Leachate tertiary treatment using wetlands cultivated with oilseeds
DOI :
https://doi.org/10.5902/2236117038519Mots-clés :
Wetlands, Sunflower, LeachateRésumé
The objective of this study was to evaluate the efficiency of the wetlands cultivated with sunflower and soybean in the removal of Chemical Oxygen Demand, ammonia, nitrate, nitrite, total phosphorus and Kjeldahl Total Nitrogen (KTN) of the treated leachate from the landfill treatment plant of the city of Lages / SC. It was also analyzed the plants development as a function of the effluent applied in the wetlands compared to wetlands irrigated with chemical fertilizer. The wetlands were operated in batch with hydraulic retention times (HRT) of 2 and 4 days, receiving treated slurry in concentrations of 10 and 25% and liquid chemical fertilizer (5 ml / L). In the tests carried out with HRT of 4 days only the concentrations of COD and of ammonia were analyzed. After 4 months, the plants size was measured to verify their growth. In the tests carried out with the soybean there was no germination of the seeds. In both HRT tested, a greater removal of phosphorus, ammonia, nitrite and KTN was observed when 25% concentration of leachate. It was observed that the sunflower plants showed a higher size when cultivated in wetlands operated with HRT of 4 days and that they received the treated leachate in the concentration of 10%.Téléchargements
Références
APHA; AWWA; WPCF. Standard Methods for the Examination of Water & Wastewater. 21 ed. Washington, 2005.
CHRISTENSEN, T.R.; JOABSSON, A. Methane emissions from wetlands and their relationship with vascular plants: an Arctic example. Global Change Biology, v. 7, p. 919-932, 2001.
DUTRA, C. C.; PRADO, E. A. F.; PAIM, L. R.; SCALON, S. P.Q. Desenvolvimento de plantas de girassol sob diferentes condições de fornecimento de água. Semina: Ciências Agrárias, Londrina, v. 33, suplemento 1, p. 2657-2668, 2012.
FERRARI, R.A.; OLIVEIRA, V.S.; SCABIO, A. Oxidative stability of biodiesel from soybean oil fatty acid ethyl esters. Quim. Nova, v. 28, n.1, p.20, 2005.
JORDÃO, E. P.; PESSÔA, C. A. 2005. Tratamento de esgotos domésticos. Associação Brasileira de Engenharia Sanitária e Ambiental. 4. ed. Rio de Janeiro, 2005
KADLEC, R. H. Overview: surface flow constructed wetlands. Wat. Sci. and Tech. v. 32, n. 3, 1995.
KERN, J.; IDLER, C. Treatment of domestic and agricultural wastewater by reed bed systems. Ecological Engineering, v. 12, 1999.
KOZERSKI, R.G.; HESS, C.S. Estimativa dos poluentes emitidos pelos ônibus e microônibus de Campo Grande/MS, empregando como combustível diesel, biodiesel ou gás natural. Eng. Sanit. Ambient., v. 11, n. 2, p.113-117, 2006.
LUTZ, I. A. Métodos Químicos e Físicos para Análise de Alimentos, São Paulo, 2ª ed. 1976.
MINISTÉRIO DO MEIO AMBIENTE – MMA. Caracterização de Diferentes Oleaginosas para a Produção de Biodiesel. Disponível on line: (http://www.mma.gov.br/estruturas/sqa_pnla/_arquivos/item_5.pdf. Acesso: 18/09/2017, 2006.
MITTELBACH, M. Lipase catalyzed alcoholysis of sunflower oil. J. of American Oil Chem. Soc., v. 67, p.168-170, 1990.
PEREIRA, B. F. F.; ABREU, C. A.; ROMEIRO, S.; PAZ-GONZÁLEZ, A. Pb phytoextraction by maize in a Pb treated Oxisol. Scientia Agricola, v.64, p.52-60, 2007.
PROCHASKA, C.A.; ZOUBOULIS, A. I. Removal of phosphates by pilot vertical-flow constructed wetlands using a mixture of sand and dolomite as substrate. Ecological Engineering, v. 26, 2006.
ROMEIRO, S.; LAGÔA, A. M. M. A.; FURLANI, P. R.; ABREU, C. A.; ABREU, M. F. Lead uptake and tolerance of Ricinus communis L. Brazilian Journal of Plant Physiology, v.18, p.1-5. 2005.
RUTTENS, A.; BOULET, J.; WEYENS, N.; SMEETS, K.; ADRIAENSEN, K.; MEERS, E.; SLYCKEN, S. VAN.; TACK, F.; MEIRESONNE, L.; THEWYS, T.; WITTERS, N.; CARLEER, R.; DUPAE, R.; VANGRONSVELD, J. Short rotation coppice culture of willows and poplars as energy crops on metal contaminated agricultural soils. International Journal of Phytoremediation, v.13, p.194-207, 2011.
SUN, G.; GRAY, K.R.; BIDDLESTONE, A. J.; COOPER, D.J. Treatment of agricultural wastewater in a combined tidal flow-downflow reed bed system. Water Science and Technology, v. 40, n. 1, 1999.
TCHOUBANOGLOUS, G.; KREITH, F. Handbook of Solid Waste Management. 2 Ed. Nova Iorque. McGraw-Hill, 2002.
WOOD, R. B. & McATAMNEY, C. F. Constructed wetlands for wastewater treatment: the use of laterite in the bed medium in phosphurus and heavy metal removal. Hidrobiology, v. 340, 1996.
ZEITOUNI, C. F.; BERTON, R. S.; ABREU, C. A fitoextração de cádmio e zinco de um latossolo vermelho-amarelo contaminado com metais pesados. Bragantia, v.66, p.649-657, 2007.
ZHAO, Y. Q.; SUN, G.; ALLEN, S. J. Anti-sized reed bed system for animal wastewater treatment: a comparative study. Water Research, v. 38, 2004.
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