Biological pattern generator for control and optimization of locomotion systems. This proposal exploits the interdisciplinary nature of systems and control area and incorporates biology science. It is expected to generate a synergy between biology science and control engineering and to advance scientific understanding in both fields. The proposed research will have impact on new innovations in a variety of fields. This will bring economic benefits for Australia. It will help to develop engineers ....Biological pattern generator for control and optimization of locomotion systems. This proposal exploits the interdisciplinary nature of systems and control area and incorporates biology science. It is expected to generate a synergy between biology science and control engineering and to advance scientific understanding in both fields. The proposed research will have impact on new innovations in a variety of fields. This will bring economic benefits for Australia. It will help to develop engineers for industry who have team-oriented problem-solving skills in a multidisciplinary working environment. It will also stimulate students' intellectual curiosity into engineering and science through a series of innovative interdisciplinary research/educational activities.Read moreRead less
Properties and Characterisation of Magneto-Rheological Materials under Rotating Magnetic Field Excitation. Through the proposed theoretical and experimental studies, new electro-magneto-mechanical phenomena of the MR materials under various vectorial magnetisations will be observed. Based on the in-depth understanding of the complex vectorial magneto-rheological mechanisms, an accurate coupled model will be developed for design and analysis of novel dampers. These outcomes will greatly enhance t ....Properties and Characterisation of Magneto-Rheological Materials under Rotating Magnetic Field Excitation. Through the proposed theoretical and experimental studies, new electro-magneto-mechanical phenomena of the MR materials under various vectorial magnetisations will be observed. Based on the in-depth understanding of the complex vectorial magneto-rheological mechanisms, an accurate coupled model will be developed for design and analysis of novel dampers. These outcomes will greatly enhance the design capacity of Australian industry in smart structures, i.e. using novel dampers to reduce harmful vibrations and protect people in vehicles, buildings, and bridges. This will help Australians to live in a safer and healthier environment, and could save billions of dollars per year nationwide for treatment, recovery, and insurance claims.Read moreRead less
Hydrodynamic Stability of the VentrAssist Blood Pump, an Experimental and Numerical Investigation. This project will investigate, both numerically and experimentally, the stability of the impeller-bearing system of a rotary blood pump and will make recommendations about the optimum bearing configurations. Findings from this project will contribute to the commercialisation of the blood pump undertaken by the research Group formed by the staff from UTS, UNSW and VentrAssist Pty Ltd - the first of ....Hydrodynamic Stability of the VentrAssist Blood Pump, an Experimental and Numerical Investigation. This project will investigate, both numerically and experimentally, the stability of the impeller-bearing system of a rotary blood pump and will make recommendations about the optimum bearing configurations. Findings from this project will contribute to the commercialisation of the blood pump undertaken by the research Group formed by the staff from UTS, UNSW and VentrAssist Pty Ltd - the first of its kind in Australia. Rotary blood pumps are at the leading edge of cardiac assist technology worldwide and an investigation of the impeller dynamics will add greatly to the understanding of the related important factors in blood pump design.Read moreRead less
Development of the applications of signal processing to mechanical problems and machine diagnostics. It is intended to extend research collaboration in the following areas of interest to both UTC and UNSW:
(1) Dynamics of gears for diagnostics and noise control
(2) Application of blind source separation techniques to mechanical problems
(3) Application of cyclostationary signal analysis techniques to machine diagnostics
(4) Determination of structural dynamic properties from response measure ....Development of the applications of signal processing to mechanical problems and machine diagnostics. It is intended to extend research collaboration in the following areas of interest to both UTC and UNSW:
(1) Dynamics of gears for diagnostics and noise control
(2) Application of blind source separation techniques to mechanical problems
(3) Application of cyclostationary signal analysis techniques to machine diagnostics
(4) Determination of structural dynamic properties from response measurements
(5) Diagnostics of diesel engines and other reciprocating machines.
This project will result in the publication of joint papers in each of these topics, and give material to form the basis of an application for at least one FAIR project in the area of gear noise control and diagnostics.Read moreRead less
Life-time Modelling of Industrial Products for Reuse. Product disposal responsibility has shifted from consumers to manufacturers. Re-use of components is the most efficient strategy for product recovery, which requires reliable methods for assessing the quality and remaining life of used components. The aim of this project is to develop a lifetime model to estimate the remaining life and quality of a used component. This will enable manufacturers to estimate the potential reusability of a compo ....Life-time Modelling of Industrial Products for Reuse. Product disposal responsibility has shifted from consumers to manufacturers. Re-use of components is the most efficient strategy for product recovery, which requires reliable methods for assessing the quality and remaining life of used components. The aim of this project is to develop a lifetime model to estimate the remaining life and quality of a used component. This will enable manufacturers to estimate the potential reusability of a component without going through costly and time consuming disassembly processes. In addition, the data from the lifetime monitoring process will provide information for improving the design and manufacture of environmentally friendly products.Read moreRead less
Time-dependent dynamic, creep and shrinkage response of curved structural members. This project concerns curved structural members, such as bridge beams, that are subjected to dynamic excitation and to concrete shrinkage and creep. Hitherto, unified formulations for the structural behaviour of these members have not been properly developed. The proposal seeks to build on a previous ARC DP of the investigator that produces significant results for static loading, by developing a sophisticated meth ....Time-dependent dynamic, creep and shrinkage response of curved structural members. This project concerns curved structural members, such as bridge beams, that are subjected to dynamic excitation and to concrete shrinkage and creep. Hitherto, unified formulations for the structural behaviour of these members have not been properly developed. The proposal seeks to build on a previous ARC DP of the investigator that produces significant results for static loading, by developing a sophisticated methodology to handle non-static dynamic loading and for shrinkage and creep. It will develop advanced mathematical tools to enable the safe and efficient design of a multiplicity of structures that is of benefit to on and offshore Australian technology.Read moreRead less
Mathematical and mechanical modeling of nano particulate flow. Nano particulates are the basis for many new technologies, including coatings in the electronics industry, composite materials and medical and pharmaceutical applications. Worldwide industrial competition is increasingly determined by our capacity to handle such highly cohesive materials, and to exploit their novel physical, chemical and mechanical characteristics. Devising handling mechanisms and understanding nano particulate flows ....Mathematical and mechanical modeling of nano particulate flow. Nano particulates are the basis for many new technologies, including coatings in the electronics industry, composite materials and medical and pharmaceutical applications. Worldwide industrial competition is increasingly determined by our capacity to handle such highly cohesive materials, and to exploit their novel physical, chemical and mechanical characteristics. Devising handling mechanisms and understanding nano particulate flows depends on formulating accurate mathematical models which reflect the correct underlying physics. This APF proposal will utilise advanced continuum mechanics to develop the correct underlying conceptual ideas to resolve fundamental nanomechanical particulate flows, which will lead to the next generation of engineering tools.
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An experimental and theoretical programme of research to resolve major obstruction-to-flow problems in bins and stockpiles. Many of Australia's industries rely on the efficient storage and handling of bulk solids materials such as minerals, chemicals, food-stuffs, agricultural products and pharmeceuticals. Often the handling processes are inefficient to the extent of affecting the economics of the industry. Here we propose two projects addressing those inefficiences resulting from stable obstr ....An experimental and theoretical programme of research to resolve major obstruction-to-flow problems in bins and stockpiles. Many of Australia's industries rely on the efficient storage and handling of bulk solids materials such as minerals, chemicals, food-stuffs, agricultural products and pharmeceuticals. Often the handling processes are inefficient to the extent of affecting the economics of the industry. Here we propose two projects addressing those inefficiences resulting from stable obstructions, such as "rat-holes", and those experimental arising from the unusual flow characteristics of fine powders. The major objectives are to use experimental and advanced mathematical modelling techniques, to produce reliable design models which minimise the occurrence of stable obstructions and provide reliable methods for increasing fine powder flow rates.Read moreRead less
Mathematical modelling of two-phase industrial granular flows. In many industrial processes involving flowing granular materials, the effect of air pressure can be significant. Such examples include pneumatic conveying, lock hoppers and air-impact moulding. The effect of pressurised air on a granular material can either compact it, or can cause sudden large flows. To model such complex phenomena, the frictional effects between the air and the solid granules must be accurately incorporated into a ....Mathematical modelling of two-phase industrial granular flows. In many industrial processes involving flowing granular materials, the effect of air pressure can be significant. Such examples include pneumatic conveying, lock hoppers and air-impact moulding. The effect of pressurised air on a granular material can either compact it, or can cause sudden large flows. To model such complex phenomena, the frictional effects between the air and the solid granules must be accurately incorporated into a two-phase continuum mechanical model for granular materials. This proposal will develop advanced mathematical models and computational procedures to predict complex two-phase granular flows for industrial problems.Read moreRead less
Development of a Local Spectral Method for the Computations of Thin-Walled Structures. This project will benefit Aust. society by providing a powerful tool for improving the safe and cost effective design of structures under extreme conditions (high frequency vibration, complicating supporting conditions). The method has the potential to be further developed to provide solutions to unsolved problems in acoustic wave transport, short electromagnetic wave propagation etc. The research training of ....Development of a Local Spectral Method for the Computations of Thin-Walled Structures. This project will benefit Aust. society by providing a powerful tool for improving the safe and cost effective design of structures under extreme conditions (high frequency vibration, complicating supporting conditions). The method has the potential to be further developed to provide solutions to unsolved problems in acoustic wave transport, short electromagnetic wave propagation etc. The research training of the project will help to keep Australia to be at the forefront in this research field and the published research findings will promote the reputation of Australian researchers in the field of computational engineering. The international collaboration will be strengthened between the Investigator's team and his colleagues in US. Read moreRead less