Assessing Water Footprint of Copper Production by Pyrometallurgy

Zhen Lu Lei; Xian Zheng Gong; Yu Liu; Xiao Qing Li; Shui Long Chen

doi:10.4028/www.scientific.net/MSF.1035.1071

Paper Titles

Kinetics of Copper Ion Leaching from Cement-Solidified Body of Blast Furnace Slag Adsorbing Copper Ion
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Ag₂O/ZnO Heterostructures with Enhanced Photocatalytic Activity
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Life Cycle Assessment of the NdFeB Recycling Process Route for Oil Sludge Waste Treatment
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Environmental Impact Analysis of Automobile Laminated Glass Production
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Assessing Water Footprint of Copper Production by Pyrometallurgy
p.1071

Preparation of Pd/PPy/Foam-Ni Electrode and its Electrocatalytic Hydrodechlorination of Dichlorophenols
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Effect of Trivalent Metal Cations on the Properties of LDHs Supercapacitors Prepared from Electroplating Sludge
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NO Reduction Using Coal and Active Carbon with and without Catalysts
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Water Footprint Evaluation of the Production of Float Flat Glass
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HomeMaterials Science ForumMaterials Science Forum Vol. 1035Assessing Water Footprint of Copper Production by...

Assessing Water Footprint of Copper Production by Pyrometallurgy

Abstract:

As an important tool for water resource environmental impact assessment, the application of water footprint assessment method in copper production process is conducive to more accurate assessment of water resource environmental impact in copper production process. The water footprint assessment method released by the Water Footprint Network was used to study the water footprint of the production process of cathode copper products produced by pyrometallurgy. It was found that the water footprint of 1 ton of copper produced by pyrometallurgy was 242m³, of which the blue water footprint accounted for 60%, the grey water footprint accounted for 40%. The direct water footprint accounted for 67% and the indirect water footprint accounted for 33%. The characteristics of water footprint contribution at each process were compared, which provided data support and reference for enterprises to better understand the water resource environmental impact of copper by pyrometallurgy and to choose the water resource utilization mode with their own production characteristics.

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Periodical:

Materials Science Forum (Volume 1035)

Pages:

1071-1077

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.1035.1071

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Online since:

June 2021

Authors:

Zhen Lu Lei, Xian Zheng Gong*, Yu Liu, Xiao Qing Li, Shui Long Chen

Keywords:

Copper Production, Water Footprint, Water Resource

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* - Corresponding Author

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