Column Separation of Vanadium(V) from Complex Sulfuric Solution Using Trialkylamine-Impregnated Resins

Separation of V(V) from simulated complex vanadium-bearing (SCV) solution containing Al(III), Fe(III), P(V), and Si(IV) using trialkylamine (N235)-impregnated resins has been investigated. Batch experiments proved that the optimal pH for adsorption and separation of V(V) from impurities was 1.8. Col...

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Veröffentlicht in:	JOM (1989) 2020-02, Vol.72 (2), p.953-961
Hauptverfasser:	Chen, Bo, Bao, Shenxu, Zhang, Yimin
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Sprache:	eng
Schlagworte:	Adsorption Aluminum Aqueous solutions Chemistry/Food Science Computer simulation Earth Sciences Effluents Electron microscopes Energy consumption Engineering Environment Experiments Flow velocity Impurities Iron Metals Physics Polymers Resins Separation Silicon Sodium carbonate Sodium sulfate Solvent extraction processes Sulfur Technical Article Vanadium
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creator	Chen, Bo Bao, Shenxu Zhang, Yimin
description	Separation of V(V) from simulated complex vanadium-bearing (SCV) solution containing Al(III), Fe(III), P(V), and Si(IV) using trialkylamine (N235)-impregnated resins has been investigated. Batch experiments proved that the optimal pH for adsorption and separation of V(V) from impurities was 1.8. Column experiments showed that V(V) was well adsorbed and separated from the impurities under conditions of flow rate of 1.0 mL min −1 and bed height of 12 cm. Most of the impurities that adsorbed on the N235-impregnated resin were effectively eluted with only 2.92% loss of V(V) using 12 bed volumes (BV) of 2 wt.% Na 2 SO 4 . Afterwards, V(V) was concentrated about 3.4 times and most of it was recovered using cycle desorption with 1 BV of 14 wt.% Na 2 CO 3 . The concentration of the impurities in the initial feed solution was greatly decreased using the present method, implying that V(V) can be effectively separated from SCV solution by such column operations.
doi_str_mv	10.1007/s11837-019-03944-4
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Batch experiments proved that the optimal pH for adsorption and separation of V(V) from impurities was 1.8. Column experiments showed that V(V) was well adsorbed and separated from the impurities under conditions of flow rate of 1.0 mL min −1 and bed height of 12 cm. Most of the impurities that adsorbed on the N235-impregnated resin were effectively eluted with only 2.92% loss of V(V) using 12 bed volumes (BV) of 2 wt.% Na 2 SO 4 . Afterwards, V(V) was concentrated about 3.4 times and most of it was recovered using cycle desorption with 1 BV of 14 wt.% Na 2 CO 3 . 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subjects	Adsorption Aluminum Aqueous solutions Chemistry/Food Science Computer simulation Earth Sciences Effluents Electron microscopes Energy consumption Engineering Environment Experiments Flow velocity Impurities Iron Metals Physics Polymers Resins Separation Silicon Sodium carbonate Sodium sulfate Solvent extraction processes Sulfur Technical Article Vanadium
title	Column Separation of Vanadium(V) from Complex Sulfuric Solution Using Trialkylamine-Impregnated Resins
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