Ultrahigh strength maraging titanium alloys for additive manufacturing . This project aims to pioneer an unprecedented class of ultrahigh-strength titanium alloys for 3D printing by capitalising on both the alloy design theory of ultrahigh-strength steels and the unique capability of laser-based 3D printing. The planned research expects to significantly advance the knowledge base of advanced metallic materials and metal 3D printing via atomistic level characterisation and systematic mechanical p ....Ultrahigh strength maraging titanium alloys for additive manufacturing . This project aims to pioneer an unprecedented class of ultrahigh-strength titanium alloys for 3D printing by capitalising on both the alloy design theory of ultrahigh-strength steels and the unique capability of laser-based 3D printing. The planned research expects to significantly advance the knowledge base of advanced metallic materials and metal 3D printing via atomistic level characterisation and systematic mechanical property evaluation in relation to specifically tailored 3D printing conditions. Expected outcomes include a group of ultrahigh-strength novel titanium alloys for 3D printing and a new alloy design theory. This should provide significant benefits to the manufacturing industry to support the national economy and security.Read moreRead less
A transformational approach to enabling the low cost fabrication of intricate titanium components. The high production cost of titanium components has been the central issue that inhibits the large-scale industrial applications of titanium and its alloys, despite their outstanding properties. This project aims to develop an innovative titanium hydride injection moulding process to enable the fabrication of intricate titanium components at low cost while ensuring excellent mechanical properties. ....A transformational approach to enabling the low cost fabrication of intricate titanium components. The high production cost of titanium components has been the central issue that inhibits the large-scale industrial applications of titanium and its alloys, despite their outstanding properties. This project aims to develop an innovative titanium hydride injection moulding process to enable the fabrication of intricate titanium components at low cost while ensuring excellent mechanical properties. The outcomes have the potential to transform the current manufacturing practice of small intricate titanium components for wide industrial applications. In addition, the project aims to create and deliver new advanced manufacturing technologies and skills urgently needed by the Australian industries for lifting productivity and economic growth.Read moreRead less
Computational alloy design for cold spray deposition. The aim of this project is to design a new generation of proprietary, high performance alloys and composites that are optimised for cold spray deposition. Cold spray is a new manufacturing technology that is used to create coatings for enhancement, repair, restoration and for additive manufacturing. Using a systems approach and by integrating experiment with computational models, this project will generate new knowledge for enhanced materials ....Computational alloy design for cold spray deposition. The aim of this project is to design a new generation of proprietary, high performance alloys and composites that are optimised for cold spray deposition. Cold spray is a new manufacturing technology that is used to create coatings for enhancement, repair, restoration and for additive manufacturing. Using a systems approach and by integrating experiment with computational models, this project will generate new knowledge for enhanced materials design. Partnering with Ruag Australia, a leading Defence aerospace supplier, the project will deliver a practical tool for the accelerated design of metal powders for cold spray and invent commercially useful advanced materials to improve the competitiveness of Australian manufacturing industry.Read moreRead less
A fast, eco-friendly approach to the fabrication of low cost high performance titanium components. The purpose of this project is to develop an innovative manufacturing approach by which the cost of titanium components can be substantially reduced. This will significantly increase the commercial applications of titanium and its alloys.
Novel micro-architecture-optimised metal lattice structures by 3D printing. This project aims to research and develop a novel methodology for the design and 3D printing of micro-architectured intricate metal lattice structures that can markedly expand the boundaries of both metal property space and structural forms. This will be achieved by harnessing the synergies across topology design, manufacturing optimisation, and in-situ microstructure control. The expected outcomes are a novel milestone ....Novel micro-architecture-optimised metal lattice structures by 3D printing. This project aims to research and develop a novel methodology for the design and 3D printing of micro-architectured intricate metal lattice structures that can markedly expand the boundaries of both metal property space and structural forms. This will be achieved by harnessing the synergies across topology design, manufacturing optimisation, and in-situ microstructure control. The expected outcomes are a novel milestone methodology that will benefit Australia by enabling a new wave of innovation in materials design and 3D printing, and a new class of lightweight intricate metal lattice structures that potentially offer exceptional mechanical and/or biological properties for near-term commercial applications.Read moreRead less
Unlocking the potential of low-cost beta-titanium alloys by three-dimensional printing. This project aims to reshape the design and fabrication of beta-titanium (beta-Ti) alloys that offer ultrahigh tensile strength and significant high cycle fatigue strength. It will exploit three-dimensional printing to enable the full use of Iron (Fe) and Chromium (Cr) as beta-stabilizers for Ti without segregation leading to beta-fleck defects. The outcomes of this project are expected to fundamentally chang ....Unlocking the potential of low-cost beta-titanium alloys by three-dimensional printing. This project aims to reshape the design and fabrication of beta-titanium (beta-Ti) alloys that offer ultrahigh tensile strength and significant high cycle fatigue strength. It will exploit three-dimensional printing to enable the full use of Iron (Fe) and Chromium (Cr) as beta-stabilizers for Ti without segregation leading to beta-fleck defects. The outcomes of this project are expected to fundamentally change the design and fabrication of ultrahigh-strength beta-Ti alloys and to significantly extend the capabilities of metal three-dimensional printing, as well as advancing the knowledge base of both metal three-dimensional printing and Ti alloys. They further provide a strategic solution to the manufacture of other similar engineering alloys in the broad field of metals.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100003
Funder
Australian Research Council
Funding Amount
$280,000.00
Summary
Flexible forming facility for low cost light weight applications. Flexible forming facility for low-cost light-weight applications: This project will establish Australia’s first flexible roll forming facility. The facility will be unique in the world, being specifically designed to roll form the most advanced high strength alloys into complex three-dimensional shapes and investigate their material behaviour under a wide range of loading conditions. This technology represents a step change in com ....Flexible forming facility for low cost light weight applications. Flexible forming facility for low-cost light-weight applications: This project will establish Australia’s first flexible roll forming facility. The facility will be unique in the world, being specifically designed to roll form the most advanced high strength alloys into complex three-dimensional shapes and investigate their material behaviour under a wide range of loading conditions. This technology represents a step change in commercial processing and has the capacity to form materials with high strength and limited ductility. This will lead to the development of new techniques for the manufacture of new advanced materials including advanced high strength steels, composites, nano structured metals and light metal alloys for automotive and aerospace applications.Read moreRead less
Metal folding fundamentals to shape new corrugated building products . FormFlow has developed a ground-breaking forming process enabling the use of corrugated iron as a structural element. This is a step change for Australia`s steel and building industry and will provide a direct benefit to fireproofing homes. Up scaling of this new technology poses significant challenges due to the lack of understanding in the new forming process and the effect of pre-processing on the incoming material. Fundam ....Metal folding fundamentals to shape new corrugated building products . FormFlow has developed a ground-breaking forming process enabling the use of corrugated iron as a structural element. This is a step change for Australia`s steel and building industry and will provide a direct benefit to fireproofing homes. Up scaling of this new technology poses significant challenges due to the lack of understanding in the new forming process and the effect of pre-processing on the incoming material. Fundamental knowledge of material behaviour will be developed with advanced models that account for the unique process deformation conditions. The intended outcome includes computer software for process design and new concepts for part shape control to improve product quality, repeatability and enable high volume manufacture.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180101407
Funder
Australian Research Council
Funding Amount
$359,446.00
Summary
Three-dimensional metal printing based on controlled removal of self-assembled monolayers. This project aims to develop a unique approach for three-dimensional metal micro-printing based on controlled removal of self-assembled monolayers. The application of electro-deposition for three-dimensional metal printing is currently hindered by the incapacity of site-selective control of the deposition area. The project expects to produce a new three dimensional metal microprinting technology, with bene ....Three-dimensional metal printing based on controlled removal of self-assembled monolayers. This project aims to develop a unique approach for three-dimensional metal micro-printing based on controlled removal of self-assembled monolayers. The application of electro-deposition for three-dimensional metal printing is currently hindered by the incapacity of site-selective control of the deposition area. The project expects to produce a new three dimensional metal microprinting technology, with benefits to manufacturing industries, particularly those requiring production of micro/nano metallic components.Read moreRead less
A new class of titanium alloys developed for additive manufacturing. This project aims to develop a new class of (Ti-Cu)-based alloys featuring high strength, high toughness, and high hydrogen-embrittlement resistance specifically for additive manufacturing (AM). This project expects to generate new knowledge of grain refinement and phase transformations in dynamic temperature field of metal AM process and to solve the common weakness – strong mechanical anisotropy and poor fatigue life – of AM ....A new class of titanium alloys developed for additive manufacturing. This project aims to develop a new class of (Ti-Cu)-based alloys featuring high strength, high toughness, and high hydrogen-embrittlement resistance specifically for additive manufacturing (AM). This project expects to generate new knowledge of grain refinement and phase transformations in dynamic temperature field of metal AM process and to solve the common weakness – strong mechanical anisotropy and poor fatigue life – of AM Ti components. The expected outcomes include a whole set of processing maps of AM (Ti-Cu)-based alloys tailored to demanding applications. This should provide significant benefits to aerospace, marine and biomedical industries by delivering better durability, sustainability, and cost-effectiveness.Read moreRead less