Functional and environmental performance of waste foundry sand applied in landfills

References

• Casotti, B.P., Bel Filho, E.D. and Castro, P.C., 2011, Foundry Industry: Present Situation and Prospects. Metallurgy, BNDS Sector, n. 33, pp.121–162. Rio de Janeiro, Brazil. Available online at: www.bndes.gov.br (accessed 10 May 2015).
   Google Scholar
• Klinsky, L.M.G., 2013, Evaluation Reuse of Foundry Sand Discarded Residual Layered Pavements. Doctoral Thesis. Postgraduate Diploma in Transport Engineering, (USP, Brazil: School of Engineering of São Carlos, University of São Paulo).
   Google Scholar
• Siddique, R., Kaur, G. and Rajor, A., 2010, Waste foundry sand and its leachate characteristics. Resources, Conservation and Recycling, 54(12), 1027–1036.
   Web of Science ®Google Scholar
• Domingues, L.G.F. and Ferreira, G.C.S., 2014, Management application of waste foundry sand (WFS) in solid waste landfills. In: 4th International Conference on Industrial and Hazardous Waste Management, Crete, Greece, v. 1, pp. 39–40.
   Google Scholar
• American Foundry Society (AFS), 2013, Introduction to foundry sand. Available online at: http://www.afsinc.org/government/AFSFirst.cfm?ItemNumber=7887&navItemNumber=528 (accessed 12 Jan 2015).
   Google Scholar
• Gomes, L.P., Moraes, C.A.M. and Boff, R.D., 2007, Use of foundry sand in intermediate and final landfill covers. Metallurgy and Materials Technology, 4(3), 71–76.
   Google Scholar
• Ferreira, M.A.S. and Mahler, C.F., 2006, Evaluation of soil layers of intermediate and final cover - case study. (Dissertation), (Rio de Janeiro: Federal University of Rio de Janeiro).
   Google Scholar
• Environmental Protection Agency - USEPA 542-F-03-015, 2003, Evapotranspiration Landfill Cover Systems Fact Sheet, (Washington DC: Environmental Protection Agency - USEPA).
   Google Scholar
• Brazilian Association of Technical Standards, 1997, NBR 13896: Landfills for Non-Hazardous Waste - Criteria for the Design, Implementation and Operation, (Rio de Janeiro: Brazilian Association of Technical Standards).
   Google Scholar
• Zhang, H.F., Wang, Y.J., Wang, J.L., Huang, T.Y. and Xiong, Y., 2013, Environmental toxicity of waste foundry sand. Huanjing Kexue/Environmental Science, 34(3), 1174–1180.
   Google Scholar
• Soares, W.A.A., Ferraresi, G.N., Quináglia, G.A. and Uumbuzeiro, G.A., 2010, Toxicity of waste foundry sand using luminescent bacteria test with Vibrio fischeri. Brazilian Journal of Toxicology, 23(1–2), 17–21.
   Google Scholar
• Coz, A., Mantzavinos, D., Karageorgos, P., Kalogerakis, N., Andrés, A., Viguri, J.R. and Irabien, A., 2006, Influence of the organic compounds of the ecotoxicity in the treatment of foundry sludge and olive mill waste. Annali di Chimica, 96(9–10), 505–514.10.1002/(ISSN)1612-8877
   PubMedGoogle Scholar
• Environmental Company of São Paulo (CETESB), 2001, Technical Standard L5.227 - Toxicity Test with the Luminescent Bacterium Vibrio fischeri: Test Method, (São Paulo: Environmental Company of São Paulo).
   Google Scholar
• Azur Environmental, 2009, MicrotoxOmni^® Software. CD-ROM.
   Google Scholar
• Boscov, M.E.G., 2008, Environmental Geotechnics, (São Paulo: Office of Texts).
   Google Scholar
• Quissini, C.S., 2009, Study of the application of discarded foundry sand as an alternative material for landfill cover layer of waste. Masters dissertation, (Florianópolis: Federal University of Santa Catarina), p. 83.
   Google Scholar
• Alonso-Santurde, R., Andrés, A., Viguri, J.R., Raimondo, M., Guarini, G., Zanelli, C. and Dondi, M., 2011, Technological behavior and recycling potential of spent foundry sands in clay bricks. Journal of Environmental Management, 92, 994–1002.10.1016/j.jenvman.2010.11.004
   PubMed Web of Science ®Google Scholar
• Prim, E.C.C., 2003, Landfills: Study of the net of retention mechanisms percolated in clay soils. 3rd Week of Education and Research of the Federal University of Santa Catarina, (Santa Catarina: Department of Sanitary and Environmental Engineering), pp. 4–7.
   Google Scholar
• Mastella, M.A., Gilson, E.S., Pelisser, F., Ricken, C., Silva, L., Angioletto, E. and Montendo, O.R.K., 2014, Mechanical and toxicological evaluation of concrete artifacts containing waste foundry sand. Waste Management, 34, 1495–1500.
   PubMed Web of Science ®Google Scholar
• Coutinho Neto, B., 2004, Evaluation reuse of foundry sand as aggregate in dense asphalt mixtures. PhD thesis, (Sao Paulo: School of Engineering of São Carlos. University of São Paulo).
   Google Scholar
• Brazilian Technical Standard Association, 2004, NBR 10004: Solid Waste – Classification, (Rio de Janeiro: Brazilian Technical Standard Association).
   Google Scholar
• Environmental Protection Agency (USEPA) 846, 2004, Evaluating Solid Waste, (Washington DC: Environmental Protection Agency - USEPA).
   Google Scholar
• Guney, Y., Aydilec, A.H. and Demirkan, M.M., 2005, Geoenvironmental behavior of foundry sand amended mixtures for highway subbases. Waste Management, 26, 932–945.
   PubMed Web of Science ®Google Scholar
• Ximenes, E., Kim, Y., Mosier, N., Dien, B. and Ladisch, M., 2010, Inhibition of cellulases by phenols. Enzyme and Microbial Technology, 46, 170–176. doi:10.1016/j.enzmictec.2009.11.001.
   Web of Science ®Google Scholar
• Wilkie, A., Riedesel, K. and Owens, J., 2000, Stillage characterization and anaerobic treatment of ethanol stillage from conventional and cellulosics feedstocks. Biomass and Bioenergy, 19, 63–102.10.1016/S0961-9534(00)00017-9
   Web of Science ®Google Scholar