哥伦比亚某油田条件下表面活性剂-聚合物配方的评价

Fabián Andrés Tapias Hernández, R. Moreno
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引用次数: 3

摘要

表面活性剂-聚合物(SP)工艺是工业上常用的化学提高采收率(CEOR)方法之一。人们一直在研究它;然而,由于难以设计注入溶液和预测过程性能,这仍然是石油行业面临的一个挑战。本文旨在根据一些已知的性质和条件,为SP工艺中使用的流体设计做出贡献。因此,将哥伦比亚某油田的储层和流体性质作为选择聚合物和表面活性剂的参考参数。然后,通过流变学研究确定了盐、温度和表面活性剂对定制聚合物溶液的影响。Ostwald-de Waele和careau - yasuda模型根据剪切速率调整了测量的粘度数据,而Arrhenius方程则根据温度拟合了7,8 s-1时的粘度值。通过相行为测试分析了表面活性剂的性能,并利用Chun Huh方程确定了界面张力(IFT)值。采用班克罗夫特规则作为微乳液形成类型的定性验证工具。从流变学来看,我们得出结论,黏性模量在所有聚合物溶液中都占主导地位,并且由于二价阳离子的存在以及温度、盐或表面活性剂浓度的升高,流体厚度会降低。另一方面,观察到的相行为对应于Winsor II到I的过渡,没有发现任何Winsor III微乳液。为此,提出了选择最优条件的准则。在理想条件下,IFT的降低幅度为10-3 ~ 10-4 [mN/m]。这些值通常与提高的采收率有关。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Assessment of a surfactant- polymer formulation for conditions in a Colombian field
The surfactant-polymer (SP) process is one of the Chemical Enhanced Oil Recovery (CEOR) methods used in the industry. It has been continuously studied; however, it is still a challenge for the petroleum industry due to the difficulty to design the solution to be injected and forecast process performance. This paper is intended to contribute to the design of fluids used in an SP process based on some previously known properties and conditions. Hence, reservoir and fluid properties of a Colombian Field were used as reference parameters to select the polymer and surfactant. Then, the effects of salts, temperature, and surfactant on tailor-made polymer solutions were determined through a rheological study. Ostwald-de Waele and Carreau-Yasuda models adjusted the measured viscosity data against shear rate, while Arrhenius equation fitted viscosity values at 7,8 s-1 against temperature. The surfactant performance was analyzed using phase behavior tests, and the Chun Huh equations determined the interfacial tension (IFT) values. The Bancroft’s rule was used as a qualitative verification tool of the kind of micro- emulsion formed. From rheology, we concluded that the viscous modulus is predominant for all polymer solutions, and the fluid thickness is reduced due to the presence of divalent cations and raise on temperature, salts or surfactant concentration. On the other hand, the observed phase behavior corresponded to a transition Winsor II to I without finding any Winsor III micro-emulsion. Therefore, some criteria were proposed to select the optimal conditions. For the desired conditions, the reduction of IFT reached values ranging in magnitudes of 10-3 to 10-4 [mN/m]. These values are usually associated with an improved oil recovery factor.
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