New technique of comprehensive utilization of spent Al2O3-based catalyst

Journal of Central South University of Technology (English Edition)

Volumn 13, Issue 2, 2006, Pages 151-155

  Feng, Qi Ming ^a   Chen, Yun ^a   Shao, Yan Hai ^a   Zhang, Guo Fan ^a   Ou, Le Ming ^a   Lu, Yi Ping ^a  

^a CENTRAL SOUTH UNIVERSITY   (China)

Author keywords

Comprehensive utilization; Leaching rate; Molybdenum; Roasting with sodium; Spent Al2O3 based catalyst; Vanadium

Indexed keywords

CARBONATION DECOMPOSITION PROCESS; COMPREHENSIVE UTILIZATION; SODIUM ALUMINATE SOLUTION; SPENT ALUMINA BASED CATALYST;

ALUMINA; CALCINATION; LEACHING; MOLYBDENUM; NICKEL; PRECIPITATION (CHEMICAL); RECOVERY; VANADIUM;

CATALYSTS;

EID: 33745959457     PISSN: 10059784     EISSN: None     Source Type: Journal    
DOI: 10.1007/s11771-006-0147-9     Document Type: Article

References (18)

1. Anon L. Refining catalyst demand[J]. Oil and Gas Journal, 2000, 98(41): 64-66.
2. Rapaport D. Are spent hydrocracking catalysts listed hazardous wastes?[J]. Hydrocarbon Processing, 2000, 79(7): 49-53.
3. Chang T. Reclamation and landfill processes are alternatives to regeneration[J]. Oil and Gas Journal, 1998, 96(42): 79-84.
4. Trimm D L. The regeneration or disposal of deactivated heterogeneous catalysts[J]. Applied Catalysis A: General, 2001, 212(1): 153-160.
5. Marafi M, Stanislaus A. Options and processes for spent catalyst handling and utilization[J]. Journal of Hazardous Materials, 2003, 101(2): 123-132.
6. LIU Huan-qun. Recovering of spent catalyst in the foreign country[J]. Chinese Resource Comprehensive Utilization, 2000(12): 35-37. (in Chinese)
7. Toukai K T, Katsuta K K, Toubai H S, et al. Process for recovering valuable metal from waste catalyst. US, 5431892[P]. 1995-07-11.
8. Veal J T, Andersen K A, Kowaleski R M. Process to recover metals from spent catalyst. US, 6180072 B1[P]. 2001-01-30.
9. Yoo J S. Metal recovery and rejuvenation of metal-loaded spent catalysts[J]. Catalysis Today, 1998, 44(1): 27-46.
10. Mansi A, Monem A. Recovery of nickel oxide from spent catalyst[J]. Waste Management, 2002, 22: 85-90.
11. Chmielewski A G, Urbanski T S, Migdal W. Separation technologies for metals recovery from industrial wastes[J]. Hydrometallurgy, 1997, 45(3): 333-344.
12. Inoue K, Zhang P, Tsuyama H. Separation and recovery of rare metals from spent hydrodesulfurization catalysts by solvent extraction[C]//Third International Symposium on Recycling of Metals and Engineered Materials. Pennsylvania: Minerals, Metals and Materials Society, 1995: 393-404.
13. Furimsky E. Spent refinery catalysts: environment, safety and utilization[J]. Catalysis Today, 1996, 30(4): 223-236.
14. Luo L, Miyazaki T, Shibayama A, et al. A novel process for recovery of tungsten and vanadium from a leach solution of tungsten alloy scrap[J]. Minerals Engineering, 2003, 16(7): 665-670.
15. Radchenko E D, Nefedov B R, Aliev R R. Catalyst of crude oil deep processing[M]. Translated by LI Feng-xiao et al. Beijing: Chinese Petrochemical Industry Press, 1998. (in Chinese)
16. Soldenhoff K, Hayward N, Wilkins D. Direct solvent extraction of cobalt and nickel from laterite-acid pressure leach liquors[C]//EPD Congress. Pennsylvania: Minerals, Metals and Materials Society, 1998: 153-165.
17. Cheng C H. Purification of synthetic laterite leach solution by solvent extraction using D2EHPA[J]. Hydrometallurgy, 2000, 56(3): 369-386.
18. Tsakiridis P E, Agatzini S L. Process for the recovery of cobalt and nickel in the presence of magnesium and calcium from sulphate solutions by Versatic 10 and Cyanex 272[J]. Minerals Engineering, 2004, 17(4): 535-543.