Discovery Early Career Researcher Award - Grant ID: DE200101079
Funder
Australian Research Council
Funding Amount
$426,241.00
Summary
Safe distractions? Taking the danger out of competing activities. Distracted driving is an increasing safety concern in Australia and worldwide. Smartphones play key roles in today’s professional and social contexts and current road safety policies based on stopping their use while driving have shown little success. Distraction is predicted to be an even greater issue in new semi-automated vehicles. This project proposes an innovative approach that will enable safe engagement in competing tasks ....Safe distractions? Taking the danger out of competing activities. Distracted driving is an increasing safety concern in Australia and worldwide. Smartphones play key roles in today’s professional and social contexts and current road safety policies based on stopping their use while driving have shown little success. Distraction is predicted to be an even greater issue in new semi-automated vehicles. This project proposes an innovative approach that will enable safe engagement in competing tasks while driving non-automated and semi-automated vehicles. The outcomes will underpin the development of new technologies to reduce the potential adverse effects of these distractions and thus reduce deaths and serious injuries, representing significant cost savings to the health system and the community.Read moreRead less
The Development of a Hybrid Energy Simulation Model for Masonry Enclosures. This project aims to develop and validate a hybrid energy simulation model for assessing the thermal performance of masonry enclosures. The model will combine the zonal and computational fluid dynamics modelling techniques into a fully integrated computational tool. Once validated, the proposed model will be employed to evaluate the thermal performance of a wide range of wall designs taking into account the Australian cl ....The Development of a Hybrid Energy Simulation Model for Masonry Enclosures. This project aims to develop and validate a hybrid energy simulation model for assessing the thermal performance of masonry enclosures. The model will combine the zonal and computational fluid dynamics modelling techniques into a fully integrated computational tool. Once validated, the proposed model will be employed to evaluate the thermal performance of a wide range of wall designs taking into account the Australian climatic conditions, construction practices and typical residential developments. The results will be then employed to modify and refine the existing wall designs and develop optimum masonry walling system(s) that are well suited for the Australian climatic conditions.Read moreRead less
Experimental Modelling of Masonry Buildings' Thermal Performance. Mathematical modelling of the thermal performance of buildings has been identified as one of the key technologies necessary for designing energy-efficient buildings. The aim of this project is to develop an experimental model of the thermal response of typical masonry enclosures by establishing relationships between input and output measurements from several full-scale test houses rather than relying on conservation principles. On ....Experimental Modelling of Masonry Buildings' Thermal Performance. Mathematical modelling of the thermal performance of buildings has been identified as one of the key technologies necessary for designing energy-efficient buildings. The aim of this project is to develop an experimental model of the thermal response of typical masonry enclosures by establishing relationships between input and output measurements from several full-scale test houses rather than relying on conservation principles. Once validated, the proposed model will be employed to evaluate the thermal performance of a wide range of walling systems. This should lead to an improved understanding of mechanisms influencing the thermal behaviour of masonry enclosures under Australian climatic conditions.Read moreRead less
Smart Utilisation of Thermal Mass in Masonry Buildings. This study will help determine the effectiveness of a range of novel technologies for smart utilisation of thermal mass in masonry buildings. The ultimate goal is to improve the thermal performance of such constructions. The project focuses on the National Research Priority 3 because of the novel and advanced technological nature of the proposed research. The project has also a significant potential in contributing to the Federal Government ....Smart Utilisation of Thermal Mass in Masonry Buildings. This study will help determine the effectiveness of a range of novel technologies for smart utilisation of thermal mass in masonry buildings. The ultimate goal is to improve the thermal performance of such constructions. The project focuses on the National Research Priority 3 because of the novel and advanced technological nature of the proposed research. The project has also a significant potential in contributing to the Federal Government's effort in the Research Priority 1 because achieving better thermal efficiency in buildings will undoubtedly help to minimise electricity usage leading to a reduction in CO2 emissions.Read moreRead less
Optimising Decentralised Membrane Bioreactors for Water Reuse. Water is a critical resource in Australia and as pressures on water resources increase, water recycling has emerged as an important component of water management practises throughout Australia. Decentralised wastewater treatment systems (or package plants) offer opportunities for water recycling in regional communities; however this application is limited by our understanding on the removal of contaminants of concern through these tr ....Optimising Decentralised Membrane Bioreactors for Water Reuse. Water is a critical resource in Australia and as pressures on water resources increase, water recycling has emerged as an important component of water management practises throughout Australia. Decentralised wastewater treatment systems (or package plants) offer opportunities for water recycling in regional communities; however this application is limited by our understanding on the removal of contaminants of concern through these treatment systems. This project will assess the suitability and efficiency of decentralised membrane bioreactors (MBRs) for the removal of endocrine disrupting chemicals (EDCs), pharmaceutically active compounds (PhACs) and pathogens in accordance with the 2006 National Guidelines for Water Recycling.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883080
Funder
Australian Research Council
Funding Amount
$490,000.00
Summary
Detection of Trace Concentrations of Chemical Contaminants in Urban Water Systems. Water is a critical resource in Australia and as pressures on water resources increase, water recycling is becoming more prevalent. The presence of chemical contaminants such as low concentrations (ng/L) of pharmaceutically active compounds (PhACs), endocrine disrupters (EDCs) and other organic micropollutants in the aquatic environment has received much attention around the world including Australia due to their ....Detection of Trace Concentrations of Chemical Contaminants in Urban Water Systems. Water is a critical resource in Australia and as pressures on water resources increase, water recycling is becoming more prevalent. The presence of chemical contaminants such as low concentrations (ng/L) of pharmaceutically active compounds (PhACs), endocrine disrupters (EDCs) and other organic micropollutants in the aquatic environment has received much attention around the world including Australia due to their potential biological impact in urban water systems. The proposed equipment aims to establish analytical techniques and instrumental capacity for the selective analysis of chemical contaminants in order to improve our understanding of the fate of these compounds through different urban water systems.Read moreRead less
Optimising dissolved air flotation (DAF) for algae removal by bubble modification in drinking water and advanced wastewater systems. Algal blooms in potable water reservoirs and advanced wastewater treatment lagoons can impact the performance and economic viability of water treatment processes resulting in taste and odour episodes and the risk of algal toxins as well as causing further limitation to already stressed water resources in Australia. This project aims to develop an adaptation of the ....Optimising dissolved air flotation (DAF) for algae removal by bubble modification in drinking water and advanced wastewater systems. Algal blooms in potable water reservoirs and advanced wastewater treatment lagoons can impact the performance and economic viability of water treatment processes resulting in taste and odour episodes and the risk of algal toxins as well as causing further limitation to already stressed water resources in Australia. This project aims to develop an adaptation of the dissolved air flotation process that is already used for algae treatment that will provide a more robust, economic and sustainable barrier to algal cells in accordance with the Australian Drinking and Recycled Water Guidelines.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100089
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Performance level structural testing facility. A structural testing facility is proposed for the new Advanced Engineering Building at The University of Queensland. The focus of the research supported by this facility will ensure the functionality of Australia’s infrastructure resources and the development of new engineering solutions that will enhance the country’s long-term economic growth.
Cost-effective integrated engineering and "community partnerships" solution to a latent water policy issue: private dam management and flood safety. Project aims to further develop an engineering model for cost-effective innovative flood safety design/review for private dams in Southeastern Australia and integrate this with community impact assessment. Together, this is a "community partnerships" solution to a significant water policy vacuum on private dam safety and flood policy. Expected outco ....Cost-effective integrated engineering and "community partnerships" solution to a latent water policy issue: private dam management and flood safety. Project aims to further develop an engineering model for cost-effective innovative flood safety design/review for private dams in Southeastern Australia and integrate this with community impact assessment. Together, this is a "community partnerships" solution to a significant water policy vacuum on private dam safety and flood policy. Expected outcomes: improved risk transparency for dam owners and State Government, minimising costs of failures, ie. loss of life, damage to public and private infrastructure and environment; giving owners an affordable and effective design/review procedure to better manage their dams, providing data on community responses and water law reform proposals consonant with international best-practice.Read moreRead less
Bridge performance assessment through advanced sensing and modelling. Bridge performance assessment through advanced sensing and modelling. This project aims to create cyber infrastructure to manage and maintain civil infrastructure, specifically bridges. Current sensor data interpretation approaches are not good at assessing the performance of civil infrastructure or evaluating the reserve capacity; in particular, they do not adequately account for high levels of systematic modelling uncertaint ....Bridge performance assessment through advanced sensing and modelling. Bridge performance assessment through advanced sensing and modelling. This project aims to create cyber infrastructure to manage and maintain civil infrastructure, specifically bridges. Current sensor data interpretation approaches are not good at assessing the performance of civil infrastructure or evaluating the reserve capacity; in particular, they do not adequately account for high levels of systematic modelling uncertainties. This project intends to ease the current scientific data interpretation bottleneck. Expected outcomes are better infrastructure management and maintenance planning, fewer redundant interventions, modified infrastructure and improved future design.Read moreRead less