Use of Passive ICD and Swellable Packer for Successful Horizontal Well Completion in Unconsolidated Sand Stone Reservoir to Eliminate Sand Breakthrough Problem Having Active Aquifer Drive: A Detailed Case Study in Assam-Arakan Basin
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引用次数: 2
Abstract
Horizontal wells are superior over conventional wells in terms of production improvement due to increased reservoir contact. Despite this, these wells pose severe production challenges due to variations in permeability, reservoir pressure, reservoir fluid properties and frictional pressure drop along horizontal section. Preventing water/gas breakthrough, equalizing inflow with minimizing pressure loss, minimizing annular flow and heel-to-toe effect, delay non-uniform water progress, avoiding by-passed oil, increasing sweep efficiency and ultimate recovery are some of the primary challenges for gaining optimum advantages of horizontal wells. One of the promising technologies to address all these challenges is the application of advanced completions utilizing Passive inflow control device (ICD) with oil swellable packers.
The use of Passive Inflow Control Device (ICD) along with oil swellable packer in long horizontal wells drilled in unconsolidated sandstone reservoirs has helped alleviate premature water breakthrough /high water production and sand production. Passive inflow control devices (ICDs) are effective in terms of balancing production flow and delaying the onset of water production. Nevertheless, when gas and/or water breakthrough occurs, a passive ICD will allow production of the unwanted fluid along with usual production.
This paper discusses the detailed of Passive ICD design workflow and execution carried out to complete 6 nos. of horizontal wells of Oil India Limited in a reservoir having active aquifer drive considering challenges encountered due to uncertainty in permeability, water saturation, permeability distribution and saturation tables distribution. In the absence of dynamic reservoir analysis, offset well data analysis assisted in filling the data gaps by enabling geological and reservoir level understanding. The passive ICD were designed on the basis of Gamma Ray, Resistivity, NPHI (Neutron Porosity Log) and RHOB (Density Log) obtained during TLC logging. A Geological Model was constructed with certain gathered data and few Assumptions were made to obtain reservoir saturation and permeability. Moreover, in this paper an assessment is provided of the production performance review conducted over unconsolidated sandstone reservoirs developed with some horizontal wells equipped with Passive ICD completions compartmentalized with oil swellable packers versus other horizontal completions completed with conventional slotted liner completions.
As drilling and completion of horizontal wells are expensive, it was critical to identify the most-suitable Passive ICD completion design with the available dataset before attempting well completion. This was addressed through a customized workflow to design and compartmentalized the horizontal section utilizing the ICD and oil swellable packers for maximizing oil recovery and water/sand breakthrough problem elimination.
水平井由于增加了储层接触,在提高产量方面优于常规井。尽管如此,由于渗透率、储层压力、储层流体性质和水平段摩擦压降的变化,这些井的生产面临着严峻的挑战。防止水/气突破,平衡流入,最大限度地减少压力损失,最大限度地减少环空流动和脚跟到脚趾效应,延迟水的不均匀流动,避免旁溢油,提高波及效率和最终采收率是水平井获得最佳优势的一些主要挑战。解决所有这些挑战的一种很有前途的技术是采用带油膨胀封隔器的被动流入控制装置(ICD)的先进完井技术。在未固结砂岩油藏的长水平井中,采用被动流入控制装置(ICD)和油膨胀封隔器,有助于缓解过早见水/高出水和出砂的问题。被动流入控制装置(icd)在平衡生产流量和延迟产水开始方面是有效的。然而,当气体和/或水发生突破时,被动ICD将允许在正常生产的同时生产不需要的流体。考虑到渗透率、含水饱和度、渗透率分布和饱和度表分布的不确定性所带来的挑战,本文详细讨论了Oil India Limited在含水层活动驱动油藏中完成6口水平井的被动式ICD设计工作流程和执行情况。在缺乏动态油藏分析的情况下,通过对地质和油藏水平的了解,邻井数据分析有助于填补数据空白。无源ICD是根据在TLC测井中获得的伽马射线、电阻率、中子孔隙度测井(NPHI)和密度测井(RHOB)进行设计的。利用收集到的一定数据,建立了一个地质模型,并对储层饱和度和渗透率进行了较少的假设。此外,本文还对未固结砂岩油藏的生产性能进行了评估,其中一些水平井采用了可膨胀封隔器的被动ICD完井,而另一些水平井则采用了常规的开槽尾管完井。由于水平井的钻井和完井成本高昂,因此在尝试完井之前,利用现有数据集确定最合适的被动ICD完井设计至关重要。通过定制的工作流程,利用ICD和油膨胀封隔器设计和划分水平段,以最大限度地提高采收率,消除水/砂突破问题。