Electroplating sludge metal recovering with vitrification using mineral powder additive

Resources, Conservation and Recycling

Volumn 58, Issue , 2012, Pages 45-49

  Chou, I Cheng ^a   Kuo, Yi Ming ^a   Lin, Chitsan ^b   Wang, Jian Wen ^a   Wang, Chih Ta ^a   Chang Chien, Guo Ping ^c  

^a CHUNG HWA UNIVERSITY OF MEDICAL TECHNOLOGY   (Taiwan)

^b NATIONAL KAOHSIUNG UNIVERSITY OF APPLIED SCIENCES   (Taiwan)

^c CHENG SHIU UNIVERSITY   (Taiwan)

Author keywords

Electroplating sludge; Metal recovery; Reductant additive; Vitrification

Indexed keywords

ATOMIC ADSORPTION SPECTROMETERS; BUILDING COSTS; COST-EFFECTIVE TECHNOLOGY; CRYSTALLINE PHASIS; ELECTROPLATING SLUDGE; FINANCIAL SUPPORT; MASS CONTENT; MASS RATIO; MINERAL POWDERS; NI ELECTROPLATING; OPTIMAL EFFICIENCY; PLATING SLUDGE; RECOVERY EFFICIENCY; REDUCTANTS; SECONDARY METALS; TOXICITY CHARACTERISTIC LEACHING PROCEDURES; VITRIFICATION PROCESS; XRD; XRD PATTERNS;

ADSORPTION; CHROMIUM; CHROMIUM COMPOUNDS; COPPER; COST BENEFIT ANALYSIS; ECONOMIC ANALYSIS; EFFICIENCY; ELECTROPLATING; LEACHING; LEAD; MANGANESE; METALS; OPTIMIZATION; POWDER METALS; QUARTZ; SILICATE MINERALS; SLAGS; VITRIFICATION;

METAL RECOVERY;

ALUMINUM; CALCIUM; CALCIUM SILICATE; CHROMIUM; COPPER; INDUSTRIAL CHEMICAL; IRON; LEAD; LIMESTONE; MANGANESE; METAL; MINERAL; NICKEL; ZINC;

ECONOMIC ANALYSIS; ELECTROKINESIS; LEACHING; METAL; METALLURGY; RECOVERY; SLUDGE; TECHNICAL EFFICIENCY; VITRIFICATION; WASTE TREATMENT;

ARTICLE; ATOMIC ABSORPTION SPECTROMETRY; BUILDING MATERIAL; CHEMICAL ANALYSIS; CHEMICAL COMPOSITION; CHEMICAL STRUCTURE; CONTROLLED STUDY; COST BENEFIT ANALYSIS; COST EFFECTIVENESS ANALYSIS; CRYSTAL STRUCTURE; ECONOMIC EVALUATION; ELECTROPLATING INDUSTRY; FINANCIAL MANAGEMENT; GOVERNMENT; INDUSTRIAL SLUDGE; LEACHING; METAL RECOVERY; VITRIFICATION;

TAIWAN;

EID: 80855130430     PISSN: 09213449     EISSN: 18790658     Source Type: Journal    
DOI: 10.1016/j.resconrec.2011.10.006     Document Type: Article

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