Reducing wear on rotary coal pulverisers. The aim of this project is to develop an understanding of the small-scale flows and particle breakage required to permit optimised redesign of the attrition stage of the 36 coal pulverisers at Gladstone Power Station, which, because of erosive wear, currently have a maintenance budget of $4M per year. CFD-DEM simulation of the air and particle flows will be used to determine particle flow patterns, particle-particle and particle-wall impact energies. Thi ....Reducing wear on rotary coal pulverisers. The aim of this project is to develop an understanding of the small-scale flows and particle breakage required to permit optimised redesign of the attrition stage of the 36 coal pulverisers at Gladstone Power Station, which, because of erosive wear, currently have a maintenance budget of $4M per year. CFD-DEM simulation of the air and particle flows will be used to determine particle flow patterns, particle-particle and particle-wall impact energies. This information will be input to comminution and wear models to predict pulveriser performance and wear patterns. Simulation results will be validated using measurements from scale visualisation and working models.Read moreRead less
Variational multiscale modelling of granular materials. Granular materials play an important role in a wide-range of problems related to physical infrastructure. These include landslides and similar catastrophic events often leading to loss of life and property. This project will aim to develop new methods for adequate simulation of granular flows to allow formulation of efficient risk mitigation strategies.
Phosphorous and iron recovery from steelmaking slag for effective recycling. This project aims to understand the principles that control phosphorus (P) partitioning in steel plant slags and to optimise the treatment process to produce P- and Fe-rich streams for recycling. Changing ore grades in Australia, especially increasing P content, are placing a substantial proportion of these ore products at a competitive disadvantage. The project will use an integrated approach to demonstrate, experiment ....Phosphorous and iron recovery from steelmaking slag for effective recycling. This project aims to understand the principles that control phosphorus (P) partitioning in steel plant slags and to optimise the treatment process to produce P- and Fe-rich streams for recycling. Changing ore grades in Australia, especially increasing P content, are placing a substantial proportion of these ore products at a competitive disadvantage. The project will use an integrated approach to demonstrate, experimentally and theoretically, how key properties of slags can be manipulated to enhance partitioning and couple this analysis with fluid dynamics to model the kinetics of the separation process. The expected outcomes of this research are to: first, provide possible solutions to address the increasing P content in Australian iron ores, which could place future ore products at a competitive disadvantage within the global iron ore market; and second, to identify treatment methods and practices which would promote higher recycling rates of steelmaking slag, significantly reducing the volume of material stockpiled or sent to landfill.Read moreRead less
Fume resistant explosives for critical areas. Fume resistant explosives for critical areas. This project aims to understand how a new explosive works and how it can be used in critical areas. This ammonium nitrate (AN) emulsion explosive provides excellent resistance against emissions of mono-nitrogen oxide (NOx) fumes. This project will investigate physical and chemical parameters of the key emulsion components and formulate new blends for higher-strength applications. This project will researc ....Fume resistant explosives for critical areas. Fume resistant explosives for critical areas. This project aims to understand how a new explosive works and how it can be used in critical areas. This ammonium nitrate (AN) emulsion explosive provides excellent resistance against emissions of mono-nitrogen oxide (NOx) fumes. This project will investigate physical and chemical parameters of the key emulsion components and formulate new blends for higher-strength applications. This project will research the surface burning process of AN prills and other materials to understand possible NOx production and mitigation pathways. The results from the project are expected to overcome the limitations of the new technology, and make Australian industries more competitive.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100204
Funder
Australian Research Council
Funding Amount
$452,147.00
Summary
Geothermal heat recovery and energy storage from underground mines. This project aims to investigate the technological aspects of re-using underground mines as a source for low-carbon heat extraction and storage – while simultaneously providing sustainable solutions for mine rehabilitation. Expected outcomes of this project include a framework to evaluate the viability of a mine-water system as a geothermal heat source; experimental and field exploration of the proposed technology; and strategie ....Geothermal heat recovery and energy storage from underground mines. This project aims to investigate the technological aspects of re-using underground mines as a source for low-carbon heat extraction and storage – while simultaneously providing sustainable solutions for mine rehabilitation. Expected outcomes of this project include a framework to evaluate the viability of a mine-water system as a geothermal heat source; experimental and field exploration of the proposed technology; and strategies to optimise the heat extraction process. Overall, the research provides significant benefits for renewable-based energy transformation while minimising the adverse impacts of post-mining landscapes.Read moreRead less
A Novel Hybrid Chemical Looping Process for Production of Liquid Hydrocarbon Fuels with a Reduced Greenhouse Gas Emissions Profile. This project determines the fundamental science underpinning the operation of a novel hybrid chemical looping carbon reforming (CLCR) process for production of alternative transportation fuels with a reduced greenhouse gas emissions profile. Compare with conventional processes, the CLCR process features a 50 per cent reduction in the energy and carbon dioxide footpr ....A Novel Hybrid Chemical Looping Process for Production of Liquid Hydrocarbon Fuels with a Reduced Greenhouse Gas Emissions Profile. This project determines the fundamental science underpinning the operation of a novel hybrid chemical looping carbon reforming (CLCR) process for production of alternative transportation fuels with a reduced greenhouse gas emissions profile. Compare with conventional processes, the CLCR process features a 50 per cent reduction in the energy and carbon dioxide footprints and represents a large sink for carbon dioxide sequestration if deployed widely. To achieve the broad objectives of the project comprehensive experimental and modelling studies will be carried out at macro, micro and molecular levels. Expected outcomes include fundamental knowledge essential to the development and commercial-scale deployment of the CLCR process.Read moreRead less
Industrial Transformation Research Hubs - Grant ID: IH210100048
Funder
Australian Research Council
Funding Amount
$4,980,000.00
Summary
ARC Industry Transformation Research Hub for Resilient and Intelligent Infrastructure Systems (RIIS) in Urban, Resources and Energy Sectors. RIIS will deliver transformational technologies to address Australia’s critical infrastructure needs. It will integrate advances in sensor technology, connectivity, data analytics, machine learning, robotics, smart materials, and reliable models to deliver resilient and adaptive infrastructure systems in urban, energy and resources sectors. All three sector ....ARC Industry Transformation Research Hub for Resilient and Intelligent Infrastructure Systems (RIIS) in Urban, Resources and Energy Sectors. RIIS will deliver transformational technologies to address Australia’s critical infrastructure needs. It will integrate advances in sensor technology, connectivity, data analytics, machine learning, robotics, smart materials, and reliable models to deliver resilient and adaptive infrastructure systems in urban, energy and resources sectors. All three sectors are critical to Australia's prosperity and well-being. It will engage with industry, government, and community to unlock scientific roadblock, deliver foundational skills, and translate research and development to commercial opportunities. Benefits include: improved productivity, competitiveness, resiliency, safety; growth, job creation; technological leadership, and export potential.Read moreRead less
Carbon-neutral copper: unlocking metal value through carbon sequestration. This project aims to explore how the concepts of reaction-induced porosity and coupled dissolution-reprecipitation reactions, which have had a profound impact in geosciences, can be exploited in the context of ore processing through carbon sequestration. The project's main outcomes are to generate a new process that maintains porosity in ore, and a combination of lixiviants, for effective Cu metal recovery and Fe capture. ....Carbon-neutral copper: unlocking metal value through carbon sequestration. This project aims to explore how the concepts of reaction-induced porosity and coupled dissolution-reprecipitation reactions, which have had a profound impact in geosciences, can be exploited in the context of ore processing through carbon sequestration. The project's main outcomes are to generate a new process that maintains porosity in ore, and a combination of lixiviants, for effective Cu metal recovery and Fe capture. This project will benefit the mineral industry by providing an alternative to the current paradigm in Copper mineral processing that requires the destruction of the mineral hosting economic value, thereby developing sustainable mining technologies well suited for the increasingly complex ores being extracted in Australia. Read moreRead less
The durability of geopolymeric products as a function of the nanostructured gel phase. A comprehensive physical, chemical and microscopic analysis will be conducted on a series of geopolymers and Ordinary Portland Cement samples manufactured from 1964 to 2001, with a focus on the characterisation of the nanostructured gel phase. The outcomes include (1) revealing the relationship between the nanostructured gel phase and durability; (2) the discovery of reaction mechanisms in geopolymerisation an ....The durability of geopolymeric products as a function of the nanostructured gel phase. A comprehensive physical, chemical and microscopic analysis will be conducted on a series of geopolymers and Ordinary Portland Cement samples manufactured from 1964 to 2001, with a focus on the characterisation of the nanostructured gel phase. The outcomes include (1) revealing the relationship between the nanostructured gel phase and durability; (2) the discovery of reaction mechanisms in geopolymerisation and formation of OPC; (3) computer modelling of nano-scale assemblies of atoms and molecules that will give desirable properties and durability, and (4) a tailored synthesis of geopolymers with vastly improved mechanical performance and acid, fire and bacterial resistance. This scientific understanding of long term durability will greatly enhance commercial acceptance of geopolymers.Read moreRead less
Passive biofiltration processes for nitrogen removal from polluted waters. Traditional urban wastewater treatment is energy and resource demanding. By combining principles of Water Sensitive Urban Design (WSUD) with advanced pollutant removal processes, we will create necessary knowledge to underpin development of novel sustainable urban water treatment systems. This project aims to understand and utilise Simultaneous Nitrification, Anammox and Denitrification (SNAD) processes within passive pla ....Passive biofiltration processes for nitrogen removal from polluted waters. Traditional urban wastewater treatment is energy and resource demanding. By combining principles of Water Sensitive Urban Design (WSUD) with advanced pollutant removal processes, we will create necessary knowledge to underpin development of novel sustainable urban water treatment systems. This project aims to understand and utilise Simultaneous Nitrification, Anammox and Denitrification (SNAD) processes within passive plant-soil-based biofilters for cost-effective removal of nitrogen from a range of polluted urban water sources. The project will open a potential for a new technological advancements in urban water management, while simultaneously providing benefits to the environment and community through greening and waterway protection.Read moreRead less