Optimization of CO-WAG and Calcite Scale Management in Pre-Salt Carbonate Reservoirs

Day 1 Tue, October 29, 2019 Pub Date : 2019-10-28 DOI:10.4043/29823-ms

H. Rodrigues, E. Mackay, D. Arnold, Duarte Silva

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引用次数: 4

Abstract

CO2-WAG (Water-Alternating-Gas) has been applied in offshore Brazilian oilfields to improve recovery rates and mitigate the environmental impact that venting produced CO2 would bring. Although CO2 is highly miscible in oil under these reservoirs conditions, this gas is also extremely mobile, and its speciation in the aqueous phase drives reactions with carbonates that can cause severe inorganic scaling problems in production systems. It is crucial, therefore, to effectively design CO2-WAG operations for mobility control and, consequently, enhance reservoir performance, CO2 utilization and flow assurance. This paper addresses the design optimization of coupled CO2-EOR and storage operations applied to the Brazilian Pre-salt offshore context (reservoir properties, infrastructure, regulatory framework and economic characteristics), examining the trade-offs of project profitability, CO2 utilization and calcite scale risk. Several compositional simulations of miscible WAG scenarios were performed and key design parameters were optimized using statistical sampling and evolutionary algorithms. Aqueous and mineral reactions were included in the calculations, allowing us to quantify the calcite mass that can potentially deposit in the perforations and production system. The results showed how optimizing WAG operations can significantly improve the economics and the scale management of oil production from carbonate reservoirs. The optimal WAG design greatly increased incremental NPV per volume of CO2 stored and reduced calcite scale risk by simply rearranging the WAG slugs in a tapered manner. Here we demonstrate that this methodology can be used to determine how to recycle CO2 in a given field for better economics and lower carbon footprint, doing so without triggering calcite mineral deposition to the point of permanent jeopardy of production wells and facilities operability. Therefore, the workflow integrates critical challenges that are correlated, yet often addressed independently, supporting the complex decision-making of CO2-EOR operational design in carbonate reservoirs.

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盐下碳酸盐岩储层CO-WAG优化及方解石垢治理

CO2- wag(水-气交替)技术已应用于巴西近海油田，以提高采收率，减轻排放产生的二氧化碳对环境的影响。尽管在这些储层条件下，二氧化碳在石油中高度混溶，但这种气体也具有极强的流动性，其在水相中的形态会与碳酸盐发生反应，从而在生产系统中造成严重的无机结垢问题。因此，有效设计CO2- wag作业以控制流动性至关重要，从而提高油藏性能、二氧化碳利用率和流动保障。本文讨论了适用于巴西盐下海上环境(油藏性质、基础设施、监管框架和经济特征)的CO2- eor和存储耦合作业的设计优化，并研究了项目盈利能力、CO2利用率和方解石结垢风险之间的权衡。采用统计抽样和进化算法对混相WAG进行了成分模拟，优化了关键设计参数。计算中包括了水反应和矿物反应，使我们能够量化可能沉积在射孔和生产系统中的方解石质量。结果表明，优化WAG操作可以显著提高碳酸盐岩油藏的经济性和规模管理。优化的WAG设计极大地增加了每体积CO2储存的增量NPV，并通过简单地以锥形方式重新排列WAG段塞来降低方解石结垢风险。在这里，我们证明了这种方法可以用来确定如何在给定的油田中回收二氧化碳，以获得更好的经济效益和更低的碳足迹，这样做不会引发方解石矿物沉积，从而危及生产井和设施的可操作性。因此，该工作流程集成了相关的关键挑战，但通常是独立解决的，为碳酸盐岩储层CO2-EOR操作设计的复杂决策提供支持。

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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Day 1 Tue, October 29, 2019

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