Performance of a hybrid constructed wetland treating piggery wastewater

► Median abatements were: 79% for COD, 64% for TN, 63% for NH4–N, and 61% for TP. ► For COD, the HF unit was more efficient than VF in reducing concentration. ► For TN and TP, VF and HF gave similar abatements. ► Average daily mass removal rates for COD was 31.4g/m2, for TN 17.5g/m2. A full-scale hy...

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Bibliographic Details
Published in:Ecological engineering 2013-02, Vol.51, p.229-236
Main Authors: Borin, Maurizio, Politeo, Marco, De Stefani, Giovanna
Format: Article
Language:English
Subjects:
Abatement
ammonium nitrogen
Animal, plant and microbial ecology
Applied ecology
Applied sciences
Biological and medical sciences
Canna indica
chemical oxygen demand
COD
Conservation, protection and management of environment and wildlife
constructed wetlands
Construction
Crack opening displacement
dissolved oxygen
electrical conductivity
Environmental degradation: ecosystems survey and restoration
Exact sciences and technology
farms
Fundamental and applied biological sciences. Psychology
Horizontal flow
Inflow
nitrate nitrogen
Nitrogen forms
Outflow
Phosphorus
Phragmites australis
planting
pollutants
Pollution
swine
Symphytum officinale
temperature
Vertical flow systems
Waste water
wastewater
Wastewaters
Water treatment and pollution
Wetlands
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Summary:► Median abatements were: 79% for COD, 64% for TN, 63% for NH4–N, and 61% for TP. ► For COD, the HF unit was more efficient than VF in reducing concentration. ► For TN and TP, VF and HF gave similar abatements. ► Average daily mass removal rates for COD was 31.4g/m2, for TN 17.5g/m2. A full-scale hybrid constructed wetland (HCW) designed to treat 5m3/d of piggery wastewaters built in 2008 on a private pig farm in northern Italy was monitored from May to December 2009 to determine its efficiency in treating COD, total nitrogen (TN), ammonia nitrogen (NH4–N), nitrate nitrogen (NO3–N) and total phosphorus (TP). In situ measurements were also taken of pH, electrical conductivity (EC), dissolved oxygen (DO) and temperature (T). The system was composed of three vertical-subsurface flow wetlands (VF) (10m2 each, one planted with Canna indica and the other two with Symphytum officinale) working in parallel, followed by one horizontal-subsurface flow wetland (HF) connected in series (100m2 planted with Phragmites australis). The system was fed with pre-treated piggery wastewater with the total daily load (5m3) divided in two batches 11h apart. Wastewater samples were collected at the inflow (IN), outflow of VF unit (OUT-VF) and outflow HF unit (OUT-HF). Median COD concentration decreased from 1126 at the inlet to 235mg/L at the outlet (79% abatement). TN concentration was abated by 64% (671–240mg/L). NH4–N and NO3–N median inflow concentrations (390 and 6.61mg/L) were reduced by 63% and 53%, respectively, with median outflow concentrations of 145 and 3.14mg/L. Inflow phosphorus concentration of 23mg/L was abated by 61%. Average daily mass removal rates were 31.4g/m2 for COD, 17.5g/m2 for TN and 0.54g/m2 for TP. The HF unit was more efficient than VF in reducing COD concentration; VF and HF gave similar abatements for TN and TP, but VF occupied a quarter of the surface of the HF. The results show that the HCW is an effective solution for treating the excess pollutants deriving from animal wastewaters where sufficient land is not available for spreading.
ISSN:0925-8574
1872-6992
DOI:10.1016/j.ecoleng.2012.12.064