Robust fluid mixing through topological chaos. The Australian chemicals and plastics industry has an annual turnover of over $20 billion and employs over 77,000 people; fluid mixing is fundamental to this industry, yet the industry is recognised as underinvesting in research and development in this essential area. Furthermore, frontier technologies such as biotechnology and the next generation of smart materials also crucially rely on fluid mixing. This project aims to evaluate a new paradigm ( ....Robust fluid mixing through topological chaos. The Australian chemicals and plastics industry has an annual turnover of over $20 billion and employs over 77,000 people; fluid mixing is fundamental to this industry, yet the industry is recognised as underinvesting in research and development in this essential area. Furthermore, frontier technologies such as biotechnology and the next generation of smart materials also crucially rely on fluid mixing. This project aims to evaluate a new paradigm (topological chaos) for the design of mixers, to provide better and more robust mixers that work from microscopic to industrial scales.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101183
Funder
Australian Research Council
Funding Amount
$361,880.00
Summary
Next-generation expanders for renewable power applications: dealing with variability and uncertainty. This project will develop new strategies to design optimum expanders capable of maintaining good performance under uncontrollable working conditions. If these innovative design methods can be applied to engineering applications they will assist Australia to meet the Renewable Energy Target and to become an international leader in the field.
Micro Process Plants - Non-Newtonian flow and particle synthesis in confined geometries. Understanding the flow behaviour of well characterised non-Newtonian fluids within microfluidic and nanofluidic devices is of vital importance to development of novel high-value added services, products and devices within Australia's burgeoning biotechnology, environmental technology, communications and information technology industries. The outcomes of this project will provide new 'systematic' design stand ....Micro Process Plants - Non-Newtonian flow and particle synthesis in confined geometries. Understanding the flow behaviour of well characterised non-Newtonian fluids within microfluidic and nanofluidic devices is of vital importance to development of novel high-value added services, products and devices within Australia's burgeoning biotechnology, environmental technology, communications and information technology industries. The outcomes of this project will provide new 'systematic' design standards for microdevice manufacture for these industries, ultimately leading to the creation of new, exciting avenues for tailoring novel biotechnology and 'point-of-care' products for Australia.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101546
Funder
Australian Research Council
Funding Amount
$288,900.00
Summary
Development of computer-based optimisation to improve hypersonic aerodynamic design. Next-generation launch vehicles using high-speed jet engines will make it cheaper and more reliable for humankind to engage in activities in space. This project will contribute to the technology of high-speed jet engines by developing optimised air intake systems. The research aims to advance the use of computational engineering and apply this to improve the design of air intake systems. The outcomes of this pro ....Development of computer-based optimisation to improve hypersonic aerodynamic design. Next-generation launch vehicles using high-speed jet engines will make it cheaper and more reliable for humankind to engage in activities in space. This project will contribute to the technology of high-speed jet engines by developing optimised air intake systems. The research aims to advance the use of computational engineering and apply this to improve the design of air intake systems. The outcomes of this project will advance the technology of high-speed jet engines with the goal of replacing existing rocket systems.Read moreRead less
Characterization of Fast Propagating Fires in Green Buildings. This project aims to gain a better understanding of the mechanisms of fast-propagating fires and to address the deficiency in current fire models in assessing the fire safety requirement of green buildings. Although there are many compelling advantages associated with green building designs, because they promote better natural ventilation they could pose a significant fire hazard to occupants due to the propensity of rapid fire and s ....Characterization of Fast Propagating Fires in Green Buildings. This project aims to gain a better understanding of the mechanisms of fast-propagating fires and to address the deficiency in current fire models in assessing the fire safety requirement of green buildings. Although there are many compelling advantages associated with green building designs, because they promote better natural ventilation they could pose a significant fire hazard to occupants due to the propensity of rapid fire and smoke spread within the enclosed space. The new predictive fire model in this project is expected to promote a safer and sustainable building environment.Read moreRead less
Heat Transfer Mechanisms in an Indirectly Fired Rotary Kiln with Lifters and Its Role in Scaling. This project will apply heat transfer principles to improve and optimise the design and performance of ANSAC's innovative kiln technology for a wide range of process applications. By understanding the mechanisms of heat transfer involved in the working of the proprietary technology, major factors limiting the performance of the kiln can be identified, resulting in design criteria that link key opera ....Heat Transfer Mechanisms in an Indirectly Fired Rotary Kiln with Lifters and Its Role in Scaling. This project will apply heat transfer principles to improve and optimise the design and performance of ANSAC's innovative kiln technology for a wide range of process applications. By understanding the mechanisms of heat transfer involved in the working of the proprietary technology, major factors limiting the performance of the kiln can be identified, resulting in design criteria that link key operating parameters for the kiln scaling and performance forecast. The research outcomes will provide a scientific basis that underpins the development of an Australian technology and supports the growth of a new Australian small business, creating employment opportunities within Australia.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101347
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Characterising the hazard, structure and impacts of convective wind storms. This project aims to characterise probabilistically the severe convective wind storm risk (thunderstorm and tornado) to Australia under current and future climates. This will be achieved using a new coupled analysis-simulation based approach to wind hazard analysis. It will also characterise the complex wind structure within these wind storms by integrating three-dimensional data from novel high-resolution observation ne ....Characterising the hazard, structure and impacts of convective wind storms. This project aims to characterise probabilistically the severe convective wind storm risk (thunderstorm and tornado) to Australia under current and future climates. This will be achieved using a new coupled analysis-simulation based approach to wind hazard analysis. It will also characterise the complex wind structure within these wind storms by integrating three-dimensional data from novel high-resolution observation networks into a unifying wind field model. The project aims to generate the requisite information that allows convective wind storms to be explicitly accounted for in national and international wind-resistant design standards, thus acting to mitigate the devastating impacts of future events.Read moreRead less
Multiphase flows in microchannels. This project will improve our understanding of how multiphase fluids (such as a gas and a liquid or two liquids) flow in very small passages. Such flows are at the heart of almost all chemical processing and miniaturisation of chemical processes depends on our ability to design for and control them. There is a worldwide interest in microplant for chemicals manufacture and the international partner investigators are leaders in this field. The particular benefit ....Multiphase flows in microchannels. This project will improve our understanding of how multiphase fluids (such as a gas and a liquid or two liquids) flow in very small passages. Such flows are at the heart of almost all chemical processing and miniaturisation of chemical processes depends on our ability to design for and control them. There is a worldwide interest in microplant for chemicals manufacture and the international partner investigators are leaders in this field. The particular benefit to Australia lies in the possibility that miniaturised, microsctructured chemical plant could become the basis for remote, distributed manufacture that could, for example, allow natural gas processing on ocean platforms directly located at the point of production. Read moreRead less
Wireless microvalve for biomedical applications. This program will investigate and perform an in-laboratory proof-of-concept demonstration of a polymer microvalve that can operate by a remote control radio signal. This will be a wireless microvalve that does not require a battery power source. This advance in the technology and scientific knowledge will have important applications for humankind ranging from drug delivery devices to through to valves in chips that can perform microfluidic chemica ....Wireless microvalve for biomedical applications. This program will investigate and perform an in-laboratory proof-of-concept demonstration of a polymer microvalve that can operate by a remote control radio signal. This will be a wireless microvalve that does not require a battery power source. This advance in the technology and scientific knowledge will have important applications for humankind ranging from drug delivery devices to through to valves in chips that can perform microfluidic chemical analysis. A far reaching long-range vision is its use in electronically reversible male fertility control. The community benefit in terms of novel biomedical devices and the resulting large international commercial market is significant.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101098
Funder
Australian Research Council
Funding Amount
$315,000.00
Summary
Novel modelling of fluid-structure interactions in biological flows. The objective of this project is to develop a novel method to model fluid-structure interactions and turbulence in cardiovascular systems. The cardiovascular system is essential in providing nutrient and waste transport throughout the body. Because blood vessels and red blood cells are flexible, they are subjected to large deformations with significant effects on physiological functions such as blood distribution and oxygen rel ....Novel modelling of fluid-structure interactions in biological flows. The objective of this project is to develop a novel method to model fluid-structure interactions and turbulence in cardiovascular systems. The cardiovascular system is essential in providing nutrient and waste transport throughout the body. Because blood vessels and red blood cells are flexible, they are subjected to large deformations with significant effects on physiological functions such as blood distribution and oxygen release. Fluid-structure interactions are critical for understanding the intricacies of such systems but it is still a challenge to model these systems realistically using numerical methods. Expected outcomes of the project include better simulations of three-dimensional fluid-structure interactions and improved understanding of the behaviours of biological systems.Read moreRead less