Investigation of Asphaltenes Precipitation Under Immiscible Interaction of Reservoir Heavy Oil and Liquid Carbon Dioxide

A. Lobanov, S. Fedorovskiy, I. Promzelev, Y. Tikhomirov, K. Schekoldin, I. Struchkov, V. Kovalenko, G. Sergeev, E. Lipatnikova
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Abstract

A new method for assessing the stability of the asphaltene phase in reservoir fluids using a high-pressure microscope is presented. The new method is based on the observation of the asphaltene particles sedimentation in a vertically oriented sapphire cell. This determines the size of sedimentation particles, their number and sedimentation rate. Experimental results are used as input parameters for calculating solid particles sedimentation of using the Stokes law equation. It makes possible to calculate the density and weight percent of the solid phase, evaluate the aggregative and kinetic stability of the fluid with respect to solid particles depending on thermodynamic parameters (pressure, temperature, reagent concentration). The proposed method was tested in the single-contact study of high-viscosity reservoir oil and liquid carbon dioxide and was compared with the results of asphaltene precipitation gravimetric test. According to the results analysis, were conclusions about the applicability of the new method and the mechanism of asphaltenes precipitation in high-viscosity oil when it contact with carbon dioxide. It is shown that the combination of gravimetric and visual analyzes allows to investigate the asphaltenes precipitaion separately in two processes: reduction of pressure and vaporization of fluids. This makes it possible to assess the likelihood of formation and the effectiveness of reagents for combating solid deposits in the entire process chain of oil production. Concluded that the asphaltenes precipitation in the contact of carbon dioxide and high-viscosity oil occurs according to the complex mechanism and includes intensification due to a drop in oil viscosity and damping due to mass transfer between carbon dioxide and oil phases. From this, inhibitors selection criteria are derived and the using of deasphalted oil as a stabilizer of asphaltenes is proposed.
储层稠油与液态二氧化碳非混相作用下沥青质沉淀研究
提出了一种利用高压显微镜评价储层流体中沥青质相稳定性的新方法。新方法是基于对垂直定向蓝宝石电池中沥青质颗粒沉降的观察。这决定了沉降颗粒的大小、数量和沉降速率。实验结果作为输入参数,应用Stokes定律方程计算固体颗粒沉降。它可以计算固体相的密度和重量百分比,根据热力学参数(压力、温度、试剂浓度)评估流体相对于固体颗粒的聚集性和动力学稳定性。将该方法应用于高粘度储层油与液态二氧化碳的单接触研究,并与沥青质沉淀重量试验结果进行了比较。通过对结果的分析,得出了新方法的适用性和沥青质在高粘度油中与二氧化碳接触时析出的机理。结果表明,重量分析和目视分析相结合,可以分别考察沥青质的减压和汽化两个过程。这使得在石油生产的整个过程链中评估形成固体沉积物的可能性和试剂的有效性成为可能。结论认为,沥青质在二氧化碳与高粘度油接触时的沉淀具有复杂的机理,其中包括油的粘度下降和二氧化碳与油相之间的传质所导致的衰减。由此导出了抑制剂的选择标准,并提出了脱沥青油作为沥青质稳定剂的使用方法。
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