Water Injectivity Decline in an Omani Oil Field: Possible Causes and Mitigation

Ibtisam Al-Shabibi, J. Naser, R. Al-Maamari, M. Karimi, A. Al-Salmi, Hajir Al-Qassabi
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Abstract

Treated oilfield produced water is injected into reservoirs to increase the depleted reservoir pressure and enhance oil recovery. The main challenges in this process are injectivity decline and high tubing head pressure (THP) which is most often caused by the deterioration in the reservoir permeability. This investigation focuses on identifying root causes behind injectivity decline in a sandstone reservoir in Oman. Acid stimulation has been applied to improve the reservoir permeability, but it turned out to be non-feasible due to frequency of such interventions and high associated costs. Several factors, such as injection water quality and reservoir mineralogy, can adversely affect the reservoir permeability and cause injectivity decline. Various approaches to tackle this problem have been adopted in this study including; water analysis, scale modeling, formation damage simulation and core flooding experiments. The scale modeling results showed compatibility between formation and injection water where the scaling potential for both barium sulphate (BaSO4) and calcium carbonate (CaCO3) scales were unlikely to form at reservoir conditions. Injection water analysis showed that, in some cases total suspended solids and oil content exceeded the recommended limit, which might contribute to reservoir permeability decline. XRD analysis of the reservoir core samples revealed that fines and expansive clays are the main components. The core flooding experiments demonstrated that reservoir pore throats get plugged due to two main factors; the suspended solid particles present in the injected water and swelling clays present in reservoir core samples. The formation damage simulator showed that fines migration and clay swelling are the two main possible formation damage mechanisms. To enhance the water injectivity process, the use of a clay swelling inhibitor along with a filtration system to remove suspended particles in the injected water are recommended for the reservoir studied.
阿曼油田注水能力下降:可能原因及缓解措施
将处理后的油田采出水注入储层,以增加衰竭储层压力,提高采收率。这一过程的主要挑战是注入能力下降和油管头压力(THP)升高,这通常是由储层渗透率下降引起的。本次调查的重点是确定阿曼砂岩油藏注入能力下降的根本原因。为了提高储层渗透率,已经采用了酸增产措施,但由于此类干预措施频繁且相关成本高,因此不可行。注入水质和储层矿物学等因素会对储层渗透率产生不利影响,导致注入能力下降。本研究采用了各种方法来解决这个问题,包括:水分析、水垢建模、地层损害模拟和岩心驱油实验。结垢模拟结果表明,在油藏条件下,硫酸钡(BaSO4)和碳酸钙(CaCO3)结垢潜力不太可能形成的情况下,地层与注入水之间存在相容性。注水分析表明,在某些情况下,总悬浮固体和含油量超过了建议限值,这可能导致储层渗透率下降。对储层岩心样品进行XRD分析,发现其主要成分为细粒和膨胀粘土。岩心驱替实验表明,储层孔喉堵塞主要由两个因素造成;注入水中存在悬浮固体颗粒,储层岩心样品中存在膨胀粘土。地层损伤模拟结果表明,细粒运移和粘土膨胀是两种可能的地层损伤机制。为了提高注水能力,建议在研究的油藏中使用粘土膨胀抑制剂和过滤系统来去除注入水中的悬浮颗粒。
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