Development of highly formable magnesium sheet. This project will develop alloy and processing technologies that can be used to fabricate lighter and better performing magnesium products. These magnesium products can improve fuel efficiency, resulting in lower emission and environmental pollution.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100155
Funder
Australian Research Council
Funding Amount
$648,000.00
Summary
NanoMin; Quantitative Mineral Mapping of Nanoscale Processes. NanoMin: quantitative mineral mapping of nanoscale processes:
The project seeks to establish an electron microscope-based mineral mapping and analysis facility to provide rapid, quantitative and statistically reliable mineralogical, petrographic and metallurgical data unobtainable by other means in fine-grained materials. The proposed equipment can identify minerals in complex mixtures of sub-µm-grain size materials by virtue of an i ....NanoMin; Quantitative Mineral Mapping of Nanoscale Processes. NanoMin: quantitative mineral mapping of nanoscale processes:
The project seeks to establish an electron microscope-based mineral mapping and analysis facility to provide rapid, quantitative and statistically reliable mineralogical, petrographic and metallurgical data unobtainable by other means in fine-grained materials. The proposed equipment can identify minerals in complex mixtures of sub-µm-grain size materials by virtue of an integrated software and hardware system called NanoMin which incorporates a spectral deconvolution engine combined with a mineral spectra database. A key limitation in understanding complex materials is sub-micron to nanometer scale spatial variability of mineralogical phases. Imaging and quantifying these phases is now possible with the NanoMin system. This promises to open up petrological, geobiological, and materials science research in complex fine-grained materials.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100094
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Selective laser melting - an advanced manufacturing and physical modelling technology for the digital age. Selective laser melting is a new manufacturing technology that creates parts layer by layer directly from a computer model, eliminating the need for tooling or machining. This technology will be applied to a diverse range of research areas from producing the next generation of medical implants and devices to improving our understanding of geo-materials.
Industrial Transformation Training Centres - Grant ID: IC160100027
Funder
Australian Research Council
Funding Amount
$4,340,802.00
Summary
ARC Training Centre for Biopharmaceutical Innovation. ARC Training Centre for Biopharmaceutical Innovation. This centre aims to transform Australia’s growing biopharmaceutical industry, an advanced manufacturing capability, by training specialist biotechnologists and bioengineers. It expects the research and development outputs will create new biopharmaceuticals and antibody-based reagents, enhanced production methods, improved manufacturing capabilities and a cohort of specialist scientists. Ne ....ARC Training Centre for Biopharmaceutical Innovation. ARC Training Centre for Biopharmaceutical Innovation. This centre aims to transform Australia’s growing biopharmaceutical industry, an advanced manufacturing capability, by training specialist biotechnologists and bioengineers. It expects the research and development outputs will create new biopharmaceuticals and antibody-based reagents, enhanced production methods, improved manufacturing capabilities and a cohort of specialist scientists. New biopharmaceuticals are expected to benefit the Australian economy and provide new therapeutic options for better health outcomes. Industry-driven research projects will also provide industry-ready graduates who can drive future growth in the sector.Read moreRead less
Cellulosic and paper-based biosensors for blood analysis. Testing the blood compatibility of an Australian evacuated for surgery; measuring the iron content from India for anemia treatment; identifying the outbreak of malaria in Pakistan; measuring prostate specific antigen/blood screening in your home. These are novel applications for paper biosensors, which will improve health and create new jobs in Australia.
Plasma-soft tissue interactions: advancing a new era of plasma technologies. This project aims to develop the prerequisite knowledge to underpin new plasma technologies. Specifically, the project plans to provide new insight into the interaction between ionised gas plasma jets and biological soft tissue. It plans to use advanced analytical techniques and modelling simulations to investigate the physics of the plasma jet and processes occurring at the jet–tissue interface. It also plans to use (b ....Plasma-soft tissue interactions: advancing a new era of plasma technologies. This project aims to develop the prerequisite knowledge to underpin new plasma technologies. Specifically, the project plans to provide new insight into the interaction between ionised gas plasma jets and biological soft tissue. It plans to use advanced analytical techniques and modelling simulations to investigate the physics of the plasma jet and processes occurring at the jet–tissue interface. It also plans to use (bio)engineered tissue targets, chemical, biological and cellular assays to probe the transport and effects of plasma reactive species deep within tissue. This new knowledge would enable the development of new plasma sources and protocols for applications in health, medicine, biotechnology and manufacturing.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100175
Funder
Australian Research Council
Funding Amount
$347,070.00
Summary
Three-dimensional additive bio-fabrication facility: printing bioprinters. This project aims to develop bioprinting systems that will provide new insights into fundamental biological processes. The 3D Additive Bio-Fabrication Facility - Printing Bioprinters capability will use 3D polymer and metal additive manufacturing technologies to create the next generation of bioprinting methodologies and 3D fabrication tools. It is the aim that these customised additive manufacturing systems will be used ....Three-dimensional additive bio-fabrication facility: printing bioprinters. This project aims to develop bioprinting systems that will provide new insights into fundamental biological processes. The 3D Additive Bio-Fabrication Facility - Printing Bioprinters capability will use 3D polymer and metal additive manufacturing technologies to create the next generation of bioprinting methodologies and 3D fabrication tools. It is the aim that these customised additive manufacturing systems will be used to produce structures wherein living cells are spatially organised in combination with appropriate biomaterials and bioactive components, such as drugs or growth factors, in order to influence subsequent biological behaviour.Read moreRead less
Finite element and optimization methods for creating complex structure in additive manufacturing. Additive manufacture based on five-axis focused ion beam is a novel manufacturing technology, which has some outstanding properties such as low pollution, no machining, net shape, high efficiency, and high precision characteristics. It produces much less waste as it adds materials, rather than subtracting. This project focuses on developing powerful finite element and topology optimisation method fo ....Finite element and optimization methods for creating complex structure in additive manufacturing. Additive manufacture based on five-axis focused ion beam is a novel manufacturing technology, which has some outstanding properties such as low pollution, no machining, net shape, high efficiency, and high precision characteristics. It produces much less waste as it adds materials, rather than subtracting. This project focuses on developing powerful finite element and topology optimisation method for analysis and design of complex structures in five-axis focused ion beam (or direct laser rapid sintering) based additive manufacturing. The success of this project may benefit Australian manufacturing industry for promoting and developing this emerging and disruptive technology.Read moreRead less
Sustainability Cockpit: an integrated tool for assessment and improvement of sustainability in manufacturing. This project aims to understand the relation between the traditional business indicators, such as cost, and the environmental indicators, such as carbon footprint. The outcome of this project will be an integrated tool which will allow manufacturers to assess and improve their environmental footprint in a cost effective manner.
Understanding the role of nanoparticles in water based lubrication. This project seeks to understand the role of nanoparticles in the lubrication of hot strip rolling and then to develop novel nano-additive water-based lubricants to solve a long-standing issue for the steel-making industry. Lubrication significantly affects the surface quality of hot-rolled strips, roll wear and energy consumption in the steel-making industry. Currently, oil-based lubricants are used. However, their lubricant ef ....Understanding the role of nanoparticles in water based lubrication. This project seeks to understand the role of nanoparticles in the lubrication of hot strip rolling and then to develop novel nano-additive water-based lubricants to solve a long-standing issue for the steel-making industry. Lubrication significantly affects the surface quality of hot-rolled strips, roll wear and energy consumption in the steel-making industry. Currently, oil-based lubricants are used. However, their lubricant effect is considerably reduced by the use of high pressure cooling water, and the waste discharge is of environmental concern. Successful outcomes for the project are expected to improve product quality and reduce resource use.Read moreRead less