部最大水平应力方向上布置井,会产生纵向裂缝,与横向裂缝相比,裂缝的封闭性更好,裂缝转向更少。当垂直于最大水平应力方向钻井时,横向裂缝的起裂时间比纵向裂缝的起裂时间要晚。建议使用流量控制装置来分割流量和井筒。这有助于确保均匀的注水,并有助于控制裂缝。
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Horizontal Water Injection Wells: Injectivity and Containment of Injection-Induced Fractures
Horizontal water injection wells have the capacity to inject larger volumes of water and have a smaller surface footprint than vertical wells. We present a new quantitative analysis on horizontal well injectivity, injection scheme (matrix vs. fracturing), and fracture containment. To precisely predict injector performance and delineate safe operating conditions, we simulate particle plugging, thermo-poro-elastic stress changes, thermal convection and conduction and fracture growth/containment in reservoirs with multiple layers. Simulation results show that matrix injection in horizontal wells continues over a longer time than vertical injectors as the particle deposition occurs slowly on the larger surface area of horizontal wellbores. At the same time, heat loss occurs uniformly over a longer wellbore length to cause less thermal stress reduction and delay fracture initiation. As a result, the horizontal well length and the injection rates are critical factors that control fracture initiation and long-term injectivity of horizontal injectors. To predict fracture containment accurately, thermal conduction in the caprock and associated thermal stresses are found to be critical factors. We show that ignoring these factors underestimates fracture height growth. Based on our simulation analysis, we suggest strategies to maintain high injectivity and delay fracture initiation by controlling the injection rate, temperature, and water quality. We also provide several methods to design horizontal water injectors to improve fracture containment considering wellbore orientation relative to the local stress orientations. Well placement in the local maximum horizontal stress direction induces longitudinal fractures with better containment and less fracture turning than transverse fractures. When the well is drilled perpendicular to the maximum horizontal stress direction, the initiation of transverse fractures is delayed compared with the longitudinal case. Flow control devices are recommended to segment the flow rate and the wellbore. This helps to ensure uniform water placement and helps to keep the fractures contained.
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