Cesium removal from drinking water using Prussian blue adsorption followed by anion exchange process

•Cesium removal from drinking water is tested with Prussian blue+ion exchange.•IE over PB granules in sand filter removed Cs and total cyanide from tap water.•PB column followed by IE column removed Cs and total cyanide from raw waters.•PB+IE can be used for emergency response for waterworks upon nu...

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Veröffentlicht in:	Separation and purification technology 2017-01, Vol.172, p.147-151
Hauptverfasser:	Chen, Guan-Ru, Chang, Yin-Ru, Liu, Xiang, Kawamoto, Tohru, Tanaka, Hisashi, Parajuli, Durga, Kawasaki, Tatsuya, Kawatsu, Yoshiaki, Kobayashi, Takeshi, Chen, Man-Li, Lo, Yu-Kuo, Lei, Zhongfang, Lee, Duu-Jong
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Sprache:	eng
Schlagworte:	Adsorbents Anion exchange Cesium Drinking water Exchange Fragments Granular materials Granules Prussian blue Sand Water utilities Waterworks
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container_title	Separation and purification technology
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creator	Chen, Guan-Ru Chang, Yin-Ru Liu, Xiang Kawamoto, Tohru Tanaka, Hisashi Parajuli, Durga Kawasaki, Tatsuya Kawatsu, Yoshiaki Kobayashi, Takeshi Chen, Man-Li Lo, Yu-Kuo Lei, Zhongfang Lee, Duu-Jong
description	•Cesium removal from drinking water is tested with Prussian blue+ion exchange.•IE over PB granules in sand filter removed Cs and total cyanide from tap water.•PB column followed by IE column removed Cs and total cyanide from raw waters.•PB+IE can be used for emergency response for waterworks upon nuclear accident. Prussian blue (PB) was proposed to be an effective cesium (Cs) adsorbent for drinking waterwork; however, the release of PB fragments from PB adsorbent matrix poses threat to water quality. This study examined the feasibility of a PB+anion exchange (AE) process for decontamination of Cs-polluted drinking water. Two scenarios were tested: AE granules over PB granules in a stimulated sand filter and PB column followed by AE column in a full-scale waterworks. Both scenarios revealed complete removal of Cs and PB fragments from the treated drinking waters, suggesting that the PB+AE unit can be the core of emergency response plan for typical drinking waterworks at nuclear accident threat.
doi_str_mv	10.1016/j.seppur.2016.07.055
format	Article
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Prussian blue (PB) was proposed to be an effective cesium (Cs) adsorbent for drinking waterwork; however, the release of PB fragments from PB adsorbent matrix poses threat to water quality. This study examined the feasibility of a PB+anion exchange (AE) process for decontamination of Cs-polluted drinking water. Two scenarios were tested: AE granules over PB granules in a stimulated sand filter and PB column followed by AE column in a full-scale waterworks. 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subjects	Adsorbents Anion exchange Cesium Drinking water Exchange Fragments Granular materials Granules Prussian blue Sand Water utilities Waterworks
title	Cesium removal from drinking water using Prussian blue adsorption followed by anion exchange process
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