复杂混驱油田水力压裂能否提高采收率?

Muktar Kindi, Carmen Hamm, S. Kindi, Shaymaa Al Toqi, Majdi Breiki, Zuwayda Saadi, A. Harthy, Mohsin Jahwari, H. Gheilani, Shaymaa Al Farsi, Bogdan Suchta, S. Persac
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摘要

本文讨论了致密井距复杂混合水驱油田水力压裂概念的结果。目的是在灰水驱油田中验证这一压裂概念,以提高产油量和采收率。阿曼苏丹国中部的一个成熟油田正面临产量下降的问题。油田侧翼部分即使注水也不能达到预期产量。主要的挑战是如何在注入井和生产井之间进行通信。5点模式在侧翼区域没有显示出效果。非均质储层的复杂性和致密性是主要影响因素。水区离水库很近或位于水库之间。从该油田的140多口井中进行了仔细的候选选择。评估的因素包括采油与注水井之间的间距、多个混合储层、油水界面(OWC)的接近程度以及岩石物性参数。其中一口井位于油田南部,距离最近的油田5公里,在此基础上进行了成功的压裂试验,随后在主油田内选择了一些裂缝候选井。选择的方法是收集所有井的数据,并选择标准,将列表缩小到那些成功率较高的井,以帮助证明通过控制裂缝长度扩展和高度密封在注水井和采油厂中间进行压裂的新概念。选择了一个候选方案,并根据不同的情况对压裂设计进行了操作,以克服具有挑战性的油水接触并控制裂缝扩展,以避免附近的生产商和注水井。最终选定了裂缝设计并成功实施,通过低含水、低矿化度和放射性示踪剂的测试结果,证实了裂缝的存在。从第一口压裂井中得到的一个教训是,应该优化泵的设计,以在压裂处理后维持新的生产剖面。最初的生产阶段取得了三倍的产量,并在作业成功后准备了压裂方案。
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Will Hydraulic Fracturing Enhance the Production Recovery in a Complex Comingled Water Flood Field?
This paper discusses the outcome of a hydraulic fracturing concept in a complex commingled water flood field with dense infill well spacing. The objective was to prove this concept of fracturing in a graywater flood field to improve oil production and increase the recovery factor. A mature oil field in the central Sultanate of Oman is facing production decline. The flank part of the field is not meeting the expected production even with water flooding. The main challenge is how to communicate between the injector wells and the producer wells. The 5-spot patterns are not showing effectiveness in the flank area. The heterogeneous reservoir complexity and tightness are the main factors for that. The water zones are very close to or imbedded in between the reservoirs. A careful candidate selection exercise was conducted from the field's 140+ wells. Factors assessed included spacing between producers and injectors, multiple commingled reservoirs, proximity to the Oil Water Contact (OWC), and petrophysical parameters. A successful fracturing trial in one of the wells, located in the southern part of the field and five kms away from nearest oil producer, was followed with a selection of fracture candidates inside the main field. The method of selection was to gather all well data and select criteria to narrow the list to those wells with a higher success probability to help prove a new concept of fracturing in the middle of water injectors and oil producers by controlling fracture length propagation and height containments. A candidate was selected and the fracturing design was manipulated with different scenarios to overcome challenging oil water contact and control fracture propagation to avoid nearby producers and water injectors. The fracture was design selected and the operation successfully implemented, which resulted in a contained fracture confirmed by the low water cut, salinity results, and the radioactive tracer. One lesson learned from the first fractured well was that the pump design should be optimized to sustain a new production profile after the fracture treatment. Triple production resulted from the initial production stage and a fracturing proposal was prepared to follow the success of the operation.
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