An Innovative Fluid Approach to Reservoir Drilling and Sand Screen Deployment: When Reality Meets Design and the Lessons Learned

Day 2 Tue, November 13, 2018 Pub Date : 2018-11-12 DOI:10.2118/193186-MS

Claire Webber, M. Langford

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Abstract

An engineered dual-purpose drilling and screen-running fluid was required to achieve optimum oil production with increased operational efficiency in a tight pressure window environment. The fluid needed to pose minimal formation damage risk while drilling and avoid completion damage through plugging of the standalone sand screen. This required a balance between bridging material content and particle size distribution (PSD), and a low fluid rheology to minimize the equivalent circulating density (ECD). The wide temperature profile and predicted restrictive narrow pressure margin in the well favored the use of a low ECD Non-Aqueous-Fluid (NAF). An organoclay-free NAF solution was selected. To reduce solids loading and ECD further, the fluid was designed with a brine phase that was high-density calcium bromide. Sized ground marble was selected to bridge the largest pore throats (42-μm) in the reservoir sand and still be screened quickly to avoid plugging of the 150-μm 6 5/8-in. standalone sand control production screens. Fluid optimization was achieved through rheology, stability, and formation-damage testing. The return permeability on cores/matched sandstone of >97%, indicated minimal formation damage risk when drilling and after production flowback/solids removal. In the field, the reservoir was drilled without major issue (i.e. no differential sticking, no down-hole losses) and the fluid quickly reached production screen test (PST) specifications prior to running screens. The sand screens were installed without issues. Although the sand section was significantly shorter than planned, the production from ~160 ft of net pay when the well was initially flowed produced as expected. After subsequent tie-in to the host floating production storage and offloading (FPSO) unit and upon choke opening, a gradual drop in production was observed. An acid job was performed via a subsea vessel-based operation and the planned production target exceeded the original clean-up well productivity.

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一种用于油藏钻井和防砂筛管部署的创新流体方法:当现实与设计相结合时的经验教训

为了在压力窗较紧的环境下实现最佳产油量，提高作业效率，需要一种工程设计的双重用途钻井和筛管下入液。该流体在钻井过程中对地层的损害风险最小，并通过堵塞独立的防砂筛管避免完井损害。这需要桥接材料含量和粒径分布(PSD)之间的平衡，以及低流体流变性以最小化等效循环密度(ECD)。该井的宽温度剖面和预测的限制性窄压力裕度有利于使用低ECD的非水流体(NAF)。选择无有机粘土NAF溶液。为了进一步降低固相载荷和ECD，设计了高密度溴化钙卤水相。选择大小适中的地面大理石来桥接储层砂中最大的孔喉(42 μm)，并且仍然可以快速筛分，以避免150-μm 6 5/8-in的堵塞。独立防砂生产筛管。流体优化是通过流变性、稳定性和地层损害测试来实现的。岩心/匹配砂岩的回归渗透率>97%，表明钻井时和生产返排/清除固体后地层损害风险最小。在现场，储层的钻探过程中没有出现重大问题(即没有压差卡钻，没有井下漏失)，并且在下筛管之前，流体很快达到了生产筛检(PST)规格。防砂筛管的安装没有出现任何问题。尽管出砂段比计划的短得多，但当该井开始生产时，净产层约160英尺处的产量符合预期。随后，在与主浮式生产储存和卸载(FPSO)装置连接后，在打开节流阀后，观察到产量逐渐下降。通过海底作业船进行酸化作业，计划生产目标超过了原清理井的产能。

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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Day 2 Tue, November 13, 2018

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