Additive manufacturing wear-resistant products for erosive environments. Additive manufacturing wear-resistant products for erosive environments. This project aims to develop technology to manufacture large scale, wear resistant components, involving new materials, computer-aided-design and direct hybrid manufacturing comprising laser additive and machining processes. The technology could produce more wear resistant components, using new iron-based powders, designed mesoscale graded structures a ....Additive manufacturing wear-resistant products for erosive environments. Additive manufacturing wear-resistant products for erosive environments. This project aims to develop technology to manufacture large scale, wear resistant components, involving new materials, computer-aided-design and direct hybrid manufacturing comprising laser additive and machining processes. The technology could produce more wear resistant components, using new iron-based powders, designed mesoscale graded structures and microscale reinforcing phases of appropriate morphology and size. The proposed approach is expected to lead to lower cost manufacturing mining products which perform better and have a lower environmental footprint, and more competitive Australian mining manufacturing operations.Read moreRead less
Mechanisms and innovative technologies for machining nanoscale multilayered thin film solar panels. This project addresses an important manufacturing bottleneck in the solar energy industry by addressing significant limitations in machining multilayered solar panels. A successful outcome will provide an important breakthrough in machining technology applicable not only to solar panels but other material science applications.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100016
Funder
Australian Research Council
Funding Amount
$490,000.00
Summary
Multi-scale fabrication facility for complex three-dimensional surface generation from nano to macro dimensions. This facility will support advances in the manufacturing of free-form surfaces with submicron features. Its unique characteristics, such as the universal profiling ability and nanometre accuracy across large dimensions, will enable many science and engineering innovations which are presently impossible to be realised in Australia.
Developing machining technologies for single crystal gallium oxide. Gallium oxide is a new semiconductor material that can be used to make diodes and transistors with lower loss than silicon (Si), and power electronic devices with lower cost and better performance than silicon carbide (SiC) and gallium nitride (GaN). This project aims to understand the nature of deformation and removal of this unique class of materials during machining. A successful outcome will not only develop an enabling mach ....Developing machining technologies for single crystal gallium oxide. Gallium oxide is a new semiconductor material that can be used to make diodes and transistors with lower loss than silicon (Si), and power electronic devices with lower cost and better performance than silicon carbide (SiC) and gallium nitride (GaN). This project aims to understand the nature of deformation and removal of this unique class of materials during machining. A successful outcome will not only develop an enabling machining technology for this next generation power semiconductor, but new understanding of machining and materials science will be generated.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100036
Funder
Australian Research Council
Funding Amount
$310,000.00
Summary
Super high speed grinding facility for difficult-to-machine materials and structures. This unique system will enable the manufacture of difficult-to-machine materials and structures with high quality and high productivity. It will support ground-breaking research activities across the country and help promote the strategic collaborations within Australian manufacturing society.