Evaluating scale deposition and scale tendency of effluent water mix with seawater for compatible injection water

Abstract Water injection technique is contributing millions of oil barrels on a daily basis to the global oil supply; one of the challenges faced by such an important production method is scale buildup due to the different dissolved solids and high salinity of the injected water. For produced water...

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Main Authors: M. Al-Samhan, K. Alanezi, J. Al-Fadhli, F. Al-Attar, S. Mukadam, J. George
Format: Article
Language:English
Published: SpringerOpen 2020-03-01
Series:Journal of Petroleum Exploration and Production Technology
Subjects:
EOR
Online Access:https://doi.org/10.1007/s13202-020-00849-w
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spelling doaj-92a8fac88aa741e38fb4b2df222abe9e2021-03-11T11:53:26ZengSpringerOpenJournal of Petroleum Exploration and Production Technology2190-05582190-05662020-03-011052105211110.1007/s13202-020-00849-wEvaluating scale deposition and scale tendency of effluent water mix with seawater for compatible injection waterM. Al-Samhan0K. Alanezi1J. Al-Fadhli2F. Al-Attar3S. Mukadam4J. George5Petroleum Research Center, Kuwait Institute for Scientific ResearchChemical Engineering Technology Department, College of Technological Studies (CTS)Petroleum Research Center, Kuwait Institute for Scientific ResearchPetroleum Research Center, Kuwait Institute for Scientific ResearchPetroleum Research Center, Kuwait Institute for Scientific ResearchPetroleum Research Center, Kuwait Institute for Scientific ResearchAbstract Water injection technique is contributing millions of oil barrels on a daily basis to the global oil supply; one of the challenges faced by such an important production method is scale buildup due to the different dissolved solids and high salinity of the injected water. For produced water or effluent water, pretreatment is a critical step before the injection process to reduce the risk of scale potential and well formation damage. One of the beneficial treatments of the effluent water is to be mixed in a compatible ratio with seawater, especially for those countries with easy access to seawater. Thus, the objective is to find a compatible mix ratio with seawater as one way of solving effluent water reuse without increasing the risk of scale and formation damage during water injection operation. In this study, effluent water samples were collected from different oilfield geographical locations in Kuwait, and then the samples were analyzed in the laboratory for their physical and chemical properties to select the most compatible one for mixing with seawater. The selected effluent water was then mixed with seawater in 1:1 ratio to evaluate the compatibility of the mix in terms of sulfate formation and scale tendency. The selected North field/seawater was tested under 75 ºC and 1000 PSi in an autoclave. The filtered precipitates were characterized by energy-dispersive spectroscopy (EDS) and scanning electronic microscope (SEM) micrographs. Further, the formations of sulfate were detected by X-ray diffraction (XRD). The OLI ScaleChem software was used to investigate the composition of mineral scales that may occur in the water mix at different ratios ranging from 0 to 100% to compare it with the actual water mix finding. In the effluent waters comparison part, North field water showed low pH (4.6) and alkalinity, as well as moderate TDS (190,000 MG/L). The main constituents of the scale deposited at the selected water mixing ratio were calcium sulfate CaSO4 and silicon oxide detected by XRD. However, the amount of barium sulfate was not presented in the precipitates indicating that all of it went in the liquid phase. The study concludes that at downhole conditions, the compatible mix of North Kuwait effluent water with seawater has high risk of barium sulfate in comparison with other common scale such as calcium sulfate, calcium carbonate and strontium sulfate (SrSO4). Also the study revealed that the prediction of different seawater ratios showed that at 70% seawater concentration, the barium sulfate concentration drops and consequently the scale risk reduced.https://doi.org/10.1007/s13202-020-00849-wWater compatibilityScale predictionWater injectionEOREffluent waterFerrous oxide
collection DOAJ
language English
format Article
sources DOAJ
author M. Al-Samhan
K. Alanezi
J. Al-Fadhli
F. Al-Attar
S. Mukadam
J. George
spellingShingle M. Al-Samhan
K. Alanezi
J. Al-Fadhli
F. Al-Attar
S. Mukadam
J. George
Evaluating scale deposition and scale tendency of effluent water mix with seawater for compatible injection water
Journal of Petroleum Exploration and Production Technology
Water compatibility
Scale prediction
Water injection
EOR
Effluent water
Ferrous oxide
author_facet M. Al-Samhan
K. Alanezi
J. Al-Fadhli
F. Al-Attar
S. Mukadam
J. George
author_sort M. Al-Samhan
title Evaluating scale deposition and scale tendency of effluent water mix with seawater for compatible injection water
title_short Evaluating scale deposition and scale tendency of effluent water mix with seawater for compatible injection water
title_full Evaluating scale deposition and scale tendency of effluent water mix with seawater for compatible injection water
title_fullStr Evaluating scale deposition and scale tendency of effluent water mix with seawater for compatible injection water
title_full_unstemmed Evaluating scale deposition and scale tendency of effluent water mix with seawater for compatible injection water
title_sort evaluating scale deposition and scale tendency of effluent water mix with seawater for compatible injection water
publisher SpringerOpen
series Journal of Petroleum Exploration and Production Technology
issn 2190-0558
2190-0566
publishDate 2020-03-01
description Abstract Water injection technique is contributing millions of oil barrels on a daily basis to the global oil supply; one of the challenges faced by such an important production method is scale buildup due to the different dissolved solids and high salinity of the injected water. For produced water or effluent water, pretreatment is a critical step before the injection process to reduce the risk of scale potential and well formation damage. One of the beneficial treatments of the effluent water is to be mixed in a compatible ratio with seawater, especially for those countries with easy access to seawater. Thus, the objective is to find a compatible mix ratio with seawater as one way of solving effluent water reuse without increasing the risk of scale and formation damage during water injection operation. In this study, effluent water samples were collected from different oilfield geographical locations in Kuwait, and then the samples were analyzed in the laboratory for their physical and chemical properties to select the most compatible one for mixing with seawater. The selected effluent water was then mixed with seawater in 1:1 ratio to evaluate the compatibility of the mix in terms of sulfate formation and scale tendency. The selected North field/seawater was tested under 75 ºC and 1000 PSi in an autoclave. The filtered precipitates were characterized by energy-dispersive spectroscopy (EDS) and scanning electronic microscope (SEM) micrographs. Further, the formations of sulfate were detected by X-ray diffraction (XRD). The OLI ScaleChem software was used to investigate the composition of mineral scales that may occur in the water mix at different ratios ranging from 0 to 100% to compare it with the actual water mix finding. In the effluent waters comparison part, North field water showed low pH (4.6) and alkalinity, as well as moderate TDS (190,000 MG/L). The main constituents of the scale deposited at the selected water mixing ratio were calcium sulfate CaSO4 and silicon oxide detected by XRD. However, the amount of barium sulfate was not presented in the precipitates indicating that all of it went in the liquid phase. The study concludes that at downhole conditions, the compatible mix of North Kuwait effluent water with seawater has high risk of barium sulfate in comparison with other common scale such as calcium sulfate, calcium carbonate and strontium sulfate (SrSO4). Also the study revealed that the prediction of different seawater ratios showed that at 70% seawater concentration, the barium sulfate concentration drops and consequently the scale risk reduced.
topic Water compatibility
Scale prediction
Water injection
EOR
Effluent water
Ferrous oxide
url https://doi.org/10.1007/s13202-020-00849-w
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