Benign recovery of precious metals from deep pristine environments. This project aims to extract precious metals from natural deposits conventional mining methods cannot reach. Glycine-peroxide systems can dissolve precious metals without pollution. Understanding these systems’ behaviour in natural orebodies could lead to in-situ leaching methods that complement conventional mining, especially in low grade deposits. This project intends to use a modern scientific workflow based on exploratory, d ....Benign recovery of precious metals from deep pristine environments. This project aims to extract precious metals from natural deposits conventional mining methods cannot reach. Glycine-peroxide systems can dissolve precious metals without pollution. Understanding these systems’ behaviour in natural orebodies could lead to in-situ leaching methods that complement conventional mining, especially in low grade deposits. This project intends to use a modern scientific workflow based on exploratory, descriptive and explanatory phases to model the coupled multi-physics of precious metals transport, introduce a high performance computing strategy for in-situ leaching, develop an experimental protocol that explains the recovery mechanisms, and propose optimal leaching patterns that maximise productivity.Read moreRead less
Ehanced Hydrodynamic Fractionation of Particles. The coal industry, which is a major contributor to the Australian economy, urgently needs a new washability method following its decision to abandon the existing laboratory standard. The existing method relies on the use of heavy organic liquids which are known to be toxic to human health. The 'water-based' approach proposed in this study overcomes the problem of risk to human health, thus benefiting Australian workers, the immediate industry, and ....Ehanced Hydrodynamic Fractionation of Particles. The coal industry, which is a major contributor to the Australian economy, urgently needs a new washability method following its decision to abandon the existing laboratory standard. The existing method relies on the use of heavy organic liquids which are known to be toxic to human health. The 'water-based' approach proposed in this study overcomes the problem of risk to human health, thus benefiting Australian workers, the immediate industry, and wider community. New separation technologies that could benefit the minerals industries and other key industries should follow. The project will also result in the education and training of two postgraduate students, and the advancement of two postdoctoral researchers in this area of industry. Read moreRead less
Fundamental studies of physical and thermal processes around the taphole of an ironmaking blast furnace. This project will investigate the fundamentals governing the complex physical and thermochemical processes in the hearth of an ironmaking blast furnace by a combined theoretical and experimental program. Its aim is to develop and validate computer models that can describe reliably the gas-liquid-solid flow and heat transfer in the hearth, particularly near the taphole region. The models will ....Fundamental studies of physical and thermal processes around the taphole of an ironmaking blast furnace. This project will investigate the fundamentals governing the complex physical and thermochemical processes in the hearth of an ironmaking blast furnace by a combined theoretical and experimental program. Its aim is to develop and validate computer models that can describe reliably the gas-liquid-solid flow and heat transfer in the hearth, particularly near the taphole region. The models will be very useful to quantify the interrelationships among fluid flow, heat transfer and furnace refractory erosion, and provide a basis for developing better control strategies and extending furnace campaign life, leading to an improved competitiveness of Australia's steel industry.Read moreRead less
In-situ Characterisation of Coal from Coal Seam Gas Developments. We aim to develop advanced methods for determination of coal properties required for optimising gas recovery, scheduling future developments and water management by Queensland Gas Company. We will characterise multiphase flow of gas and water in coal cores by Positron Emission Tomography and flooding experiments. Advancement in knowledge is achieved by using massive data from 4D-imaging to predict evolution of petrophysical proper ....In-situ Characterisation of Coal from Coal Seam Gas Developments. We aim to develop advanced methods for determination of coal properties required for optimising gas recovery, scheduling future developments and water management by Queensland Gas Company. We will characterise multiphase flow of gas and water in coal cores by Positron Emission Tomography and flooding experiments. Advancement in knowledge is achieved by using massive data from 4D-imaging to predict evolution of petrophysical properties at in situ condition in different types of coal. This will future proof Australia as the world’s largest exporter of natural gas and will provide significant benefit for the industry in satisfying domestic gas security, maintaining international commitment and addressing environmental concerns. Read moreRead less
Future copper metallurgy for the age of e-mobility and the circular economy. Copper, nickel, cobalt, chromium and tin metals are essential for the manufacture of new battery materials, electrical and electronic devices and technologies that will enable the global transition to sustainable energy systems. There are major technical challenges associated with the industrial scale high temperature production, separation and recycling of these metals. The aim of the present study is develop advanced ....Future copper metallurgy for the age of e-mobility and the circular economy. Copper, nickel, cobalt, chromium and tin metals are essential for the manufacture of new battery materials, electrical and electronic devices and technologies that will enable the global transition to sustainable energy systems. There are major technical challenges associated with the industrial scale high temperature production, separation and recycling of these metals. The aim of the present study is develop advanced chemical thermodynamic databases and models that can be used to predict the outcomes of these complex chemical reactions, and in doing so provide the industry with the vital fundamental scientific information and tools needed to be able to design and improve new, more efficient metal production and recycling technologies. Read moreRead less
Optimising non-explosive rock breaking technology. Non-explosive rock breaking technology has the potential to significantly improve safety and production in mining and construction industries. This project will quantify a non-explosive hydraulic rock breaking technology through innovative theoretical and numerical investigations. The influences of all the key factors on the efficiency of this technology will the examined. It is envisaged that the outcomes from this proposal will optimise the no ....Optimising non-explosive rock breaking technology. Non-explosive rock breaking technology has the potential to significantly improve safety and production in mining and construction industries. This project will quantify a non-explosive hydraulic rock breaking technology through innovative theoretical and numerical investigations. The influences of all the key factors on the efficiency of this technology will the examined. It is envisaged that the outcomes from this proposal will optimise the non-explosive rock breaking technology, greatly improve its application and guide our industry partner to develop reliable equipment.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0452650
Funder
Australian Research Council
Funding Amount
$696,005.00
Summary
South Australian Virtual Reality Centre (SAVRC). It is proposed to install a fully immersive three dimensional visualisation facility in Adelaide, at a cost of $5.3 million including requested ARC contribution of $696,005. Applicant Institutions (Adelaide, Flinders, UniSA and Curtin universities) and Industry will provide the remainder.
The facility will support South Australia's leading scientific researchers in the sciences, engineering, business management, carbon dioxide sequestration, p ....South Australian Virtual Reality Centre (SAVRC). It is proposed to install a fully immersive three dimensional visualisation facility in Adelaide, at a cost of $5.3 million including requested ARC contribution of $696,005. Applicant Institutions (Adelaide, Flinders, UniSA and Curtin universities) and Industry will provide the remainder.
The facility will support South Australia's leading scientific researchers in the sciences, engineering, business management, carbon dioxide sequestration, petroleum exploration and production, space environment, bioinformatics, architecture, surgery, dentistry, archaeology and arts.
The facility will enable researchers and industry to significantly leverage other projects leading to much improved research outcomes and efficiency, potentially worth a hundred million dollars or more.
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A novel low-energy process route for primary copper production utilising synergistic hydro- and pyro-metallurgical processes. With increasing demand for copper metal, there is an urgent need to find new ways to efficiently treat lower grade ores. The new process offers a way of significantly reducing energy consumption and greenhouse gas emissions in primary copper production and making more efficient use of the world's copper resources.
A Fundamental Study of the Breakage of Gibbsite and Smelter Grade Alumina. This project aims to develop a fundamental understanding of the cracking of gibbsite and smelter grade alumina, thus providing useful guidance for the alumina refineries to control the particle size distribution of the smelter grade alumina. This addresses an important issue in alumina refineries in terms of providing a high quality product for the downstream aluminium smelter.
Economical Offshore Foundation for Deep Water - Suction Embedded Plate Anchor. The oil/gas industry's venture in finding large resources in deep water has lead to a number of important economic and technical challenges including, among others, new types of foundations. Suction Embedded Plate Anchor (SEPA) has shown its potential of cost-saving against other types of foundations in deep waters. The aim of this project is to use the experties of investigators, on numerical and centrifuge modelling ....Economical Offshore Foundation for Deep Water - Suction Embedded Plate Anchor. The oil/gas industry's venture in finding large resources in deep water has lead to a number of important economic and technical challenges including, among others, new types of foundations. Suction Embedded Plate Anchor (SEPA) has shown its potential of cost-saving against other types of foundations in deep waters. The aim of this project is to use the experties of investigators, on numerical and centrifuge modelling, to study the behaviour of SEPA in sub-marine deposit. Successful completing of the project will contribute to the very little existing data on this new type of foundation - SEPA.Read moreRead less