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Magnetic filtration/adsorption process for Snake River Plain Groundwater Treatment

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
A magnetic filtration/adsorption process has been evaluated for development for groundwater treatment at the Idaho National Engineering and Environmental Laboratory (INEEL). The process uses inexpensive magnetite (FeOźFe2O3) in a supported mode surrounded by an external magnetic field. Prior studies have been shown to remove actinides and fission products in laboratory studies. This research has focused on supporting magnetite in an economical manner that promotes both magnetic filtration/adsorption of metal species and satisfactory water flow. The process utilizes the natural metal ion adsorptive properties of magnetite as well as the High Gradient Magnetic Separation (HGMS) effect for removing metal colloids and submicron particles. Results are presented on scoping studies for developing the process for groundwater treatment at the INEEL.
Słowa kluczowe
Czasopismo
Rocznik
Strony
17--23
Opis fizyczny
Bibliogr. 29 poz., rys.
Twórcy
autor
  • Chemistry Department, United States Naval Academy, 572 Holloway Road, Annapolis, MD 21402, U.S.A., Tel.: 410-293-6601, Fax: 410-293-2218
autor
  • Eldredge Engineering, 1111 Caysie Ln, Idaho Falls, ID 83402, U.S.A
autor
  • Environmental Engineering and Science, Clemson University, 342 Computer Court, Anderson, South Carolina 29625-6510, U.S.A.
Bibliografia
  • 1. Boyd TE, Cusick MJ, Navratil JD (1986) Ferrite use in separation science and technology. In: Li NN, Navratil JD (eds) Recent developments in separation science, vol. 8. CRC Press, Inc., Boca Raton
  • 2. Boyd TE, Kochen RL (1982) Ferrite treatment of actinide waste solutions: a preliminary study. RFP-3299, CRD 81-064. Rockwell International, Golden, CO
  • 3. Boyd TE, Kochen RL, Chambers MJ, Shekell G (1983) Ferrite treatment of actinide waste solutions: continuous processing of rocky flats process waste. RFP-3476, UC-10 Chemical separations processes for plutonium and uranium, DOE/TIC4500 (Rev. 69). Rockwell International, Golden, CO
  • 4. Boyd TE, Kochen RL, Price MY (1982) Removal of radioactive materials from waste solutions via magnetic ferrites. In: Proc American Nuclear Society Topical Meeting on Treatment and Handling of Radioactive Waste, April 19−22, Richland, U S A, pp 1−10
  • 5. Boyd TE, Kochen RL, Price MY, Deitesfeld CA, Morales LM (1985) Ferrite treatment of actinide waste solutions: alternative methods of ferrite productions for use in waste treatment. RFP-3692, UC-10 Chemical separations processes for plutonium and uranium, DOE/TIC-4500 (Rev. 73). Rockwell International, Golden, CO
  • 6. Boyd TE, Kochen RL, Riordan GA, Morales LM (1984) Ferrite treatment of actinide waste solutions: multi-stage continuous processing. RFP-3582, UC-4 Chemistry, DOE/TIC-4500 (Rev. 72). Rockwell International, Golden, CO
  • 7. Boyd TE, Price MY, Kochen RL, Deitesfeld CA, Delaney CJ (1985) Ferrite treatment of actinide waste solutions: chemical interferences in actinide removal by ferrite treatment. RFP-3601, UC-10 Chemical separations processes for plutonium and uranium, DOE/TIC-4500 (Rev. 73). Rockwell International, Golden, CO
  • 8. Corbitt RA (1990) Standard handbook of environmental engineering. McGraw-Hill, New York
  • 9. Dixon DR (1985) Interaction of alkaline-earth-metal ions with magnetite. Colloids Surf 13:273−286
  • 10. Ebner AD, Ritter JA, Ploehn HJ, Kochen RL, Navratil JD (1999) New magnetic field-enhanced process for the treatment of aqueous waste. Separ Sci Technol 34;6-7:1277−1300
  • 11. Freeman HM (1998) Standard handbook of hazardous waste treatment and disposal. McGraw-Hill, New York
  • 12. Gurevitz D (1998) Method and apparatus for processing waste water. U S Patent 5,759,407
  • 13. Harusuke N (1997) Water purifier having a magnetic field generation device. U S Patent 5,628,900
  • 14. King CJ, Navratil JD (1986) Chemical separations. Litarvan, Denver
  • 15. Kochen RL, Navratil JD (1997) Method for regenerating magnetic polyamine-epichlorohydrine resin. U S Patent 5,652,190
  • 16. Kochen RL, Navratil JD (1997) Removal of radioactivematerials and heavy metals from water using magnetic resin. U S Patent 5,595,666
  • 17. Kochen RL, Thomas RL, Morales LM (1987) Actinide removal from aqueous solution with activated magnetite. RFP-4100, UC-4 Chemistry, DOE/TIC-4500 (Rev. 73). Rockwell International, Golden, CO
  • 18. LaGrega MD, Buckingham PL, Evans JC (1994) The environmental resources management group “Hazardous Waste Management”. McGraw-Hill, New York
  • 19. Macasek F, Navratil JD (1992) Separation chemistry. Horwood, New York
  • 20. Milonjić SK, Kopecni MM, Ilić ZE (1983) The point of zero charge and adsorption properties of natural magnetite. J Radioanal Nucl Chem 78;1:15−24
  • 21. Milonjić SK, Ruvarac A (1970) Adsorption of Cs+, Co2+ and Ce3+ from acid aqueous solutions on natural magnetite. Bulletin of the Boris Kidric Institute of Nuclear Sciences, Chemistry 21;3:21−26
  • 22. Navratil JD (1988) Removal of impurities using ferrites and magnetite. Australian Patent Application PJ0198
  • 23. Navratil JD, Kochen RL, Ritter JA (1995) Magnetic swing adsorption process. In: Proc for Waste Management Symp, Tucson, AZ: 7−38
  • 24. Petković DM, Milonjić SK (1969) Adsorption of cesium from basic water solutions on natural magnetite. Bulletin of the Boris Kidric Institute of Nuclear Sciences, Chemistry 20;3:17−23
  • 25. Schwertmann U, Cornell RM (1991) Iron oxides in the laboratory: preparation and characterization. VCH Publishers, Inc., New York
  • 26. Stadmuller A (1998) Magnetic separators. U S Patent 5,759,391
  • 27. Sun Z, Su F, Forsling W, Samskog P (1998) Surface characteristics of magnetite in aqueous suspension. J Colloid Interface Sci 197:151−159
  • 28. Tchobanoglous G, Burton FL, Stensel HD (1991) Wastewater engineering, treatment, disposal, and reuse. Metcalf & Eddy, Inc., 3rd ed. McGraw-Hill, New York
  • 29. U S Dept of Energy (1992) Record of decision technical support facility (TSF) injection well (TSF-05) and surrounding groundwater contamination (TSF-23). Operable Unit 1-07A, Waste Area Group 1, Idaho National Engineering Laboratory
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BUJ5-0004-0004
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