Engineered Wellbore Strengthening Application Enables Successful Drilling of Challenging Wells

Godwin Chimara, A. Calder, W. Amer, Philip Leslie
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Abstract

Four wells were successfully drilled and completed, but high drilling fluid densities (1.95 to 1.98 SG) were necessary to maintain wellbore stability in the overburden section immediately above the depleted reservoir. The estimated hydrostatic overbalance from the drilling fluid was approximately 800 bar (11,603 psi) higher than reservoir pressure. A wellbore strengthening technique was selected to seal the calculated 1500 μm fractures induced by these high pressures. This paper highlights the engineering, logistical, and operational challenges encountered while successfully drilling and completing such wells. Geomechanical data was initially acquired, including Young's modulus, Poisson's ratio, and minimum in-situ horizontal stress; and, together with the operational parameters [hole diameter and equivalent circulating density (ECD)], these data were used to estimate fracture width (1500 μm). Subsequently, a drilling fluid system was engineered and customized to seal such fractures, thereby strengthening the wellbore to help minimize losses in the reservoir. The solution was validated at two separate laboratories. Large particulate materials with a D50 of 600 to 2300 μm were used. Improvement opportunities during execution were captured for the next cycle. A total drilling fluid loss of 512 m3 during a 16-hour period was experienced in one well after a drilling liner packoff occurred, and fractures greater than 1500 μm were initiated; however, the liner was successfully cemented in place. The coarse particulate materials (600 to 2300 μm) were mobilized in 500 and 1000 kg bags to minimize deck space requirements on the rig and help facilitate ease of mixing. Rig mixing and pit agitation capacity were important for effective mixing of the fluid system. The application also provided the opportunity to align testing procedures and equipment between the field and laboratory. With increasing reservoir depletion, the potential exists for fracture width increases that can impact the particle size of materials necessary to effectively design a solution. Engineered particulate solutions provided a pathway for sourcing and procuring the necessary wellbore strengthening materials.
工程井眼强化应用能够成功钻探具有挑战性的井
虽然已经成功钻完4口井,但为了保持枯竭油藏上方覆盖层的井眼稳定性,需要较高的钻井液密度(1.95 ~ 1.98 SG)。钻井液产生的流体静压过平衡估计比油藏压力高出约800 bar (11,603 psi)。研究人员选择了一种井筒强化技术来封堵由高压引起的1500 μm裂缝。本文重点介绍了在成功钻井和完井过程中遇到的工程、后勤和操作挑战。首先获取地质力学数据,包括杨氏模量、泊松比和最小地应力;结合作业参数(井径和当量循环密度),这些数据可用于估算裂缝宽度(1500 μm)。随后,设计并定制了一种钻井液体系来密封此类裂缝,从而加强井眼,帮助最大限度地减少储层的损失。该溶液在两个独立的实验室进行了验证。采用D50为600 ~ 2300 μm的大颗粒材料。执行期间的改进机会被捕捉到下一个周期。在钻井尾管封隔后的16小时内,一口井的钻井液总漏失量为512 m3,并且开始了大于1500 μm的裂缝;然而,尾管成功地固井到位。粗颗粒材料(600 ~ 2300 μm)被装入500和1000 kg的袋子中,以最大限度地减少钻井平台上的甲板空间需求,并有助于易于混合。钻机搅拌和坑内搅拌能力对流体系统的有效混合至关重要。该应用程序还提供了在现场和实验室之间调整测试程序和设备的机会。随着油藏枯竭程度的增加,裂缝宽度的增加可能会影响有效设计解决方案所需的材料粒度。工程颗粒解决方案为寻找和获取必要的井筒强化材料提供了途径。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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