Simultaneous CO2 Treatment and Blue Energy Generation from Wasted Industrial Streams

Building Resilience at Universities: Role of Innovation and Entrepreneurship Pub Date : 2021-10-20 DOI:10.29117/quarfe.2021.0009

Tasneem Elmakki, Sifani Zavahir, Mona Gulied, Reem S. Azam, P. Kasák, A. Popelka, D. Han

{"title":"Simultaneous CO2 Treatment and Blue Energy Generation from Wasted Industrial Streams","authors":"Tasneem Elmakki, Sifani Zavahir, Mona Gulied, Reem S. Azam, P. Kasák, A. Popelka, D. Han","doi":"10.29117/quarfe.2021.0009","DOIUrl":null,"url":null,"abstract":"In the last decade, there has been an increased global need for finding bright solutions to tackle industrial wastes and emissions release. Herein, this work explores the utilization of a compact Reverse Electrodialysis (RED) system that transforms the chemical potential energy of mixing an ammonia based purified industrial wastewater stream (low concentration stream - LC), with an effluent high salinity RO brine stream (High concentration-HC) into viable electrical energy. The LC and HC streams are directed from ammonia production plants and seawater reverse osmosis desalination plants, respectively. The acquired electrical energy from this RED process is simultaneously used to power an Electrochemical (EC) system. The electrochemical system utilizes two critical waste streams produced from ammonia production plants. One being a wastewater stream that is purified in the anode chamber of the cell via the use of active chlorine species, and the other being the huge amount of emitted CO2 that is directed into the cathode chamber and there converted to value added chemicals. The purified wastewater stream coming out of the EC system is used as the aforementioned LC stream in the RED process, hence, forming an integrated RED-EC system that manages industrial waste streams, minimizes liquid discharge & CO2 emissions, and employs a sustainable internal energy production process. In this study, the RED system is first optimized to attain the maximum power density through exploring the influence of concentrate and dilute stream concentrations, compositions and flowrates. In addition, to the number of membrane pairs needed to produce desired voltages. The RED cell gave a maximum power density of 3.25 W.m-2 with 20 membrane pairs and a salinity gradient of 0.98M between a concentrated brine stream and a mixed NaCl/(NH4)2SO4 stream. Furthermore, around 15 cell pairs were needed to provide -1.5 V of energy to drive CO2 conversion to formate.","PeriodicalId":9295,"journal":{"name":"Building Resilience at Universities: Role of Innovation and Entrepreneurship","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2021-10-20","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Building Resilience at Universities: Role of Innovation and Entrepreneurship","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.29117/quarfe.2021.0009","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 0

Abstract

In the last decade, there has been an increased global need for finding bright solutions to tackle industrial wastes and emissions release. Herein, this work explores the utilization of a compact Reverse Electrodialysis (RED) system that transforms the chemical potential energy of mixing an ammonia based purified industrial wastewater stream (low concentration stream - LC), with an effluent high salinity RO brine stream (High concentration-HC) into viable electrical energy. The LC and HC streams are directed from ammonia production plants and seawater reverse osmosis desalination plants, respectively. The acquired electrical energy from this RED process is simultaneously used to power an Electrochemical (EC) system. The electrochemical system utilizes two critical waste streams produced from ammonia production plants. One being a wastewater stream that is purified in the anode chamber of the cell via the use of active chlorine species, and the other being the huge amount of emitted CO2 that is directed into the cathode chamber and there converted to value added chemicals. The purified wastewater stream coming out of the EC system is used as the aforementioned LC stream in the RED process, hence, forming an integrated RED-EC system that manages industrial waste streams, minimizes liquid discharge & CO2 emissions, and employs a sustainable internal energy production process. In this study, the RED system is first optimized to attain the maximum power density through exploring the influence of concentrate and dilute stream concentrations, compositions and flowrates. In addition, to the number of membrane pairs needed to produce desired voltages. The RED cell gave a maximum power density of 3.25 W.m-2 with 20 membrane pairs and a salinity gradient of 0.98M between a concentrated brine stream and a mixed NaCl/(NH4)2SO4 stream. Furthermore, around 15 cell pairs were needed to provide -1.5 V of energy to drive CO2 conversion to formate.

查看原文本刊更多论文

利用废弃工业废水同时处理二氧化碳和生成蓝色能源

在过去的十年里，全球越来越需要找到解决工业废物和排放的解决方案。在此，本研究探索了紧凑型反电渗析(RED)系统的利用，该系统将氨基净化工业废水流(低浓度流- LC)与排出的高盐度RO盐水流(高浓度- hc)混合的化学势能转化为可行的电能。LC和HC流分别来自氨生产厂和海水反渗透淡化厂。从该RED过程中获得的电能同时用于为电化学(EC)系统供电。电化学系统利用从氨生产厂产生的两个关键废物流。一种是废水流，通过使用活性氯在电池的阳极室净化，另一种是大量排放的二氧化碳，直接进入阴极室，在那里转化为增值化学品。从EC系统出来的纯化废水流在RED过程中用作上述LC流，从而形成一个集成的RED-EC系统，管理工业废水流，最大限度地减少液体排放和二氧化碳排放，并采用可持续的内能生产过程。在本研究中，首先通过探索浓、稀流浓度、成分和流量的影响，对RED系统进行优化，以获得最大功率密度。此外，需要产生所需电压的膜对的数量。RED细胞的最大功率密度为3.25 w - m-2，膜对为20对，浓盐水流和混合NaCl/(NH4)2SO4流的盐度梯度为0.98M。此外，大约需要15对电池来提供-1.5 V的能量来驱动二氧化碳转化为甲酸。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Building Resilience at Universities: Role of Innovation and Entrepreneurship

自引率

0.00%

发文量