Process optimization of nickel extraction from hazardous waste

Journal title

Archives of Environmental Protection




vol. 38


No 3



Factorial design ; hazardous waste ; nickel extraction ; optimization

Divisions of PAS

Nauki Techniczne


Polish Academy of Sciences




Artykuły / Articles


DOI: 10.2478/v10265-012-0020-x ; ISSN 2083-4772 ; eISSN 2083-4810


Archives of Environmental Protection; 2012; vol. 38; No 3


Alane N. (2008), Acid Leaching of Zinc from ZNO/Al<sub>2</sub>O<sub>3</sub> Catalyst, Lebanese Science Journal, 9, 2, 63. ; Bernstad A. (2011), Property-close source separation of hazardous waste and waste electrical and electronic equipment - A Swedish case study, Waste Management, 31, 536, ; Hagelücken C. (2006), <i>Improving metal returns and eco-efficiency in lectronic recycling</i>, Umicore Precious Metals Refining, null, 218. ; Altundoğan H. (1998), Heavy Metal Pollution Potential of Zinc Leach Residues discarded in Çinkur Plant, Turkish Journal of Engineering and Environmental Science, 22, 167. ; Turan M. (2004), Recovery of zinc and lead from zinc plant residue, Hydrometallurgy, 75, 169, ; Safarzadeh M. (2009), Kinetics of sulfuric acid leaching of cadmium from Cd-Ni zinc plant residues, Journal of Hazardous Materials, 163, 880, ; Gharabaghi M. (2011), Acidic leaching of cadmium from zinc plant residue, Physicochem. Problem of Mineral Processing, 47, 91. ; Hanson D. (2003), Nickel Chemical and Engineering News, 81, 82, ; Mudd G. (2010), Global trends and environmental issues in nickel mining: Sulfides versus laterites, Ore Geology Reviews. ; Marafi M. (2008), Spent hydroprocessing catalyst management: A review: Part II. Advances in metal recovery and safe disposal methods, Resources, Conservation and Recycling, 53, 126, ; I. Valverde, Jr (2008), Hydrometallurgical route to recover molybdenum, nickel, cobalt and aluminum from spent hydrotreating catalysts in sulphuric acid medium, Journal of Hazardous Materials, 160, 310, ; Abdel-Aal E. (2004), Kinetic study on the leaching of spent nickel oxide catalyst with sulfuric acid, Hydrometallurgy, 74, 189, ; Lupi C. (2003), Electrolytic nickel recovery from lithium-ion batteries, Minerals Engineering, 16, 537, ; Nogueira C. (2004), Leaching behaviour of electrode materials of spent nickel-cadmium batteries in sulphuric acid media, Hydrometallurgy, 72, 111, ; Lothongkum A. (2009), Selective recovery of nickel ions from wastewater of stainless steel industry via HFSLM, Journal of Alloys and Compounds, 476, 940, ; Nan J. (2006), Recovery of metal values from a mixture of spent lithium-ion batteries and nickel-metal hydride batteries, Hydrometallurgy, 84, 75, ; Shen Y.-F. (2008), Recovery of Co(II) and Ni(II) from hydrochloric acid solution of alloy scrap, Transactions of Nonferrous Metals Society of China, 18, 1262, ; Tenório J. (2002), Recovery of Ni-based alloys from spent NiMH batteries, Journal of Power Sources, 108, 70, ; Feng Q.-M. (2009), Kinetics of nickel leaching from roasting-dissolving residue of spent catalyst with sulfuric acid, Journal of Central South University of Technology, 16, 410, ; Zhuang J. (2006), Nickel recovery and stabilization of nickel waste tailings, International Journal of Mining, Reclamation and Environment, 20, 127, ; Lee J. (2010), Nickel recovery from spent Raneynickel catalyst through dilute sulfuric acid leaching and soda ash precipitation, Journal of Hazardous Materials, 176, 1122, ; Mulak W. (2005), Kinetics of nickel leaching from spent catalyst in sulphuric acid solution, International Journal of Mineral Processing, 77, 231, ; Senanayake G. (2010), Effect of thiosulfate, sulfide, copper(II), cobalt(II)/(III) and iron oxides on the ammoniacal carbonate leaching of nickel and ferronickel in the Caron process, Hydrometallurgy, 105, 60, ; Safarzadeh M. (2010), The effect of heat treatment on selective separation of nickel from Cd-Ni zinc plant residues, Separation and Purification Technology, 73, 339, ; Lee I. (2006), Factorial experimental design for recovering heavy metals from sludge with ion-exchange resin, Journal of Hazardous Materials, 138, 549, ; Myers R. (2009), Response Surface Methodology: Process and product optimization using designed experiments. ; Box G. (1978), Data Analysis and Modeling. ; Montgomery D. (2008), Design and Analysis of Experiments. ; Paterakis P. (2002), Evaluation and simultaneous optimization of some pellets characteristics using a 33 factorial design and the desirability function, International Journal of Pharmaceutics, 248, 51, ; Bezerra M. (2008), Response surface methodology (RSM) as a tool for optimization in analytical chemistry, Talanta, 76, 965, ; Lundstedt T. (1998), Experimental design and optimization, Chemometrics and Intelligent Laboratory Systems, 42, 3, ; Mason R. (2003), Statistical Design and Analysis of Experiments, Eighth Applications to Engineering and Science, ; Pagnanelli F. (2004), Leaching of low-grade manganese ores by using nitric acid and glucose: optimization of the operating conditions, Hydrometallurgy, 75, 157, ; Bose A. (2009), Factorial Design of Experiments, Examples & Exercises in: BIMITECH, 38.

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