Kinetics of In-Situ Calcium Magnesium Carbonate Precipitation and the Need for Desulfation in Seawater-Flooded Carbonate Reservoirs

SPE Journal Pub Date : 2024-07-01 DOI:10.2118/221486-pa
Ali M. Al-Behadili, E. Mackay
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Abstract

Mixing of incompatible injection and formation brines leads to the deposition of inorganic sulfate scales such as barite, celestite, and anhydrite in and around production wells. This process is well documented in seawater-flooded clastic reservoirs. One technique to avoid the resulting formation damage is to remove sulfate from seawater before injection using nanofiltration; however, this process is costly. We identify in this paper that it may not always be necessary in higher-temperature carbonate reservoirs. In this paper, we describe the use of reactive transport reservoir simulation to investigate the impact of carbon dioxide (CO2) partitioning and changes in pH, ionic concentrations, and temperature on carbonate reactivity and the sulfate scaling risk in waterflooded carbonate reservoirs. Dissolution and precipitation of calcite, dolomite, gypsum, anhydrite, barite, and celestite are all modeled and found to be coupled through (various) common ion effects. The produced brine compositions are used to calculate the saturation ratios (SRs) and mass of precipitate that may form in the production system. Sensitivity to mineral reaction kinetics, particularly for the dolomite reactions, is accounted for. Results identify that there is a strong relationship between calcite dissolution and dolomite (or other calcium/magnesium carbonate mineral) precipitation reactions, which drive each other and are affected by the availability of CO2 in the residual oil phase. This evolves over time, and as the thermal front propagates, impacts the concentration of calcium and magnesium in the brines traversing the reservoir. Temperature changes around the injection wellbore impact CO2 and mineral solubilities. The concentration of calcium in the displaced brine mix is thus determined more by contact with rock and temperature than by mixing between injection and formation brines. Depending on location relative to the thermal front, this may lead to gypsum or anhydrite precipitation, thereby stripping sulfate out of the injection brine. Thus, the sulfate scaling risk at the production wells is significantly reduced by this sulfate depletion process: The sulfate is stripped out of the seawater as it warms up in the reservoir before it mixes extensively with the formation water and significantly before any mixture of the two brines reaches the production zone. Thus, any loss of permeability is restricted to deep within the reservoir, where the pore volume (PV) that can accommodate mineral precipitation is very large. In this work, we identify that for carbonate reservoirs above 90–100°C, stripping of sulfate due to coupled mineral reactions may reduce or eliminate the need for use of a sulfate reduction plant (SRP). The process is modeled for the first time, accounting for the impact of CO2 partitioning and thermal front propagation. Knowledge of the kinetics of calcium/magnesium carbonate precipitation is shown to be critical in predicting the extent of sulfate depletion.
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海水淹没碳酸盐储层中碳酸钙镁原位沉淀动力学及脱硫需求
不相容的注入盐水和地层盐水的混合会导致无机硫酸盐鳞片(如重晶石、天青石和无水石膏)在生产井内和周围沉积。这一过程在海水淹没的碎屑岩储层中得到了很好的记录。避免对地层造成损害的一种技术是在注入前使用纳滤技术去除海水中的硫酸盐,但这一过程成本高昂。我们在本文中指出,在温度较高的碳酸盐岩储层中,可能并不总是有必要这样做。在本文中,我们介绍了如何利用反应输运储层模拟来研究二氧化碳(CO2)分配以及 pH 值、离子浓度和温度变化对碳酸盐反应性和注水碳酸盐储层中硫酸盐缩放风险的影响。对方解石、白云石、石膏、无水石膏、重晶石和天青石的溶解和沉淀都进行了建模,发现它们通过(各种)共同离子效应耦合在一起。生成的盐水成分可用于计算生产系统中可能形成的沉淀物的饱和度(SR)和质量。考虑了矿物反应动力学的敏感性,特别是白云石反应。结果表明,方解石溶解和白云石(或其他碳酸钙/镁矿物)沉淀反应之间存在密切关系,它们相互驱动,并受到残余油相中二氧化碳供应量的影响。随着时间的推移,随着热锋面的扩展,这将影响穿越储层的盐水中钙和镁的浓度。注入井筒周围的温度变化会影响二氧化碳和矿物溶解度。因此,盐水混合物中的钙浓度更多取决于与岩石的接触情况和温度,而不是注入盐水和地层盐水之间的混合情况。根据与热前线的相对位置,这可能会导致石膏或无水石膏沉淀,从而将硫酸盐从注入盐水中剥离出来。因此,生产井的硫酸盐结垢风险可通过这种硫酸盐贫化过程大大降低:海水在储层中升温时,在与地层水广泛混合之前,以及在两种盐水的任何混合物到达生产区之前,硫酸盐就已被剥离。因此,任何渗透率的损失都仅限于储层深处,因为那里能够容纳矿物沉淀的孔隙体积(PV)非常大。在这项工作中,我们发现对于温度高于 90-100°C 的碳酸盐岩储层,耦合矿物反应导致的硫酸盐剥离可能会减少或消除使用硫酸盐还原厂(SRP)的必要性。首次对这一过程进行了建模,考虑了二氧化碳分区和热前沿传播的影响。碳酸钙/镁沉淀动力学知识对于预测硫酸盐耗竭程度至关重要。
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