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Hydrodynamic enhancement and transformation of flotation. The purpose of this project is to address emerging challenges in coal and mineral processing associated with the steep decline in the quality of mining assets and the long term resource demands of China and India. A major advance in flotation technology is expected, leading to the highest possible product grade at a given recovery.
Fundamental studies of multiphase flow and separation performance of natural medium cyclones for recovering waste coal. This project aims to develop an effective method to design, control and optimise natural medium cyclones for recovering waste coal, important for environmental protection and for energy efficiency. Its conduct will enhance Australia's leading position in the coal industry.
Three-dimensional flotation of fine particles. Three-dimensional flotation of fine particles. This project aims to research three-dimensional flotation of fine particles under both batch and continuous steady state conditions. In flotation, fine hydrophobic particles adhere to the two-dimensional surface of rising air bubbles, forming concentrate. In three-dimensional flotation, however, the particles adhere to and become embedded in a novel binder, forming a highly buoyant product. The process ....Three-dimensional flotation of fine particles. Three-dimensional flotation of fine particles. This project aims to research three-dimensional flotation of fine particles under both batch and continuous steady state conditions. In flotation, fine hydrophobic particles adhere to the two-dimensional surface of rising air bubbles, forming concentrate. In three-dimensional flotation, however, the particles adhere to and become embedded in a novel binder, forming a highly buoyant product. The process is very selective and arguably 1000 times faster than conventional flotation. The project is expected to provide the knowledge required to achieve scale-up, so the technology can be used to recover high value product from tailings waste, eliminating the capital impediment and possibly transforming the entire mining industry.Read moreRead less
Maximizing the kinetics of flotation processes. The purpose of this project is to develop a new flotation technology that can be operated at feed rates vastly higher than existing technologies. The technology will be applicable to low grade feeds often discarded to tailings, delivering billions of dollars in additional exports of Australian resources and contributing to the growth in the mining services sector.
A Framework for Understanding and Applying the Reflux Classifier in Fine Particle Beneficiation. The Reflux Classifier is a novel Australian technology that is re-defining what is possible in the field of gravity separation across the mining industry. This new research aims to focus on a critical gap in the knowledge, concerned with the powerful internal synergies that exist between the particle-fluid hydrodynamics of the lower fluidised bed and the upper system of inclined channels. The technol ....A Framework for Understanding and Applying the Reflux Classifier in Fine Particle Beneficiation. The Reflux Classifier is a novel Australian technology that is re-defining what is possible in the field of gravity separation across the mining industry. This new research aims to focus on a critical gap in the knowledge, concerned with the powerful internal synergies that exist between the particle-fluid hydrodynamics of the lower fluidised bed and the upper system of inclined channels. The technology has already delivered nearly $1 billion in economic benefit, solving previously intractable problems. Through an experimental and theoretical study a new framework for understanding and applying this technology in fine particle beneficiation across an increasingly diverse range of applications is intended to be established.Read moreRead less
Fine particle beneficiation through agglomeration with a novel binder. New South Wales and Queensland have massive tailings dams, each with many millions of tonnes of valuable resource. These dams represent a significant liability. This project will develop a technology that can be used to recover the fine coal resource, in turn making the site rehabilitation an economic proposition.
Engineered functional metal silica membranes for hydrogen processing. This project focuses on hydrogen processing technologies for the petrochemical, agricultural and coal/energy industries. These sectors employ 110,000 people with annual combined revenues of $80 billion. Advanced technologies are vital for the competitiveness of the Australian economy, and to sustain Australia's social stability and economic growth.
Swirling turbulent pipe flow technology for drying brown coal. This project aims to understand the complex fluid mechanicalprocesses in a brown coal drying machine. Brown coal from the Latrobe Valley contains about 70 percent moisture, which must be reduced for it to be used efficiently in power stations. Utilising cutting-edge techniques in laboratory and field measurements together with advanced computational methods in fluid mechanics, the project intends to further knowledge in swirling turb ....Swirling turbulent pipe flow technology for drying brown coal. This project aims to understand the complex fluid mechanicalprocesses in a brown coal drying machine. Brown coal from the Latrobe Valley contains about 70 percent moisture, which must be reduced for it to be used efficiently in power stations. Utilising cutting-edge techniques in laboratory and field measurements together with advanced computational methods in fluid mechanics, the project intends to further knowledge in swirling turbulent flows, particle transport and vortex breakdown. The result of this research is expected to produce a drier brown coal, leading to a cleaner environment and an increase in Australian coal value. Read moreRead less
Heat-resisting iron-nickel base alloys in challenging new applications: oxygen permeabilities and resistance to internal oxidation. There is a pressing need to develop heat resisting alloys which can function adequately in higher operating temperatures and gas mixtures rich in carbon and hydrogen to be handled in advanced technologies for power generation. The expected outcomes of this project will provide the basis for design/selection of these more corrosion-resistant alloys.
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