Step Change in Delivering High Fracture Wells by Eliminating Expandable Liner

Ali Salim Al Sheidi, Hatim Abdul Raheem Al Balushi, Zahra Al Rawahi, Yahya Hilal Al Amri, D. Mansur
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Abstract

This paper discusses the journey of finding alternate solution for having to run the Expandable Liners operations in the Fahud field which is already one of the most operationally challenging fields to drill in Petroleum Development Oman (PDO), due to the presence of a gas cap in highly fractured and depleted limestone formations with total losses and the need for dynamic annulus fill to maintain primary well control. In Fahud field, there is a highly reactive shale formation within reservoir limestone formation. Due to high likelihood of total losses, this shale formation caused bore hole instability challenges while drilling. And with more depletion took place, the challenges became more frequently to occurred. In 2001, expandable tubular liner was introduced to address these bore hole instability challenges while drilling highly reactive shale formation under total losses in the 8-1/2″ section. The use of expandable technology was sustained over the years in delivering all wells drilled to traverse this reactive shale column. Previously before 2001, wells used to have fat well design by installations of extra casing to cover the formations and problematic zones. Also, Fahud field was not depleted as it is now, and the problematic shale zone used to drill by normal conventional way without any issue using inhibition frilling fluid. Petroleum Development Oman (PDO) identified expandable liner as a preferred alternative to ‘Fat’ well design. The ‘Fat’ well design would have a large hole size through potential loss zones, resulting in unmanageable volumes of water being required. Expandable liber was fast-tracked - various technical options were considered by PDO with expandable liner technology being identified as the best solution to address the problem of the shale column. However, the deployment of expandable tubular liner technology supported to drill & deliver wells but also has its associated challenges incurring additional time and cost with reasonable installation and low operations success rate due to number of operational steps required prior and after the expandable liner. Adding to that, all the challenges associated with each step. The installation of the expandable liner required eight operational steps with multiple trips to under-ream, install and expand, cement, caliper log and drill through the liner which increased the probability of something going wrong due to mainly the challenging well profile and multiple operations steps. The expandable liners technology was required when the target formation was below the reactive shale interval. The team carried out a study of previous deployments with the intention of identifying well planning and operational contributors to the installation difficulties and operations failures, with a view of eliminating the need for installing the expandable liner and drilling the well to the desired landing point at designed section total depth. Most of the unsuccessful installation rates were observed to be prevalent in wells with high angle applications. The team also observed that the length of the hole interval below the reactive shale column contributed to the number of unsuccessful installation and operational failure rates recorded. The team evaluated the impact of reducing well inclination on the ability to deliver the hole section without installing the expandable liner. Subsequently the team developed an optimization plan which involved keeping all build activities above and below the problematic interval and holding tangent at less than 45° inclination while drilling across the problematic shale. In conclusion, in 2020 the team delivered six wells (90% of wells crossing reactive shale formation delivered) using the above described approach and traversed the historically highly reactive shale formation without installing expandable liners. This resulted in a 20% reduction in total well construction time and 17% reduction in total well delivery cost per well. In addition to the time and cost saving, with the new approach, described in this paper, less water needed to be pumped for dynamic fill. This allowed bringing the wells quicker to production, thus reducing oil deferment.
通过消除膨胀尾管,实现高压裂井交付的阶梯式变化
Fahud油田是阿曼石油开发公司(PDO)钻井作业中最具挑战性的油田之一,由于在高度裂缝和枯竭的石灰岩地层中存在气顶,并且存在完全漏失,需要动态环空填充来维持主要的井控,因此Fahud油田必须寻找可膨胀尾管作业的替代解决方案。在Fahud油田,储层灰岩组中存在高活性的页岩组。由于极有可能发生漏失,这种页岩地层在钻井过程中会造成井眼不稳定性的挑战。随着消耗的增加,挑战也越来越频繁地发生。2001年,在8-1/2″井段全漏失的情况下,在钻井高活性页岩地层时,引入了可膨胀管尾管,以解决这些井眼不稳定性问题。多年来,所有钻过活性页岩柱的井都采用了可扩展技术。在2001年之前,通常的井设计是通过安装额外的套管来覆盖地层和问题层。此外,Fahud油田并没有像现在这样枯竭,问题页岩区使用常规方法钻井,没有任何问题,使用了抑制打钻液。阿曼石油开发公司(PDO)将可膨胀尾管确定为“Fat”井设计的首选替代方案。“Fat”井设计的井眼尺寸较大,可以穿过潜在的漏失层,因此需要大量的水。可膨胀尾管得到了快速跟踪,PDO考虑了各种技术方案,最终确定可膨胀尾管技术是解决页岩柱问题的最佳解决方案。然而,可膨胀管尾管技术的部署支持钻井和交付井,但由于在可膨胀尾管之前和之后需要许多操作步骤,因此在合理安装时需要额外的时间和成本,并且作业成功率较低,因此存在相关挑战。除此之外,每一步都有挑战。可膨胀尾管的安装需要8个操作步骤,包括多次起下钻,包括扩眼、安装和膨胀、固井、井径测井和钻穿尾管,这增加了出现问题的可能性,主要是由于具有挑战性的井型和多个操作步骤。当目标地层低于活性页岩层段时,需要使用膨胀尾管技术。该团队对之前的部署进行了研究,旨在确定导致安装困难和操作失败的井规划和操作因素,以期消除安装可膨胀尾管的需要,并在设计的段总深度上钻到期望的着陆点。大多数不成功的安装率普遍存在于大斜度井中。该团队还观察到,活性页岩柱下方的井段长度是导致安装失败次数和作业失败率的原因之一。该团队评估了在不安装膨胀尾管的情况下降低井斜对井段交付能力的影响。随后,该团队制定了一个优化计划,包括在有问题的段段上下进行所有建造活动,并在钻过有问题的页岩时保持切线倾角小于45°。总而言之,在2020年,该团队使用上述方法交付了6口井(90%的井穿过反应性页岩地层),并且在没有安装可膨胀尾管的情况下穿越了历史上反应性很强的页岩地层。这使得总施工时间减少了20%,每口井的总交付成本减少了17%。采用本文所述的新方法,除了节省时间和成本外,还减少了动态充填所需的抽水。这使得油井能够更快地投产,从而减少了产油延迟。
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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