Field demonstration of intensified membrane distillation for treating oilfield produced waters from unconventional wells | AIChE

Field demonstration of intensified membrane distillation for treating oilfield produced waters from unconventional wells

TitleField demonstration of intensified membrane distillation for treating oilfield produced waters from unconventional wells
Publication TypeJournal Article
Year of Publication2023
AuthorsHsieh, I-M, Lin, B, Mahbu, H, Carter, Z, Jebur, M, Cao, Y, Brownlow, J, Wickramasinghe, R, Malmali, M
JournalDesalination
Volume564
Pagination116771
Date Publishedoct
Keywords8.8
Abstract

Increasing disposal costs and environmental concerns have encouraged desalination projects in the Permian basin to cut down produced water (PW) volumes and improve the handling. This study aims to demonstrate performance of membrane-distillation (MD) for desalinating high-salinity PW. Prior to MD, electrocoagulation (EC) and microfiltration (MF) are used as primary and secondary pretreatments, respectively. These pretreatment steps are necessary to remove constituents such as suspended solids, oil, and grease. The integrated EC-MF process was followed by vacuum MD (VMD) to recover water and concentrate the brine stream. To improve latent heat recovery, vapor compression is integrated into the vacuum membrane distillation (VMD). Our EC-MF-VMD PW treatment process can treat 1000 L of PW per day, with water recoveries in the range of 30–70 %. Suspended solids and turbidity removal of 90 % and total organic carbon (TOC) removal of 60 % were achieved with EC-MF pretreatments, which effectively mitigated PW fouling potential. A custom-designed plate-and-frame VMD module was established which enabled unparalleled service flexibility to change membrane replacement and active area. Results from our systematic evaluation revealed that the flux of the commercial membranes in our VMD module varied from 5 to 66 Lm−2 h−1. The intensified VMD performance achieved by vapor compression led to remarkable improvement in energy efficiency in terms of gained output ratio (GOR = 2.7) and energy consumption per unit of water production (248 kWh m−3). This study demonstrates the capability of the MD process for PW treatment, revealing the reasonable potential for PW reuse and recycling. Although this process might be of interest for unique applications that justifies the cost, further improvements in energy consumption are required to make this technology feasible for commercialized desalination of oilfield produced waters.

URLhttps://www.sciencedirect.com/science/article/abs/pii/S0011916423004034
DOI10.1016/j.desal.2023.116771