TY - JOUR
T1 - Developing a novel biofiltration treatment system by coupling high-rate infiltration trench technology with a plug-flow porous-media bioreactor
AU - Karakurt-Fischer, Sema
AU - Sanz-Prat, Alicia
AU - Greskowiak, Janek
AU - Ergh, Martin
AU - Gerdes, Heiko
AU - Massmann, Gudrun
AU - Ederer, Jürgen
AU - Regnery, Julia
AU - Hübner, Uwe
AU - Drewes, Jörg E.
N1 - Publisher Copyright:
© 2020 Elsevier B.V.
PY - 2020/6/20
Y1 - 2020/6/20
N2 - The sequence of two infiltration steps combined with an intermediate aeration named ‘sequential managed aquifer recharge technology (SMART)’ proved to be a promising approach to replenish groundwater using treated wastewater effluents or impaired surface waters due to efficient inactivation of pathogens and improved removal of many trace organic chemicals. To minimize the physical footprint of such systems and overcome limitations through site-specific heterogeneity at conventional MAR sites, an engineered approach was taken to further advance the SMART concept. This study investigated the establishment of plug-flow conditions in a pilot scale subsurface bioreactor by providing highly controlled hydraulic conditions. Such a system, with a substantially reduced physical footprint in comparison to conventional MAR systems, could be applied independent of local hydrogeological conditions. The desired redox conditions in the bioreactor are achieved by in-situ oxygen delivery, to maintain the homogenous flow conditions and eliminate typical pumping costs. For the time being, this study investigated hydraulic conditions and the initial performance regarding the removal of chemical constituents during baseline operation of the SMARTplus bioreactor. The fit of the observed and simulated breakthrough curves from the pulse injection tracer test indicated successful establishment of plug-flow conditions throughout the bioreactor. The performance data obtained during baseline operation confirmed similar trace organic chemical biotransformation as previously observed in lab- and field-scale MAR systems during travel times of <13 h.
AB - The sequence of two infiltration steps combined with an intermediate aeration named ‘sequential managed aquifer recharge technology (SMART)’ proved to be a promising approach to replenish groundwater using treated wastewater effluents or impaired surface waters due to efficient inactivation of pathogens and improved removal of many trace organic chemicals. To minimize the physical footprint of such systems and overcome limitations through site-specific heterogeneity at conventional MAR sites, an engineered approach was taken to further advance the SMART concept. This study investigated the establishment of plug-flow conditions in a pilot scale subsurface bioreactor by providing highly controlled hydraulic conditions. Such a system, with a substantially reduced physical footprint in comparison to conventional MAR systems, could be applied independent of local hydrogeological conditions. The desired redox conditions in the bioreactor are achieved by in-situ oxygen delivery, to maintain the homogenous flow conditions and eliminate typical pumping costs. For the time being, this study investigated hydraulic conditions and the initial performance regarding the removal of chemical constituents during baseline operation of the SMARTplus bioreactor. The fit of the observed and simulated breakthrough curves from the pulse injection tracer test indicated successful establishment of plug-flow conditions throughout the bioreactor. The performance data obtained during baseline operation confirmed similar trace organic chemical biotransformation as previously observed in lab- and field-scale MAR systems during travel times of <13 h.
KW - Controlled hydraulics
KW - High rate infiltration
KW - Indirect potable reuse
KW - Managed aquifer recharge
KW - Plug flow conditions
KW - Trace organic chemicals
UR - http://www.scopus.com/inward/record.url?scp=85081685448&partnerID=8YFLogxK
U2 - 10.1016/j.scitotenv.2020.137890
DO - 10.1016/j.scitotenv.2020.137890
M3 - Article
C2 - 32208260
AN - SCOPUS:85081685448
SN - 0048-9697
VL - 722
JO - Science of the Total Environment
JF - Science of the Total Environment
M1 - 137890
ER -