Drilling Offshore Wells with HP WBM in Extreme HP HT Conditions

L. Affede, R. Lorefice, Larissa Pinto Vieira, M. Giubertoni, Lorenzo Buzzi, G. Carpineta
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Abstract

During drilling of three exploration wells challenging conditions encountered, such as temperatures up to 180°C, interbedded highly reactive shales/silts, formation pressures which required mud weights up to 2.35 sg and narrow margin between pore and fracture gradients, posed a host of technical, logistical and cost challenges to Eni activities. These conditions required an accurate drilling fluids design to maximize operational efficiency and to minimize the risks related to such an extreme environment. Technical demands were particularly critical since the reactive shale formations had historically proved to be difficult to inhibit when drilled with Water Based Mud and might have caused swelling, tight hole, sticky wireline runs, bit-balling and accretion that could have resulted, among other issues, in low penetration rates (ROP). The formation nature coupled with ECD (Equivalent Circulation Density) constraints due to the high mud weight required to cope with high pore pressure, which also caused high mud rheology readings, were therefore the main limits to be overcome to achieve the well objectives. A tailored drilling fluid program was thus proposed which consisted of an inhibitive HPWBM (High Performance Water Based Mud) that could be converted to an HT-HPWBM, (High Temperature-High Performances Water Based Mud) while drilling, to cross the deeper and hotter sections of the well. This fluid was specifically engineered and optimized after each well in order to contain high concentration of a combination of monovalent salts to guarantee inhibition and reduce solids loading, dedicated polyamine shale inhibitor and fluid loss additives to minimize API/HPHT filtrate and filter cake thickness with the aim to reduce shale water invasion throughout the drilling campaign, graphite to minimizes fluid invasion and fracture propagation and ROP (Rate Of Penetration) enhancer continuously injected using dedicated pump to act as anti-balling and anti-accretion additive. The achieved results were drilling targets delivered safely, on time and with good overall fluid performances which either reduced or eliminated many of the challenges seen in offset wells, including: no barite sag, rheology stability, and stable long-term mud properties and wellbore conditions even during extended formation logs acquisitions. This paper covers the design, execution and accomplishments of the water-based drilling fluids employed on three HP/HT wells drilled, together with all of the lessons learned captured, highlighting the evolution of these systems to reach a step-change in terms of performances in such a harsh environment.
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在极端高温高压条件下,使用高压水轮机钻井海上油井
在三口勘探井的钻井过程中,遇到了一些具有挑战性的条件,例如温度高达180°C,层间存在高反应性的页岩/淤泥,地层压力要求泥浆重量高达2.35 sg,孔隙和裂缝梯度之间的边界很窄,这些都给埃尼公司的活动带来了一系列技术、后勤和成本方面的挑战。这些条件需要精确的钻井液设计,以最大限度地提高作业效率,并最大限度地降低与这种极端环境相关的风险。技术要求尤其关键,因为在使用水基泥浆钻井时,反应性页岩地层很难抑制,并且可能会导致膨胀、井眼紧致、电缆粘连、钻头滚球和膨胀等问题,这些问题可能导致低钻速(ROP)。因此,地层性质和ECD(等效循环密度)的限制(由于应对高孔隙压力需要高泥浆比重,这也会导致高泥浆流变性读数)是实现井目标需要克服的主要限制。因此,提出了一种定制的钻井液方案,其中包括一种抑制性HPWBM(高性能水基泥浆),可以在钻井时转化为高温-高性能水基泥浆),以穿过井的更深和更热的部分。该钻井液在每口井后经过专门设计和优化,以含有高浓度的一价盐组合,以保证抑制作用和减少固体载荷,专用的多胺页岩抑制剂和滤失剂添加剂,以最大限度地减少API/HPHT滤液和滤饼厚度,旨在减少整个钻井过程中页岩水的侵入。石墨可以最大限度地减少流体侵入和裂缝扩展,并使用专用泵连续注入ROP(钻速)增强剂,作为防球和防吸积添加剂。取得的成果是安全、及时地完成钻井目标,并具有良好的整体流体性能,减少或消除了邻井中的许多挑战,包括:无重晶石凹陷,流变性稳定,即使在长时间的地层测井采集期间,长期稳定的泥浆性质和井眼条件。本文介绍了在三口高温高压井中使用水基钻井液的设计、实施和成果,以及所获得的经验教训,重点介绍了这些系统在如此恶劣环境下的性能变化。
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