聚合物粘度:油藏中聚合物粘度随时间变化的认识及其预测方法

Katz Marquez, E. Roman
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引用次数: 1

摘要

在提高采收率(EOR)项目中,聚合物的流变特性是决定聚合物注入是否能有效提高油田产量的关键因素之一。由于该参数的测量及其在储层中的变化非常复杂,因此了解粘度行为的挑战依赖于实验室和现场测试,这成为解决这一问题的关键因素。这项研究是在Los Perales油田(Santa Cruz,阿根廷)的一个EOR项目的注入能力测试中进行的,测试的三口井具有不同的操作和地下条件,每天进行两次测试,每次测试30天,以获得足够的时间范围的数据。在储层条件下进行的实验室流变学测试中,主要目的是分析粘度随时间的变化,观察到两种不同的趋势:一种影响早期,另一种在后期变得突出。根据这些结果,开发了一个描述方程来预测粘度随时间的变化。该方程由三个项组成,包括热变化、化学降解和聚合物趋向的最终粘度。尽管该方程恰当地描述了实验室和现场的聚合物溶液,但存在相当大的差异,特别是当上述效应成为优势时。这种差异是由于用于混合物的水和在聚合物成熟或转移过程中可能加入的杂质造成的。由于使用的大多数数据都是从现场试验中获得的,因此强调了该方程在现场的应用。杂质被证明是至关重要的,特别是氧(O2)和硫化氢(H2S)的结合。它们的存在对渐近粘度有很大的影响,因此也建立了H2S含量与最终粘度之间的相关性。最后,分析了温度对粘度的影响。最终粘度和温度之间的相关性被发现,并用于将温度变化纳入预测,从而将在不同条件下进行的测量联系起来。本研究的主要优点是,该方程和相关关系可以在任何时候预测聚合物溶液的粘度。这样就可以在任何温度和杂质含量下通过常规测量来估计储层中的实际聚合物粘度。该方程的多功能性使其在面向EOR项目的行业中变得新颖和有用。
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Polymer Viscosity: Understanding of Changes Through Time in the Reservoir and a Way to Predict Them
Polymer rheological behavior in an Enhanced Oil Recovery (EOR) project is one of the critical factors to determine whether the polymer injection would be effective to increase the oil production in a field. Due to complications on the measurement of this parameter and its variation within the reservoir, the challenge of understanding viscosity behavior relies on lab and field tests that become key factors to solve this issue. This study was conducted during an injectivity test for an EOR project in Los Perales field (Santa Cruz, Argentina) in three wells with different operational and subsurface conditions, and tests were performed twice a day for 30 days each in order to obtain sufficient time span of data. From lab rheology tests performed at reservoir conditions, where the main objective was to analyze viscosity changes through time, two different tendencies were observed: one that affects in early times and another that becomes preeminent at late times. With these results, a describing equation was developed to predict viscosity evolution over time. The equation consists of three terms including thermal variation, chemical degradation and the final viscosity towards which the polymer tends. Although the equation properly describes both lab and field polymer solution, there is a considerable difference, especially when the effects mentioned become preponderant. This difference is attributed to both the water used for the mixture and the possible impurities that may be incorporated during the maturation or transfer of the polymer. Since most of the data used was obtained from field tests, this emphasizes the appliance of the equation on the field. Impurities turn out to be crucial, specially oxygen (O2) and hydrogen sulfide (H2S) combined. Their presence highly impacts the asymptotic viscosity, so a correlation between H2S content and final viscosity was also developed. Finally, an analysis of the temperature influence on the viscosity was conducted. A correlation between the final viscosity and temperature was found and used to incorporate temperature variations in the predictions and therefore to relate measurements performed at different conditions. The primary advantage of this study is that the equation and correlations enable the prediction of the polymer solution viscosity at any time. This allows the estimation of actual polymer viscosity in the reservoir from a routine measurement at any temperature and impurities content. The versatility of this equation is what makes it novel and useful in an industry going towards EOR projects.
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