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Environmental Technology Volume 41, 2020 - Issue 7
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Articles

Post-treatment of effluents from UASB reactor treating industrial wastewater sediment by constructed wetland

Fatih TufanerDepartment of Environmental Engineering, Faculty of Engineering, Adiyaman University, Adiyaman, TurkeyCorrespondence[email protected]
ORCID Iconhttps://orcid.org/0000-0002-1286-7846View further author information
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Pages 912-920 | Received 02 Jun 2018, Accepted 12 Aug 2018, Published online: 06 Sep 2018

References

  • Álvarez JA, Ruíz I, Soto M. Anaerobic digesters as a pretreatment for constructed wetlands. Ecol Eng. 2008;33(1):54–67.
  • von Sperling MV. Comparison among the most frequently used systems for wastewater treatment in developing countries. Water Sci Technol. 1996;33(3):59–72.
  • Foresti E. Anaerobic treatment of domestic sewage: established technologies and perspectives. Water Sci Technol. 2002;45(10):181–186.
  • Tufaner F, Avşar Y. Effects of co-substrate on biogas production from cattle manure: a review. Int J Environ Sci Technol. 2016;13(9):2303–2312.
  • Tufaner F. Investigation of improving biomethanization processes of cattle manure [PhD thesis]. Istanbul: Yıldız Technical University; 2015.
  • Penetra RG, Reali MAP, Foresti E, et al. Post-treatment of effluents from anaerobic reactor treating domestic sewage by dissolved-air flotation. Water Sci Technol. 1999;40(8):137–143.
  • de la Varga D, Díaz MA, Ruiz I, et al. Heavy metal removal in an UASB-CW system treating municipal wastewater. Chemosphere. 2013;93(7):1317–1323.
  • El-Khateeb MA, Al-Herrawy AZ, Kamel MM, et al. Use of wetlands as post-treatment of anaerobically treated effluent. Desalination. 2009;245(1–3):50–59.
  • Shutes RBE, Revitt DM, Lagerberg IM, et al. The design of vegetative constructed wetlands for the treatment of highway runoff. Sci Total Environ. 1999;235(1–3):189–197.
  • Barros P, Ruiz I, Soto M. Performance of an anaerobic digester-constructed wetland system for a small community. Ecol Eng. 2008;33(2):142–149.
  • Singh S, Haberl R, Moog O, et al. Performance of an anaerobic baffled reactor and hybrid constructed wetland treating high-strength wastewater in Nepal – a model for DEWATS. Ecol Eng. 2009;35(5):654–660.
  • Matos MP, von Sperling M, Matos AT, et al. Key factors in the clogging process of horizontal subsurface flow constructed wetlands receiving anaerobically treated sewage. Ecol Eng. 2017;106:588–596.
  • Comino E, Riggio VA, Rosso M. Constructed wetland treatment of agricultural effluent from an anaerobic digester. Ecol Eng. 2013;54:165–172.
  • Ruiz I, Álvarez JA, Díaz MA, et al. Municipal wastewater treatment in an anaerobic digester-constructed wetland system. Environ Technol. 2008;29(11):1249–1256.
  • Mbuligwe SE. Comparative effectiveness of engineered wetland systems in the treatment of anaerobically pre-treated domestic wastewater. Ecol Eng. 2004;23(4–5):269–284.
  • de Sousa JT, Van Haandel A, Lima EPC, et al. Performance of constructed wetland systems treating anerobic effluents. Water Sci Technol. 2003;48(6):295–299.
  • Kadlec R, Knight R, Vymazal J, et al. Constructed wetlands for pollution control: processes, performance, design and operation. IWA Specialist Group on Use of Macrophytes in Water Pollution Control, Scientific and Technical Report 8. London: IWA Publishing; 2000.
  • Yousefi Z, Mohseni-Bandpei A. Nitrogen and phosphorus removal from wastewater by subsurface wetlands planted with Iris pseudacorus. Ecol Eng. 2010;36(6):777–782.
  • Peruzzi E, Masciandaro G, Macci C, et al. Heavy metal fractionation and organic matter stabilization in sewage sludge treatment wetlands. Ecol Eng. 2011;37(5):771–778.
  • Yang J, Zheng G, Yang J, et al. Phytoaccumulation of heavy metals (Pb, Zn, and Cd) by 10 wetland plant species under different hydrological regimes. Ecol Eng. 2017;107:56–64.
  • García JA, Paredes D, Cubillos JA. Effect of plants and the combination of wetland treatment type systems on pathogen removal in tropical climate conditions. Ecol Eng. 2013;58:57–62.
  • Lu X, Kruatrachue M, Pokethitiyook P, et al. Removal of cadmium and zinc by water hyacinth, Eichhornia crassipes. Sci Asia. 2004;30:93–103.
  • Rahmani GNH, Sternberg SPK. Bioremoval of lead from water using Lemna minor. Bioresour Technol. 1999;70(3):225–230.
  • Lettinga G, Van Velsen AFM, Hobma SW, et al. Use of the upflow sludge blanket (USB) reactor concept for biological wastewater treatment, especially for anaerobic treatment. Biotechnol Bioeng. 1980;22(4):699–734.
  • Ruiz I, Díaz MA, Crujeiras B, et al. Solids hydrolysis and accumulation in a hybrid anaerobic digester-constructed wetlands system. Ecol Eng. 2010;36(8):1007–1016.
  • Aziz SQ, Aziz HA, Bashir MJ, et al. Wastewater Engineering: Advanced Wastewater Treatment Systems: Landfill leachate treatment techniques. Penang: IJSR Publications; 2014. p. 208–224.
  • Dalkılıç K, Uğurlu A. Influence of hydraulic retention time and reactor configuration during fermentation of diluted chicken manure. Appl Biochem Biotechnol. 2017;181(1):157–176.
  • Chong S, Sen TK, Kayaalp A, et al. The performance enhancements of upflow anaerobic sludge blanket (UASB) reactors for domestic sludge treatment – a state-of-the-art review. Water Res. 2012;46(11):3434–3470.
  • Tian D-J, Lim H-S, Chung J, et al. Nitrogen and phosphorus removal in an anaerobic (UASB)-aerobic (ABF) sewage treatment system. Desalin Water Treat. 2015;53(10):2856–2865.
  • Tiwari MK, Guha S, Harendranath CS, et al. Influence of extrinsic factors on granulation in UASB reactor. Appl Microbiol Biotechnol. 2006;71(2):145–154.
  • van der Steen P, Brenner A, van Buuren J, et al. Post-treatment of UASB reactor effluent in an integrated duckweed and stabilization pond system. Water Res. 1999;33(3):615–620.
  • El-Shafai SA, El-Gohary FA, Nasr FA, et al. Nutrient recovery from domestic wastewater using a UASB-duckweed ponds system. Bioresour Technol. 2007;98(4):798–807.
  • Vymazal J. Constructed wetlands for treatment of industrial wastewaters: a review. Ecol Eng. 2014;73:724–751.
  • de la Varga D, Díaz MA, Ruiz I, et al. Avoiding clogging in constructed wetlands by using anaerobic digesters as pre-treatment. Ecol Eng. 2013;52:262–269.
  • Wang L, Li T. Anaerobic ammonium oxidation in constructed wetlands with bio-contact oxidation as pretreatment. Ecol Eng. 2011;37(8):1225–1230.
  • Jørgensen C, Inglett KS, Jensen HS, et al. Characterization of biogenic phosphorus in outflow water from constructed wetlands. Geoderma. 2015;257–258:58–66.
  • Ayaz SÇ, Aktaş Ö, Akça L, et al. Effluent quality and reuse potential of domestic wastewater treated in a pilot-scale hybrid constructed wetland system. J Environ Manage. 2015;156:115–120.
  • Ramprasad C, Smith CS, Memon FA, et al. Removal of chemical and microbial contaminants from greywater using a novel constructed wetland: GROW. Ecol Eng. 2017;106:55–65.
  • Vymazal J. The use of sub-surface constructed wetlands for wastewater treatment in the Czech Republic: 10 years experience. Ecol Eng. 2002;18(5):633–646.
  • Vymazal J, Kröpfelová L. Multistage hybrid constructed wetland for enhanced removal of nitrogen. Ecol Eng. 2015;84:202–208.
  • Öövel M, Tooming A, Mauring T, et al. Schoolhouse wastewater purification in a LWA-filled hybrid constructed wetland in Estonia. Ecol Eng. 2007;29(1):17–26.
  • Vymazal J. Removal of nutrients in various types of constructed wetlands. Sci Total Environ. 2007;380(1–3):48–65.
  • Corbella C, Puigagut J. Effect of primary treatment and organic loading on methane emissions from horizontal subsurface flow constructed wetlands treating urban wastewater. Ecol Eng. 2015;80:79–84.
  • Hickey A, Arnscheidt J, Joyce E, et al. An assessment of the performance of municipal constructed wetlands in Ireland. J Environ Manage. 2018;210:263–272.
  • Vymazal J, Březinová T. Accumulation of heavy metals in aboveground biomass of Phragmites australis in horizontal flow constructed wetlands for wastewater treatment: a review. Chem Eng J. 2016;290:232–242.
  • Guimaraes FP, Aguiar R, Oliveira JA, et al. Potential of macrophyte for removing arsenic from aqueous solution. Planta Daninha. 2012;30(4):683–696.
  • Alvarado S, Guédez M, Lué-Merú MP, et al. Arsenic removal from waters by bioremediation with the aquatic plants Water Hyacinth (Eichhornia crassipes) and Lesser Duckweed (Lemna minor). Bioresour Technol. 2008;99(17):8436–8440.
  • Parra L-MM, Torres G, Arenas AD, et al. Phytoremediation of low levels of heavy metals using duckweed (Lemna minor). In: Abiotic stress responses in plants. New York: Springer; 2012. p. 451–463.
  • Bokhari SH, Ahmad I, Mahmood-Ul-Hassan M, et al. Phytoremediation potential of Lemna minor L. for heavy metals. Int J Phytoremediation. 2016;18(1):25–32.
  • Uysal Y. Removal of chromium ions from wastewater by duckweed, Lemna minor L. by using a pilot system with continuous flow. J Hazard Mater. 2013;263:486–492.
  • Balcıgil M. Nutrient and heavy metal removal from domestic wastewater by using duckweed (Lemna minor L.) [master’s thesis]. İstanbul: Marmara University; 2013.
  • Uysal Y, Taner F. Bioremoval of cadmium by Lemna minor in different aquatic conditions. Clean Soil Air Water. 2010;38(4):370–377.
  • Khellaf N, Zerdaoui M. Phytoaccumulation of zinc using the duckweed Lemna gibba L.: effect of temperature, pH and metal source. Desalin Water Treat. 2013;51(28–30):5755–5760.
  • Chawla G, Singh J, Viswanathan P. Effect of pH and temperature on the uptake of cadmium by Lemna minor L. Bull Environ Contam Toxicol. 1991;47(1):84–90.
  • Sobrino AS, Miranda MG, Alvarez C, et al. Bio-accumulation and toxicity of lead (Pb) in Lemna gibba L (duckweed). J Environ Sci Health A. 2010;45(1):107–110.
  • Verma R, Suthar S. Lead and cadmium removal from water using duckweed – Lemna gibba L.: impact of pH and initial metal load. Alexandria Eng J. 2015;54(4):1297–1304.
  • Horvat T, Vidaković-Cifrek Ž, Oreščanin V, et al. Toxicity assessment of heavy metal mixtures by Lemna minor L. Sci Total Environ. 2007;384(1–3):229–238.
  • Dirilgen N. Mercury and lead: assessing the toxic effects on growth and metal accumulation by Lemna minor. Ecotoxicol Environ Saf. 2011;74(1):48–54.
  • Goswami C, Majumder A. Potential of Lemna minor in Ni and Cr removal from aqueous solution. Pollution. 2015;1(4):373–385.
  • Jain S, Vasudevan P, Jha N. Azolla pinnata R. Br. and Lemna minor L. for removal of lead and zinc from polluted water. Water Res. 1990;24(2):177–183.
  • Zayed A, Gowthaman S, Terry N. Phytoaccumulation of trace elements by wetland plants: I. Duckweed. J Environ Qual. 1998;27(3):715–721.

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