Your search keyword '"Toze, Simon"' showing total 5 results

1. Aquifer residence times for recycled water estimated using chemical tracers and the propagation of temperature signals at a managed aquifer recharge site in Australia

Author

Bekele, Elise, Patterson, Bradley, Toze, Simon, Furness, Andrew, Higginson, Simon, and Shackleton, Mark

Published

2014

2. Evaluating two infiltration gallery designs for managed aquifer recharge using secondary treated wastewater

Author

Bekele, Elise, Toze, Simon, Patterson, Bradley, Fegg, Wolfgang, Shackleton, Mark, and Higginson, Simon

Subjects

*PILOT projects, *GROUNDWATER recharge, *SOIL infiltration, *FILTER efficiency, *WASTEWATER treatment, *SEWAGE purification, *WATER reuse, *HYDRAULICS

Abstract

As managed aquifer recharge (MAR) becomes increasingly considered for augmenting water-sensitive urban areas, fundamental knowledge of the achievable scale, longevity and maintenance requirements of different options will become paramount. This paper reports on a 39 month pilot scale MAR scheme that infiltrated secondary treated wastewater through unsaturated sand into a limestone and sand aquifer. Two types of infiltration gallery were constructed to compare their hydraulic performance, one using crushed, graded gravel, the other using an engineered leach drain system (Atlantis Leach System®). Both galleries received 25 kL of nutrient-rich, secondary treated wastewater per day. The Atlantis gallery successfully infiltrated 17 ML of treated wastewater over three years. The slotted distribution pipe in the gravel gallery became clogged with plant roots after operating for one year. The infiltration capacity of the gravel gallery could not be restored despite high pressure cleaning, thus it was replaced with an Atlantis system. Reduction in the infiltration capacity of the Atlantis system was only observed when inflow was increased by about 3 fold for two months. The performance of the Atlantis system suggests it is superior to the gravel gallery, requiring less maintenance within at least the time frame of this study. The results from a bromide tracer test revealed a minimum transport time of 3.7 days for the recharged water to reach the water table below 9 m of sand and limestone. This set a limit on the time available for attenuation by natural treatment within the unsaturated zone before it recharged groundwater. [Copyright &y& Elsevier]

Published

2013

3. Managed aquifer recharge of treated wastewater: Water quality changes resulting from infiltration through the vadose zone

Author

Bekele, Elise, Toze, Simon, Patterson, Bradley, and Higginson, Simon

Subjects

*WASTEWATER treatment, *GROUNDWATER management, *WATER quality, *ZONE of aeration, *GROUNDWATER recharge, *WATER reuse, *WATER chemistry, *AQUATIC microbiology, *CLINICAL drug trials

Abstract

Abstract: Secondary treated wastewater was infiltrated through a 9 m-thick calcareous vadose zone during a 39 month managed aquifer recharge (MAR) field trial to determine potential improvements in the recycled water quality. The water quality improvements of the recycled water were based on changes in the chemistry and microbiology of (i) the recycled water prior to infiltration relative to (ii) groundwater immediately down-gradient from the infiltration gallery. Changes in the average concentrations of several constituents in the recycled water were identified with reductions of 30% for phosphorous, 66% for fluoride, 62% for iron and 51% for total organic carbon when the secondary treated wastewater was infiltrated at an applied rate of 17.5 L per minute with a residence time of approximately four days in the vadose zone and less than two days in the aquifer. Reductions were also noted for oxazepam and temazepam among the pharmaceuticals tested and for a range of microbial pathogens, but reductions were harder to quantify as their magnitudes varied over time. Total nitrogen and carbamazepine persisted in groundwater down-gradient from the infiltration galleries. Infiltration does potentially offer a range of water quality improvements over direct injection to the water table without passage through the unsaturated zone; however, additional treatment options for the non-potable water may still need to be considered, depending on the receiving environment or the end use of the recovered water. [Copyright &y& Elsevier]

Published

2011

4. Use of static Quantitative Microbial Risk Assessment to determine pathogen risks in an unconfined carbonate aquifer used for Managed Aquifer Recharge

Author

Toze, Simon, Bekele, Elise, Page, Declan, Sidhu, Jatinder, and Shackleton, Mark

Subjects

*GROUNDWATER recharge, *WASTEWATER treatment, *CARBONATES, *PATHOGENIC microorganisms, *HEALTH risk assessment, *WASTE recycling, *GROUNDWATER pollution, *CRYPTOSPORIDIUM, *QUANTITATIVE chemical analysis

Abstract

Abstract: Managed Aquifer Recharge (MAR) is becoming a mechanism used for recycling treated wastewater and captured urban stormwater and is being used as a treatment barrier to remove contaminants such as pathogens from the recharged water. There is still a need, however, to demonstrate the effectiveness of MAR to reduce any residual risk of pathogens in the recovered water. A MAR research site recharging secondary treated wastewater in an unconfined carbonate aquifer was used in conjunction with a static Quantitative Microbial Risk Assessment (QMRA) to assess the microbial pathogen risk in the recovered water following infiltration and aquifer passage. The research involved undertaking a detailed hydrogeological assessment of the aquifer at the MAR site and determining the decay rates of reference pathogens from an in-situ decay study. These variables along with literature data were then used in the static QMRA which demonstrated that the recovered water at this site did not meet the Australian Guidelines for recycled water when used for differing private green space irrigation scenarios. The results also confirmed the importance of obtaining local hydrogeological data as local heterogeneity can influence of residence time in the aquifer which, in turn, influences the outcomes. The research demonstrated that a static QMRA can be used to determine the residual risk from pathogens in recovered water and showed that it can be a valuable tool in the preliminary design and operation of MAR systems and the incorporation of complementary engineered treatment processes to ensure that there is acceptable health risk from the recovered water. [Copyright &y& Elsevier]

Published

2010

5. Valuing the subsurface pathogen treatment barrier in water recycling via aquifers for drinking supplies

Author

Page, Declan, Dillon, Peter, Toze, Simon, Bixio, Davide, Genthe, Bettina, Jiménez Cisneros, Blanca Elena, and Wintgens, Thomas

Subjects

*HYDROLOGIC cycle, *WATER supply, *GROUNDWATER recharge, *DRINKING water microbiology, *ENVIRONMENTAL risk assessment, *WATER purification, *CASE studies

Abstract

Abstract: A quantitative microbial risk assessment (QMRA) was performed at four managed aquifer recharge (MAR) sites (Australia, South Africa, Belgium, Mexico) where reclaimed wastewater and stormwater is recycled via aquifers for drinking water supplies, using the same risk-based approach that is used for public water supplies. For each of the sites, the aquifer treatment barrier was assessed for its log10 removal capacity much like for other water treatment technologies. This information was then integrated into a broader risk assessment to determine the human health burden from the four MAR sites. For the Australian and South African cases, managing the aquifer treatment barrier was found to be critical for the schemes to have low risk. For the Belgian case study, the large treatment trains both in terms of pre- and post-aquifer recharge ensures that the risk is always low. In the Mexico case study, the risk was high due to the lack of pre-treatment and the low residence times of the recharge water in the aquifer. A further sensitivity analysis demonstrated that human health risk can be managed if aquifers are integrated into a treatment train to attenuate pathogens. However, reduction in human health disease burden (as measured in disability adjusted life years, DALYs) varied depending upon the number of pathogens in the recharge source water. The beta-Poisson dose response curve used for translating rotavirus and Cryptosporidium numbers into DALYs coupled with their slow environmental decay rates means poor quality injectant leads to aquifers having reduced value to reduce DALYs. For these systems, like the Mexican case study, longer residence times are required to meet their DALYs guideline for drinking water. Nevertheless the results showed that the risks from pathogens can still be reduced and recharging via an aquifer is safer than discharging directly into surface water bodies. [Copyright &y& Elsevier]

Published

2010