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Falamaki, Amin. (1393). Toxicity Characteristic Leaching Procedure for Health Assessment of Stabilized Plating Sludge Using Amendments. سامانه مدیریت نشریات علمی, 3(1), 36-44.
Amin Falamaki. "Toxicity Characteristic Leaching Procedure for Health Assessment of Stabilized Plating Sludge Using Amendments". سامانه مدیریت نشریات علمی, 3, 1, 1393, 36-44.
Falamaki, Amin. (1393). 'Toxicity Characteristic Leaching Procedure for Health Assessment of Stabilized Plating Sludge Using Amendments', سامانه مدیریت نشریات علمی, 3(1), pp. 36-44.
Falamaki, Amin. Toxicity Characteristic Leaching Procedure for Health Assessment of Stabilized Plating Sludge Using Amendments. سامانه مدیریت نشریات علمی, 1393; 3(1): 36-44.

Toxicity Characteristic Leaching Procedure for Health Assessment of Stabilized Plating Sludge Using Amendments

Journal of Health Sciences & Surveillance System
مقاله 5، دوره 3، شماره 1، فروردین 2015، صفحه 36-44    اصل مقاله (829.76 K)
نوع مقاله: Original Articles
نویسنده
Amin Falamaki*
Department of Civil Engineering; Payame Noor University
چکیده
Background: The occurrence of heavy metals in the environment is of important concern due to their toxicity and health effects on humans, including cancer. Because metals have been extensively used for centuries in commerce, environmental contamination is widespread; moreover, exposure to metals and metal compounds continues to be a significant public health problem. Electroplating sludge contains heavy metals. Solidification/Stabilization can be used to avoid leaching of these metals to the environment. The aim of this study was evaluating the effectiveness of the application of dicalcium phosphate (DCP) and sodium tripolyphosphate (STPP) on Cd, Co, Cu, Ni, Pb and Zn immobilization in dewatered metal plating sludge.Methods: The ratios of STPP and DCP per dry plating sludge were determined to be 0.1%, 0.2% and 0.5% by weight. Metal leaching from the solidified plating wastes was assessed using the toxicity characteristic leaching procedure (TCLP). The results showed that the concentration of metals in untreated sludge were appropriate to classify this sludge as a hazardous waste as described in The Code of Federal Regulations (CFR) 40 CFR 261.24.Results: DCP and STPP lowered the concentration of metal in the effluent. Increasing DCP concentration from 0.1 to 0.5% decreases the contaminant concentration in the effluent. F or Cd, Pb, Cu and Ni increasing the percentage of STPP in the sludge increases the contaminant’s concentration resulting from TCLP extraction.Conclusion: Immobilization of heavy metals was more effective through application of DCP rather than STPP. Moreover, it may minimize the potential risk of groundwater eutrophication connected with the application of highly soluble phosphate like STPP.
کلیدواژه‌ها
Heavy metals؛ Immobilization؛ Plating sludge؛ Phosphate treatment؛ Toxicity
مراجع
  1. Nzihou A, Sharrock P. Role of Phosphate in the
  2. Remediation and Reuse of Heavy Metal Polluted
  3. Wastes and Sites. Waste Biomass Valor 2010; 1: 163-74.
  4. Zhao Q, Wang Y, Cao Y, Chen A, Ren M, Ge Y, et
  5. al. Potential health risks of heavy metals in cultivated
  6. topsoil and grain, including correlations with human
  7. primary liver, lung and gastric cancer, in Anhui
  8. province, Eastern China. Sci Total Environ 2014;
  9. -471: 340-7.
  10. Brady NC, Weil R: The nature and properties of soils.
  11. th ed. Pearson Prentice Hall, 2008.
  12. Caussy D, Gochfeld M, Gurzau E, Neagu C, Ruedel
  13. H. Lessons from case studies of metals: investigating
  14. exposure, bioavailability, and risk. Ecotoxicol Environ
  15. Saf 2003; 56(1): 45-51.
  16. Jafarnejadi AR, Homaee M, Sayyad G, Bybordi
  17. M. Large Scale Spatial Variability of Accumulated
  18. Cadmium in the Wheat Farm Grains. Soil Sediment
  19. Contam 2011; 20: 98-113.
  20. Forti E, Salovaara S, Cetin Y, Bulgheroni A, Tessadri
  21. R, Jennings P, et al. In vitro evaluation of the toxicity
  22. induced by nickel soluble and particulate forms in
  23. human airway epithelial cells. toxicol In vitro 2011;
  24. (2): 454-61.
  25. Navarro A, Cardellach E, Corbella M. Immobilization
  26. of Cu, Pb and Zn in mine-contaminated soils using
  27. reactive materials. J Hazard Mater 2011; 186(2-3):
  28. -85.
  29. Song YC, Sivakumar S, Nguyen T, Kim SH, Kim BG.
  30. The immobilization of heavy metals in biosolids using
  31. phosphate amendments-Comparison of EPA (6010 and
  32. and selective sequential extraction methods. J
  33. Hazard Mater 2009; 167: 1033-7.
  34. US EPA. Toxicity Characteristic Leaching Procedure
  35. (Method 1311) in SW-846. Office of Solid Waste,
  36. Washington DC. 1992. 35 p.
  37. Tang P, Zhou Y, Xie Z. Immobilization of heavy metals
  38. in sludge using phosphoric acid and monobasic calcium
  39. phosphate. J Zhejiang Univer. (SCIENCE A: Applied
  40. Physics & Engineering) 2013; 14(3): 177-86.
  41. Mignardi S, Corami A, Ferrini V. Evaluation of the
  42. effectiveness of phosphate treatment for the remediation
  43. of mine waste soils contaminated with Cd, Cu, Pb, and
  44. Zn. Chemosphere 2012; 86(4): 354-60.
  45. Falamaki A, Shariatmadari N, Noorzad A. Strength
  46. properties of Hexametaphosphate treated soil. J of
  47. Geotech Geoenviron Eng. ASCE2008; 134(8): 1215-18.
  48. Falamaki A, Tavallali H, Eskandari M, Rezanejad
  49. Farahmand S. Immobilizing some heavy metals by
  50. mixing contaminated soils with phosphate admixtures.
  51. Int J Civ Eng. In press 2015. 14 Tavallali H, Falamaki A, Salehi H. Stabilization of
  52. metal contaminants in municipal waste leachate using
  53. metal precipitant additives. Int J Chemtech Res 2010;
  54. (3): 1753-60.
  55. Falamaki A, Tavallali H, Eskandari M, Moradi
  56. Estahbanati M. Remediation of contaminated soils
  57. with cadmium and copper using dicalcium phosphate.
  58. J Soil Water Resour Conserv 2013; 3(1): 33-42.
  59. Zupancic M, Bukovec N, Milacic R, Scancar J.
  60. Comparison of various phosphate stabilisation agents
  61. for the immobilisation of Ni and Zn in sewage sludge.
  62. Water Air Soil Poll 2004; 156: 57-69.
  63. Asavapisit S, Naksrichum S, Harnwajanawong N.
  64. Strength, leachability and microstructure characteristics
  65. of cement-based solidified plating sludge. Cement
  66. Concrete Res 2005; 35: 1042-9.
  67. Chindaprasirt P, Sinsiri T, Napia C, Jaturapitakkul
  68. C. solidification of heavy metal sludge using cement,
  69. fly ash and silica fume. Indian J Eng Mater Sci 2013;
  70. : 405-14.
  71. SchrodterK, Bettermann G, Staffel T, Wahl F, Klein
  72. T, Hofmann T. Phosphoric Acid and Phosphates. In
  73. Ullmann’s Encyclopedia of Industrial Chemistry.
  74. Wiley-VCH, Weinheim; 2008. doi:10.1002/14356007.
  75. a19_465.pub3
  76. Miretzky P, Cirelli AF. Phosphates for Pb Immobilization
  77. in Soils: A Review. In Lichtfouse E, editor: Sustainable
  78. Agriculture Reviews. Springer Dordrecht Heidelberg
  79. London New York; 2009. P. 351-370.
  80. Cotter-Howells J, Caporn S. Remediation of
  81. contaminated land by formation of heavy metal
  82. phosphates. Appl Geochem 1996; 11: 335-42.
  83. Venkateswaran P, Vellaichamy S, Palanivel K.
  84. Speciation of heavy metals in electroplating industry
  85. sludge and wastewater residue using inductively
  86. coupled plasma. Int J Environ Sci Tech 2007; 4(4):
  87. -504.
  88. Corami A, Mignardi S, Ferrini V. Cadmium removal
  89. from single- and multi-metal (Cd+Pb+Zn+Cu) solutions
  90. by sorption on hydroxyapatite. J Colloid Interf Sci
  91. ; 317: 402-8.
  92. Corami A, Mignardi S, Ferrini V. Copper and zinc
  93. decontamination from single- and binary-metal
  94. solutions using hydroxyapatite. J Hazard Mater 2007;
  95. (1-2): 164-70.
  96. Mignardi, S, Corami, A, Ferrini, V. Immobilization of
  97. Co and Ni in mining-impacted soils using phosphate
  98. amendments. Water Air Soil Pollut. 2013; 224: pp. 1-10.
  99. Theodoratos P, Papassiopi N, Xenidis A. Evaluation of
  100. monobasic calcium phosphate for the immobilization
  101. of heavy metals in contaminated soils from Lavrion.
  102. J Hazard Mater 2002; 94(2): 135-46.
  103. Dybowska A, Manning DAC, Collins MJ, Wess T,
  104. Woodgate S, Valsami-Jones E. An evaluation of the
  105. reactivity of synthetic and natural apatites in the
  106. presence of aqueous metals. Sci Total Environ 2009;
  107. : 2953-65.
  108. Hettiarachchi GM, Pierzynski GM, Ransom MD.
  109. In situ stabilization of soil lead using phosphorus. J
  110. Environ Qual 2001; 30(4): 1214-21.
  111. Sugiyama S, Ichii T, Masayoshi F, Katsuhiro K, Tahei T,
  112. Shigemoto N, Hayashi H. Heavy metal immobilization
  113. in aqueous solution using calcium phosphate and
  114. calcium hydrogen phosphates. J Colloid Interf Sci
  115. ; 259(2): 408-10.
  116. Cao XD, Ma LQ, Rhue DR, Appel CS. Mechanisms
  117. of lead, copper and zinc retention by phosphate rock.
  118. Environ Pollut 2004; 131(3): 435-44.
  119. Xu Y, Schwartz FW, Traina SJ. Sorption of Zn2+ and
  120. Cd2+ on hydroxyapatite surfaces. Environ Sci Tech
  121. ; 28(8): 1472-80.
  122. Ma QY, Traina SJ, Logan TJ, Ryan JA. Effects
  123. of aqueous Al, Cd, Cu, Fe (II), Ni, and Zn on Pb
  124. immobilization by hydroxyapatite. Environ Sci Tech
  125. ; 28(7): 1219-28.
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