The use of treated effluent for agricultural irrigation in the Bottelary River area: Effluent quality, farmers perception and potential extent

Rui, Li

January 2005

Magister Scientiae - MSc / The Bottelary River area is located in a Mediterranean climate region, where the agricultural sector plays an important role. During the dry summer season, there is not enough precipitation to meet the agricultural irrigation requirements. Some farmers extract river water which is practically the final treated effluent from the Scottsdene Wastewater Treatment Works to irrigate crops. This research investigated the use of treated effluent for agricultural irrigation in this area, particularly focused on the effluent quality, farmers perception, and the potential extent. / South Africa

Sewage disposal

South Africa

Water reuse

Water-supply

Agriculture

Sewage

Purification

Biosorption of precious metals from synthetic and refinery wastewaters by immobilized saccharomyces cerevisiae

Mack, Cherie-Lynn

January 2008

The process of precious metal refining can be up to 99.99% efficient at best, and although it may seem small, the amount of valuable metal lost to waste streams is appreciable enough to warrant recovery. The method currently used to remove entrained metal ions from refinery wastewaters, chemical precipitation, is not an effective means for selective recovery of precious metals from a wastewater. Biosorption, the ability of certain types of biomass to bind and concentrate metals from even very dilute aqueous solutions, may be an effective point-source metal recovery strategy. The yeast, Saccharomyces cerevisiae, has been found capable of sorbing numerous precious and base metals, and is a cheap and abundant source of biomass. As such, it represents a possible precious metal sorbent for application to refining wastewaters. In this investigation, S. cerevisiae biomass was immobilized, using polyethyleneimine and glutaraldehyde, to produce a suitable sorbent, which was found to be capable of high platinum uptake (150 to 170 mg/g) at low pH (< 2). The sorption mechanism was elucidated and found to be a chemical reaction, which made effective desorption impossible. The sorption process was investigated in a packed bed column conformation, the results of which showed that the diameter and height of the column require further optimization in order to attain the metal uptake values achieved in the batch studies. When applied to a refinery wastewater, two key wastewater characteristics limited the success of the sorption process; the high inorganic ion content and the complex speciation of the platinum ions. The results proved the concept principle of platinum recovery by immobilized yeast biosorption and indicated that a more detailed understanding of the platinum speciation within the wastewater is required before the biosorption process can be applied. Overall, the sorption of platinum by the S. cerevisiae sorbent was demonstrated to be highly effective in principle, but the complexity of the wastewater requires that pretreatment steps be taken before the successful application of this process to an industrial wastewater.

Metals -- Refining

Metals -- Absorption and adsorption

Saccharomyces cerevisiae

Factory and trade waste

Water reuse

Platinum

Novel Microbial Electrochemical Technologies and Microorganisms for Power Generation and Desalination

Chehab, Noura A.

12 1900

Global increases in water demand and decreases in both the quantity and quality of fresh water resources have served as the major driving forces to develop sustainable use of water resources. One viable alternative is to explore non-traditional (impaired quality) water sources such as wastewater and seawater. The current paradigm for wastewater treatment is based on technologies that are energy intensive and fail to recover the potential resources (water and energy) in wastewater. Also, conventional desalination technologies like reverse osmosis (RO) are energy intensive. Therefore, there is a need for the development of sustainable wastewater treatment and desalination technologies for practical applications. Processes based on microbial electrochemical technologies (METs) such as microbial fuel cells (MFCs), microbial electrolysis cells (MECs) and microbial desalination cells (MDCs) hold promise for the treatment of wastewater with recovery of the inherent energy, and MDCs could be used for both desalination of seawater and energy recovery. METs use anaerobic bacteria, referred to as exoelectrogens, that are capable of transferring electrons exogenously to convert soluble organic matter present in the wastewater directly into an electrical current to produce electrical power (MFC and MDC) or biogas (MEC). In my dissertation, I investigated the three types of METs mentioned above to: 1) have a better insight on the effect of 4 oxygen intrusion on the microbial community structure and performance of air-cathode MFCs; 2) improve the desalination efficiency of air-cathode MDCs using ion exchange resins (IXRs); and 3) enrich for extremophilic exoelectrogens from the Red Sea brine pool using MECs. The findings from these studies can shape further research aimed at developing more efficient air-cathode MFCs for practical applications, a more efficient integrated IXRMDC configuration that can be used as a pre-treatment to RO, and exploring extreme environments as a source of extremophilic exoelectrogens for niche-specific applications of METs.

Microbial Fuel Cells

Microbial Desalination Cells

Desalination

Exoelectrogens

Microbial Electrolysis Cells

Water Reuse

Passive and active surfaces to reduce fouling of membranes and membane modules

January 2019

abstract: This dissertation investigates the mechanisms that lead to fouling, as well as how an understanding of how these mechanisms can be leveraged to mitigate fouling. To limit fouling on feed spacers, various coatings were applied. The results showed silver-coated biocidal spacers outperformed other spacers by all measures. The control polypropylene spacers performed in-line with, or better than, the other coatings. Polypropylene’s relative anti-adhesiveness is due to its surface free energy (SFE; 30.0 +/- 2.8 mN/m), which, according to previously generated models, is near the ideal SFE for resisting adhesion of bacteria and organics (~25 mN/m). Previous research has indicated that electrochemical surfaces can be used to remove biofilms. To better elucidate the conditions and kinetics of biofilm removal, optical coherence tomography microscopy was used to visualize the biofouling and subsequent cleaning of the surface. The 50.0 mA cm-2 and 87.5 mA cm-2 current densities proved most effective in removing the biofilm. The 50.0 mA cm-2 condition offers the best balance between performance and energy use for anodic operation. To test the potential to incorporate electrochemical coatings into infrastructure, membranes were coated with carbon nanotubes (CNTs), rendering the membranes electrochemically active. These membranes were biofouled and subsequently cleaned via electrochemical reactions. P. aeruginosa was given 72h to develop a biofilm on the CNT-coated membranes in a synthetic medium simulating desalination brines. Cathodic reactions, which generate H2 gas, produce vigorous bubbling at a current density of 12.5 mA cm-2 and higher, leading to a rapid and complete displacement of the biofilm from the CNT-functionalized membrane surface. In comparison, anodic reactions were unable to disperse the biofilms from the surface at similar current densities. The scaling behavior of a nanophotonics-enabled solar membrane distillation (NESMD) system was investigated. The results showed the NESMD system to be resistant to scaling. The system operated without any decline in flux up to concentrations 6x higher than the initial salt concentration (8,439 mg/L), whereas in traditional membrane distillation (MD), flux essentially stopped at a salt concentration factor of 2x. Microscope and analytical analyses showed more fouling on the membranes from the MD system. / Dissertation/Thesis / Doctoral Dissertation Civil, Environmental and Sustainable Engineering 2019

Environmental engineering

Civil engineering

Water resources management

Biofouling

Desalination

Fouling

Nanomaterials

Scaling

Water reuse

Pollution Prevention and Water Reuse at Utah Department of Transportation Facilities

Stoudt, Amanda

01 May 2020

As stormwater flows over roads, sidewalks, and other impervious surfaces, it picks up pollutants that are deposited on these surfaces. One common pollutant transported by stormwater is road salt. While the application of road salt is crucial for wintertime public safety, road salt has a host of negative environmental impacts. Road salt has been linked to increasing levels of dissolved solids in groundwater, vegetation damage, and behavioral changes in aquatic organisms. Studies have shown that these impacts are concentrated around salt storage facilities. As a result, the United States Environmental Protection Agency issued many state departments of transportation municipal separate storm sewer system (MS4) permits. In Utah, road salt is stored at Utah Department of Transportation (UDOT) maintenance stations, which are regulated by a Phase I MS4 permit. To comply with their MS4 permit, UDOT constructed retention ponds to capture salt-laden stormwater and truck wash water. However, without information and established maintenance and management plans informing pond design, these retention ponds suffer from design issues such as overflow throughout the winter season. Through pollution prevention assessments, pond and tap water analysis, pond sediment analysis, and surface water quality modeling at 11 UDOT maintenance stations, this project provides UDOT with site design guidelines and best management practices to ultimately reduce the impact of UDOT road salt facilities on the environment.

brine

pollution prevention

retention pond water reuse

UDOT

Civil and Environmental Engineering

Ozonation and/or Coagulation - Ceramic Membrane Hybrid for Filtration of Impaired-Quality Source Waters

Ha, Changwon

09 1900

When microfiltration (MF) and ultrafiltration (UF) membranes are applied for drinking water treatment/wastewater reuse, membrane fouling is an evitable problem, causing the loss of productivity over time. Polymeric membranes have been often reported to experience rapid and/or problematical fouling, restraining sustainable operation. Ceramic membranes can be effectively employed to treat impaired-quality source waters due to their inherent robustness in terms of physical and chemical stability. This research aimed to identify the effects of coagulation and/or ozonation on ceramic membrane filtration for seawater and wastewater (WW) effluent. Two different types of MF and UF ceramic membranes obtained by sintering (i.e., TAMI made of TiO2+ZrO2) and anodic oxidation process (i.e., AAO made of Al2O3) were employed for bench-scale tests. Precoagulation was shown to play an important role in both enhancing membrane filterability and natural organic matter (NOM) removal efficacy for treating a highorganic surface water. The most critical factors were found to be pH and coagulant dosage with the highest efficiency resulting under low pH and high coagulant dose. Due to the ozone-resistance nature of the ceramic membranes, preozonation allowed the ceramic membranes to be operated at higher flux, especially leading to significant flux improvement when treating seawater in the presence of calcium and magnesium. 4 Dissolved ozone in contact with the TAMI ceramic membrane surface accelerated the formation of hydroxyl (˙OH) radicals in WW effluent treatment. Flux restoration of both ceramic membranes, fouled with seawater and WW effluent, was efficiently achieved by high backwash (BW) pressure and ozone in chemically enhanced backwashing (CEB). Ceramic membranes exhibited a pH-dependent permeate flux while filtering WW effluent, showing reduced fouling with increased pH. On the other hand, for filtering seawater, differences in permeate flux between the two membranes was observed under basic pH conditions, showing that the TAMI membrane flux was stable regardless of changes in pH, while the AAO membrane flux was significantly decreased as pH increased to 10. Consequently, it is expected that ozone and/or coagulation prior to ceramic membrane filtration can play a significant role in treating impaired-quality source waters (e.g., seawater and WW effluent), leading to maintaining sustainable membrane flux in seawater pretreatment before reverse osmosis (RO) or water reuse applications.

drinking water

ceramic membrane

ozonation

coagulation

natural organic matter

water reuse

NOM

precoagulation

Florida’s Recycled Water Footprint: A Geospatial Analysis of Distribution (2009 and 2015)

Archer, Jana E., Luffman, Ingrid E., Nandi, Arpita N., Joyner, T. Andrew

01 January 2019

Water shortages resulting from increased demand or reduced supply may be addressed, in part, by redirecting recycled water for irrigation, industrial reuse, groundwater recharge, and as effluent discharge returned to streams. Recycled water is an essential component of integrated water management and broader adoption of recycled water will increase water conservation in water-stressed coastal communities. This study examined spatial patterns of recycled water use in Florida in 2009 and 2015 to detect gaps in distribution, quantify temporal change, and identify potential areas for expansion. Databases of recycled water products and distribution centers for Florida in 2009 and 2015 were developed by combining the 2008 and 2012 Clean Water Needs Survey databases with Florida’s 2009 and 2015 Reuse Inventory databases, respectively. Florida increased recycled water production from 674.85 mgd in 2009 to 738.15 mgd in 2015, an increase of 63.30 mgd. The increase was primarily allocated to use in public access areas, groundwater recharge, and industrial reuse, all within the South Florida Water Management District (WMD). In particular, Miami was identified in 2009 as an area of opportunity for recycled water development, and by 2015 it had increased production and reduced the production gap. Overall, South Florida WMD had the largest increase in production of 44.38 mgd (69%), while Southwest Florida WMD decreased production of recycled water by 1.68 mgd, or 3%. Overall increase in use of recycled water may be related to higher demand due to increased population coupled with public programs and policy changes that promote recycled water use at both the municipal and individual level.

Florida

geospatial analysis

kernel density estimation

recycled water

spatiotemporal change

water management districts

water reuse

Geosciences

Integrating Microbial Electrochemical Technology with Forward Osmosis and Membrane Bioreactors: Low-Energy Wastewater Treatment, Energy Recovery and Water Reuse

Werner, Craig M.

06 1900

Wastewater treatment is energy intensive, with modern wastewater treatment processes consuming 0.6 kWh/m3 of water treated, half of which is required for aeration. Considering that wastewater contains approximately 2 kWh/m3 of energy and represents a reliable alternative water resource, capturing part of this energy and reclaiming the water would offset or even eliminate energy requirements for wastewater treatment and provide a means to augment traditional water supplies. Microbial electrochemical technology is a novel technology platform that uses bacteria capable of producing an electric current outside of the cell to recover energy from wastewater. These bacteria do not require oxygen to respire but instead use an insoluble electrode as their terminal electron acceptor. Two types of microbial electrochemical technologies were investigated in this dissertation: 1) a microbial fuel cell that produces electricity; and 2) a microbial electrolysis cell that produces hydrogen with the addition of external power. On their own, microbial electrochemical technologies do not achieve sufficiently high treatment levels. Innovative approaches that integrate microbial electrochemical technologies with emerging and established membrane-based treatment processes may improve the overall extent of wastewater treatment and reclaim treated water. Forward osmosis is an emerging low-energy membrane-based technology for seawater desalination. In forward osmosis water is transported across a semipermeable membrane driven by an osmotic gradient. The microbial osmotic fuel cell described in this dissertation integrates a microbial fuel cell with forward osmosis to achieve wastewater treatment, energy recovery and partial desalination. This system required no aeration and generated more power than conventional microbial fuel cells using ion exchange membranes by minimizing electrochemical losses. Membrane bioreactors incorporate semipermeable membranes within a biological wastewater treatment process. The anaerobic electrochemical membrane bioreactor described here integrates a microbial electrolysis cell with a membrane bioreactor using conductive hollow fiber membrane to produce hydrogen gas, treat wastewater and reclaim treated water. The energy recovered as hydrogen gas in this system was sufficient to offset all the electrical energy requirements for operation. The findings from these studies significantly improve the prospects for simultaneous wastewater treatment, energy recovery and water reclamation in a single reactor but challenges such as membrane biofouling and conversion of hydrogen to methane by methanogenesis require further study.

Microbial Fuel Cell

Forward Osmosis

Membrane Bioreactor

water reuse

Wastewater Treatment

energy recovery

Towards developing a communication strategy for water re-use in South Africa

Mamabolo, Mamogobo Rosinah

January 2020

Thesis (M.A. (Communication Studies)) -- University of Limpopo, 2020 / This study aimed to develop a communication strategy for water re-use in Basic Education, which included illustrative learning materials which were suitable for online learning. To attain the intended aim, the study focussed on the subsequent objectives: to review and analyse learners’ and educators’ perceptions and understanding (knowledge) of water re-use; to examine strategies that could be employed to gain learners’ and educators’ understanding and acceptance of water re-use; to develop information or learning materials that would educate and enhance their understanding and informed decision making related to water re-use; and to discuss approaches to communicate water re-use in Basic Education. A qualitative orientation utilising participatory action research was employed as a research design for this study. A sample size of 80 participants, from four primary and four secondary schools in Mankweng Township was selected. 40 learners and 40 educators were selected. Convenience sampling was used to select the participants for this study. Data was collected by means of interviews, focus group discussions, workshops, teaching and participant observation. Thereafter, thematic analysis and NVivo software were employed to analyse data. This study employed Geertz’s notion of culture, Vygotsky’s social constructivism and the behaviour ecological model as theoretical frameworks to guide the research. Geertz’s interpretation of cultures was employed to understand culture and its effects on human behaviour, Vygotsky’s social constructivism was employed to understand the process of effective learning in educational contexts and the behaviour ecological model was employed to understand individuals’ behaviours and the background of the given behaviour. Understanding an individual’s behaviour and experiences towards water re-use assisted in developing water re-use illustrative learning materials. It also assisted with a communication strategy, which integrated Steyn and Puth’s steps, in the formulation of a communication strategy, joint approach model and a step by step content of a communication strategy and action plan model. The study revealed that the majority of individuals have negative perceptions and attitudes towards water re-use, due to a lack of awareness, knowledge and education. The “yuck” factor and health apprehensions were revealed to be major causes of such perceptions and attitudes. Education, campaigns and programmes, traditional and v new media, community meetings, rules, policies and regulation were reported as strategies which might be employed to promote water re-use. The study revealed that individuals’ home language must be made use of in all the water re-use promotional strategies. Communication approaches which promoted a platform for community participation, were revealed as appropriate for development programmes. As a result, participatory and development approaches to communication were considered suitable for communicating water re-use in Basic Education. The study further indicated that posters and storyboards were effective illustrative learning materials which could be employed to educate learners and raise their cognition regarding water re-use as a water conservation method. This would increase acceptability, awareness and practice and reduce negative perceptions, attitudes and concerns. The study indicated that water re-use communication should consider an individuals’ environmental, religious and cultural backgrounds, which would affect water re-use projects. The study also indicated that there was a relationship between an individuals’ perceptions, attitudes, education and culture.

Water re-use

greywater

water

communication

communication strategy

illustrative learning materials

Communication strategy

Communication

Water reuse

CONSTRUCTION AND VALIDATION OF A STERIC PORE-FLOW MODEL FOR PREDICTING REJECTION OF SMALL AND UNCHARGED COMPOUNDS BY POLlYMIDE REVERSE OSMOSIS MEMBRANES / RO膜処理における低分子量物質の除去率予測手法の開発

Haruka, Takeuchi

23 July 2018

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第21308号 / 工博第4506号 / 新制||工||1701(附属図書館) / 京都大学大学院工学研究科都市環境工学専攻 / (主査)教授 田中 宏明, 教授 清水 芳久, 教授 伊藤 禎彦 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM

Water reuse

Reverse osmosis membrane

N-nitrosamines

Steric pore-flow model

500