A Roadmap for Greening Existing Australian Housing. The project will minimise the impact of the Greenhouse Pollution Reduction Scheme and anticipated rises in water costs on the householders. It will assist the consumers and the building industry in evaluating the environmental and economic costs and benefits of specific retrofitting actions for building envelope and major fixed appliances (thermal insulation, glazing, air infiltration, hot water, heating/cooling, lighting, low water flow and wa ....A Roadmap for Greening Existing Australian Housing. The project will minimise the impact of the Greenhouse Pollution Reduction Scheme and anticipated rises in water costs on the householders. It will assist the consumers and the building industry in evaluating the environmental and economic costs and benefits of specific retrofitting actions for building envelope and major fixed appliances (thermal insulation, glazing, air infiltration, hot water, heating/cooling, lighting, low water flow and water reuse appliances, and solar photovoltaic systems). In addition to assisting a burgeoning renovation industry, the project will enable accurate assessment of the impacts of the Green Loans Program and guide future national and local energy and water reduction policies. Read moreRead less
The impact of work-from-home environments on comfort and productivity. This project aims to quantify the effect of indoor environmental quality (IEQ) in work-from-home (WFH) settings on worker comfort, productivity and household energy use, by employing a longitudinal field monitoring approach. This project expects to generate new knowledge that will inform current indoor environment standards and regulations to make them more relevant to our “new WFH normal”. Quantifying the impact of decentral ....The impact of work-from-home environments on comfort and productivity. This project aims to quantify the effect of indoor environmental quality (IEQ) in work-from-home (WFH) settings on worker comfort, productivity and household energy use, by employing a longitudinal field monitoring approach. This project expects to generate new knowledge that will inform current indoor environment standards and regulations to make them more relevant to our “new WFH normal”. Quantifying the impact of decentralised workforces on shifting energy usage between sectors can also help in the formulation of relevant energy efficiency policies and building codes. The project will provide significant benefits such as enhancing the quality of work-life of workers and enabling better management of residential energy use.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100451
Funder
Australian Research Council
Funding Amount
$435,232.00
Summary
Quantifying thermal environmental impact on office productivity. This project aims to quantify thermal environmental impacts on office productivity. It expects to firmly dismiss the prevailing misbelief that an indoor temperature of 22 °C leads to maximum workplace productivity, and create a paradigm shift in building management practice in commercial buildings. Expected outcomes of this project include a novel productivity metric, a standard measurement protocol for assessing thermal environmen ....Quantifying thermal environmental impact on office productivity. This project aims to quantify thermal environmental impacts on office productivity. It expects to firmly dismiss the prevailing misbelief that an indoor temperature of 22 °C leads to maximum workplace productivity, and create a paradigm shift in building management practice in commercial buildings. Expected outcomes of this project include a novel productivity metric, a standard measurement protocol for assessing thermal environmental impacts on office productivity, and world first indoor thermal environmental control guidelines tailored to diverse cognitive activities in the workplaces of different industries. This should provide cost-effective solutions to reduce building energy use while maintaining optimum workforce productivity.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL220100082
Funder
Australian Research Council
Funding Amount
$3,450,896.00
Summary
My Air Space: the Science of Buildings that Make us Thrive. Nothing is more necessary in human life than the air we breathe, mostly indoors where air quality has been relatively overlooked. This project aims to deliver new science and technology as a foundation for optimising indoor atmospheres to improve health, wellbeing, and comfort. Expected outcomes include innovative, efficient, low-cost diagnostic sensing of indoor atmospheres and human–space interactions, real-time detection of airborne ....My Air Space: the Science of Buildings that Make us Thrive. Nothing is more necessary in human life than the air we breathe, mostly indoors where air quality has been relatively overlooked. This project aims to deliver new science and technology as a foundation for optimising indoor atmospheres to improve health, wellbeing, and comfort. Expected outcomes include innovative, efficient, low-cost diagnostic sensing of indoor atmospheres and human–space interactions, real-time detection of airborne pathogens and particles that host them, and cost-effective localised conditioning of spaces for comfort at points of actual use. Benefits should be seen in areas of health, productivity, reduced energy use, and new industries for the design, modernising, and operation of buildings across Australia and beyond.Read moreRead less
Het-Crete: High-Grade Chemical-Treated Heterogeneous Recycled Concrete. Of over 20 million tons of mixed construction and demolition waste generated annually, only 5% is recycled and less than 1% is adopted for low-grade construction activities. This innovative research aims to solve Australia’s mixed construction and demolition waste disposal problem and lower its greenhouse-gas emissions at the same time. The research develops Het-Gregate with novel chemical admixtures and greenhouse-gas emiss ....Het-Crete: High-Grade Chemical-Treated Heterogeneous Recycled Concrete. Of over 20 million tons of mixed construction and demolition waste generated annually, only 5% is recycled and less than 1% is adopted for low-grade construction activities. This innovative research aims to solve Australia’s mixed construction and demolition waste disposal problem and lower its greenhouse-gas emissions at the same time. The research develops Het-Gregate with novel chemical admixtures and greenhouse-gas emissions to create Het-Crete, with new mixing techniques for its an optimal performance high-grade concrete. Life-cycle analyses will be conducted to generate Het-Crete specifications for the industry. This will significantly elevate Australia’s world standing in recycled concrete research.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC220100012
Funder
Australian Research Council
Funding Amount
$4,939,486.00
Summary
ARC Training Centre for Advanced Building Systems Against Airborne Infection Transmission. The aim of the Centre is to engineer building systems whose elements work together to reduce airborne infection transmission by improving indoor air quality while maintaining comfort and efficiency. The significance is in establishing clean indoor air as the norm, with Australian industry being the forerunner in this process. The outcomes include new intelligent building systems, improved building technolo ....ARC Training Centre for Advanced Building Systems Against Airborne Infection Transmission. The aim of the Centre is to engineer building systems whose elements work together to reduce airborne infection transmission by improving indoor air quality while maintaining comfort and efficiency. The significance is in establishing clean indoor air as the norm, with Australian industry being the forerunner in this process. The outcomes include new intelligent building systems, improved building technologies, quantitative methods for building control, evidence for policymaking and recommendations for operational guidelines. Wide-ranging benefits include reducing the health and economic burden of inadequate indoor air and increasing the competitiveness of Australian industry in the face of increasing demand for next-level building systems.Read moreRead less
The performance of environmentally sustainable design features in commercial buildings. Two office buildings are to be analysed in respect of environmental performance both technically and in terms of the building occupants. The buildings are similar in location, use, quality and materials. One building contains several environmentally sustainable design features and it is expected that improvements in environmental outcomes will be observed when compared with the other building. The results ....The performance of environmentally sustainable design features in commercial buildings. Two office buildings are to be analysed in respect of environmental performance both technically and in terms of the building occupants. The buildings are similar in location, use, quality and materials. One building contains several environmentally sustainable design features and it is expected that improvements in environmental outcomes will be observed when compared with the other building. The results will provide a useful benchmark and a guide to the potential of environmentally sustainable property development.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101597
Funder
Australian Research Council
Funding Amount
$424,398.00
Summary
Integrated design optimization of novel photovoltaic envelope for buildings. The research will couple the building integrated renewable application with traditional architectural passive design strategies. A new indoor environment quality index will be proposed as an objective function to be optimized together with the net building energy consumption. Surrogate models trained for each modelling software will be incorporated into the proposed optimization algorithm to improve the calculation effi ....Integrated design optimization of novel photovoltaic envelope for buildings. The research will couple the building integrated renewable application with traditional architectural passive design strategies. A new indoor environment quality index will be proposed as an objective function to be optimized together with the net building energy consumption. Surrogate models trained for each modelling software will be incorporated into the proposed optimization algorithm to improve the calculation efficiency and provide a convenient tool to assist sustainable building designs. In addition, significant urban context parameters will be incorporated to quantify their impact. Research findings will serve as significant guidance to effectively promote the application of the passive design in green building projects.Read moreRead less
Impact and Effectiveness of Personal Ventilation in Open Plan Offices: a study of the Task Air system. Centralised air-conditioning systems are the standard for commercial office buildings in Australia. These systems are energy intensive, typically accounting for around 50% of building energy use. However, lack of occupant control over set temperatures or air movement tends to reduce thermal comfort, which can adversely affect worker productivity. The benefit of this project is that it will qu ....Impact and Effectiveness of Personal Ventilation in Open Plan Offices: a study of the Task Air system. Centralised air-conditioning systems are the standard for commercial office buildings in Australia. These systems are energy intensive, typically accounting for around 50% of building energy use. However, lack of occupant control over set temperatures or air movement tends to reduce thermal comfort, which can adversely affect worker productivity. The benefit of this project is that it will quantify the improvements to occupant comfort and energy savings possible with a PV system. This study will enable PV systems to be evaluated as an alternative to traditional air-conditioning, thereby demonstrating their effectiveness as a means of improving the sustainability rating of commercial office buildings in Australia.Read moreRead less
The Characterisation of Fires in Tunnels. A series of 22 fires ranging from 2 megawatt up to 20 megawatt intensity will be set under controlled conditions in unused tunnel facilities, in New South Wales. Instrumentation in the tunnel, donated by the State Rail Authority of New South Wales, will monitor the movement of particulates (smoke). This information is vital to tunnel design, and for passenger life safety. This information will be applicable to all tunnels worldwide.