Surface reaction kinetics of zinc gas relevant to the ZINCALUME coating process. The proposed project aims to develop a sound understanding of the mechanism and rate of condensation of zinc vapour on clean and partially oxidised steel strip surfaces. This Fundamental scientific knowledge is the key to furthering our understanding of the effect of process variables on the occurrence of pinholes and bare patches on ZINCALUME coated steel strip. Should the fundamental causes of defect formation be ....Surface reaction kinetics of zinc gas relevant to the ZINCALUME coating process. The proposed project aims to develop a sound understanding of the mechanism and rate of condensation of zinc vapour on clean and partially oxidised steel strip surfaces. This Fundamental scientific knowledge is the key to furthering our understanding of the effect of process variables on the occurrence of pinholes and bare patches on ZINCALUME coated steel strip. Should the fundamental causes of defect formation be established, product quality can be improved, process costs reduced and the Australian industry's competitive position in the market place retained. A new experimental approach will be taken; conductive to the training of the researchers involved in advanced research techniques.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775499
Funder
Australian Research Council
Funding Amount
$130,000.00
Summary
High Performance Optical Profilometer for mapping micro/meso/macroscopic topography. Developing advanced, high performance new materials requires an understanding of surfaces and interfaces. Making a small area, low yield material or device is a regular occurrence within the Australian research community. The ability to create reproducible, high yield materials requires greater understanding of the stresses, uniformities and deformations in a material over large areas. The proposed instrument ....High Performance Optical Profilometer for mapping micro/meso/macroscopic topography. Developing advanced, high performance new materials requires an understanding of surfaces and interfaces. Making a small area, low yield material or device is a regular occurrence within the Australian research community. The ability to create reproducible, high yield materials requires greater understanding of the stresses, uniformities and deformations in a material over large areas. The proposed instrument can measure topography over many centimeters-squared with sub-micron spatial resolution, currently beyond the capabilities of researchers in Australia. By providing a quantitative method to measure surface textures, the instrument will also support Australian industries looking for improved process control.Read moreRead less
ARC Centre of Excellence - Design in Light Metals. Under the national Light Metals Action Agenda, Australia recognizes a strategic interest in the production, processing and applications of the light metals, and a growth in global markets for light metals technology. Light metals research is a designated national priority, and this Centre will provide the national focus in strategic fundamental research, the critical level of investment and the level of innovation necessary to achieve competiti ....ARC Centre of Excellence - Design in Light Metals. Under the national Light Metals Action Agenda, Australia recognizes a strategic interest in the production, processing and applications of the light metals, and a growth in global markets for light metals technology. Light metals research is a designated national priority, and this Centre will provide the national focus in strategic fundamental research, the critical level of investment and the level of innovation necessary to achieve competitive advantage from an outstanding research base. As a major contributor to a strategic network of national research capabilities, it will underpin substantial developments in the light metals industry nationally and globally, and extend linkages with major research centres internationally.Read moreRead less
Intelligent Materials Processing: Microstructure And Texture Control In Bcc Metals. In Australia, steel companies are continuing to search for cost effective steel compositions and processing routes. Concurrently, applications for Ti alloys in chemical, medical and aerospace industries are continuing to widen. As an outcome of this project, the basis for the optimisation of processing routes in order to achieve enhanced product properties at lower cost will be established. In the course of this ....Intelligent Materials Processing: Microstructure And Texture Control In Bcc Metals. In Australia, steel companies are continuing to search for cost effective steel compositions and processing routes. Concurrently, applications for Ti alloys in chemical, medical and aerospace industries are continuing to widen. As an outcome of this project, the basis for the optimisation of processing routes in order to achieve enhanced product properties at lower cost will be established. In the course of this work, a new model for the prediction of microstructure and texture evolution during recrystallisation will be developed and new process routes will be designed. Read moreRead less
Dynamically responding metals: a new generation of engineering alloys. The manufacture of engineering metals is a major Australian industry and the worldwide metal manufacturing sector is estimated to be worth $1 trillion USD per annum. Advanced materials and, particularly the light metals, are both designated national research priority areas. The availability of new classes of metals with greatly improved combinations of properties will profoundly affect not only metal use by existing industry, ....Dynamically responding metals: a new generation of engineering alloys. The manufacture of engineering metals is a major Australian industry and the worldwide metal manufacturing sector is estimated to be worth $1 trillion USD per annum. Advanced materials and, particularly the light metals, are both designated national research priority areas. The availability of new classes of metals with greatly improved combinations of properties will profoundly affect not only metal use by existing industry, through the introduction of new, stronger and safer metal grades, but also allows for new engineering designs which will lead, for example, to lighter and more efficient automobiles and more sustainable construction.Read moreRead less
Tribological contact of work roll in hot rolling. Steel and aluminium manufacturers form their products by shaping a hot metal billet using, for example, presses and rollers which contact the rapidly cooling metal in the production line. The economic benefits of lubrication, reduced rolling force (up to 25%), reduced roll wear and extended roll life (up to 40%), reduced down time due to roll change, and better strip quality are very significant for these manufacturing processes. This comprehens ....Tribological contact of work roll in hot rolling. Steel and aluminium manufacturers form their products by shaping a hot metal billet using, for example, presses and rollers which contact the rapidly cooling metal in the production line. The economic benefits of lubrication, reduced rolling force (up to 25%), reduced roll wear and extended roll life (up to 40%), reduced down time due to roll change, and better strip quality are very significant for these manufacturing processes. This comprehensive program will provide new knowledge on lubrication and roll wear to help Australian manufacturing industry (e.g. steel and aluminium) to better understand and optimise their processes to achieve maximum benefits.Read moreRead less
INVESTIGATION OF THE EFFECT OF ALLOYING ELEMENTS ON SHEAR BAND FORMATION DURING THE WARM ROLLING OF LOW CARBON AND INTERSTITIAL FREE STEELS. This proposal involves the application of three dimensional atom probe field ion microscopy and advanced transmission electron microscopy techniques to study the phenomena of precipitation and solute atoms' interactions with dislocations in warm rolled low carbon steels and interstitial free steels. It is intended to examine the effect of alloying addition ....INVESTIGATION OF THE EFFECT OF ALLOYING ELEMENTS ON SHEAR BAND FORMATION DURING THE WARM ROLLING OF LOW CARBON AND INTERSTITIAL FREE STEELS. This proposal involves the application of three dimensional atom probe field ion microscopy and advanced transmission electron microscopy techniques to study the phenomena of precipitation and solute atoms' interactions with dislocations in warm rolled low carbon steels and interstitial free steels. It is intended to examine the effect of alloying additions on in-grain shear bands formation, texture formation and formability of warm rolled and annealed low carbon steels. Ultimately, the project is concerned with developing of fundamental understanging of solute interactions which provide an improved basis for design of these economically significant steels.Read moreRead less
MICROFORMING: effects of microstructural scale on metal formability. Microforming is a rapidly growing industry, and already enjoys considerable activity in Germany, Japan, the US, and Korea, all of which are major trading partners of Australia. This project couples fundamental insight into the effects of microstructural and geometric scale with the frontier technology of microforming. Thus, the project will place Australian researchers at the frontier of microforming research, with the capacity ....MICROFORMING: effects of microstructural scale on metal formability. Microforming is a rapidly growing industry, and already enjoys considerable activity in Germany, Japan, the US, and Korea, all of which are major trading partners of Australia. This project couples fundamental insight into the effects of microstructural and geometric scale with the frontier technology of microforming. Thus, the project will place Australian researchers at the frontier of microforming research, with the capacity to be involved in shaping the industry. In the course of this work, new process routes will be developed, new materials may be created, and new opportunities will certainly emerge.Read moreRead less
ENHANCED PERFORMANCE OF AUTOMOTIVE SHEET ALLOYS VIA CONTROL OF COMPOSITION, THERMAL PROCESSING AND NANOSTRUCTURE. This project involves characterisation using modern facilities of the form and identity of atomic-scale clusters of alloying elements in selected automotive sheet alloys that have been subjected to single and multiple ageing treatments and examination and modelling of deformation mechanisms and behaviour in such alloys. The aim is to establish the precise role of clusters of solute a ....ENHANCED PERFORMANCE OF AUTOMOTIVE SHEET ALLOYS VIA CONTROL OF COMPOSITION, THERMAL PROCESSING AND NANOSTRUCTURE. This project involves characterisation using modern facilities of the form and identity of atomic-scale clusters of alloying elements in selected automotive sheet alloys that have been subjected to single and multiple ageing treatments and examination and modelling of deformation mechanisms and behaviour in such alloys. The aim is to establish the precise role of clusters of solute atoms and vacancies in the formation of precipitate phases that control the final strength and deformation behaviour of the alloys, and to provide useful guidelines for further improvements in strength of these alloys via the control of alloy composition and of multiple ageing treatments.Read moreRead less
Competitive nucleation and growth during rapid solidification of steel. This research will assist in maintaining Australia at the forefront of research into strip casting of steel. Fundamental understanding and new modelling capabilities will help to promote the take-up of this energy/emission/cost efficient revolutionary process. It will furthermore provide, through the development of a novel experimental technique, new research capabilities for Australian researchers in other fields such as ra ....Competitive nucleation and growth during rapid solidification of steel. This research will assist in maintaining Australia at the forefront of research into strip casting of steel. Fundamental understanding and new modelling capabilities will help to promote the take-up of this energy/emission/cost efficient revolutionary process. It will furthermore provide, through the development of a novel experimental technique, new research capabilities for Australian researchers in other fields such as rapid solidification of advanced materials, e.g. hard magnets and thermoelectric alloys.Read moreRead less