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Effect of salinity and ion type on formation damage due to inorganic scale deposition and introducing optimum salinity

Ghasemian, J ; Sharif University of Technology | 2019

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  1. Type of Document: Article
  2. DOI: 10.1016/j.petrol.2019.02.019
  3. Publisher: Elsevier B.V , 2019
  4. Abstract:
  5. Smart water injection is recognized as an effective EOR process to alter the wettability and interfacial tension to obtain higher micro/macro sweep efficiencies. This water contains reactive ions such asMg2+, Ca2+ andSO42- which can act as potential-determining ions and change the surface charge of calcite rocks. One of the major concerns in the execution of an effective water-flood process, especially in tight carbonate reservoirs, is the chemical incompatibility between the formation brine and the injecting water. In the present study, laboratory fluid compatibility tests were carried out and software simulation was done to investigate the most important challenges of the water-flooding process in one of the West Iranian oil fields with the possibility of developing formation damage. The chemical incompatibility between injected smart water and formation water leads to inorganic scale deposition. For this purpose, sea water as the basis of smart water was prepared to examine the impact of determining ions such asMg2+, Ca2+, and SO42- and, to examine the effect of the salinity of the injected brine on the total amount of CaSO4 scale precipitation. According to the obtained results, as the concentration of SO42- in the injecting sea water increases from 1/4to 1 times its concentration in ordinary sea water, the CaSO4 precipitation increases smoothly, and then it is accelerated as the concentration increases beyond that. Therefore, even though the increasing of the sulfate concentration improved the wettability alteration ability of the smart water, calcium sulfate deposition was noticed, resulting in permanent formation damage. The test results also showed that CaSO4 deposition increases as the concentration of Ca2+in the sea water increases. On the other hand, the presence of Mg2+ ion in sea water increases the solubility of CaSO4 and subsequently, lower scale formation was noticed by increasing the concentration of magnesium. This study also showed that there is an optimum salinity in which the minimum amount of mineral scale is deposited, and 5 times dilution of sea water is determined as the optimum salinity. The findings would enable us to optimize the ion contents of smart water for both, better oil sweep efficiency and lower risk of formation damage. In the end, this paper discusses the laboratory fluid compatibility results and scale prediction analysis for different smart water injection utilizations. © 2019 Elsevier B.V
  6. Keywords:
  7. Enhanced oil recovery ; Optimum composition ; Potential determining ions ; Scale ; Smart water ; Water flooding ; Calcite ; Efficiency ; Enhanced recovery ; Floods ; Ions ; Oil fields ; Oil well flooding ; Reservoirs (water) ; Scale (deposits) ; Seawater ; Software testing ; Water injection ; Wetting ; Chemical incompatibility ; Enhanced oil recovery ; Inorganic scale deposition ; Potential-determining ions ; Sulfate concentrations ; Tight carbonate reservoir ; Sulfur compounds ; Depositional environment ; Enhanced oil recovery ; Fluid injection ; Inorganic compound ; Ion exchange ; Laboratory method ; Optimization ; Salinity
  8. Source: Journal of Petroleum Science and Engineering ; Volume 177 , 2019 , Pages 270-281 ; 09204105 (ISSN)
  9. URL: https://www.sciencedirect.com/science/article/abs/pii/S0920410519301561