Experimental Study on the Synthesis and Interfacial Properties of Oligomeric Silicone Surfactant

Zhang Jie, Xianguang Xu, Lihui Wang, Li Long, Zhang Die, Zhao Zhiliang, S. Wang
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引用次数: 1

Abstract

Severe formation damage is induced by the invasion of working fluid and the subsequent water blocking. Surface modification by surfactant adsorption can change the wettability of the rock surface to enhance the removal efficiency of reservoir fluid and reduce the water blockage damage. Therefore, surfactant shows a good potential applicant in condense reservoir. In the current paper, an oligomeric silicone surfactant (OSSF) containing sulfonic acid groups is synthesized to improve the water flowback effect. The critical micelle concentration (CMC) is determined by equilibrium surface tension. Micelle can be formed above the CMC and its size and distribution increase with the concentration. At the same time, the surface tension increases with the aging temperature but decreases with the adding of inorganic salt. The OSSF adsorption through solid-liquid surface can change the surface chemical composition and transfer the wettability of reservoir from water-wet to gas-wet by decreasing the surface energy. Increasing temperature leads to the change in the adsorption isotherm from Langmuir type (L-type) to "double plateau" type (LS- type). Quantum chemistry study shows that the adsorbed layer of OSSF can reduce the adhesive force of CH4 and H2O on the pore surface of cores. The OSSF can also decease the initial foaming volume and stability in induction period and accelerating period of sodium dodecyl benzene sulfonate (SDBS). It is found that the surface tension of OSSF increases with aging temperature but decreases with the adding of inorganic salts.The OSSF has positive effect on wettability reversal to water-wet reservoir by adsorption on solid-liquid interface. The results indicate OSSF adsorption layer can change surface chemical composition and exhibit lower interface energy than that of the cores. The presence of NaCl can decrease foaming volume and improve foam stability of OSSF. At the same time, OSSF can decease the initial foaming volume and stability in induction period and accelerating period of sodium dodecyl benzene sulfonate (SDBS).
低聚有机硅表面活性剂的合成及其界面性能的实验研究
工作流体的侵入和随后的水堵塞会导致严重的地层损害。表面活性剂吸附改性可以改变岩石表面的润湿性,提高储层流体的去除效率,减少堵水损害。因此,表面活性剂在凝析油藏中具有良好的应用前景。本文合成了一种含有磺酸基的低聚有机硅表面活性剂(OSSF),以改善反排效果。临界胶束浓度(CMC)由平衡表面张力决定。CMC上方可形成胶束,胶束的大小和分布随浓度的增加而增大。同时,表面张力随时效温度的升高而升高,随无机盐的加入而降低。固液表面吸附OSSF可以改变储层表面化学成分,通过降低表面能使储层润湿性由水湿型向气湿型转变。温度升高导致吸附等温线由Langmuir型(l -型)转变为双平台型(LS-型)。量子化学研究表明,OSSF的吸附层可以降低岩心孔表面CH4和H2O的附着力。在十二烷基苯磺酸钠(SDBS)的诱导期和加速期,OSSF还能降低初始泡沫体积和稳定性。结果表明,表面张力随时效温度的升高而升高,但随无机盐的加入而降低。OSSF通过固液界面吸附对水湿储层的润湿性反转有积极作用。结果表明,OSSF吸附层可以改变表面化学成分,界面能低于岩心。NaCl的存在可以减小泡沫体积,提高泡沫稳定性。同时,OSSF可以降低十二烷基苯磺酸钠(SDBS)诱导期和加速期的初始发泡体积和稳定性。
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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