Abstract
Reverse electrodialysis (RED) is a process to harvest renewable energy from salinity gradients. Under lab conditions with artificial salt solutions, promising results have been achieved in recent years. However, in large scale industrial applications, natural waters are used and that poses challenges such as fouling. Fouling of anion exchange membranes (AEMs) by organic matter (e.g. humic acids) has been identified as a possible cause that lowers RED performance with natural waters. In this work, natural river and seawater at the Afsluitdijk (The Netherlands) are used to study the RED performance of six different AEMs. These AEMs are characterized before and after RED experiments with natural waters. The effect of natural fouling is found to be specific for each AEM and highly dependent on their respective chemistries and associated membrane properties. Firstly, aromatic AEMs with a low swelling degree showed a permselectivity decrease as well as membrane resistance increase. Secondly, aliphatic AEMs with a medium swelling degree experienced only a membrane resistance increase. Finally, only a decrease in permselectivity was observed for aliphatic AEMs with large swelling degrees. Subsequently, the effect of AEM fouling is compared to the observed decrease in RED performance and this shows that AEM fouling can only explain a minor part of the losses in open circuit voltage (OCV). The RED power densities dropped by 15–20% over 12 days, independent of the AEMs selected, while the reduced AEM performance could only explain 2–4% of this reduction in power density. This demonstrates that next to AEM fouling, also other factors, such as spacer fouling, are expected to be the dominant fouling mechanism, reducing the performance to a much larger extent.
Highlights
Reverse electrodialysis (RED) is a membrane-based process to harvest renewable energy from natural salinity gradients
Prior to RED measurements, all anion exchange membranes (AEMs) are characterized to determine the differences between AEMs and to examine the effect of fouling after the RED experiments
V3A has the same support as V2, but a chemistry with a higher ion exchange capacity (IEC), which leads to a very high water content
Summary
Reverse electrodialysis (RED) is a membrane-based process to harvest renewable energy from natural salinity gradients. Feed waters with a difference in salinity (river and seawater for example) are fed to alternating stack compartments. In these RED systems, the salinity gradient between the two water sources generates an electromotive force (the open circuit voltage; OCV) and the charge-selective ion exchange membranes facilitate ionic transport (ionic current). In this way, the natural salinity gradient can be converted into electrical energy. Anticipated feed streams for this process are natural water sources with a salinity difference (e.g. river and seawater). In lab experiments, where artificial river and seawater were prepared using NaCl only, promising results have been obtained [1,2]
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