Natural water treatment method for intensive aquaculture effluent purification

Natural water treatment method for intensive aquaculture effluent purification

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Title: Natural water treatment method for intensive aquaculture effluent purification
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Article_Title: Natural water treatment method for intensive aquaculture effluent purification
Authors: Éva Kerepeczki*, Dénes Gál, Tünde Kosáros, Réka Hegedűs, Gergő Gyalog, Ferenc Pekár
Affiliation: Research Institute for Fisheries, Aquaculture and Irrigation, Szarvas, Hungary
Abstract: Several intensive flow-through fish production plants were established in Hungary in the last  decades, representing a significant share of the total fish production. However, the full management of the discharged  waste from such systems is still unsolved. Searching new sustainable methods for treatment and  utilisation of output nutrients a pilot-scale constructed wetland system was built in Szarvas in  2000. The pilot-scale system consisted of two subsystems (total area of 1.4ha) of similar structure: one stabilisation pond and one fishpond connected serially; the water was channelled  from the fishpond into macrophyte ponds (surface-flow wetlands) and additionally spread on one irrigated field. The nutrient removal of the wetland units was most efficient in the case of  organic carbon in the subsystem “A”; for all nutrients the removal efficiency reached 90%, except  for the phosphorus in the “A” subsystem, where the lowest efficiency was found (80%).
Keywords: aquaculture, constructed wetland, macrophyte, water treatment, nutrient
References: Costa-Pierce BA, Preliminary investigation of an integrated aquaculture-wetland ecosystem using tertiary-treated municipal wastewater in Los Angeles county, California. Ecological engineering. 10, 341-354, 1998.
Kerepeczki É, Treatment of intensive aquaculture effluents in constructed wetlands. Doctoral Thesis, University of Debrecen. 111p, 2006.
Kerepeczki É, Gál D, Szabó P, Pekár F, Preliminary investigations on the nutrient removal efficiency of a wetland-type ecosystem. Hydrobiologia. 506, 665-670, 2003.
Klasnja B, Kopitovic S, Orlovic S, Wood and bark of some poplar and willow clones as fuelwood. Biomass and Bioenergy. 23(6), 427-432, 2002.
Miles TR, Miles TR JR, Baxter L, Bryers RW, Jenkins BM, Oden LL, Alkali deposits found in biomass power plants. A preliminary investigation of their extend and nature, NREL/TP-433-8142, 82 p, 1995.
Szczukowski S, Tworkowski J, Klasa A, Stolarski M, Productivity and chemical composition of wood tissues of short rotation willow coppice cultivated on arable land. Rostlinna Vyroba. 48(9), 413-417, 2002.
Lin Y-F, Jing S-R, Lee D-Y, Chang Y-F, Chen Y-M, Shih K-C, Performance of a constructed wetland treating intensive shrimp aquaculture wastewater under high hydraulic loading rate. Environmental Pollution 134(3), 411-421, 2005.
Paist A, The suitability of energy plants as fuel for power boilers. Tallinn University of Technology, Thermal Engineering Department. 7-8. October 2005. International conference on “Contribution of agriculture to energy production” http://www.agri.ee/public/juurkataloog/BIOENERGEETIKA/Paist.ppt, 2005.
Pintér K, Magyarország halászata 2006-ban [Fish production and fishery in Hungary in 2006]. Halászat. 2007(3), 111-116, (in Hungarian) 2007.
Schulz C, Gelbrecht J, Rennert B, Treatment of rainbow trout farm effluents in constructed wetland with emergent plants and subsurface horizontal water flow. Aquaculture 217(1-4), 207-221, 2003.
Tilley DR, Badrinarayanan H, Rosati R, Son J, Constructed wetlands as recirculation filters in largescale shrimp aquaculture. Aquacultural Engineering 26(2), 81-109, 2002.
Read_full_article: pdf/21-2011/21-4-2011/SU21-4-2011-Kerepeczki.pdf
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Article Title: Natural water treatment method for intensive aquaculture effluent purification
Authors: Éva Kerepeczki*, Dénes Gál, Tünde Kosáros, Réka Hegedűs, Gergő Gyalog, Ferenc Pekár
Affiliation: Research Institute for Fisheries, Aquaculture and Irrigation, Szarvas, Hungary
Abstract: Several intensive flow-through fish production plants were established in Hungary in the last  decades, representing a significant share of the total fish production. However, the full management of the discharged  waste from such systems is still unsolved. Searching new sustainable methods for treatment and  utilisation of output nutrients a pilot-scale constructed wetland system was built in Szarvas in  2000. The pilot-scale system consisted of two subsystems (total area of 1.4ha) of similar  structure: one stabilisation pond and one fishpond connected serially; the water was channelled  from the fishpond into macrophyte ponds (surface-flow wetlands) and additionally spread on one  irrigated field. The nutrient removal of the wetland units was most efficient in the case of  organic carbon in the subsystem “A”; for all nutrients the removal efficiency reached 90%, except  for the phosphorus in the “A” subsystem, where the lowest efficiency was found (80%).
Keywords: aquaculture, constructed wetland, macrophyte, water treatment, nutrient
References: Costa-Pierce BA, Preliminary investigation of an integrated aquaculture-wetland ecosystem using tertiary-treated municipal wastewater in Los Angeles county, California. Ecological engineering. 10, 341-354, 1998.
Kerepeczki É, Treatment of intensive aquaculture effluents in constructed wetlands. Doctoral Thesis, University of Debrecen. 111p, 2006.
Kerepeczki É, Gál D, Szabó P, Pekár F, Preliminary investigations on the nutrient removal efficiency of a wetland-type ecosystem. Hydrobiologia. 506, 665-670, 2003.
Klasnja B, Kopitovic S, Orlovic S, Wood and bark of some poplar and willow clones as fuelwood. Biomass and Bioenergy. 23(6), 427-432, 2002.
Miles TR, Miles TR JR, Baxter L, Bryers RW, Jenkins BM, Oden LL, Alkali deposits found in biomass power plants. A preliminary investigation of their extend and nature, NREL/TP-433-8142, 82 p, 1995.
Szczukowski S, Tworkowski J, Klasa A, Stolarski M, Productivity and chemical composition of wood tissues of short rotation willow coppice cultivated on arable land. Rostlinna Vyroba. 48(9), 413-417, 2002.
Lin Y-F, Jing S-R, Lee D-Y, Chang Y-F, Chen Y-M, Shih K-C, Performance of a constructed wetland treating intensive shrimp aquaculture wastewater under high hydraulic loading rate. Environmental Pollution 134(3), 411-421, 2005.
Paist A, The suitability of energy plants as fuel for power boilers. Tallinn University of Technology, Thermal Engineering Department. 7-8. October 2005. International conference on “Contribution of agriculture to energy production” http://www.agri.ee/public/juurkataloog/BIOENERGEETIKA/Paist.ppt, 2005.
Pintér K, Magyarország halászata 2006-ban [Fish production and fishery in Hungary in 2006]. Halászat. 2007(3), 111-116, (in Hungarian) 2007.
Schulz C, Gelbrecht J, Rennert B, Treatment of rainbow trout farm effluents in constructed wetland with emergent plants and subsurface horizontal water flow. Aquaculture 217(1-4), 207-221, 2003.
Tilley DR, Badrinarayanan H, Rosati R, Son J, Constructed wetlands as recirculation filters in largescale shrimp aquaculture. Aquacultural Engineering 26(2), 81-109, 2002.
*Correspondence: