An Integrated Systems Analysis: Fire Growth and Severity in Enclosures. An integrated systems risk-based model for fire safety has been developed and has been internationally acclaimed. A new fire severity submodel urgently needs to be developed before ramifications of the World Trade Centre catastrophe impact on fire safety regulations. Current submodels seriously misrepresent the real fires. They were developed from 1970's experiments on 2-3 metre cube-like enclosures and predict that fires ....An Integrated Systems Analysis: Fire Growth and Severity in Enclosures. An integrated systems risk-based model for fire safety has been developed and has been internationally acclaimed. A new fire severity submodel urgently needs to be developed before ramifications of the World Trade Centre catastrophe impact on fire safety regulations. Current submodels seriously misrepresent the real fires. They were developed from 1970's experiments on 2-3 metre cube-like enclosures and predict that fires engulf enclosures. Recent preliminary experiments have revealed that real fires burn locally at windows and only appear to be all engulfing. The research will lead international collaboration involving extensive experiments and some modelling to be completed in twelve months.Read moreRead less
Embodied energy modelling of individual commercial buildings. This research will develop a method for modelling the energy embodied in individual commercial building construction. Construction material manufacturing emissions are well known in most industries, but the total embodied energy of the construction supply chain is difficult to model for individual buildings. For efficient commercial buildings, the embodied energy can represent up to 40 years of operational energy. The results will be ....Embodied energy modelling of individual commercial buildings. This research will develop a method for modelling the energy embodied in individual commercial building construction. Construction material manufacturing emissions are well known in most industries, but the total embodied energy of the construction supply chain is difficult to model for individual buildings. For efficient commercial buildings, the embodied energy can represent up to 40 years of operational energy. The results will be used to develop cost effective strategies for optimising the total life cycle energy of individual commercial buildings. This will in part improve the environmental performance of the Australian construction industry.Read moreRead less
Occupant comfort, cognitive performance and task performance in wind-excited tall buildings. Strong winds are sensitive to climate change and highly unpredictable, critically affecting the design of tall buildings and our built environment. The outcomes of this research will revolutionalise current design approach for occupant comfort in wind-excited tall buildings and deliver a new generation of tall buildings that provides a comfortable living and working environment without a degradation of w ....Occupant comfort, cognitive performance and task performance in wind-excited tall buildings. Strong winds are sensitive to climate change and highly unpredictable, critically affecting the design of tall buildings and our built environment. The outcomes of this research will revolutionalise current design approach for occupant comfort in wind-excited tall buildings and deliver a new generation of tall buildings that provides a comfortable living and working environment without a degradation of work performance due to wind-induced vibration. The transfer of this knowledge from research to practice will enhance the international competitiveness of our architecture, engineering and construction professionals, boosting our involvement in major tall building projects worldwide and bringing long-term economical benefits to Australia.Read moreRead less