Search results for "PDMS degassing Membrane"

showing 2 items of 2 documents

Widening the applicability of AnMBR for urban wastewater treatment through PDMS membranes for dissolved methane capture: Effect of temperature and hy…

2021

[EN] AnMBR technology is a promising alternative to achieve future energy-efficiency and environmental-friendly urban wastewater (UWW) treatment. However, the large amount of dissolved methane lost in the effluent represents a potential high environmental impact that hinder the feasibility of this technology for full-scale applications. The use of degassing membranes (DM) to capture the dissolved methane from AnMBR effluents can be considered as an interesting alternative to solve this problem although further research is required to assess the suitability of this emerging technology. The aim of this study was to assess the effect of operating temperature and hydrodynamics on the capture of…

Dissolved methane captureEnvironmental EngineeringGreenhouse gas (GHG) emissions0208 environmental biotechnology02 engineering and technology010501 environmental sciencesManagement Monitoring Policy and LawWastewater01 natural sciencesWaste Disposal FluidMethaneWater Purificationchemistry.chemical_compoundBioreactorsOperating temperatureMass transferAnaerobiosisDimethylpolysiloxanesWaste Management and DisposalEffluentTECNOLOGIA DEL MEDIO AMBIENTE0105 earth and related environmental sciencesPDMS degassing MembraneEnergy recoveryFoulingAnaerobic membrane bioreactor (AnMBR)Membrane foulingUrban wastewaterTemperatureMembranes ArtificialGeneral MedicinePulp and paper industry020801 environmental engineeringWastewaterchemistryHydrodynamicsEnvironmental scienceMethaneJournal of environmental management
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PDMS membranes for feasible recovery of dissolved methane from AnMBR effluents

2020

[EN] This study aimed to evaluate the feasibility of degassing membrane (DM) technology for recovering dissolved methane from AnMBR effluents. For that purpose, a PDMS membrane module was operated for treating the effluent from an AnMBR prototype-plant, which treated urban wastewater (UWW) at ambient temperature. Different transmembrane pressures and liquid flow rates were applied for evaluating methane recovery efficiency. Maximum methane recoveries were achieved when increasing the vacuum pressure and reducing the liquid flow rate, reaching a maximum methane recovery efficiency of around 80% at a transmembrane pressure (TMP) of 0.8 bars and a treatment flow rate (Q(L)) of 50 L h(-1). The …

Payback periodFiltration and Separation02 engineering and technology010402 general chemistry01 natural sciencesBiochemistryMethanechemistry.chemical_compoundGeneral Materials SciencePhysical and Theoretical ChemistryEffluentTECNOLOGIA DEL MEDIO AMBIENTEPDMS degassing MembraneTreated waterAnaerobic membrane bioreactor (AnMBR)Urban wastewaterMethane recovery021001 nanoscience & nanotechnologyPulp and paper industry0104 chemical sciencesVolumetric flow rateGreenhouse gas (GHG)MembranechemistryWastewaterGreenhouse gasEnvironmental science0210 nano-technology
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