Implementation of an Integrated Floating Wetland and Biofilter for Water Treatment in Nile Tilapia Aquaculture

Somprasert, Somanas; Mungkung, Sattaya; Kreetachat, Nathiya; Imman, Saksit; Homklin, Supreeda

doi:10.12911/22998993/140267

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Tytuł artykułu

Implementation of an Integrated Floating Wetland and Biofilter for Water Treatment in Nile Tilapia Aquaculture

Autorzy

Somprasert Somanas , Mungkung Sattaya , Kreetachat Nathiya , Imman Saksit , Homklin Supreeda

Treść / Zawartość

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16_somprasert_implementation_jee_8_2021.pdf

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DOI

10.12911/22998993/140267

Warianty tytułu

Języki publikacji

Abstrakty

Due to the high nutrient and organic matter contents of fish pond water, the water must be treated before disposal to prevent the eutrophication and deterioration of natural receiving waters. Floating wetlands (FTWs) and biofilters are environmentally friendly ecological treatments that can be used for this water. Thus, this study aimed to investigate the performance of FTWs with biofilters (FTW/Bs) for nutrient and organic compound removal. Two FTW/ Bs were applied in a pond with 5,000 Nile tilapia. The macrophyte species in the FTWs were Cyperus (Cyperus spp.) and Heliconia (Heliconia spp.). The buoyant mats of the FTWs were made from bamboo, and 200 bioballs were loaded below the mats. The water quality parameters in the pond were monitored for 5 weeks between the control test without the FTW/Bs and the experimental test with FTW/Bs at sites 1 (S1) to 8 (S8). The FTW/Bs were located at sites 2 (S2) and 3 (S3). The results showed reductions in all water quality parameters except orthophosphate (ortho-P) at S2 and S3. The COD, BOD, NH_4-N, and SS at S2 and S3 parameters during the experimental test were significantly lower than those during the control test, in the ranges of 20.34–33.96, 25.47–29.41, 25.86–27.87, and 26.00–28.44%, respectively.

Słowa kluczowe

aquaculture biofilter fish pond water floating wetland

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2021

Tom

Vol. 22, nr 8

Strony

146--152

Opis fizyczny

Bibliogr. 34 poz., rys.

Twórcy

autor

Somprasert Somanas

School of Energy and Environment, University of Phayao, 19, Moo 2, Maeka, Phayao, Thailand

autor

Mungkung Sattaya

School of Energy and Environment, University of Phayao, 19, Moo 2, Maeka, Phayao, Thailand

autor

Kreetachat Nathiya

School of Energy and Environment, University of Phayao, 19, Moo 2, Maeka, Phayao, Thailand

autor

Imman Saksit

School of Energy and Environment, University of Phayao, 19, Moo 2, Maeka, Phayao, Thailand

autor

Homklin Supreeda

supreeda.ho@up.ac.th

School of Energy and Environment, University of Phayao, 19, Moo 2, Maeka, Phayao, Thailand

https://orcid.org/0000-0003-0642-1917

Bibliografia

1. Abed S.N., Almuktar S.A., Scholz M. 2017. Remediation of synthetic greywater in mesocosm-Scale floating treatment wetlands. Ecological Engineering, 102, 303–319.
2. APAH. 2005. Standard Methods for the Examination of Water and Wastewater, 21st edition. American Public Health Association, American Water Works Association, Water Environment Federation, Washington, D.C.
3. Barco A., Borin M. 2020. Treatment performances of floating wetlands: A decade of studies in North Italy. Ecological Engineering, 158, 106016.
4. Benvenuti T., Hamerski F., Giacobbo A., Bernardes A.M., Zoppas-Ferreira J., Rodrigues M.A.S. 2018. Constructed floating wetland for the treatment of domestic sewage: A real-scale study. Journal of Environmental Chemical Engineering, 6, 5706–5711.
5. Bissegger S., Rodriguez M., Brisson J., Weber K.P. 2014. Catabolic profiles of microbial communities in relation to plant identity and diversity in free floating plant treatment wetland mesocosms. Ecological Engineering, 67, 190–197.
6. Borne K.E. 2014. Floating treatment wetland influences on the fate and removal performance of phosphorus in stormwater retention ponds. Ecological Engineering, 69, 76–82.
7. Borne K.E., Fassman E.A., Tanner C.C. 2013. Floating treatment wetland retrofit to improve stormwater pond performance for suspended solids, copper and zinc. Ecological Engineering, 54, 173–182.
8. Brune D.E., Schwartz G., Eversole A.G., Collier J.A., Schwedler T.E. 2003. Intensification of pond aquaculture and high rate photosynthetic systems. Aquacultural Engineering, 28, 65–86.
9. Cao W., Wang Y., Sun L., Jiang J., Zhang Y. 2016. Removal of nitrogenous compounds from polluted river water by floating constructed wetland using rice straw and ceramsite as substrates under low temperature condition. Ecological Engineering, 88, 77–81.
10. Castro-Castello A.T., Chipps M.J., Hankins N.P., Hughes J.M.R. 2016. Lessons from the “Living-Filter”: An in-reservoir floating treatment wetland for phytoplankton reduction prior to a water treatment works intake. Ecological Engineering, 95, 839–851.
11. Chang N.B., Xuan Z., Marimon Z., Islam K., Wanielista M.P. 2013. Exploring hydro biogeochemical processes of floating treatment wetlands in a subtropical stormwater wet detention pond. Ecological Engineering, 54, 66–76.
12. Crab R., Avnimelech Y., Defoirdt T., Bossier P., Verstraete W. 2007. Nitrogen removal techniques in aquaculture for a sustainable production. Aquaculture, 270, 1–14.
13. Dunne E.J., Coveney M.F., Marzolf E.R., Hoge V.R., Conrow R., Naleway R., Lowe E.F., Battoe L.E. 2012. Efficacy of a large-scale constructed wetland to remove phosphorus and suspended solids from Lake Apopka, Florida. Ecological Engineering, 42, 90–100.
14. Dunne E.J., Coveney M.F., Marzolf E.R., Hoge V.R., Conrow R., Naleway R., Low E.F., Battoe L.E., Inglett P.W. 2013. Nitrogen dynamics of a large-scale contructed wetland used to remove excess nitrogen from eutrophic lake water. Ecological Engineering, 61, 224–234.
15. El-Sherif M.S., El-Feky A.M. 2008. Effect of ammonia on Nile tilapia (O. niloticus) performance and some hematological and histological measures. The 8th International Symposium on Tilapia in Aquaculture. 513–530.
16. FAO. 2020. The state of world fisheries and aquaculture sustainability in action.
17. Hegazi M.M., Attia Z.I., Ashour O.A. 2010. Oxidative stress and antioxidant enzymes in liver and white muscle of Nile tilapia juveniles in chronic ammonia exposure. Aquatic Toxicology, 99, 118–125.
18. Langergraber G. 2005. The role of plant uptake on the removal of organic matter and nutrients in subsurface flow constructed wetlands: a simulation study. Water Science and Technology, 51, 213–223.
19. Lopardo C.R., Zhang L., Mitsch W.J., Urakawa H. 2019. Comparison of nutrient retention efficiency between vertical-flow and floating treatment wetland mesocosms with and without biodegradable plastic. Ecological Engineering, 131, 120–130.
20. Maucieri C., Salvato M., Borin M. 2020. Vegetation contribution on phosphorus removal in wetland microcosms. Ecological Engineering, 152, 105853.
21. Mungkung S., Homklin S., Somprasert S. 2016. The removal of nutrients in water from Nile tilapia fishery farm by floating constructed wetland system with biological filters. The 16th National Environmental Conference, 11–12.
22. Pappalardo S.E., Ibrahim H.M.S., Cerinato S., Borin M. 2017. Assessing the water purification service in an integrated agricultural wetland within the venetian Lagoon drainage system. Marine and Freshwater Research, 68, 2205–2215.
23. Pavlineri N., Shoulikidis N.T., Tsihrintzis V.A. 2017. Constructed floating wetlands: a review of research, design, operation and management aspects, and data meta-analysis. Chemical Engineering Journal, 308, 1120–1132.
24. Piedrahita R.H. 2003. Reducing the potential environmental impact of tank aquaculture effluents through intensification and recirculation. Aquaculture, 226, 35–44.
25. Saeed T., Al-Muyeed A., Afrin R., Rahman H., Guangzhi S. 2014. Pollutant removal from municipal wastewater employing baffled subsurface flow and integrated surface flow-floating treatment wetlands. Journal of Environmental Sciences, 26, 726–736.
26. Shahid M.J., Arslan M., Siddque M., Ali S., Tahseen R., Afzal M. 2019. Potentialities of floating wetlands for the treatment of polluted water of river Ravi, Pakistan. Ecological Engineering, 133, 167–176.
27. Siddiqut A.Q., Howlader M.S., Adam A.A. 1988. Effects of dietary protein levels on growth, feed conversion and protein utilization in fry and young Nile tilapia, Oreochromis niloticus. Aquaculture, 70, 63–73.
28. Tanner C.C., Headley T.R. 2011. Components of floating emergent macrophyte treatment wetlands influencing removal of stormwater pollutants. Ecological Engineering, 37, 474–486.
29. Tharp R., Westhelle K., Hurley S. 2019. Macrophyte performance in floating treatment wetlands on a suburban stormwater pond: Implications for cold climate condition. Ecological Engineering. 136 (2019) 152–159.
30. Wang C.Y., Sample D.J., Bell C. 2014. Vegetation effects on floating treatment wetland nutrient removal and harvesting strategies in urban stormwater ponds. Science of the Total Environment, 499, 384–393.
31. White S.A., Cousins M. 2013. Floating treatment wetland aided remediation of nitrogen and phosphorus from simulated stormwater runoff. Ecological Engineering, 61, 207–215.
32. Wu H., Zhang J., Ngo H.H., Guo W., Hu Z., Liang S., Fan J., Liu H. 2015. A review on the sustainability of constructed wetlands for wastewater treatment: Design and operation. Bioresource Technology, 175, 594–601.
33. Wu Q., Hu Y., Li S., Peng S., Zhao H. 2016. Microbial mechanisms of using enhanced ecological floating beds for eutrophic water improvement. Bioresource Technology, 211, 451–456.
34. Zhang C.B., Liu W.L., Pan X.C., Guan M., Liu S.Y., Ge Y., Chang J. 2014. Comparison of effects of plant and biofilm bacterial community parameters on removal performances of pollutants in floating island systems. Ecological Engineering, 73, 58–63.

Typ dokumentu

Bibliografia

Identyfikator YADDA

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