Laboratory Efficacy of Locally Available Backwashing Methods at Removing Fouling in Hollow-Fiber Membrane Filters Used for Household Water Treatment

Heylen, Camille; Aguiar, Alice; String, Gabrielle; Domini, Marta; Goff, Nathaniel; Murray, Anna; Asatekin, Ayşe; Lantagne, Daniele

doi:10.3390/membranes11050375

Cited by 3 publications

(2 citation statements)

References 29 publications

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“…On the other hand, the membranes can be fully recovered using the back-flushing method. This method applies higher pressure on the permeate side of the membrane, in so doing causing backward movement of the permeate through the membrane [ 54 ]. Backwashing is the furthermost broadly employed fouling reversal technique used in industry [ 2 ].…”

Section: Resultsmentioning

confidence: 99%

Development of Environment-Friendly Membrane for Oily Industrial Wastewater Filtration

et al. 2021

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Latex phase blending and crosslinking method was used in this research work to produce nitrile butadiene rubber-graphene oxide (NBR-GO) membranes. This fabrication technique is new and yields environmentally friendly membranes for oil-water separation. GO loading was varied from 0.5 to 2.0 part per hundred-part rubber (pphr) to study its effect on the performance of NBR-GO membrane. GO was found to alter the surface morphology of the NBR matrix by introducing creases and fold on its surface, which then increases the permeation flux and rejection rate efficiency of the membrane. X-Ray diffraction analysis proves that GO was well dispersed in the membrane due to the non-existence of GO fingerprint diffraction peak at 2θ value of 10–12° in the membrane samples. The membrane filled with 2.0 pphr GO has the capability to permeate 7688.54 Lm−2 h−1 water at operating pressure of 0.3 bar with the corresponding rejection rate of oil recorded at 94.89%. As the GO loading increases from 0.5 to 2.0 pphr, fouling on the membrane surface also increases from Rt value of 45.03% to 87.96%. However, 100% recovery on membrane performance could be achieved by chemical backwashing.

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Section: Resultsmentioning

confidence: 99%

Development of Environment-Friendly Membrane for Oily Industrial Wastewater Filtration

et al. 2021

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“…An acid compound such as vinegar is possible to remove the foulants. Nonetheless, it is still possible to see remnants on the membrane surface and a challenge to recovery the foulants, pharmaceutical active compounds, from membrane surface [ 116 ]. Consequently, it also aggravated the scaling of the membrane due to the increased concentrations and temperature polarization effects.…”

Section: Challenge and Future Recommendationmentioning

confidence: 99%

Modified polymer membranes for the removal of pharmaceutical active compounds in wastewater and its mechanism-A review

Ratnasari

2023

Bioengineered

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Membrane technology can play a suitable role in removing pharmaceutical active compounds since it requires low energy and simple operation. Even though membrane technology has progressed for wastewater applications nowadays, modifying membranes to achieve the strong desired membrane performance is still needed. Thus, this study overviews a comprehensive insight into the application of modified polymer membranes to remove pharmaceutical active compounds from wastewater. Biotoxicity of pharmaceutical active compounds is first prescribed to gain deep insight into how membranes can remove pharmaceutical active compounds from wastewater. Then, the behavior of the diffusion mechanism can be concisely determined using mass transfer factor model that represented by β and B with value up to 2.004 g h mg −1 and 1.833 mg g −1 for organic compounds including pharmaceutical active compounds. The model refers to the adsorption of solute to attach onto acceptor sites of the membrane surface, external mass transport of solute materials from the bulk liquid to the membrane surface, and internal mass transfer to diffuse a solute toward acceptor sites of the membrane surface with evidenced up to 0.999. Different pharmaceutical compounds have different solubility and relates to the membrane hydrophilicity properties and mechanisms. Ultimately, challenges and future recommendations have been presented to view the future need to enhance membrane performance regarding fouling mitigation and recovering compounds. Afterwards, the discussion of this study is projected to play a critical role in advance of better-quality membrane technologies for removing pharmaceutical active compounds from wastewater in an eco-friendly strategy and without damaging the ecosystem.

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Impacts of hydration and dehydration on microfiltration point-of-use filters: performance and cleaning impacts

Ocampo,

Holden,

Basu

2023

Journal of Water, Sanitation and Hygiene for Development

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This research examines the performance of two commercially available point-of-use (POU) microfiltration membrane filters (MF) under hydrated (wet) versus a multi-day dry period (dehydrated). Filter performance is monitored in terms of water quality and flowrate, as well as flowrate recovery following different cleaning regimes. The cleaning methods tested were backwashing with filtrate at room temperature, filtrate heated to 45 °C, filtrate at 45 °C with gentle shaking, and a vinegar solution (5% acetic acid). The selected cleaning methods reflect easily accessible cleaning methods with a goal to assess their impacts on flowrate recovery under both wet and dry conditions. After initial testing, hydrated MF flowrate varied between 197 ± 22 mL/min and backwashing with filtrate at room temperature was sufficient to maintain the membrane flowrate, while any of the other methods initially improved the system flowrate. In experiments where the filters were subject to a 5-day dry condition MF flowrates dropped to 65 ± 35 mL/min and filtrate at room temperature did not recover the flowrate sufficiently, however heated filtrate (45 °C) with/without gentle shaking was effective at recovering the MF for use. Water quality remained similar throughout the study, and 0 CFU/mL of E. coli were found in filtrate samples.

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Laboratory Efficacy of Locally Available Backwashing Methods at Removing Fouling in Hollow-Fiber Membrane Filters Used for Household Water Treatment

Cited by 3 publications

References 29 publications

Development of Environment-Friendly Membrane for Oily Industrial Wastewater Filtration

Development of Environment-Friendly Membrane for Oily Industrial Wastewater Filtration

Modified polymer membranes for the removal of pharmaceutical active compounds in wastewater and its mechanism-A review

Impacts of hydration and dehydration on microfiltration point-of-use filters: performance and cleaning impacts

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