We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Performanceof Coagulation-Assisted Dissolved AirFlotation Process for Microplastics Removal from Synthetic WastewaterContaining Fat, Oil and Grease
Summary
Researchers optimized a coagulation-assisted dissolved air flotation (DAF) process for removing polyethylene and polystyrene microplastics from synthetic wastewater containing fat, oil, and grease, achieving removal efficiencies of 88-90% with added coagulants compared to only 27-28% for DAF alone. The presence of fat, oil, and grease further enhanced MP removal to 95%, suggesting that hydrophobic interactions facilitate aggregation between MPs and these substances.
Microplastics (MPs) are emerging contaminants of growing concern due to their ubiquity and negative environmental impacts. Owing to their small size, hydrophobicity, and large surface area, MPs adsorb toxic chemicals and bypass conventional wastewater treatment processes. Fat, oil and grease (FOG) from domestic and industrial discharges interferes with wastewater treatment plant (WWTP) operations and serves as a carrier for MPs, facilitating their release in aquatic environments. This study investigates the performance of dissolved air flotation (DAF) process, coupled with coagulation, for polyethylene (PE) and polystyrene (PS) removal from synthetic wastewater. Key operational parameters, including air pressure, coagulant dosage, water flow rate, and pH, were optimized. DAF alone achieved limited MP removal efficiencies (27–28%). However, the addition of coagulants (150 mg/L alum and 15 mg/L polyacrylamide) substantially improved efficiencies to 88.4% for PE and 90.2% for PS. Hydrophobic interactions and charge neutralization were identified as the dominant removal mechanisms. Furthermore, the presence of FOG enhanced MP removal to 95%, suggesting that hydrophobic interactions facilitate the aggregation of MPs and their association with FOG. These findings demonstrate that an optimized coagulation-assisted DAF at the primary treatment stage provides a sustainable and effective method to remove MPs and FOG, reducing their environmental release.
Sign in to start a discussion.
More Papers Like This
Removal of Microplastic From Liquid Medium By Dissolved Air Flotation
Researchers tested dissolved air flotation (DAF) as a technique for removing PVC microplastics from water, conducting flotation tests with coagulant dosage optimization using a suspension of 400 mg/L PVC particles in water supply.
Influence of ionic surfactant contaminants on polystyrene-air bubble interactions for microplastics removal from wastewater
Researchers investigated how ionic surfactants present in municipal and industrial wastewater affect the efficiency of froth flotation for removing polystyrene microplastics. Surfactant type and concentration strongly influenced bubble-particle interactions, with some surfactants dramatically reducing removal efficiency, highlighting a challenge for flotation-based MP removal systems.
Is froth flotation a potential scheme for microplastics removal? Analysis on flotation kinetics and surface characteristics
This study evaluated froth flotation as a method for removing microplastics from water, finding that surface hydrophobicity governs flotation efficiency and that the technique shows promise as a scalable treatment option for certain polymer types.
Modelling and application of dissolved air flotation for efficient separation of microplastics from sludges and sediments
Researchers developed and tested predictive models for dissolved air flotation (DAF) — a process that uses tiny air bubbles to lift particles out of water — to more efficiently remove microplastics from industrial sludge and sediments. The models accurately predicted how different plastic types, sizes, and shapes attach to air bubbles, enabling better design of microplastic removal systems at industrial scale.
CFD Simulation of DAF processing for removal microplastic in different flotation solution
Researchers used computational fluid dynamics to simulate dissolved air flotation (DAF) for removing microplastics from various wastewater types. The simulations showed that optimal bubble-to-particle ratios and flow conditions significantly improved removal efficiency, providing a design framework for scaling up DAF in water treatment systems.