Ultralow emission panel systems for rapid modular construction. This proposed project aims to develop an innovative ultra-low emission precast panel comprising a novel ultra-low carbon concrete mixture that is cast in vertical battery moulds. The new precast panels will have several significant enhancements compared to traditional precast panels, including faster manufacturing, reduced cost, and a much lower carbon footprint and life-cycle costs. A holistic theoretical and design framework will ....Ultralow emission panel systems for rapid modular construction. This proposed project aims to develop an innovative ultra-low emission precast panel comprising a novel ultra-low carbon concrete mixture that is cast in vertical battery moulds. The new precast panels will have several significant enhancements compared to traditional precast panels, including faster manufacturing, reduced cost, and a much lower carbon footprint and life-cycle costs. A holistic theoretical and design framework will be developed for predicting the behaviour of the innovative precast panel under structural, fire and impact loading. The panel will offer desirable benefits such as industry leading durability, ease of construction and assembly, economy and recyclability.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100548
Funder
Australian Research Council
Funding Amount
$439,847.00
Summary
A novel high-temperature concrete-based system for renewable energy storage. This project aims to develop a novel alkali-activated concrete-based system for renewable energy storage. The system is based on the excellent performance, durability and affordability of concrete, which is widely used in the construction industry. The project expects to generate new knowledge in concrete thermal energy storage by using a holistic experimental and computational approach. Expected outcomes include insigh ....A novel high-temperature concrete-based system for renewable energy storage. This project aims to develop a novel alkali-activated concrete-based system for renewable energy storage. The system is based on the excellent performance, durability and affordability of concrete, which is widely used in the construction industry. The project expects to generate new knowledge in concrete thermal energy storage by using a holistic experimental and computational approach. Expected outcomes include insights into the novel high-temperature concrete, the advanced numerical, data-driven model and the system, that is highly scalable, efficient and low cost. This should provide significant benefits in accelerating the use of concrete for energy storage technologies and fostering the national and global renewable energy transition.Read moreRead less
Novel test and design methods for base course reinforced flexible pavements. This project aims to develop the mechanics of geosynthetic-reinforced flexible pavements as an urgent need for the Australian pavement industry to build more sustainable and economical roads. Novel laboratory test apparatus and in-situ test programs, and mathematical models will be developed, for the first time, to capture the responses of reinforced base courses in a complete and optimised way to determine the paramete ....Novel test and design methods for base course reinforced flexible pavements. This project aims to develop the mechanics of geosynthetic-reinforced flexible pavements as an urgent need for the Australian pavement industry to build more sustainable and economical roads. Novel laboratory test apparatus and in-situ test programs, and mathematical models will be developed, for the first time, to capture the responses of reinforced base courses in a complete and optimised way to determine the parameters for pavement design and performance evaluation. The outcomes will enable reliable prediction of reinforced pavement behaviour, leading to better-performing geosynthetic products and more resilient pavements, reduced material usage and damage in pavements, and less environmental impact and maintenance cost.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101221
Funder
Australian Research Council
Funding Amount
$431,154.00
Summary
Eco-friendly low shrinkage concrete integrating upcycled textile waste. This project aims to investigate a novel solution incorporating upcycled textile waste to reduce shrinkage induced cracking in reinforced concrete. The project is expected to generate new knowledge in crack nucleation and healing mechanisms in concrete and the application of flexible textile fibre reinforcement to control shrinkage induced cracking, creating a new fibre reinforced composite. The expected outcome is a reducti ....Eco-friendly low shrinkage concrete integrating upcycled textile waste. This project aims to investigate a novel solution incorporating upcycled textile waste to reduce shrinkage induced cracking in reinforced concrete. The project is expected to generate new knowledge in crack nucleation and healing mechanisms in concrete and the application of flexible textile fibre reinforcement to control shrinkage induced cracking, creating a new fibre reinforced composite. The expected outcome is a reduction in construction waste through extending the life span of concrete structures and reducing textile waste, 85% of which is currently disposed in landfills. The new composite could deliver a circular solution to textile waste leading to significant social, environmental and economic benefits.Read moreRead less