Quantification and Modelling of Particle Flow Mechanisms in Conveyor Transfers. A critical area of solids handling and processing is the transfer of bulk material between conveyor belts. Design of conveyor transfers rely heavily on trial and error and/or experience and cannot cope with the complexities of varying particle properties and process requirements. Poor transfer designs can result in reduced QC and service life, significant maintenance/environmental costs and safety concerns. The main ....Quantification and Modelling of Particle Flow Mechanisms in Conveyor Transfers. A critical area of solids handling and processing is the transfer of bulk material between conveyor belts. Design of conveyor transfers rely heavily on trial and error and/or experience and cannot cope with the complexities of varying particle properties and process requirements. Poor transfer designs can result in reduced QC and service life, significant maintenance/environmental costs and safety concerns. The main aims of this project are experimental and theoretical investigations into the flow of particulates through conveyor transfers. This will result in: development of a novel conveyor transfer facility; quantification of transfer parameters and data; development of models to simulate and assist in the design of complete transfers.Read moreRead less
Advanced Nanoscale Materials Engineered from Diatomaceous Earth. Using natural materials of diatomaceous earth (DE) as a cheap and available resource by applying synthetic routes this project is directed towards the innovative development of new nanoscale materials with advanced properties. New mesoporous materials with intricate 3-D structures and nano sized features will be engineered from diatom silica for use in demanding applications such as separation and catalysis. These research outcomes ....Advanced Nanoscale Materials Engineered from Diatomaceous Earth. Using natural materials of diatomaceous earth (DE) as a cheap and available resource by applying synthetic routes this project is directed towards the innovative development of new nanoscale materials with advanced properties. New mesoporous materials with intricate 3-D structures and nano sized features will be engineered from diatom silica for use in demanding applications such as separation and catalysis. These research outcomes will enhance Australia's capacity in frontier technology and advanced materials, as well as bringing a competitive advantage to local industry through the development of such advanced materials.Read moreRead less
Utilization of fly ash in manufacturing polypropylene composites: a fundamental study. A large amount of coal fly ash is generated from thermal power stations and only a small amount has found applications, causing a significant economic and environmental problem in Australia and worldwide. This project aims to develop techniques to use fly ash in the manufacture of polymer composite and, in particular, explore the underlying fundamentals by means of various advanced characterization and simulat ....Utilization of fly ash in manufacturing polypropylene composites: a fundamental study. A large amount of coal fly ash is generated from thermal power stations and only a small amount has found applications, causing a significant economic and environmental problem in Australia and worldwide. This project aims to develop techniques to use fly ash in the manufacture of polymer composite and, in particular, explore the underlying fundamentals by means of various advanced characterization and simulation techniques. The expected outcomes may lead to an environmentally sustainable and large quantity use of fly ash and bring about new business opportunities. This, together with the proposed research training, represents a useful contribution to the development of a more competitive Australia.Read moreRead less
A Stress Transfer Principle for Carbon Nanotube Reinforced Materials under Complex Loading. Many breakthrough technologies in the future will build upon carbon nanotube reinforced materials but the scientific basis in the area is still unavailable. This project aims to establish a reliable stress transfer principle so that the design, production and application of the materials can be accurately controlled and the great strength of carbon nanotubes can be wisely utilized. The research will resol ....A Stress Transfer Principle for Carbon Nanotube Reinforced Materials under Complex Loading. Many breakthrough technologies in the future will build upon carbon nanotube reinforced materials but the scientific basis in the area is still unavailable. This project aims to establish a reliable stress transfer principle so that the design, production and application of the materials can be accurately controlled and the great strength of carbon nanotubes can be wisely utilized. The research will resolve a key paradox and develop a series of innovative theories and technologies. The success of the project will make a significant impact on the nanoscience and nanotechnology associated with the applications of carbon nanotube reinforced materials.Read moreRead less
Developing new, water-based lubricants for sheet metal forming. There is increasing pressure on manufacturers, including the sheet metal forming industry, to use less toxic, water-based lubricants with a number of common additives being banned or being phased out internationally. In the case of automotive manufacturers, this is combined with demand for alternative sheet materials to reduce costs or cater for export markets. Efficient development of new lubricants or replacement additives require ....Developing new, water-based lubricants for sheet metal forming. There is increasing pressure on manufacturers, including the sheet metal forming industry, to use less toxic, water-based lubricants with a number of common additives being banned or being phased out internationally. In the case of automotive manufacturers, this is combined with demand for alternative sheet materials to reduce costs or cater for export markets. Efficient development of new lubricants or replacement additives requires a comprehensive understanding of the interactions between lubricant components and the surface of the sheet metal. This project will explore and model these interactions and how they are affected by the variables in a metal forming process.Read moreRead less
Micro-electromechanics and finite element analysis models for adaptive structures. Adaptive structures are becoming increasingly important due to their direct improvement of structural system performance. However, electroelastic behaviour and damage mechanism, which are primary concerns for adaptive structural design, are poorly understood. This project aims at developing micro-electromechanics and finite element analysis models to investigate the electroelastic properties and detect delaminatio ....Micro-electromechanics and finite element analysis models for adaptive structures. Adaptive structures are becoming increasingly important due to their direct improvement of structural system performance. However, electroelastic behaviour and damage mechanism, which are primary concerns for adaptive structural design, are poorly understood. This project aims at developing micro-electromechanics and finite element analysis models to investigate the electroelastic properties and detect delamination for adaptive structures. It combines the fields of micro-electromechanics and composite material analysis in a computational framework to provide a useful and cost-effective tool for modelling the response of adaptive structures. It is a challenging task and will have significant impact in the adaptive structure design community.Read moreRead less
Bacterial cell behaviour in micro/nano-confined environments. The project aims to progress the understanding of the mechanisms of marine bacteria biofilm formation and surface-modulated metabolic response. We will adjust the surface characteristics of photopolymers (as ?model? surfaces) and probe the bacterial response to surfaces, passively with micro/nano-fabricated structures and Atomic Force Microscopy; and actively with optical manipulation of single cells. The results will contribute to th ....Bacterial cell behaviour in micro/nano-confined environments. The project aims to progress the understanding of the mechanisms of marine bacteria biofilm formation and surface-modulated metabolic response. We will adjust the surface characteristics of photopolymers (as ?model? surfaces) and probe the bacterial response to surfaces, passively with micro/nano-fabricated structures and Atomic Force Microscopy; and actively with optical manipulation of single cells. The results will contribute to the fundamental knowledge regarding central biological phenomena -down to single-cell processes- as well as on applied knowledge regarding the manufacturing of antimicrobial surfaces that mimic natural bactericide processes, with larger implications on biomedical practice, and environmental, civil, mining and manufacturing industrial applications.Read moreRead less
Interface Engineering of Multilayer Nanostructures. Nanostructured multilayers can outperform coatings of their constituent layers in both hardness and strength. It is believed that the nature of interfaces in these materials is critical since they mediate dislocation motion and crack propagation. This project will use advanced synthesis, microanalysis and theoretical methods to investigate multilayer coatings with sharp, diffuse and rough interfaces in order to reveal their failure mechanisms u ....Interface Engineering of Multilayer Nanostructures. Nanostructured multilayers can outperform coatings of their constituent layers in both hardness and strength. It is believed that the nature of interfaces in these materials is critical since they mediate dislocation motion and crack propagation. This project will use advanced synthesis, microanalysis and theoretical methods to investigate multilayer coatings with sharp, diffuse and rough interfaces in order to reveal their failure mechanisms under stress. This will enable us to understand the principles required to design the strongest structures and facilitate the selection of materials and deposition parameters in order to produce coatings optimised for a range of demanding applications.Read moreRead less
Optimisation of Mass Flow Bin Design Using 3D Parametric Modelling. The storage, feeding and transfer of bulk solids are of vital importance to the resource and process industries. The current techniques used for the design of storage vessels are reliable but time consuming and limit the degree of optimisation that can be achieved. This project will develop a design methodology for bulk solids storage vessels such that it can be integrated with the parametric design system developed by Gulf Con ....Optimisation of Mass Flow Bin Design Using 3D Parametric Modelling. The storage, feeding and transfer of bulk solids are of vital importance to the resource and process industries. The current techniques used for the design of storage vessels are reliable but time consuming and limit the degree of optimisation that can be achieved. This project will develop a design methodology for bulk solids storage vessels such that it can be integrated with the parametric design system developed by Gulf Conveyor Holdings to provide a reliable, accelerated design process that provides a high degree of optimisation. This will lead to greater use of the technique in industry and a consequent increase in reliability and cost effectiveness.Read moreRead less
Measuring and modelling the mechanical response of soils incorporating recycled tyres. Civil engineers use backfill to refill excavated areas around new structures. They have found recently that rubber chips and shredded rubber make excellent backfill when combined with a small percentage of cement to make ‘rubber soil’. The widespread use of rubber soil therefore offers a tremendous opportunity to make use of a serious waste product to achieve important engineering outcomes. However, too little ....Measuring and modelling the mechanical response of soils incorporating recycled tyres. Civil engineers use backfill to refill excavated areas around new structures. They have found recently that rubber chips and shredded rubber make excellent backfill when combined with a small percentage of cement to make ‘rubber soil’. The widespread use of rubber soil therefore offers a tremendous opportunity to make use of a serious waste product to achieve important engineering outcomes. However, too little is known about the technology. This project will model the behaviour of rubber soil in order to introduce it as an environmentally sustainable, cost-effective and technically sound choice of geomaterial for both standard and non-standard geotechnical structures.Read moreRead less