Fire resistance of complex light gauge steel framed wall systems. This project aims to investigate the thermal and structural behaviour of high-strength Light gauge Steel Framed (LSF) wall systems when exposed to fire, and develop a generic model for predicting fire resistance levels of all LSF wall systems. Plasterboard-lined LSF walls are increasingly used as cost-effective load-bearing walls in low and mid-rise buildings worldwide. This has required new wall designs with complex steel stud wa ....Fire resistance of complex light gauge steel framed wall systems. This project aims to investigate the thermal and structural behaviour of high-strength Light gauge Steel Framed (LSF) wall systems when exposed to fire, and develop a generic model for predicting fire resistance levels of all LSF wall systems. Plasterboard-lined LSF walls are increasingly used as cost-effective load-bearing walls in low and mid-rise buildings worldwide. This has required new wall designs with complex steel stud wall configurations, but their fire resistance is not understood. This project will provide validated fire resistance data and fire design methods for a proposed national Fire Design Handbook and steel design codes, enabling more widespread, safer use of these walls. This will benefit the Australian steel industry, the construction industry and the community.
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Light steel roof and wall systems under combined wind and bushfire actions. The project aims to investigate the complex behaviour of light cold-formed-steel roof and wall systems involving localized failures under the combined action of wind and bushfire using wind suction tests at elevated temperatures combined with advanced numerical modelling. It will generate new knowledge of the behaviour and strength of cold-formed-steel roof and wall systems under bushfire conditions. Expected outcomes in ....Light steel roof and wall systems under combined wind and bushfire actions. The project aims to investigate the complex behaviour of light cold-formed-steel roof and wall systems involving localized failures under the combined action of wind and bushfire using wind suction tests at elevated temperatures combined with advanced numerical modelling. It will generate new knowledge of the behaviour and strength of cold-formed-steel roof and wall systems under bushfire conditions. Expected outcomes include new design models for wind, bushfire and cold-formed-steel Standards. This will significantly improve the bushfire safety of buildings, since non-combustible steel roof and wall systems are used as building envelopes in bushfire prone areas, but are not designed to withstand recently discovered bushfire-enhanced winds.Read moreRead less
Enhancing the fire and energy ratings of cold-formed steel wall systems. This project intends to develop novel cold-formed light-gauge steel frame (LSF) wall systems with superior fire resistance and energy ratings for use in buildings. LSF systems are increasingly used in homes and offices. The project plans to investigate fundamental thermal, structural and energy performances of LSF walls and their components using experimental and numerical studies. It plans to develop enhanced plasterboards ....Enhancing the fire and energy ratings of cold-formed steel wall systems. This project intends to develop novel cold-formed light-gauge steel frame (LSF) wall systems with superior fire resistance and energy ratings for use in buildings. LSF systems are increasingly used in homes and offices. The project plans to investigate fundamental thermal, structural and energy performances of LSF walls and their components using experimental and numerical studies. It plans to develop enhanced plasterboards, insulations and innovative composite panels using suitable nanomaterials, chemical additives, fillers and phase-change materials and use these with innovative wall configurations to significantly improve the fire and energy performance of LSF walls. The new wall systems may increase occupant comfort and safety, reduce business losses in fires, and lead to low-energy buildings.Read moreRead less
Large-volume gradient materials: Manufacturing and deformation mechanism. This project aims to develop a low-cost and high productivity process to produce large-volume metals with high strength and good ductility, suitable for engineering application. Ultrafine grained (UFG) materials and nano-grained (NG) materials are usually strong, but not very ductile. This project will use an accumulative skin-pass rolling (ASPR) technique to fabricate the metallic strips with gradient structure. The numer ....Large-volume gradient materials: Manufacturing and deformation mechanism. This project aims to develop a low-cost and high productivity process to produce large-volume metals with high strength and good ductility, suitable for engineering application. Ultrafine grained (UFG) materials and nano-grained (NG) materials are usually strong, but not very ductile. This project will use an accumulative skin-pass rolling (ASPR) technique to fabricate the metallic strips with gradient structure. The numerical simulations developed in the project are expected to contribute to understanding the deformation mechanism of gradient materials.Read moreRead less
Ultra-lightweight alloys with unique multi-dimensional property profiles. Lightweight alloys with high specific-strength are an essential prerequisite in modern and future technologies. To be useful, they must also possess ductility and inherent corrosion resistance. The latter two properties, however, are inversely correlated with strength. This project proposes to break this paradox - not only in terms of a paradigm change regarding multi-property alloy design - but as applied to the most ligh ....Ultra-lightweight alloys with unique multi-dimensional property profiles. Lightweight alloys with high specific-strength are an essential prerequisite in modern and future technologies. To be useful, they must also possess ductility and inherent corrosion resistance. The latter two properties, however, are inversely correlated with strength. This project proposes to break this paradox - not only in terms of a paradigm change regarding multi-property alloy design - but as applied to the most lightweight engineering alloy system in existence, Magnesium-Lithium (Mg-Li), for which the impact on specific properties is immense. The aim is to develop ultra-lightweight Mg-Li based alloys with formidable property profiles via alloy design and thermomechanical processing. The expected outcome is a new class of structural corrosion resistant metal.Read moreRead less
Flexible roll forming of advanced high strength steel sheet . This project will develop light weight automotive components to assist fuel economy and crash worthiness through flexible roll forming. This process has the potential to form complex shapes from very high strength steels in a very cost effective and efficient small scale operation, highly suited to Australian manufacturing.
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.
Reducing the environmental impact of steel making through direct strip casting. This project will investigate direct strip casting of steel, a technology that reduces the environmental footprint of liquid steel processing by up to 90 per cent. With the industry partner Baosteel, the project hopes to expand the application of this process to more steel grades and to also assess possible new steel grades with improved properties.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100123
Funder
Australian Research Council
Funding Amount
$190,000.00
Summary
Quench and deformation dilatometer for studying phase transformations. Quench and deformation dilatometer for studying phase transformations: The quenching and deformation dilatometer is a high precision thermal analysis tool used to measure phase transformations in situ. This technique can make time-resolved measurements of transformations under the extreme conditions of heating, cooling and deformation that are experienced during industrial processing. This instrument will be the only one in A ....Quench and deformation dilatometer for studying phase transformations. Quench and deformation dilatometer for studying phase transformations: The quenching and deformation dilatometer is a high precision thermal analysis tool used to measure phase transformations in situ. This technique can make time-resolved measurements of transformations under the extreme conditions of heating, cooling and deformation that are experienced during industrial processing. This instrument will be the only one in Australia capable of temperature changes above 2000 degrees Celsius and will also be the only one equipped with a cryogenic module. The instrument is intended to be used to characterise new processing technologies and new alloy systems such as advanced high strength steels, age hardenable magnesium, high entropy alloys, and cluster hardening aluminium alloys.Read moreRead less
Micro-roll forming of metal bipolar plates for fuel cells. This project aims to develop a novel forming technology for the production of metal bipolar plates for fuel cells: micro-roll forming. This poses a number of challenges particularly due to the low material thickness to be formed. These challenges include the development of advanced models that account for size effects in the process and represent the unique deformation conditions and material fracture behaviour. The project plans to prod ....Micro-roll forming of metal bipolar plates for fuel cells. This project aims to develop a novel forming technology for the production of metal bipolar plates for fuel cells: micro-roll forming. This poses a number of challenges particularly due to the low material thickness to be formed. These challenges include the development of advanced models that account for size effects in the process and represent the unique deformation conditions and material fracture behaviour. The project plans to produce prototypes and to compare part complexity with that achievable by conventional micro stamping. The intended outcome of the project includes advanced computer models for process design and the new micro-forming technology validated through extensive laboratory and plant trials.Read moreRead less