Separation of metals and phosphorus from incinerated sewage sludge ash

Water Science and Technology

Volumn 67, Issue 11, 2013, Pages 2488-2493

  Ito, A ^a   Yamada, K ^a   Ishikawa, N ^a   Umita, T ^a  

^a IWATE UNIVERSITY   (Japan)

Author keywords

Biological acidification; Incinerated sewage sludge ash; Metals; Phosphorus; Recovery

Indexed keywords

DISSOLUTION EFFICIENCIES; EFFECT OF PH; FERRIC IONS; NEUTRALISATION; PH VALUE; RETENTION TIME; SEMIBATCH REACTOR; SEWAGE SLUDGE ASH;

ACIDIFICATION; ALUMINUM; DISSOLUTION; HEAVY METALS; LASERS; METAL RECOVERY; METALS; PH; PHOSPHORUS; PRECIPITATION (CHEMICAL); RECOVERY; SEWAGE SLUDGE;

FILTRATION;

ALUMINUM; ARSENIC; CADMIUM; CALCIUM PHOSPHATE; CHROMIUM; COPPER; EDETIC ACID; FERRIC ION; IRON; MANGANESE; METAL; NICKEL; PHOSPHORUS; SULFUR; SULFURIC ACID;

ACIDIFICATION; DISSOLUTION; INCINERATION; PH; PHOSPHORUS; PRECIPITATION (CHEMISTRY); SEPARATION; SEWAGE;

ACIDIFICATION; ARTICLE; ASH; BATCH REACTOR; BIOLEACHING; DISSOLUTION; HEAVY METAL REMOVAL; INCINERATION; PH; PRECIPITATION; SLUDGE; SULFUR OXIDIZING BACTERIUM;

BACTERIA; BIOREACTORS; CHELATING AGENTS; EDETIC ACID; ENVIRONMENTAL POLLUTANTS; INCINERATION; INDUSTRIAL WASTE; METALS; PARTICULATE MATTER; PHOSPHORUS; RECYCLING; SEWAGE; SULFURIC ACIDS;

EID: 84878899973     PISSN: 02731223     EISSN: None     Source Type: Journal    
DOI: 10.2166/wst.2013.142     Document Type: Article

References (12)

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