Design of Underbalanced Drilling Program to Improve Wells Productivity Index and Characterize Multi Layered Tight Oil Reservoir in an Environmentally Sensitive Field

Jose Ardila Jaimes, Adnan Al Menhali, Sultan Al Yamani, Ayoub Hadj-moussa, M. Saleh
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引用次数: 3

Abstract

Reservoir-A is a tight oil reservoir (<1 mD) with four subzones. Production from existing wells in this reservoir has been low due to the reservoir tightness (< 500 BPD), dual phases injection program is implemented to support the wells productivity and to increase the overall recovery factor (RF). Building on the success of the Underbalance Drilling and completion technology (UBD) in similar tight reservoirs in ADNOC Onshore fields, the asset team decided to drill one pilot well (Well-1) to minimize the formation damage, practicaly increasing the Productivity Index (PI) and to measure the individual contribution of each subzone to the total well production in order to optimize the lateral length in each subzone to reduce the Unit Technical Cost (TUC). A transient hydraulic flow modelling software was utilized to study how to achieve underbalance conditions and to estimate the reservoir production during the UBD operations The UBD mythology proposed to drill Well-1 includes using crude native oil as a drilling fluid instead of Water Based Mud to minimize the formation damage. Membrane Nitrogen was chosen as a gaseous phase to reduce the effective Bottom Hole Pressure (BHP) below the reservoir pressure to create underbalance condition allowing the reservoir to flow through a four phases separation package that allows separating produced oil and gas to enable reservoir characterisation. To eliminate the need to kill the well during tripping and completion, a Downhole Deployment Valve (DDV) was proposed to be rung on a retrievable tie back casing string that extends from the top of the liner to surface. A transient hydraulic flow modelling software was utilized to study how to achieve underbalance conditions and to estimate the reservoir production during the UBD operations. The engineering evaluation study concluded that UBD is feasible on Well-1, it provided the required UBD equipment capacities to drill Well-1 maintaining UB condition during drilling, tripping and completion operations. A detailed UBD program was compiled by ADNOC onshore and Weatherford teams taking into consideration different anticipated scenarios and contingency plans. Weatherford set up classroom and on-site UBD training for the teams involved in the operation, including ADNOC onshore, rig contractor and other services providers. Having Well-1 in a cluster field adds complexity to the UBD operations and raises new HSE concerns. Moreover, the field exists in environmentally sensitive place close to urban areas and surrounded by sea and mangrove trees. The project team set a detailed HSE plan for the UBD operations on Well-1 involving all stakeholders. A three days HAZID/HAZOP workshop was conducted to identify potential hazards by applying what-if approach to ensure that adequate safeguards are in place before starting the UBD operations. The uniqueness of Well-1 UBD design lies in its comprehensiveness in addressing multiple operational scenarios and in its ability to address complex HSE scenarios to safely and successfully unlock the true potential of a tight oil reservoir which has been witnessing low production rates. The outcomes of the UBD pilot well (Well-1) will be closely studied and might change the field development plan.
环境敏感油田欠平衡钻井方案设计,提高油井产能指标,刻画多层致密油储层
a储层为致密油储层(小于1 mD),分为4个子层。由于储层致密(< 500 BPD),该储层现有油井的产量一直很低,因此实施了两阶段注入计划,以支持油井的产能并提高总体采收率(RF)。基于ADNOC陆上油田类似致密储层的欠平衡钻井完井技术(UBD)的成功,资产团队决定钻一口试验井(井1),以最大限度地减少地层损害,实际提高生产力指数(PI),并测量每个子层对油井总产量的贡献,从而优化每个子层的横向长度,以降低单位技术成本(TUC)。利用瞬态水力流动建模软件来研究如何在UBD作业期间达到欠平衡状态,并估算储层产量。UBD方案建议钻井1号井使用原生原油作为钻井液,而不是水基泥浆,以尽量减少对地层的损害。选择氮气膜作为气相,将有效井底压力(BHP)降低到油藏压力以下,从而产生欠平衡状态,使油藏能够通过四相分离包流动,从而分离出产出的石油和天然气,从而实现油藏表征。为了避免在起下钻和完井过程中进行压井作业,设计人员将井下部署阀(DDV)安装在可回收的回扎套管上,从尾管顶部一直延伸到地面。利用瞬态水力流动建模软件,研究了在UBD作业过程中如何达到欠平衡状态,并对储层产量进行了估算。工程评估研究得出结论,UBD在1号井上是可行的,它提供了所需的UBD设备能力,可以在钻井、起下钻和完井作业中保持1号井的UB状态。ADNOC陆上和威德福团队考虑了不同的预期情景和应急计划,编制了详细的UBD计划。威德福为参与作业的团队,包括ADNOC陆上、钻机承包商和其他服务提供商,建立了教室和现场UBD培训。在集群油田中使用Well-1增加了UBD操作的复杂性,并引发了新的HSE问题。此外,该领域存在于靠近城市地区的环境敏感地区,周围有海洋和红树林。项目团队为1号井的UBD作业制定了详细的HSE计划,涉及所有利益相关者。进行了为期三天的HAZID/HAZOP研讨会,通过采用假设方法来识别潜在的危害,以确保在开始UBD操作之前有足够的防护措施。Well-1 UBD设计的独特之处在于,它能够全面解决多种操作场景,并能够解决复杂的HSE问题,从而安全、成功地释放致密油油藏的真正潜力,而致密油油藏一直处于低产量状态。UBD试验井(井1)的结果将被密切研究,并可能改变油田开发计划。
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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