Characterisation of Pyrolytic Thermal Regions in Coal Macerals using Computer Aided Thermal Analysis. The research will assist in the fundamental understanding of coal pyrolysis mechanisms. All coal contains proportions of different fossilised plant material, which behaves differently when heated. This proposal studies thermal behaviour of the density separated fractions in Australian coals using a highly sensitive technique. The characterisation adds value and use to current coal reserves and ....Characterisation of Pyrolytic Thermal Regions in Coal Macerals using Computer Aided Thermal Analysis. The research will assist in the fundamental understanding of coal pyrolysis mechanisms. All coal contains proportions of different fossilised plant material, which behaves differently when heated. This proposal studies thermal behaviour of the density separated fractions in Australian coals using a highly sensitive technique. The characterisation adds value and use to current coal reserves and is aimed towards producing an advanced modelling capability to promote efficient coal usage in existing and future technologies. Such innovative approaches support the sustainability of Australian coal reserves, particularly in the transition towards decarbonised energy.Read moreRead less
Selective generation of hydrogen from biomass and waste fuels. Biomass fuels account for 14% of global energy supply. This is likely to increase in future as the population increases, energy demand rises, cheap oil and coal reserves are depleted, and the effects of global warming become more readily visible. In Australia the development of a sustainable hydrogen economy is a national priority. The hydrogen economy could bring about improved energy security, substantially reduced greenhouse gas e ....Selective generation of hydrogen from biomass and waste fuels. Biomass fuels account for 14% of global energy supply. This is likely to increase in future as the population increases, energy demand rises, cheap oil and coal reserves are depleted, and the effects of global warming become more readily visible. In Australia the development of a sustainable hydrogen economy is a national priority. The hydrogen economy could bring about improved energy security, substantially reduced greenhouse gas emissions, improved energy efficiency and improved air quality. This proposal directly addresses this challenge by investigating the science underpinning a large-scale sustainable hydrogen synthesis process using biomass and waste fuels. Read moreRead less
A Fundamental Investigation of the Thermoplastic Behaviour and Porous Structural Evolution of Coke and Char Particles. During heating, solid fuel particles undergo complex physical changes resulting in sophisticated structures in the residual material (coke and char) which influence the operational performance of these materials in ironmaking and power generation processes. The mechanistic understanding of the evolution of physical structure and the coupled role of gas evolution has not been wel ....A Fundamental Investigation of the Thermoplastic Behaviour and Porous Structural Evolution of Coke and Char Particles. During heating, solid fuel particles undergo complex physical changes resulting in sophisticated structures in the residual material (coke and char) which influence the operational performance of these materials in ironmaking and power generation processes. The mechanistic understanding of the evolution of physical structure and the coupled role of gas evolution has not been well established. An interpretive and predictive mechanism to describe the process will be developed through experimental observations and mathematical modelling. The project will provide fundamental new insights and understanding of operational issues concerning the complex behaviour of solid fuel residues in coal based industrial processes.Read moreRead less
A novel whole-process analysis method for fractured rock slopes . Aims: The project aims to develop a discontinuous deformation and displacement analysis method to study the jointed rock slope instability.
Significance: The proposed method verified by experimental tests will be inherit the advantages of finite element method and discontinuous deformation analysis and is able to provide an entire and unified description of rock deformation and failure.
Expected Outcomes: The results of this integ ....A novel whole-process analysis method for fractured rock slopes . Aims: The project aims to develop a discontinuous deformation and displacement analysis method to study the jointed rock slope instability.
Significance: The proposed method verified by experimental tests will be inherit the advantages of finite element method and discontinuous deformation analysis and is able to provide an entire and unified description of rock deformation and failure.
Expected Outcomes: The results of this integrated study will provide a new method for engineers who wish to characterise and predict the stability of rock/tunnel slopes in Australia and worldwide.
Benefits: Australian society will benefit from new tools to facilitate more reliable assessment of risks associated with instability in rock slopes.
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Microdynamic modelling and analysis of gas fluidization of particle mixtures. The project aims to develop a comprehensive understanding of the mechanisms governing the particle-fluid flow in gas fluidization of mixtures of particles of different sizes. This will be achieved through detailed analysis of the particle-particle and particle-fluid interactions on the basis of the microdynamic or particle scale results generated by the newly developed discrete simulation technique. The microscopic fin ....Microdynamic modelling and analysis of gas fluidization of particle mixtures. The project aims to develop a comprehensive understanding of the mechanisms governing the particle-fluid flow in gas fluidization of mixtures of particles of different sizes. This will be achieved through detailed analysis of the particle-particle and particle-fluid interactions on the basis of the microdynamic or particle scale results generated by the newly developed discrete simulation technique. The microscopic findings will be implemented in the macroscopic, continuum-based modelling and tested by comparing numerical and experimental results. It will significantly enhance the present capability of modelling particle-fluid flow in gas fluidization which is widely used in mineral/chemical industries.Read moreRead less
Geomechanics of multiple seam mining interactions. This project will address a highly significant and timely problem that has arisen in the coal mining industry. Through the application of scientific principles and advanced methods of engineering analysis, this research will develop practical guidelines that in turn will provide the means for rational planning of multi-seam mining operations.
Granular dynamics: from discrete simulation towards continuum modelling. The project aims to develop a general averaging theory to link discrete to continuum description of granular dynamics and a comprehensive understanding of the underlying physics. This will be achieved through detailed analysis of the particle-particle and particle-wall interactions at both microscopic and macroscopic levels, supported by the newly developed averaging theory and novel discrete particle simulation. The result ....Granular dynamics: from discrete simulation towards continuum modelling. The project aims to develop a general averaging theory to link discrete to continuum description of granular dynamics and a comprehensive understanding of the underlying physics. This will be achieved through detailed analysis of the particle-particle and particle-wall interactions at both microscopic and macroscopic levels, supported by the newly developed averaging theory and novel discrete particle simulation. The results, in terms of constitutive relations and boundary conditions, will be implemented in continuum-based process modelling and tested by comparing numerical and experimental results via typical case studies. It will significantly enhance the present capability of modelling granular flow that is widely encountered in many industries and in nature.Read moreRead less
Carbon surface oxides: the key to understanding the chemical rate of carbon combustion. This project employs a unique combination of experimental measurements and fundamental quantum chemical calculations to study the oxides which form on the surface of carbon as it burns. Our objective is to develop a quantitative model for the kinetics of carbon combustion which will be a profound improvement over existing approaches. Such a model would provide the basis for the improved prediction of carbon c ....Carbon surface oxides: the key to understanding the chemical rate of carbon combustion. This project employs a unique combination of experimental measurements and fundamental quantum chemical calculations to study the oxides which form on the surface of carbon as it burns. Our objective is to develop a quantitative model for the kinetics of carbon combustion which will be a profound improvement over existing approaches. Such a model would provide the basis for the improved prediction of carbon combustion and gasification in current (coal-burning) power generation appliances, as well as catering for new approaches to lowering greenhouse emissions which also depend on the combustion and gasification of carbon as coal, biomass or refuse-derived fuel.Read moreRead less
Understanding mass extinctions and deep-time climate change: International Timescale Calibration of the Late Permian-Early Triassic of Australia. The project will enhance Australia's research strength as world leaders in isotope geochronology, geological timescale calibration, and global biological evolution studies, and will expand knowledge and provide a long overdue robust chronostratigraphic framework for a critical part of Earth's history that is a particular focus for energy resources in A ....Understanding mass extinctions and deep-time climate change: International Timescale Calibration of the Late Permian-Early Triassic of Australia. The project will enhance Australia's research strength as world leaders in isotope geochronology, geological timescale calibration, and global biological evolution studies, and will expand knowledge and provide a long overdue robust chronostratigraphic framework for a critical part of Earth's history that is a particular focus for energy resources in Australia. Our work will provide vital input to enhanced models for deep-time biotic turnover, climate change and global warming that will aid prediction of modern global atmospheric and climate changes due to human impact and provide vital data and information for Australian policy makers.Read moreRead less
A complex systems approach to granular rheology: interconnecting topology, stability, dynamics and function. The response of granular materials (e.g. soil, rocks) to applied stresses and strains will be characterised in detail. Information mined from experimental and simulation tests will be used to develop robust predictive models of granular behaviour, crucial for effective earthquake mitigation as well as greener mining and construction technologies.