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3. Exploring the Occupational Physical Activity Levels in young Adult Restaurant Servers

Author

Patricia K. Doyle-Baker and Heather E. Wray

Subjects
Gerontology, 03 medical and health sciences, 0302 clinical medicine, Server, Physical activity, 030229 sport sciences, Young adult, Psychology, 030210 environmental & occupational health
Abstract

Physical activity (PA) decreases in late adolescence and young adulthood when this age cohort enters the workforce with many being employed in the foodservice industry. Daily energy expenditure can be divided between occupational physical activity (OPA) and leisure-time physical activity (LTPA). Although LTPA is known to be associated with positive health benefits, a limited number of studies have investigated the influence of OPA on LTPA in young restaurant servers. This study measured via accelerometry, OPA and LTPA for a 7-day period from a sample of young adult servers (n = 7, 23-29 years old) from two restaurants. Resting metabolic rate was measured via indirect calorimetry and inputted into the AMP 331 accelerometer for energy expenditure calculations. Energy expenditure patterns were compared to age- and sex-specific normative data, occupational classifications, and the Canadian PA Guidelines to Healthy Active Living (CPAG). Energy expenditure results and step count values were higher for working versus non-working days and working versus non-working periods. Daily, working energy expenditure was approximately equal to normative data, while non-working daily energy expenditure was lower. The working period energy expenditure placed this population in the ‘exceptionally active’ OPA classification. Minimum PA levels, based on CPAG were met each day, however 10,000-steps-per-day were only achieved on working days. None of the participants logged LTPA and therefore 100% of their PA came from OPA. More research is needed over a longer duration and at different times in the year to identify the effect OPA has on LTPA in this population.

Published
2019
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4. The impact of loading approach and biological activity on NOM removal by ion exchange resins

Author

Roman Vortisch, Heather E. Wray, Benoit Barbeau, Pierre R. Bérubé, Martin Schulz, and Joerg Winter

Subjects
Environmental Engineering, 0208 environmental biotechnology, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, Natural organic matter, Water Purification, Organic matter, Biological activated carbon, Ion-exchange resin, Waste Management and Disposal, 0105 earth and related environmental sciences, Water Science and Technology, Civil and Structural Engineering, chemistry.chemical_classification, Ion exchange, Ecological Modeling, Contamination, Pulp and paper industry, Pollution, Carbon, 020801 environmental engineering, Ion Exchange, chemistry, Microbial population biology, Ion Exchange Resins
Abstract

The present study investigated the impact of different loading approaches and microbial activity on the Natural Organic Matter (NOM) removal efficiency and capacity of ion exchange resins. Gaining further knowledge on the impact of loading approaches is of relevance because laboratory-scale multiple loading tests (MLTs) have been introduced as a simpler and faster alternative to column tests for predicting the performance of IEX, but only anecdotal evidence exists to support their ability to forecast contaminant removal and runtime until breakthrough of IEX systems. The overall trends observed for the removal and the time to breakthrough of organic material estimated using MLTs differed from those estimated using column tests. The results nonetheless suggest that MLTs could best be used as an effective tool to screen different ion exchange resins in terms of their ability to remove various contaminants of interest from different raw waters. The microbial activity was also observed to impact the removal and time to breakthrough. In the absence of regeneration, a microbial community rapidly established itself in ion exchange columns and contributed to the removal of organic material. Biological ion exchange (BIEX) removed more organic material and enabled operation beyond the point when the resin capacity would have otherwise been exhausted using conventional (i.e. in the absence of a microbial community) ion exchange. Furthermore, significantly greater removal of organic matter could be achieved with BIEX than biological activated carbon (BAC) (i.e. 56 ± 7% vs. 15 ± 5%, respectively) when operated at similar loading rates. The results suggest that for some raw waters, BIEX could replace BAC as the technology of choice for the removal of organic material.

Published
2018
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5. Optimization of air sparging and in-line coagulation for ultrafiltration fouling control

Author

Pierre R. Bérubé, Robert C. Andrews, Heather E. Wray, and Appana Lok

Subjects
Fouling mitigation, Fouling, Chemistry, Membrane fouling, Ultrafiltration, Environmental engineering, Filtration and Separation, 02 engineering and technology, 010501 environmental sciences, Pulp and paper industry, 01 natural sciences, 6. Clean water, Analytical Chemistry, Membrane technology, 020401 chemical engineering, Coagulation (water treatment), 0204 chemical engineering, Air sparging, Sparging, 0105 earth and related environmental sciences
Abstract

A major drawback to ultrafiltration membrane operation for drinking water treatment is fouling, which results in lower water production and increased maintenance costs. The impact of different fouling mitigation strategies including, sparging conditions (duration and air flow rate) as well as phased in-line coagulation were investigated at pilot-scale. Unexpectedly, sparging during permeation and backwash resulted in a significantly higher rate of increase in irreversible resistance compared to Sparging only during backwash. Lower irreversible fouling observed without sparging during permeation was attributed to the formation of a protective layer on the membrane in the absence of sparging. Sparging at reduced air flow rates and intermittently, during the permeation cycle did not improve the irreversible resistance rate when compared to sparging only during backwash. The application of phased in-line coagulation to pre-coat membranes was also investigated. Coagulating for only the first half of the permeation cycle (phased coagulation) did not negatively impact membrane performance in terms of irreversible resistance and organics removal. Phased coagulation, which would lead to reduced coagulant and sludge disposal costs, appears to be a promising fouling control strategy.

Published
2017
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6. Biologically active ion exchange (BIEX) for NOM removal and membrane fouling prevention

Author

Heather E. Wray, Pierre R. Bérubé, Joerg Winter, Benoit Barbeau, and M. Schulz

Subjects
chemistry.chemical_classification, Chromatography, Fouling, 0208 environmental biotechnology, Membrane fouling, Ultrafiltration, 02 engineering and technology, 010501 environmental sciences, Permeation, Pulp and paper industry, 01 natural sciences, 020801 environmental engineering, law.invention, Membrane, chemistry, law, Degradation (geology), Organic matter, Filtration, 0105 earth and related environmental sciences, Water Science and Technology
Abstract

The natural organic matter (NOM) removal efficiency and regeneration behavior of ion-exchange filters with promoted biological activity (BIEX) was compared to operation where biological activity was suppressed (i.e. abiotic conditions). The impact of BIEX pre-treatment on fouling in subsequent ultrafiltration was also investigated. Biological operation enhanced NOM removal by approximately 50% due to an additional degradation of smaller humic substances, building blocks and low molecular weight acids. Promotion of biological activity significantly increased the time to breakthrough of the filters and, therefore, is expected to lower the regeneration frequency as well as the amount of regenerate of which to dispose. Pre-treatment using BIEX filters resulted in a significant decrease in total and irreversible fouling during subsequent ultrafiltration. The decrease was attributed to the effective removal of medium and low molecular weight NOM fractions. The results indicate that BIEX filtration is a robust, affordable and easy-to-operate pre-treatment approach to minimize fouling in ultrafiltration systems and enhance the quality of the produced permeate.

Published
2017
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7. Coagulation optimization for DOC removal: pilot-scale analysis of UF fouling and disinfection byproduct formation potential

Author

Heather E. Wray, Pierre R. Bérubé, and Robert C. Andrews

Subjects
Chromatography, Haloacetic acids, Fouling, Chemistry, 0208 environmental biotechnology, Membrane fouling, Ultrafiltration, 02 engineering and technology, 010501 environmental sciences, engineering.material, 01 natural sciences, 020801 environmental engineering, law.invention, Membrane, law, medicine, engineering, Coagulation (water treatment), Biopolymer, Filtration, 0105 earth and related environmental sciences, Water Science and Technology, medicine.drug
Abstract

A pilot-scale study was performed to evaluate a coagulant dose which had been optimized for biopolymer (i.e., foulant) removal on subsequent ultrafiltration (UF) fouling, as well as disinfection by-product (DBP) precursor removal. Polyaluminum chloride (PACl) dosages were selected based on a point of diminishing returns for biopolymer removal (0.5 mg/L) and directly compared to that applied at full-scale (6 mg/L). Membrane fouling (reversible and irreversible) was measured as resistance increase over a 48 hour filtration period. DBP formation potential (total trihalomethanes (TTHMs), haloacetic acids (HAA9) and total adsorbable organic halides (AOX)) were measured in both raw and treated waters. Results of the study indicate that application of a PACl dose optimized for biopolymer reduction (0.5 mg/L) resulted in 65% less irreversible UF fouling when compared to 6 mg/L. The addition of PACl prior to the membrane resulted in up to a 14% reduction in DBP precursors relative to the UF membrane alone. A similar level of DBP precursor reduction was achieved for both 0.5 and 6 mg/L dosages. The results have implications for cost savings, which may be realized due to decreased chemical use, as well as increased membrane life associated with lower irreversible fouling rates.

Published
2015
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8. Distribution of surface shear stress for a densely packed submerged hollow fiber membrane system

Author

Syed Z. Abdullah, Pierre R. Bérubé, Heather E. Wray, and Robert C. Andrews

Subjects
Materials science, Fouling, Mechanical Engineering, General Chemical Engineering, Bubble, Airflow, Environmental engineering, General Chemistry, Physics::Fluid Dynamics, Hollow fiber membrane, Shear stress, General Materials Science, Fiber, Composite material, Air sparging, Sparging, Water Science and Technology
Abstract

Surface shear stress induced by different air sparging regimes on a submerged hollow fiber ultrafiltration module with horizontally-oriented, densely packed fibers was characterized. Continuous and intermittent (cycling on and off) coarse bubbles (0.75–2.5 mL), as well as large pulse bubble (150 and 500 mL) sparging were considered for a range of air flow rates. The power required to induce surface shear stress on the surface of the hollow fibers was substantially lower when using large pulse bubble sparging compared to both continuous and intermittent coarse bubble sparging. Results indicated that the air flow required for pulse bubble sparging was more than 80% lower than that required for coarse bubble sparging to induce comparable surface shear stress (and corresponding fouling control). This study demonstrates the potential value and efficiency of pulse bubble air sparging as a fouling control option in densely packed hollow fiber membrane systems.

Published
2015
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9. Ultrafiltration Fouling: Impact of Backwash Frequency and Air Sparging

Author

Lan Li, Robert C. Andrews, Pierre R. Bérubé, and Heather E. Wray

Subjects
Chromatography, Fouling, Chemistry, Process Chemistry and Technology, General Chemical Engineering, Bubble, Backwashing, Environmental engineering, Ultrafiltration, Filtration and Separation, General Chemistry, Permeation, Shear stress, Water treatment, Air sparging
Abstract

A bench-scale study was performed to optimize backwash frequency and air sparging conditions during ultrafiltration (UF) for drinking water treatment in order to minimize hydraulically irreversible fouling as well as operating and maintenance costs. Surface shear stress representing different air sparging conditions (continuous coarse bubble, intermittent coarse bubble, and large pulse bubble) was applied in combination with various backwash frequencies (0.5, 2, and 6 hours) during UF of two natural surface waters. Results indicated that air sparging during permeation with intermittent coarse or large pulse bubbles significantly reduced the rate of irreversible fouling. This allowed for longer permeation times (up to 6 hours) between backwashing, when compared to a baseline condition which assumed a 0.5 h-backwash frequency with no air sparging during permeation. As a result, operation and maintenance cost savings estimated at > $350,000/year for a 29 MLD membrane train could be realized. This study demon...

Published
2014
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10. Optimization of coagulant dose for biopolymer removal: Impact on ultrafiltration fouling and retention of organic micropollutants

Author

Heather E. Wray and Robert C. Andrews

Subjects
Chromatography, Fouling, Alum, Process Chemistry and Technology, Membrane fouling, Ultrafiltration, engineering.material, Permeation, Pulp and paper industry, chemistry.chemical_compound, Membrane, chemistry, engineering, Coagulation (water treatment), Biopolymer, Safety, Risk, Reliability and Quality, Waste Management and Disposal, Biotechnology
Abstract

Coagulation as pre-treatment to ultrafiltration (UF) was optimized for the removal of biopolymers, i.e., a primary UF foulant, for three different natural water matrices. The impact of pre-coagulation on membrane reversible and irreversible fouling, as well as the retention of organic micropollutants, was investigated at bench scale. Jar test experiments indicated that the optimum alum dosage for removal of biopolymers, based on a point of diminishing returns analysis, was relatively low (0.5 mg/L as coagulant; 0.05 mg/L as Al 3+ ). This dose was effective at reducing membrane reversible and irreversible fouling (up to 48%) for waters with higher concentrations of organics (>4 mg/L as DOC) over 24 h of permeation and backwash cycles. Biopolymers were identified as contributing to both reversible and irreversible fouling. The retention of organic micropollutants was relatively low for UF alone ( K ow > 2). This study demonstrates that a low dose of coagulant, optimized for biopolymer removal, may reduce membrane fouling and may provide value added for the retention of some organic micropollutants; however dosages depend on the specific water being treated, as well as treatment-related water quality targets.

Published
2014
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11. Surface shear stress and retention of emerging contaminants during ultrafiltration for drinking water treatment

Author

Heather E. Wray, Pierre R. Bérubé, and Robert C. Andrews

Subjects
chemistry.chemical_classification, chemistry, Fouling, Shear (geology), Bubble, Environmental chemistry, Shear stress, Filtration and Separation, Organic matter, Water treatment, Air sparging, Sparging, Analytical Chemistry
Abstract

This study investigated the impact of surface shear stress, to represent air sparging employed for fouling control, on the retention of organic micropollutants during ultrafiltration for drinking water treatment. The retention of 16 different pharmaceutically-active and endocrine disrupting compounds was examined during ultrafiltration of three natural surface waters (two lake, one river) under four different surface shear stress regimes: no shear stress, low peak shear stress (representative of continuous coarse bubble sparging), sustained peak shear stress (representative of intermittent coarse bubble sparging), and high peak shear stress (representative of large pulse bubble sparging). Results indicate that surface shear stress does impact the retention of emerging contaminants; however, it is dependent on water matrix and compound properties. The greatest retention of micropollutants was observed in waters with a higher concentrations of organic matter, and for conditions where no surface shear stress was applied (average 32% retention), and under conditions representative of large pulse bubble sparging (average 34% retention). The observed retention under conditions of no shear stress was likely due to a heavy fouling layer that altered the membrane selectivity and was able to entrap organic micropollutants of larger molecular weight. Under conditions that mimicked air sparging, increasing the shear stress (quantified as the root mean square applied shear) resulted in increased retention of organic micropollutants, particularly those that are neutral and hydrophobic in nature. This may be related to solute–solute complexes, which are kept in solution when shear stress is applied, or related to modification of the fouling layer by the shear stress induced onto the membrane surface. The results suggest that there may be value added with respect to removal of organic micropollutants, such as pharmaceuticals, when employing air sparging as a fouling control strategy during ultrafiltration.

Published
2014
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13. Surface shear stress and membrane fouling when considering natural water matrices

Author

Robert C. Andrews, Heather E. Wray, and Pierre R. Bérubé

Subjects
Materials science, Fouling, Mechanical Engineering, General Chemical Engineering, Bubble, Membrane fouling, Environmental engineering, General Chemistry, Surface shear, Shear (geology), Shear stress, General Materials Science, Composite material, Air sparging, Sparging, Water Science and Technology
Abstract

The effect of surface shear stress on membrane fouling during submerged hollow fiber ultrafiltration of three different surface waters (two lakes, one river) was investigated. Surface shear stresses that mimicked those induced when applying continuous and intermittent coarse bubble air sparging, large pulse bubble air sparging, as well as no air sparging were considered. The results suggest that fouling was mainly due to the accumulation of the biopolymer fraction of the natural organic matter present in the raw water. Inducing shear stresses onto the membrane surface significantly decreased the rate of membrane fouling (relative to no shear stress applied) in all waters tested. Of the shear stress conditions studied, that which mimicked large pulse bubble sparging had the greatest effect, reducing fouling by up to 80% when compared to conditions with no sparging applied. Conditions that mimicked intermittent and continuous coarse bubble fouling reduced the rate of fouling by up to 77 and 49%, respectively. These results suggest that the shear stresses induced by sparging can promote back transport of soluble organic material from the membrane surface. A semi-empirical relationship was developed to estimate the effect of raw water characteristics and applied sparging conditions on membrane fouling.

Published
2013
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14. Denitrification rates in marsh fringes and fens in two boreal peatlands in Alberta, Canada

Author

Heather E. Wray and Suzanne E. Bayley

Subjects
Hydrology, geography, geography.geographical_feature_category, Peat, Denitrification, Ecology, Wetland, chemistry.chemical_compound, Nitrate, chemistry, Boreal, Environmental Chemistry, Environmental science, Nitrification, Water content, Nitrogen cycle, General Environmental Science
Abstract

Western Boreal Plain peatlands can play an important role in the global nitrogen cycle by storing N in peat and potentially releasing large amounts of N to the atmosphere. In this study, biological denitrification rates were measured in marsh and fen vegetation zones in two boreal peatland-pond complexes in northcentral Alberta, Canada. Assuming negligible winter denitrification, we estimated annual denitrification rates of 11 g N·m−2 in marshes and 24 g N·m−2 in fens. Two techniques were employed to measure denitrification: 1) measurements of direct N2-flux were taken from intact cores in gas-tight N-free chambers, and 2) nitrous oxide (N2O) flux was measured in the two fens using in situ chambers. N2 fluxes ranged from 2.14–4.19 mg N·m−2·h−1 in marshes and 6.19–6.81 mg N·m−2·h−1 in fens. N2O release from fen peat ranged from consumption to 0.025 mg N·m−2·h−1. Peat with higher carbon and moisture content was a source of N2O whereas peat with lower carbon and moisture content was a sink. Surface water did not appear to be a major source of nitrate for denitrification. However, denitrification rates were positively correlated with peat extractable nitrate. Combined with mineralization studies, this indicated that soil nitrification provided most of the substrate for denitrification.

Published
2007
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