Characteristics of New Absorbent System of Heteropoly Compound Solution for H2S Removal

Jing Wang; Rui Wang

doi:10.4028/www.scientific.net/KEM.531-532.246

Paper Titles

Enhanced Photoelectrochemical Performance of Fe-Doped WO₃ Film Electrode under Visible Light
p.230

Evolution of Defect Photoluminescence in Annealed N-Rich a-SiN_x:H Films
p.234

Bioinspired Synthesis of Cross-Linking of Dopamine-Containing Block Copolymers to Form Thermosensitive Covalent Hydrogels
p.238

Surface Hardening of 18CrNi3MoA-SH Steel with Heating in Electrolytic Plasma
p.242

Characteristics of New Absorbent System of Heteropoly Compound Solution for H₂S Removal
p.246

Synthesis and Structural Characterization of Zinc and Magnesium Doped Hydroxyapatite
p.250

Mechanochemical Synthesis of Hydroxyapatite Bioceramics through Two Different Milling Media
p.254

Development of Triphasic Calcium Phosphate–Carbon Nanotubes (HA/TCP-CNT) Composite: A Preliminary Study
p.258

The Optimization of Lapping Process Parameters Based on Extension Theory
p.262

HomeKey Engineering MaterialsKey Engineering Materials Vols. 531-532Characteristics of New Absorbent System of...

Characteristics of New Absorbent System of Heteropoly Compound Solution for H₂S Removal

Abstract:

A new liquid redox method for low sulfur containing gas treatment, with H2S concentration less than 1000mg/m3, was developed employing the heteropoly compounds of molybdenum and phosphorus by the present authors. The desulfurization characteristics of the absorbent system of vanadium substituted heteropoly acid, viz. H4PVMo11O40, were investigated by dynamic outlet-gas H2S concentration detection method. Like the aqueous solution of the parent compound, namely H3PMo12O40 or its sodium salt, H4PVMo11O40 solution can also be used as efficient absorbent for H2S removal. The absorbent system of H4PVMo11O40 solution was found to have fairly good absorption-regeneration performance, with a H2S removal rate of up to 100% in the presence of CuS as additive, hence it is promising in pollution control and resource reclamation.