A preliminary cost and engineering estimate for desalinating produced formation water associated with carbon dioxide capture and storage |
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| Authors: | WL Bourcier TJ Wolery T Wolfe C Haussmann TA Buscheck RD Aines |
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| Institution: | aLawrence Livermore National Laboratory, 7000 East Avenue, Livermore, CA 94550, United States;bPerLorica Inc., P.O. Box 190, Rough and Ready, CA 95975, United States;cWater Systems Specialists, Inc., 5808 Princeton Ave NE, Seattle, WA 98105, United States |
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| Abstract: | The risk associated with storage of carbon dioxide in the subsurface can be reduced by removal of a comparable volume of existing brines (e.g. Buscheck et al., 2011). In order to avoid high costs for disposal, the brines should be processed into useful forms such as fresh and low-hardness water. We have carried out a cost analysis of treatment of typical subsurface saline waters found in sedimentary basins, compared with conventional seawater desalination. We have also accounted for some cost savings by utilization of potential well-head pressures at brine production wells, which may be present in some fields due to CO2 injection, to drive desalination using reverse osmosis. Predicted desalination costs for brines having salinities equal to seawater are about half the cost of conventional seawater desalination when we assume the energy can be obtained from excess pressure at the well head. These costs range from 32 to 40¢ per m3 permeate produced. Without well-head energy recovery, the costs are from 60 to 80¢ per m3 permeate. These costs do not include the cost of any brine production or brine reinjection wells, or pipelines to the well field, or other site-dependent factors. |
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| Keywords: | Carbon capture and storage Desalination Brines Reverse osmosis Osmotic pressure Produced waters |
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