Design Aspects, Energy Consumption Evaluation, and Offset for Drinking Water Treatment Operation

Bukhary, Saria; Batista, Jacimaria R.; Ahmad, Sajjad

doi:10.3390/w12061772

Cited by 19 publications

(5 citation statements)

References 95 publications

(70 reference statements)

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“…The energy consumption obtained for all the flocculants coagulants is comparable to the obtained in other studies , which is taking account the current density of microalgae culture [10,44].…”

Section: Energy Consumptionsupporting

confidence: 82%

Direct biohydrogen production from chitosan harvested microalgae biomass and an isolated yeast

Suastes-Rivas,

Romero-Pineda,

Monje-Ramírez

et al. 2024

Energy Conversion and Management

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Section: Energy Consumptionsupporting

confidence: 82%

Direct biohydrogen production from chitosan harvested microalgae biomass and an isolated yeast

Suastes-Rivas,

Romero-Pineda,

Monje-Ramírez

et al. 2024

Energy Conversion and Management

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“…A sensitivity analysis was performed on solar panel efficiency. If a low panel efficiency value of 15% was used [26,30,31], this would result in a reduction of 25.0% of the energy generated by the panels. If a high panel efficiency of 23% was used [62], an increase in energy generation of 15.0% would result.…”

Section: Resultsmentioning

confidence: 99%

“…To decrease the GHG emissions and dependency on fossil fuels, the use of renewables as energy source in wastewater treatment has become popular. Efforts to offset the energy consumption of the WWTPs include methane generation from anaerobic sludge digestion and the installation of PV solar panels [23][24][25][26][27].…”

Section: Introductionmentioning

confidence: 99%

Renewable Energy Generation and GHG Emission Reduction Potential of a Satellite Water Reuse Plant by Using Solar Photovoltaics and Anaerobic Digestion

Bailey

Bukhary

Batista

et al. 2021

Water

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Wastewater treatment is a very energy-intensive process. The growing population, increased demands for energy and water, and rising pollution levels caused by fossil-fuel-based energy generation, warrants the transition from fossil fuels to renewable energy. This research explored the energy consumption offset of a satellite water reuse plant (WRP) by using solar photovoltaics (PVs) and anaerobic digestion. The analysis was performed for two types of WRPs: conventional (conventional activated sludge system (CAS) bioreactor with secondary clarifiers and dual media filtration) and advanced (bioreactor with membrane filtration (MBR)) treatment satellite WRPs. The associated greenhouse gas (GHG) emissions were also evaluated. For conventional treatment, it was found that 28% and 31.1% of the WRP’s total energy consumption and for advanced treatment, 14.7% and 5.9% of the WRP’s total energy consumption could be generated by anaerobic digestion and solar PVs, respectively. When both energy-generating units are incorporated in the satellite WRPs, MBR WRPs were on average 1.86 times more energy intensive than CAS WRPs, translating to a cost savings in electricity of $7.4/1000 m3 and $13.3/1000 m3 treated, at MBR and CAS facilities, respectively. Further, it was found that solar PVs require on average 30% longer to pay back compared to anaerobic digestion. For GHG emissions, MBR WRPs without incorporating energy generating units were found to be 1.9 times more intensive than CAS WRPs and 2.9 times more intensive with energy generating units. This study successfully showed that the addition of renewable energy generating units reduced the energy consumption and carbon emissions of the WRP.

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“…Modified after [37]. Table S1: Environmental emission pathways relevant to the LCA of the water treatment studies; Table S2: Data types and sources indicating the quality and authenticity of inventory dataset; Table S3: Characteristic parameters for raw and treated water and sludge for the study systems; Table S4: Electricity consumption in kWh per m 3 for unit processes at the study water treatment plants; Table S5: Transport distances for chemicals and materials used at the study plants; Table S6: Environmental impact categories and measurement Author Contributions: Conceptualization, S.J., S.P. and S.U.U.J.…”

Section: Supplementary Materialsmentioning

confidence: 99%

“…This is primarily due to the heavy reliance of water utilities on the energy sector in addition to their extensive chemical usage [2]. In the U.S. alone, an estimated 45 million tons of greenhouse gases (GHGs) are emitted annually from the energy used for water and wastewater treatment [3]. The need to evaluate the environmental impact of water treatment systems is driven by multiple challenges, particularly the regulatory criteria, present infrastructure condition, population growth, and financial constraints [4,5].…”

Section: Introductionmentioning

confidence: 99%

Lifecycle Assessment of Two Urban Water Treatment Plants of Pakistan

Jamil,

Pervez,

Sarwar

et al. 2023

Sustainability

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Water treatment technologies are striving to retain their ecological and economic viability despite the rising demand, conventional infrastructure, financial constraints, fluctuating climatic patterns, and highly stringent regulations. This study evaluates the lifecycle environmental impact of urban water treatment systems within the two densely populated South Asian municipalities of Islamabad and Rawalpindi, Pakistan. The scope of this study includes a process-based Life Cycle Assessment (LCA) of the entire water treatment system, particularly the resources and materials consumed during the operation of the treatment plant. The individual and cumulative environmental impact was assessed based on the treatment system data and an in-depth lifecycle inventory analysis. Other than the direct emissions to the environment, the electricity used for service and distribution pumping, coagulant use for floc formation, chlorine gas used for disinfection, and caustic soda used for pH stabilization were the processes identified as the most significant sources of emissions to air and water. The water distribution consumed up to 98% of energy resources. The highest global warming impacts (from 0.3 to 0.6 kg CO2 eq./m3) were assessed as being from the coagulation and distribution processes due to extensive electricity consumption. Direct discharge of the wash and wastewater to the open environment contributed approximately 0.08% of kg-N and 0.002% of kg-P to the eutrophication potential. The outcome of this study resulted in a thorough lifecycle inventory development, including possible alternatives to enhance system sustainability. A definite gap was identified in intermittent sampling at the treatment systems. However, more stringent sampling including the emissions to air can provide a better sustainability score for each unit process.

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Design Aspects, Energy Consumption Evaluation, and Offset for Drinking Water Treatment Operation

Cited by 19 publications

References 95 publications

Direct biohydrogen production from chitosan harvested microalgae biomass and an isolated yeast

Direct biohydrogen production from chitosan harvested microalgae biomass and an isolated yeast

Renewable Energy Generation and GHG Emission Reduction Potential of a Satellite Water Reuse Plant by Using Solar Photovoltaics and Anaerobic Digestion

Lifecycle Assessment of Two Urban Water Treatment Plants of Pakistan

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