Demonstrating the feasibility of designing sustainable buildings using evolutionary systems. The design approach proposed in this research will result in two key areas of national benefit. First, the research will enable Australian built environment design professions to become more competitive in both domestic and international markets. There is a growing demand for environmentally-friendly buildings and the proposed design approach will enable Australian firms to be at the cutting edge of sust ....Demonstrating the feasibility of designing sustainable buildings using evolutionary systems. The design approach proposed in this research will result in two key areas of national benefit. First, the research will enable Australian built environment design professions to become more competitive in both domestic and international markets. There is a growing demand for environmentally-friendly buildings and the proposed design approach will enable Australian firms to be at the cutting edge of sustainable design. Second, the research will enable the Australian built environment to become more sustainable. The proposed approach will enable buildings to be designed that perform well, that are cost effective and that minimise their environmental impact. 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
Carbon neutral communities: making the transition. This project has well defined National benefits, both economic and social, for the collaborative partners, the business community, policy makers, community groups and the broader Australian community. It contributes toward NRP 1, through developing practical measures for reducing GHG emissions in Australian urban areas, and strategies for overcoming barriers to greater uptake of energy efficiency and alternative technologies; and helping Austra ....Carbon neutral communities: making the transition. This project has well defined National benefits, both economic and social, for the collaborative partners, the business community, policy makers, community groups and the broader Australian community. It contributes toward NRP 1, through developing practical measures for reducing GHG emissions in Australian urban areas, and strategies for overcoming barriers to greater uptake of energy efficiency and alternative technologies; and helping Australia to meet its greenhouse reduction targets. The project economic benefits to through energy savings; stimulating innovation in urban design, building design and transport use; promoting new business opportunities; and encouraging more sustainable lifestyle decisions. Read moreRead less
Towards Novel Biomimetic Building Materials: Evaluating Aboriginal and Western Scientific Knowledge of Spinifex Grasses. The project contributes to an environmentally sustainable Australia by examining the potential value of a hitherto ignored natural resource and assessing its usage with sustainable harvesting. Aboriginal knowledge and Western science will be combined to identify potential technological applications for a widespread but uniquely Australian resource. The project promotes the wel ....Towards Novel Biomimetic Building Materials: Evaluating Aboriginal and Western Scientific Knowledge of Spinifex Grasses. The project contributes to an environmentally sustainable Australia by examining the potential value of a hitherto ignored natural resource and assessing its usage with sustainable harvesting. Aboriginal knowledge and Western science will be combined to identify potential technological applications for a widespread but uniquely Australian resource. The project promotes the well-being and health of Aboriginal people through seeking out a new economic enterprise for remote area groups. This project examines the material properties of spinifex, specifically for new building industry applications, both in its natural state and replicated as a synthesized biomimetic material. Read moreRead less
New generation nanostructured coatings with combined control of spectral and angular emissivity. The aim of this project is to generate a complete scientific understanding of a new generation of hybrid, tri-layered, optically-selective coatings. The new design paradigm combines the very different attributes of smooth and nanostructured layers so that superior and simultaneous control of both spectral and angular properties of light can be achieved. Existing theory will be extended so that quanti ....New generation nanostructured coatings with combined control of spectral and angular emissivity. The aim of this project is to generate a complete scientific understanding of a new generation of hybrid, tri-layered, optically-selective coatings. The new design paradigm combines the very different attributes of smooth and nanostructured layers so that superior and simultaneous control of both spectral and angular properties of light can be achieved. Existing theory will be extended so that quantitative analyses of these new systems and other hybrids become possible and new and improved fabrication techniques will be developed. The work will unlock new technological possibilities for coating performance and application and is likely to be associated with significant improvements in energy conservation and generation. Read moreRead less
Industrial Transformation Research Hubs - Grant ID: IH150100030
Funder
Australian Research Council
Funding Amount
$1,577,087.00
Summary
ARC Research Hub to Transform Future Tall Timber Buildings. ARC Research Hub for Advanced Solutions to Transform Tall Timber Buildings. This hub aims to develop skills, knowledge and resources for novel designs of tall timber buildings that incorporate architectural, engineering and sustainability drivers while meeting regulatory constraints. The project aims to develop innovative engineering solutions that address crucial barriers to the use of structural timber in the fast growing and extensiv ....ARC Research Hub to Transform Future Tall Timber Buildings. ARC Research Hub for Advanced Solutions to Transform Tall Timber Buildings. This hub aims to develop skills, knowledge and resources for novel designs of tall timber buildings that incorporate architectural, engineering and sustainability drivers while meeting regulatory constraints. The project aims to develop innovative engineering solutions that address crucial barriers to the use of structural timber in the fast growing and extensive medium-rise tall buildings market where timber is, on many counts, the ideal construction material. It is expected that eliminating these barriers will open a new market for novel technologies and methods generated through this work.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
From innovators to mainstream market: a toolkit for transforming Australian housing and maximising sustainability outcomes for stakeholders. As a significant national asset, Australia's housing needs to provide economic, social and environmental value to occupants, owners and the broader society. Learning from innovation, this project will deliver strategies to improve the productivity of the housing sector and enhance the value proposition of sustainable homes for all stakeholders.
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
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