Power Generation Performance of a Pilot-Scale Reverse Electrodialysis Using Monovalent Selective Ion-Exchange Membranes.

Soroush Mehdizadeh,Takakazu Abo,Mitsuru Higa,Yuriko Kakihana,Qingchun Yuan

doi:10.3390/membranes11010027

Soroush Mehdizadeh, Takakazu Abo + Show 3 more

Open Access

https://doi.org/10.3390/membranes11010027

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Journal: Membranes	Publication Date: Jan 1, 2021
Citations: 28	License type: CC BY 4.0

Affiliation: Yamaguchi University, Aston University

Abstract

Reverse electrodialysis (RED) is a promising process for harvesting energy from the salinity gradient between two solutions without environmental impacts. Seawater (SW) and river water (RW) are considered the main RED feed solutions because of their good availability. In Okinawa Island (Japan), SW desalination via the reverse osmosis (RO) can be integrated with the RED process due to the production of a large amount of RO brine (concentrated SW, containing ~1 mol/dm3 of NaCl), which is usually discharged directly into the sea. In this study, a pilot-scale RED stack, with 299 cell pairs and 179.4 m2 of effective membrane area, was installed in the SW desalination plant. For the first time, asymmetric monovalent selective membranes with monovalent selective layer just at the side of the membranes were used as the ion exchange membranes (IEMs) inside the RED stack. Natural and model RO brines, as well as SW, were used as the high-concentrate feed solutions. RW, which was in fact surface water in this study and close to the desalination plant, was utilized as the low-concentrate feed solution. The power generation performance investigated by the current-voltage (I–V) test showed the maximum gross power density of 0.96 and 1.46 W/m2 respectively, when the natural and model RO brine/RW were used. These are a 50–60% improvement of the maximum gross power of 0.62 and 0.97 W/m2 generated from the natural and model SW, respectively. The approximate 50% more power generated from the model feed solutions can be assigned to the suppression of concentration polarization of the RED stack due to the absence of multivalent ions.

Highlights

Increasing world energy demand, especially in the last few decades, has caused the continuous use and burning of fossil fuels [1,2,3,4]
We evaluated the performance of the reverse electrodialysis (RED) pilot plant (RED stack) with 299 cell pairs and a 179.4 m2 membrane effective area
The power generation performance of a pilot-scale RED stack, located at Okinawa (Japan) SW desalination plant, by the reverse osmosis (RO) process was presented in this study

Summary

Introduction

Increasing world energy demand, especially in the last few decades, has caused the continuous use and burning of fossil fuels [1,2,3,4]. In 1954, Pattel made a novel demonstration of SGE as an electrochemical potential between two solutions with different salinities [5]. In this regard, solvated ions in solutions have an electrochemical potential to move from a high concentrate to a low concentrate area until they reach equilibrium. In RED, high and low concentrate solutions flow alternatively through stacked anion exchange membranes (AEMs) and cation exchange membranes (CEMs) [15]. The internal ion transportation stack makes a potential difference through the RED stack and converts it into an external electric current using a suitable electrolyte and electrode system

Methods

Results

Conclusion