Your search keyword '"Mohamed, A.Y.A."' showing total 4 results

1. Effects of wastewater pre-treatment on clogging of an intermittent sand filter

Author

Mohamed, A.Y.A., Tuohy, P., Healy, Mark G., Ó hUallacháin, D., Fenton, O., Siggins, A., and Teagasc

Subjects

dairy wastewater, Environmental Engineering, Environmental Chemistry, filter clogging, field-saturated hydraulic conductivity, Pollution, Waste Management and Disposal, biomass growth, volumetric moisture content

Abstract

Intermittent sand filters (ISFs) are widely used in rural areas to treat domestic and dilute agricultural wastewater due to their simplicity, efficacy and relative low cost. However, filter clogging reduces their operational lifetime and sustainability. To reduce the potential of filter clogging, this study examined pre-treatment of dairy wastewater (DWW) by coagulation with ferric chloride (FeCl3) prior to treatment in replicated, pilot-scale ISFs and monitored their performance over an entire milking season (301 days). Over the study duration and at the end of the study, the extent of clogging across hybrid coagulation-ISFs was quantified and the results were compared to ISFs treating raw DWW without a coagulation pre-treatment, but otherwise operated under the same conditions. During operation, biomass growth/extent of clogging was higher in ISFs treating raw DWW, which were fully clogged after 280 days of operation. The hybrid coagulation-ISFs remained fully operational until the end of the study. Examination of the filter media in both filter types showed that the ISFs treating raw DWW lost approximately 85% of their initial infiltration capacity in the uppermost layer due to biomass build-up versus 40% loss for hybrid coagulation-ISFs. Furthermore, ISFs treating raw DWW retained more organic matter and proportionally higher amounts of phosphorus, nitrogen and sulphur than the pre-treated DWW, with values decreasing with depth below the filter surface. Overall, hybrid coagulation-ISFs are likely to sustain infiltration capacity for a longer period than filters treating raw wastewater; therefore, requiring smaller surface area for treatment and minimal maintenance. The authors would like to acknowledge Teagasc for the grant of a Walsh Fellowship to the first author [funding number: RMIS-0386]. The authors appreciate the help of technical staff: Seamus McShane, Adrian Hawe, Tomas Condon & John Paul Murphy (Teagasc Moorepark), Denis Brennan (Teagasc Johnstown Castle), and Emma McDermott (Centre for Microscopy and Imaging, University of Galway). peer-reviewed

Published

2023

2. Effects of coagulation pre-treatment on chemical and microbial properties of water-soil-plant systems of constructed wetlands.

Author

Mohamed, A.Y.A., Tuohy, P., Healy, M.G., Ó hUallacháin, D., Fenton, O., and Siggins, A.

Subjects

*FERRIC chloride, *COAGULATION (Sewage purification), *EFFLUENT quality, *IRON chlorides, *CHEMICAL properties

Abstract

Chemical coagulation has gained recognition as an effective technique to enhance the removal efficiency of pollutants in wastewater prior to their entry into a constructed wetland (CW) system. However, its potential impact on the chemical and microbial properties of soil and plant systems within CWs requires further research. This study investigated the impact of using ferric chloride (FeCl 3) as a pre-treatment stage for dairy wastewater (DWW) on the chemical and microbial properties of water-soil-plant systems of replicated pilot-scale CWs, comparing them to CWs treating untreated DWW. CWs treating amended DWW had better performance than CWs treating raw DWW for all water quality parameters (COD, TSS, TP, and TN), ensuring compliance with the EU wastewater discharge directives. Soil properties remained mostly unaffected except for pH, calcium and phosphorus (P), which were lower in CWs treating amended DWW. As a result of lower nitrogen (N) and P loads, the plants in CWs receiving FeCl 3 -amended DWW had lower N and P contents than the plants of raw DWW CWs. However, the lower loads of P into amended DWW CWs did not limit the growth of Phragmites australis, which were able to accumulate trace elements higher than CWs receiving raw DWW. Alpha and Beta-diversity analysis revealed minor differences in community richness and composition between both treatments, with only 3.7% (34 genera) showed significant disparities. Overall, the application of chemical coagulation produced superior effluent quality without affecting the properties of soil and plant of CWs or altering the functioning of the microbial community. [Display omitted] • Wastewater pre-treatment using FeCl 3 improved the performance of CWs. • FeCl 3 pre-treatment had no negative effects on soil and plant properties. • FeCl 3 pre-treatment did not alter microbial community diversity and composition. [ABSTRACT FROM AUTHOR]

Published

2024

3. A novel hybrid coagulation-constructed wetland system for the treatment of dairy wastewater.

Author

Mohamed, A.Y.A., Siggins, A., Healy, M.G., Ó hUallacháin, D., Fenton, O., and Tuohy, P.

Published

2022

4. A novel hybrid coagulation-intermittent sand filter for the treatment of dairy wastewater.

Author

Mohamed, A.Y.A., Siggins, A., Healy, M.G., Fenton, O., Ó hUallacháin, D., and Tuohy, P.

Subjects

*SEWAGE purification, *HYBRID systems, *WASTEWATER treatment, *TOTAL suspended solids, *EFFLUENT quality, *CHEMICAL oxygen demand

Abstract

An intermittent sand filter (ISF) is a simple and cost-effective treatment method that may be adopted on farms to treat dairy wastewater (DWW). However, the use of ISFs has been limited due to the large area required for treatment, and the risk of filter clogging and phosphorus (P) breakthrough, which decrease the operational lifetime. To overcome these limitations, this study uses a novel, pilot-scale coagulation-sedimentation process prior to loading ISFs with DWW. The performance and operational lifetime of this new hybrid coagulation-ISF system was compared to a conventional ISF system in a replicated outdoor pilot-scale experiment over a 43-wk study duration (covering an entire milking season on a farm in Ireland). The hybrid system was able to operate effectively at a higher hydraulic loading rate than a conventional ISF system. The effluent quality from the conventional ISF deteriorated over the timeframe of the study until clogging occurred, while the hybrid system continued to perform effectively without any evidence of clogging or P breakthrough. The hybrid system obtained removal efficiencies ≥99% for all measured water quality parameters (chemical oxygen demand, total suspended solids, total P, ammonium and turbidity), and complied with EU directives concerning urban wastewater treatment. Overall, the hybrid coagulation-ISF is a promising technology that requires a small area (75% reduction in footprint in comparison to a conventional ISF) and minimal operator input, and produces high effluent quality. [Display omitted] • Performance of novel hybrid coagulation-ISF was compared to conventional ISF. • The coagulation-ISF system required only 25% of the conventional ISF size. • The coagulation-ISF system did not experience any clogging or P breakthrough. • The conventional ISF encountered both clogging and P breakthrough. • The coagulation-ISF produced better effluent quality than conventional ISF. [ABSTRACT FROM AUTHOR]

Published

2022