Water Compatibility and Scale Risk Evaluation by Integrating Scale Prediction of Fluid Modelling, Reservoir Simulation and Laboratory Coreflood Experiment for a Giant Oil Field in Offshore Abu Dhabi

Y. Nomura, M. Almarzooqi, K. Makishima, Jon Tuck
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引用次数: 2

Abstract

An offshore field is producing oil from multiple reservoirs with peripheral water injection scheme. Seawater is injected through a subsea network and wellhead towers located along the original reservoir edge. However, because its OWC has moved upward, wells from wellhead towers are too remote to inject seawater effectively, with some portion going to the aquifer rather than oil pool. Therefore, it is planned to migrate injection strategy from peripheral to mid-dip pattern. An expected risk is scaling by mixing incompatible seawater and formation water. Such risk and mitigation measures were evaluated. To achieve the objective, the following methodology was applied: 1. Scale modelling based on water chemical analysis. 2. Define scale risk envelope with three risk categories 3. Tracer dynamic reservoir simulation to track formation water, connate water, dump flood water, injection seawater and treated seawater. 4. Review the past field scale history data 5. Coreflood experiment to observe actual phenomena inside the reservoir with various parameters such as water mixing ratio, sulphate concentration, temperature and chemical inhibitor 6. Consolidate all study results, conclude field scale risk and impact of mitigation measures. Scale prediction modelling, verified by coreflood tests, found that mixing reservoir formation water and injection seawater causes a sulphate scale risk, with risk severity depending on mixing ratio and sulphate concentration. Reservoir temperature was also found to correlate strongly with scale risk. Therefore, each reservoir should have different water management strategy. Scale impact is limited in the shallower wide reservoir with cooler reservoir temperature. Such reservoir should therefore have mid-dip pattern water injection to avoid low water injection efficiency with possible scale inhibitor squeezing as a contingency option. On the other hand, deeper reservoir has higher risk of scaling due to its higher temperature, causing scale plugging easily in reservoir pores and production wells. For such reservoir, peripheral aquifer water injection, treated low-sulphate seawater with sulphate-removal system, or no water injection development concept should be selected. By using modelling and experiment to quantify the scale risk over a range of conditions, the field operator has identified opportunities to optimize the water injection strategy. The temperature dependence of the scale risk means, in principal, that different injection strategy for each reservoir can minimize flow assurance challenges and maximize return on investment in scale mitigation measures.
阿布扎比海上某大油田流体模型、油藏模拟和室内岩心驱油实验相结合的水相容性及结垢风险评价
某海上油田采用外围注水方案从多个油藏采油。海水通过海底网络和位于原始油藏边缘的井口塔注入。然而,由于其OWC已经向上移动,井口塔的油井距离太远,无法有效注入海水,部分海水进入含水层而不是油藏。因此,计划将注入策略从外围转向中倾角模式。预期的风险是混合不相容的海水和地层水而结垢。对这些风险和缓解措施进行了评估。为实现这一目标,采用了下列方法:基于水化学分析的比例模型。2. 用三个风险类别定义规模风险包络。示踪剂动态油藏模拟,跟踪地层水、原生水、倾驱水、注入海水和处理海水。4. 回顾过去的油田规模历史数据。通过混水比、硫酸盐浓度、温度、化学抑制剂等参数,观察储层内部的实际现象。整合所有研究结果,总结现场规模的风险和缓解措施的影响。通过岩心注水试验验证的结垢预测模型发现,地层水与注入海水混合会产生硫酸盐结垢风险,其风险程度取决于混合比例和硫酸盐浓度。储层温度也与结垢风险密切相关。因此,每个水库应该有不同的水管理策略。在储层温度较低的浅宽储层中,结垢影响有限。因此,这种油藏应该采用中倾角注水模式,以避免低注水效率,并可能采用阻垢剂挤压作为应急选择。另一方面,深层储层温度较高,结垢风险较高,容易造成储层孔隙和生产井的结垢堵塞。对于此类油藏,应选择外围含水层注水、采用除硫系统处理过的低硫酸盐海水或不注水开发方案。通过建模和实验来量化一系列条件下的结垢风险,油田运营商已经确定了优化注水策略的机会。原则上,温度对结垢风险的依赖性意味着,针对每个储层的不同注入策略可以最大限度地减少流动保障挑战,并最大化降低结垢措施的投资回报。
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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