Barite-Free Non-Aqueous Drill-In Fluid System Maximizes Productivity in High Temperature Wells

Godwin Chimara, W. Amer, Stephane L'Hostis, Philip Leslie
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Abstract

Minimizing formation damage is vital for maximizing productivity when an openhole (slotted liner) completion strategy is used, and it is particularly challenging in high temperature wells with bottomhole static temperature approaching 190°C (374°F). A barite-weighted fluid system for such high temperature wells was identified as unsuitable due to lack of ability to remediate via acid treatment. This paper discusses how a customized barite-free non-aqueous drill-in fluid system was used to successfully achieve productivity objectives for three such wells. Based on reservoir and well data provided, a 1.15 to 1.20 sg (9.60 to 10.0 lbm/gal) barite-free, non-aqueous drill-in fluid system was designed using a high density calcium chloride/calcium bromide brine as the internal phase to compensate for the absence of barite as a weighting agent. An engineered acid-soluble bridging package was included to protect the reservoir from excess filtrate invasion and allow for potential remediation by acid treatment at a later stage. The fluid system was subjected to formation response testing, and the results obtained proved satisfactory, confirming the fluid system was suited for drilling the reservoir. A similar solids-free system using higher density brine as the internal phase, was also formulated. This was spotted in the open hole once drilling was completed to help eliminate any potential for solids settling before running the slotted liner. Three wells were successfully drilled and completed. The barite-free system remained stable, allowed for trouble-free fluids-handling and drilling operations, and performed as expected. To aid in minimizing fluid invasion into the reservoir, onsite particle size distribution (PSD) measurements were performed in order to optimize bridging material additions while drilling and enhance efficiency in managing the solids control system. Because of the extremely high bottomhole temperature, a mud cooler was installed to help control the flowline temperature below 60°C (140°F); this helped maintain fluid stability and preserve functionality of downhole tools in this hostile environment. The solids-free system was successfully spotted in the open hole after drilling the section before well completion. This eliminated any settling potential and reduced flowback of solids during production. The recorded productivity of these wells met expectations.
无重晶石非水钻井液体系可最大限度地提高高温井的产能
当使用裸眼(缝眼尾管)完井策略时,最小化地层损害对于提高产能至关重要,在井底静温度接近190°C(374°F)的高温井中尤其具有挑战性。由于缺乏通过酸处理进行补救的能力,重晶石加重的流体体系被认为不适合这种高温井。本文讨论了如何使用定制的无重晶石非水钻井液体系成功实现三口此类井的产能目标。根据所提供的油藏和井数据,设计了一种1.15 ~ 1.20 sg (9.60 ~ 10.0 lbm/gal)的无重晶石非水钻井液体系,使用高密度氯化钙/溴化钙卤水作为内相,以弥补重晶石作为增重剂的缺失。设计的酸溶性桥接包可保护储层免受过量滤液侵入,并允许在后期通过酸处理进行潜在的修复。对该流体体系进行了地层响应测试,测试结果令人满意,证明该流体体系适合于该油藏的钻井作业。还配制了一种类似的无固相体系,采用高密度卤水作为内相。一旦钻井完成,裸眼井中就会发现这种现象,以帮助消除在下入开槽尾管之前固体沉降的可能性。成功钻完3口井。无重晶石系统保持稳定,可以进行无故障的流体处理和钻井作业,并达到预期效果。为了最大限度地减少流体侵入储层,现场进行了粒径分布(PSD)测量,以优化钻井过程中桥接材料的添加,提高固控系统的管理效率。由于井底温度极高,安装了泥浆冷却器,以帮助将流线温度控制在60°C(140°F)以下;这有助于在恶劣的环境中保持流体稳定性和井下工具的功能。在完井前钻完该段后,在裸眼井中成功发现了无固相体系。这消除了任何沉淀的可能性,并减少了生产过程中的固体返排。这些井的产能达到了预期。
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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