Economic Operability Assessment of Leaching Process at Kwinana Nickel Refinery. Process operability is concerned with systematic analysis and improvement of process performance in the face of variable operating conditions. This project will develop a rigorous methodology for analysis of process operability with respect to short-term and transient disturbances. The proposed technique will be applied to the Kwinana Nickel Refinery Leach section, in order to reduce the plant variability and increas ....Economic Operability Assessment of Leaching Process at Kwinana Nickel Refinery. Process operability is concerned with systematic analysis and improvement of process performance in the face of variable operating conditions. This project will develop a rigorous methodology for analysis of process operability with respect to short-term and transient disturbances. The proposed technique will be applied to the Kwinana Nickel Refinery Leach section, in order to reduce the plant variability and increase nickel throughput and plant availability. This can be considered as significant move by a process industry to embrace advanced theoretical developments and will act as a benchmark to promote future links between Australian industry and academia.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220101043
Funder
Australian Research Council
Funding Amount
$413,482.00
Summary
Peculiar membrane structures for removing microplastics from water. Microplastic pollution can inflict irreparable damage to human health and the environment. This project aims to develop functional membrane structures specifically designed to remove microplastics from aquatic and wastewater treatment systems. The approach will utilise advanced techniques in material science, separation science and fluid mechanics. The expected outcomes include advanced membranes with high separation efficiency ....Peculiar membrane structures for removing microplastics from water. Microplastic pollution can inflict irreparable damage to human health and the environment. This project aims to develop functional membrane structures specifically designed to remove microplastics from aquatic and wastewater treatment systems. The approach will utilise advanced techniques in material science, separation science and fluid mechanics. The expected outcomes include advanced membranes with high separation efficiency for microplastics filtration. This will have significant benefits, including the efficient removal of microplastics from water sources securing cleaner potable, irrigation and recycled water, and contributing to a safer, healthier environment for all Australians.Read moreRead less
Use of Gas Expanded Liquids to Facilitate Process Intensification. The aim of this research is the utilisation of gas expanded liquids (GXLs) in technology platforms based on the principles of process intensification (PI). In order to facilitate the attainment of project objectives a comprehensive investigation of the fundamental properties of GXLs, and their interactions is proposed. A significant component of the programme is expected to be to use the knowledge obtained to facilitate the devel ....Use of Gas Expanded Liquids to Facilitate Process Intensification. The aim of this research is the utilisation of gas expanded liquids (GXLs) in technology platforms based on the principles of process intensification (PI). In order to facilitate the attainment of project objectives a comprehensive investigation of the fundamental properties of GXLs, and their interactions is proposed. A significant component of the programme is expected to be to use the knowledge obtained to facilitate the development of scale-up protocol for PI based methodologies, with particular emphasis on the production of biomaterials. GXLs technology is frontier technology with regard to the biomaterials sector.Read moreRead less
Vaporization of heavier gas oil in Fluid Catalytic Cracking risers. Fluid Catalytic Cracking (FCC) is an important refinery operation responsible for about 45 per cent of the total petrol produced. The project is aimed at improving production efficiency of Australian refineries by applying fundamental modelling to the FCC. The outcomes will enable refiners to produce cleaner fuel and decrease greenhouse gas emissions.
Novel gas-liquid columns for liquefied natural gas (LNG) production. Novel gas-liquid columns for liquefied natural gas (LNG) production. This project aims to design distillation and absorption columns, perhaps the most important unit operations in a liquefied natural gas (LNG) plant, and whose optimization is integral to overall performance of any LNG plant. This project will use 3D printers to rapidly prototype concepts of columns and their internals, and test them using flow characterization ....Novel gas-liquid columns for liquefied natural gas (LNG) production. Novel gas-liquid columns for liquefied natural gas (LNG) production. This project aims to design distillation and absorption columns, perhaps the most important unit operations in a liquefied natural gas (LNG) plant, and whose optimization is integral to overall performance of any LNG plant. This project will use 3D printers to rapidly prototype concepts of columns and their internals, and test them using flow characterization tools and numerical models. The final outcome of the project will be a set of designs of the columns, which should be more efficient, safer and cheaper to operate, and have smaller physical and environmental footprints, thus helping the Australian LNG industry to stay globally competitive.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100959
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Adsorptive removal of mercury from natural gas by carbonaceous material. The project aims to improve understanding of the adsorption mechanism of mercury removal from natural gas with porous carbon materials, by applying novel molecular simulation tools. An increasing number of Australian gas reservoirs have been found to contain higher levels of mercury than the specified safety, environment and product requirements. Although most of the current methods of mercury removal are based on adsorptio ....Adsorptive removal of mercury from natural gas by carbonaceous material. The project aims to improve understanding of the adsorption mechanism of mercury removal from natural gas with porous carbon materials, by applying novel molecular simulation tools. An increasing number of Australian gas reservoirs have been found to contain higher levels of mercury than the specified safety, environment and product requirements. Although most of the current methods of mercury removal are based on adsorption technology, its development and use to full potential has been impeded by a lack of understanding. This project aims to investigate the fundamental mechanism of mercury removal from natural gas with adsorption methods at the molecular level. The project is intended to pave the way for optimal design of mercury removal systems.Read moreRead less
Rare Earth Metal Separation by Polymer Inclusion Membranes. The project aims to develop a novel hydrometallurgical method for the separation of the rare earth metals dysprosium and terbium from mixed rare earth metal solutions using polymer inclusion membranes with a crosslinked or non-crosslinked polymer backbone. These metals are crucial for the manufacturing of advanced technology products. The membrane-based method is expected to offer significant advantages over the currently used solvent e ....Rare Earth Metal Separation by Polymer Inclusion Membranes. The project aims to develop a novel hydrometallurgical method for the separation of the rare earth metals dysprosium and terbium from mixed rare earth metal solutions using polymer inclusion membranes with a crosslinked or non-crosslinked polymer backbone. These metals are crucial for the manufacturing of advanced technology products. The membrane-based method is expected to offer significant advantages over the currently used solvent extraction methods by eliminating the use of solvents and conducting the separation as a continuous process where the extraction and back-extraction steps take place simultaneously. These advantages are expected to make the separation process more cost-effective and drastically reduce its environmental impact.Read moreRead less
Alarm Management - Silence is Golden. This project develops novel strategies and tools that aid alarm rationalisation in all types of process plants (e.g. gas, petrochemical, mining) by extracting groupings of related alarm tags from an enormous dataset of complex process data. These groupings are used in re-aligning the alarm systems, thus overcoming problems associated with the common practice of over-alarming, which may contribute to incidents like the Longford tragedy in Victoria. The approa ....Alarm Management - Silence is Golden. This project develops novel strategies and tools that aid alarm rationalisation in all types of process plants (e.g. gas, petrochemical, mining) by extracting groupings of related alarm tags from an enormous dataset of complex process data. These groupings are used in re-aligning the alarm systems, thus overcoming problems associated with the common practice of over-alarming, which may contribute to incidents like the Longford tragedy in Victoria. The approach is cost effective and improves alarm management. It addresses economic and safety concerns of the process industry as well as concerns raised in the study commissioned by the Institute of Engineers, Australia.Read moreRead less
Novel Characterization of Porous Structure and Surface Chemistry of Carbon. The aim of this project is to develop novel characterisation methods that probe the structure and surface chemistry of carbons, ranging from highly graphitised thermal carbon black through ordered mesoporous carbon to disordered porous activated carbon. The project plans to develop a new generic molecular model based on wedge-shaped pores. Conventional parallel sided pore models fail to account for real structures and th ....Novel Characterization of Porous Structure and Surface Chemistry of Carbon. The aim of this project is to develop novel characterisation methods that probe the structure and surface chemistry of carbons, ranging from highly graphitised thermal carbon black through ordered mesoporous carbon to disordered porous activated carbon. The project plans to develop a new generic molecular model based on wedge-shaped pores. Conventional parallel sided pore models fail to account for real structures and therefore for the physics of adsorption in real materials. The project then plans to back the theoretical model with high-resolution experimental measurements. It is expected that the model will unify the structural analysis for all carbons and account for all experimental isotherms within a rational and physically plausible framework.Read moreRead less
Wavelet approaches for solving nonlinear dynamic systems in process engineering. The success of the proposed project will enable us to obtain more accurate numerical solutions for the nonlinear dynamical systems arising from process engineering. This ensures the potential for understanding and optimising industrial and engineering processes. Hence, a wide range of processing industries in Australia, such as agricultural chemicals, mineral processing, food, detergents, pharmaceuticals, ceramics ....Wavelet approaches for solving nonlinear dynamic systems in process engineering. The success of the proposed project will enable us to obtain more accurate numerical solutions for the nonlinear dynamical systems arising from process engineering. This ensures the potential for understanding and optimising industrial and engineering processes. Hence, a wide range of processing industries in Australia, such as agricultural chemicals, mineral processing, food, detergents, pharmaceuticals, ceramics and specialty chemicals will benefit from the results of this project. This will ensure globally competitive production and, therefore, greater contributions to the Australian economy.Read moreRead less