First Deployment of a Novel Advanced Tracers System for Improved Waterflood Recovery Optimization

Hooisweng Ow, Sehoon Chang, Gawain Thomas, Rena Shi, Wei Wang, Hsieh Chen, M. Poitzsch, A. Abdel-Fattah
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引用次数: 5

Abstract

We are developing an integrated, real-time system for deploying Advanced Tracers cost-effectively in a ubiquitous and potentially long-term way. This campaign is for the sake of increasing the oil recovery factor in large waterflooded reservoirs through improved optimization of the water injection for oil production. This paper explains key features of this novel system and reports main results from the ongoing field test of our second-generation tracer material and detection methodology. Existing inter-well tracers require elaborate laboratory processing for analysis and are not compatible with ubiquitous or real-time deployment. Additionally, conventional tracer material and service costs are not economically viable for widespread and long-term deployment; also, available material barcodes compatible with carbonate reservoirs may be inadequate to monitor dozens of wells simultaneously. Our system addresses all of these inadequacies using novel materials and detection methods, with detailed modeling studies providing strong justification of the financial benefit of this tracer deployment through quantification of increased oil recovery from waterflooded reservoirs. Key elements of this new inter-well Advanced Tracers system include: An optically-detectable tracer material that can in principle be detected in real-time or near real-time at low limits of detection (LODs), even in the presence of background oil in producing water by means of an intrinsic oil background-subtraction method. The material also has high mobility in high-salinity carbonate reservoirs.A rich palette of tracer barcodes (potentially 50 - 100 or more) to enable simultaneous injection and sampling in dozens of nearby wells.Modeling feasibility studies, performed on an ensemble of different reservoir geometries and with sensitivity analyses, showing that including routine inter-well tracer data along with injection and production rates improves the history match quality and therefore, the optimization of the water injection and oil extraction rates so as to achieve a few percent increase in net present values (NPV). Recent field tests of the detectability and discrimination of injected prototype tracer materials will be described. This work adapts novel technology development at the state of the art of modern nanotechnology and bioanalysis to the long-term reservoir stewardship objectives. The integrated, real-time tracer-detection system promises financial benefits through increased NPV and/or ultimate recovery factor via better optimization of water injection.
首次部署新型先进示踪剂系统,以提高水驱采收率
我们正在开发一种集成的实时系统,以经济有效的方式部署先进的示踪剂,无处不在,而且可能是长期的。该活动旨在通过优化注水采油,提高大型水淹油藏的采收率。本文解释了这种新系统的主要特点,并报告了我们的第二代示踪材料和检测方法正在进行的现场测试的主要结果。现有的井间示踪剂需要经过复杂的实验室处理才能进行分析,而且不适合普遍使用或实时部署。此外,传统的示踪剂材料和服务成本在经济上不适合广泛和长期部署;此外,与碳酸盐岩储层兼容的现有材料条形码可能不足以同时监测数十口井。我们的系统利用新型材料和检测方法解决了所有这些不足之处,详细的建模研究通过量化水淹油藏的采收率,为该示踪剂的经济效益提供了强有力的理由。这种新型井间先进示踪剂系统的关键要素包括:一种光学可探测示踪剂材料,原则上可以在低检测限(lod)下实时或近实时检测,即使在生产水中存在本底油的情况下,也可以通过本底油减法进行检测。该材料在高盐度碳酸盐岩储层中也具有高流动性。丰富的示踪条形码(可能有50 - 100个或更多),可以同时在数十口附近的井中进行注入和采样。建模可行性研究在不同油藏几何形状的集合上进行,并进行了敏感性分析,结果表明,将常规井间示踪剂数据与注入和生产速度相结合,可以提高历史匹配质量,从而优化注水和采油速度,从而实现净现值(NPV)增加几个百分点。本文将介绍最近对注入原型示踪材料的可探测性和识别性进行的现场试验。这项工作适应了现代纳米技术和生物分析的最新技术发展,以实现长期的油藏管理目标。集成的实时示踪检测系统通过更好地优化注水,提高了NPV和/或最终采收率,从而保证了经济效益。
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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