碳酸盐岩水成分对地层损害及采收率影响的地球化学研究

I. Khurshid, E. Al-Shalabi, W. Alameri
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摘要

文献中已经报道了低矿化度/工程注水(LSWI/EWI)的几个优点,包括它能够以低成本提高石油采收率,并且对环境影响最小。然而,与这些技术相关的油藏工程问题,如地层损害和流体流动性控制,仍然是不确定的,也没有得到深入的研究。从地球化学角度探讨了水成分对地层损害及采收率的影响。将IPhreeqc地球化学引擎与Matlab进行耦合,同时求解油水多相流及相关地球化学反应。通过这种耦合技术,Phreeqc的地球化学功能成功地整合到多相流模拟器中。后者能够模拟地下多相储层的反应输运和地层损害。结果表明,在LSWI/EWI过程中,温度、硫酸盐浓度和注入水稀释度对地层溶解和沉淀有显著影响。硬石膏结垢是造成地层损害的主要控制固体。此外,碳酸盐岩储层应避免高温注水,因为高温可能导致硬石膏沉淀和地层破坏。这种析出是由于硬石膏在高温下溶解度低。水的稀释可以减少水垢的形成,而硫酸盐的添加可以增加水垢的沉淀。因此,应优化硫酸盐浓度作为润湿性改造剂,以提高采收率,同时避免对地层造成损害。此外,在选定的案例研究中,由于硫酸盐抽提导致硬石膏沉淀,预计石油产量将下降约23%。LSWI过程中的溶解和沉淀机制非常依赖于具体情况,受孔隙分布、原油/盐水/岩石成分和热力学条件的影响。因此,本研究的结果不能一概而论。
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Geochemical Investigation of Water Composition Effect on Formation Damage and Related Oil Recovery in Carbonates
Several benefits of low salinity/engineered water injection (LSWI/EWI) have been reported in the literature including its ability to increase oil recovery at low cost and with least environmental impact. However, the related reservoir-engineering problems to these techniques such as formation damage and fluid mobility control are still uncertain and have not been thoroughly investigated. This study investigates the effect of water composition on formation damage and the related oil recovery from a geochemical prospective. The study presents coupling of the IPhreeqc geochemical engine with Matlab to simultaneously solve the oil-water multiphase flow and the related geochemical reactions. Using this coupling technique, the geochemical capabilities of Phreeqc were successfully incorporated in a multiphase flow simulator. The latter enabled modeling of reactive transport and formation damage in subsurface multiphase reservoir. The results showed that the temperature, sulfate concentration, and dilution of injection water have a pronounced effect on formation dissolution and precipitation during LSWI/EWI. Also, anhydrite scale is the main controlling solid specie for formation damage. In addition, high temperature water injection should be avoided in carbonate reservoirs due to the likelihood of anhydrite precipitation and formation damage. This precipitation occurs because of the low-solubility of anhydrite at high temperature. Moreover, water dilution could decrease the scale formation while sulfate spiking might increase scale precipitation. Hence, sulfate concentration should be optimized as a wettability alteration agent to enhance oil recovery while avoid formation damage. Furthermore, as a sequence of anhydrite precipitation by sulfate spiking, oil production is expected to decrease by around 23% in the selected case study. The dissolution and precipitation mechanisms during LSWI are very case-dependent and subject of pore distribution, crude oil/brine/rock compositions, and thermodynamic conditions. Hence, the findings of this study cannot be generalized.
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