从油藏到油藏:适用于注水管理和增产的集成工作流程

Mohamed Abdel-Basset, J. Rodriguez, K. Slimani, Mostafa Afifi, M. Jamal, Mariam Al-Shuaib
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引用次数: 0

摘要

由于相关的动态变化和不确定性,综合解决方案对于制定水驱成熟油藏的规划非常重要。油藏和油田的管理需要作为一个综合系统来处理,因此需要多学科的方法。本文展示了综合多学科团队如何开发了几个工作流程,包括水驱管理、增产和最大限度地提高北科威特资产油藏的经济采收率。开发了许多用于水驱和生产优化的集成工作流程。主要集成工作流程如下:PVT属性工具:旨在根据趋势和现有数据覆盖范围,考虑区域和垂直变化,估计整个储层的流体属性。机会图:结合了最新的油藏压力和流体特性,可以根据开发策略快速确定有机会增加/减少注入或产量的区域。水驱模式/分段审查工作流程和允许使用的工具:该集成分析工作流程适用于基于地质分布和/或水力通信的预定义油藏模式或分段,包括几种工具,如生产和注入趋势分析、评估好水和坏水的诊断图、霍尔图、油藏压力数据、示踪剂数据、盐度变化和泵入口压力趋势。每层的地质分析(横截面、井相关性、砂层厚度图)都被整合到每个模式/段的评估中,以支持储层的连通性(或缺乏连通性)。计算瞬时VRR和累计VRR,并与总体开发策略和注水效率进行比较。开发了其他子工作流程来改善和管理水驱性能,如水再循环工具和流线型扇区建模仿真。结构化集成的主动生产和ESP优化工作流程:生产优化是一个不断迭代的过程(周期),以提高产量,特别是在成熟油田。该工作流程有助于识别生产优化的机会,通过积极主动的方法专注于流动井和无钻机干预,以应对生产挑战并实现生产目标。利用非均质性指数(HI)方法可以快速显示产量增加的机会。这提供了家庭型问题,然后用类型井表示,以便进行详细诊断。持续应用和嵌入这种结构化集成工作流程作为标准最佳实践,在提高对油藏性能的理解方面具有重要价值,从而实现智能注入(需要的地点和时间)和智能生产(最佳健康点)。这可以在多学科团队领域的油藏、分段、井网和单井水平上进行。最终的结果体现在水驱管理的不断改进(注入效率、垂直和面积波及效率、通过改变流线波及新油)。这反过来又有助于通过最佳油藏管理方法显著增加产油量和可采储量。这些集成的工作流程非常友好,可以应用于不同的油藏和油田。以结构化、一致和主动的方式应用这些工作流程,可以在最大限度地提高产量和可采储量方面改善整体资产管理。
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Reservoir to Tank: Fit for Purpose Integrated Workflows for Waterflood Management and Production Enhancement
Integrated solutions are important to formulate plans for mature reservoirs under waterflooding due to related dynamic changes and uncertainties. The reservoir and field management need to be handled as an integrated system, and therefore needing a multidisciplinary approach. This paper demonstrates how the integrated multidisciplinary team has developed several workflows covering water-flooding management, production enhancement and maximizing the economic recovery of reservoirs in the North Kuwait asset. Many integrated workflows were developed for water flooding and production optimization. The main integrated workflows that were implemented are as follows: PVT Properties Tool: is designed to estimate the fluid properties throughout the reservoir taking into consideration areal and vertical variations based on trends, and existing data coverage. Opportunity Maps: is a combination of updated reservoir pressure and fluids properties to provide a fast way to identify areas of opportunity to increase/decrease injection or production based on the development strategy. Waterflooding Patterns/segments Review Workflow and Allowable Tool: This integrated analytical workflow applied on predefined reservoir patterns or segments based on geological distribution and/or hydraulic communication, includes several tools like the analysis of production and injection trends, diagnostic plots to assess good vs bad water, Hall plots, Reservoir Pressure data, tracer data, salinity changes and pump intake pressure trends. Geological analysis (cross-sections, well correlations, sand thickness maps) for each layer are integrated in each pattern/segment review to support reservoir connectivity (or the lack thereof). Instantaneous and cumulative VRR are calculated and compared with the overall exploitation strategy and water injection efficiency. Other sub-workflows were developed to improve and manage waterflooding performance such as water recirculation tool and streamline sector modeling simulation. Structured integrated proactive production and ESP optimization workflows: Production optimization is a continuous iterative process (cycles) to improve production, especially in mature fields. This workflow facilitates the identification of opportunities for production optimization with a pro-active approach focusing on flowing wells and rig-less interventions to tackle production challenges and achieve production targets. The Heterogeneity Index (HI) process is utilized to rapidly demonstrate production gain opportunities. This provides family-type problems that are then represented by type-wells for detailed diagnostics. Continuous application and embedding of such structured integrated workflows as standard best practices, deliver significant value in terms of improving the understanding of reservoir performance in order to inject smart (where and when required) and produce smart (sweet healthy spots). This is done on reservoir, segment, pattern and individual well levels in multidisciplinary team domains. The ultimate results reflected in continuous improvement in waterflooding management (injection efficiency, vertical and areal sweep efficiency, sweep new oil via changing streamlines). This in turn contributes to significant added oil gain and recoverable reserves with best practices reservoir management. These integrated workflows are user friendly and can be applied across different reservoirs and fields. The application of such workflows in a structured, consistent and proactive approach improves the overall asset management in terms of maximizing production and recoverable reserves.
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