Modeling Cost, Energy, and Total Organic Carbon Trade-Offs for Stormwater Spreading Basin Systems Receiving Recycled Water Produced Using Membrane-Based, Ozone-Based, and Hybrid Advanced Treatment Trains

Bradshaw, Jonathan L.; Ashoori, Negin; Osorio, M.; Luthy, Richard G.

doi:10.1021/acs.est.9b00184

Cited by 15 publications

(12 citation statements)

References 51 publications

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“…The RO process was assumed to achieve 90% water recovery and 99% TDS rejection (DDW, ). Overall recovery from conventional MF‐RO might be as low as 70%–80% (Bradshaw et al, ; Trussell et al, ), but 90% was assumed to be a best‐case scenario. The second treatment train (DPR 2), which is a potentially more sustainable alternative (Gerrity et al, ), included ultrafiltration (UF), O 3 , biological activated carbon (BAC), and UV AOP.…”

Section: Methodsmentioning

confidence: 99%

“…When considering various water supply alternatives, the evaluation and optimization of life cycle cost can be invaluable to the decision‐making process (Bradshaw, Ashoori, Osorio, & Luthy, ). A more comprehensive triple bottom line analysis might even be warranted because of its ability to simultaneously consider the social, environmental, and economic implications of an engineering design (Haak, Sundaram, & Pagilla, ; Schimmoller, Kealy, & Foster, ; Schoen et al, ).…”

Section: Introductionmentioning

confidence: 99%

“…With respect to social considerations, the recent literature demonstrates that, when designed and operated properly, potable reuse systems provide adequate protection of public health (Amoueyan, Ahmad, Eisenberg, & Gerrity, ; Amoueyan, Ahmad, Eisenberg, Pecson, & Gerrity, ; Chaudhry, Hamilton, Haas, & Nelson, ; Pecson et al, ; Pecson, Trussell, Pisarenko, & Trussell, ; Soller, Eftim, Warren, & Nappier, ). Particularly in California, potable reuse treatment trains often use both low‐pressure and high‐pressure (i.e., reverse osmosis [RO]) membranes, but when not mandated by local regulations or necessitated by salinity management, the use of membranes may lead to excessive costs or overall sustainability concerns (Bradshaw et al, ; Schimmoller et al, ). Alternative treatment trains using ozone (O 3 )‐biofiltration have been identified as “equivalent” on the basis of public health (Trussell, Salveson, Snyder, Trussell, & Gerrity, ) and are more cost and energy efficient (Gerrity et al, ; Herman, Scruggs, & Thomson, ), but these benefits must be evaluated against certain water quality limitations, including higher concentrations of total organic carbon (TOC) and total dissolved solids (TDS) in the final product water.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Evaluating the sustainability of indirect potable reuse and direct potable reuse: a southern Nevada case study

et al. 2019

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This case study presents a framework for evaluating the sustainability of indirect potable reuse (IPR) and direct potable reuse (DPR) in Las Vegas, Nevada. A system dynamics model was developed to simulate population growth, water supply, water quality, energy costs, net present worth (NPW), and greenhouse gas (GHG) emissions. The model confirmed that DPR could achieve a net reduction in energy costs of up to US$250 million while still ensuring an adequate water supply. However, the high NPW of DPR ($1.0-$4.0 billion) relative to the status quo IPR approach ($0.6 billion) represents a significant economic hurdle, although future monetization of salt loadings and GHGs could reduce that disparity. DPR with ozone-biofiltration would also be hindered by an estimated concentration of total dissolved solids of up to 1,300 mg/L. Despite these barriers to implementation in Las Vegas, certain site-specific conditions may make DPR more attractive in other locations. K E Y W O R D S direct potable reuse, indirect potable reuse, net present worth, sustainability, system dynamics, water supply

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Evaluating the sustainability of indirect potable reuse and direct potable reuse: a southern Nevada case study

et al. 2019

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“…Last, users could adapt this modeling framework to investigate the effect of policy or regulations on these systems. For example, a forthcoming study (Bradshaw et al, ) incorporates regulatory requirements to dilute certain types of recycled water for water quality purposes. In all cases, life cycle assessment could inform the impacts of various infrastructure designs on environmental factors outside our study's scope.…”

Section: Resultsmentioning

confidence: 99%

System Modeling, Optimization, and Analysis of Recycled Water and Dynamic Storm Water Deliveries to Spreading Basins for Urban Groundwater Recharge

Bradshaw

Osorio

Schmitt³

et al. 2019

Water Resources Research

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To bolster freshwater supplies, water managers are increasingly interested in recharging groundwater using storm water and recycled water. However, such multisupply groundwater recharge projects are hindered by the lack of planning tools to evaluate system design costs and trade‐offs. This study presents modeling advancements that provide enhanced insights into multisupply spreading basin systems (i.e., spreading basins that accommodate both advanced treated recycled water and dynamically available storm water), a form of managed aquifer recharge. The model identifies system designs that optimize infrastructure life cycle cost and water volumes infiltrated for groundwater recharge. To illustrate the model's application under realistic conditions, we present a case study of Los Angeles, California. In this case study, we find that competition between storm water and recycled water for spreading basin use is relatively minor. Moreover, compared to systems based on existing conservative assumptions, our methods identify optimal dynamic system designs that are 5%–20% more cost‐effective, primarily resulting from higher water recycling facility utilization. Overall, this approach, which considers the dynamic nature of storm water availability and variable recycled water production, can inform water planners of the cost, water volume, and energy trade‐offs associated with different multisupply spreading basin system designs, including varying levels of centralization.

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“…Consequently, MBRs have shown increased removal of enteric viruses in comparison to activated sludge treatment [21]. Also, MBR technology shows cost-effective with higher efficiency and low energy consumption [22], providing an advanced method to effectively separate complex contaminant mixtures and pathogenic microbes from wastewater [23].…”

Section: Introductionmentioning

confidence: 99%

Membrane bioreactors for hospital wastewater treatment: recent advancements in membranes and processes

Zhao

Qiu

Mamrol

et al. 2021

Front. Chem. Sci. Eng.

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Discharged hospital wastewater contains various pathogenic microorganisms, antibiotic groups, toxic organic compounds, radioactive elements, and ionic pollutants. These contaminants harm the environment and human health causing the spread of disease. Thus, effective treatment of hospital wastewater is an urgent task for sustainable development. Membranes, with controllable porous and nonporous structures, have been rapidly developed for molecular separations. In particular, membrane bioreactor (MBR) technology demonstrated high removal efficiency toward organic compounds and low waste sludge production. To further enhance the separation efficiency and achieve material recovery from hospital waste streams, novel concepts of MBRs and their applications are rapidly evolved through hybridizing novel membranes (non hydrophilic ultrafiltration/microfiltration) into the MBR units (hybrid MBRs) or the MBR as a pretreatment step and integrating other membrane processes as subsequent secondary purification step (integrated MBR-membrane systems). However, there is a lack of reviews on the latest advancement in MBR technologies for hospital wastewater treatment, and analysis on its major challenges and future trends. This review started with an overview of main pollutants in common hospital wastewater, followed by an understanding on the key performance indicators/criteria in MBR membranes (i.e., solute selectivity) and processes (e.g., fouling). Then, an in-depth analysis was provided into the recent development of hybrid MBR and integrated MBR-membrane system concepts, and applications correlated with wastewater sources, with a particular focus on hospital wastewaters. It is anticipated that this review will shed light on the knowledge gaps in the field, highlighting the potential contribution of hybrid MBRs and integrated MBRmembrane systems toward global epidemic prevention.

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Modeling Cost, Energy, and Total Organic Carbon Trade-Offs for Stormwater Spreading Basin Systems Receiving Recycled Water Produced Using Membrane-Based, Ozone-Based, and Hybrid Advanced Treatment Trains

Cited by 15 publications

References 51 publications

Evaluating the sustainability of indirect potable reuse and direct potable reuse: a southern Nevada case study

Evaluating the sustainability of indirect potable reuse and direct potable reuse: a southern Nevada case study

System Modeling, Optimization, and Analysis of Recycled Water and Dynamic Storm Water Deliveries to Spreading Basins for Urban Groundwater Recharge

Membrane bioreactors for hospital wastewater treatment: recent advancements in membranes and processes

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