Non-contact Integrity Assessment of Façade Panels of High-rise Buildings. Disintegration of the external façade (with tiles, plates, etc.) of high-rise buildings presents a great challenge and a threat to community. This project develops fundamental knowledge and algorithms that underpin the deployment of a new technique for fast and automated quantitative integrity assessment of façade units of high-rise buildings, integrating mechanisms of directional acoustic waves, vibro-acoustics of façade ....Non-contact Integrity Assessment of Façade Panels of High-rise Buildings. Disintegration of the external façade (with tiles, plates, etc.) of high-rise buildings presents a great challenge and a threat to community. This project develops fundamental knowledge and algorithms that underpin the deployment of a new technique for fast and automated quantitative integrity assessment of façade units of high-rise buildings, integrating mechanisms of directional acoustic waves, vibro-acoustics of façade tiles or panels, laser sensing technology, deep learning algorithms and drone technology. Outcomes of this project are critical for implementing the new technology for enhanced safety to community and the development of new procedures for driving down maintenance costs of the external façade of high-rise buildings.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100023
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Integrated command and control facility for large-scale critical infrastructure management. This is a test bed facility for achieving sustainable operation of Australia's critical infrastructure, particularly at airports. The facility will enable an integrated and coordinated strategy to increase operational resilience while not losing sight of the complex nature and dynamic requirements of critical infrastructure management.
Economical Particleboard Product from Hardwood Sawmill Waste for Domestic and Industrial Applications. The proposed project is aimed at developing a methodology to produce particleboard using hardwood saw-mill residue. Currently, 20% of logs used to produce sawn hardwood are disposed of by burning or as fertiliser. Using innovative concepts of high-moisture pressing and understanding composite material behaviour and internal dynamics during hot-pressing of particleboard, the proposed project wil ....Economical Particleboard Product from Hardwood Sawmill Waste for Domestic and Industrial Applications. The proposed project is aimed at developing a methodology to produce particleboard using hardwood saw-mill residue. Currently, 20% of logs used to produce sawn hardwood are disposed of by burning or as fertiliser. Using innovative concepts of high-moisture pressing and understanding composite material behaviour and internal dynamics during hot-pressing of particleboard, the proposed project will have a significant potential for revolutionising particleboard technology. Outcomes will be a significant contribution towards sustainability of the Australian Timber Industry and the environment by reducing logging for custom flaked softwood chips, which will be of significant benefit to regional and rural communities as well.Read moreRead less
Three-dimensional printing of structures using fibre reinforced geopolymer concrete. This project aims to investigate geopolymer binders for cement. Three-dimensional printing using concrete can eliminate expensive formwork but is hampered by a lack of underpinning theoretical material and structural research. Conventional Portland cement’s setting characteristics limit its use for three-dimensional (3D) printing. The project will develop a theoretical framework for the structural properties of ....Three-dimensional printing of structures using fibre reinforced geopolymer concrete. This project aims to investigate geopolymer binders for cement. Three-dimensional printing using concrete can eliminate expensive formwork but is hampered by a lack of underpinning theoretical material and structural research. Conventional Portland cement’s setting characteristics limit its use for three-dimensional (3D) printing. The project will develop a theoretical framework for the structural properties of the 3D printed concrete and flow of geopolymer binder through aggregate bed, and design a fibre reinforcement system. This project is expected to improve construction, reduce injury rates and create high-end technology-based jobs.Read moreRead less
Additive manufacturing of functionally graded geopolymers. This project aims to use contour crafting for three-dimensional printing of functionally graded geopolymer concrete. Contour crafting has been touted for producing uniform structural members made of conventional concrete mixtures. This project will develop the existing technique to produce microstructurally graded geopolymer structures and include functionally graded placement of fibre within a geopolymer matrix. It will investigate mech ....Additive manufacturing of functionally graded geopolymers. This project aims to use contour crafting for three-dimensional printing of functionally graded geopolymer concrete. Contour crafting has been touted for producing uniform structural members made of conventional concrete mixtures. This project will develop the existing technique to produce microstructurally graded geopolymer structures and include functionally graded placement of fibre within a geopolymer matrix. It will investigate mechanical, thermal and durability properties of printed composite structures. The outcome of this research could lead to cost-effective automated production of specialised structural components.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180101587
Funder
Australian Research Council
Funding Amount
$364,446.00
Summary
Three-dimensional printable geo-polymer with orientable fibres for construction application. This project aims to develop a fibre-reinforced geo-polymer for three-dimensional concrete printing (3DCP). 3DCP allows freeform construction without the use of expensive formwork, but is limited by the range of printable concretes and reinforcing methods. Geo-polymer is a sustainable material and has adjustable setting characteristics and better fibre-matrix interface properties than conventional cemen ....Three-dimensional printable geo-polymer with orientable fibres for construction application. This project aims to develop a fibre-reinforced geo-polymer for three-dimensional concrete printing (3DCP). 3DCP allows freeform construction without the use of expensive formwork, but is limited by the range of printable concretes and reinforcing methods. Geo-polymer is a sustainable material and has adjustable setting characteristics and better fibre-matrix interface properties than conventional cement. This project is expected to improve construction safety and costs.Read moreRead less
Will geopolymer concretes stand the test of time? In developing new 'green' materials to replace traditional, high-carbon dioxide cements and concretes, it is essential to show that the new materials will be at least as durable as the traditional options. This project will enable prediction of the durability of low-carbon dioxide geopolymer concrete, using laboratory tests, cutting-edge structural analysis and computations.
Evaluating potential static liquefaction of tailings to prevent failures. This project aims to reduce risk in the mining industry from failing mine tailings by producing a methodology for predicting the susceptibility of these tailings to static liquefaction. The impact of a mine tailing failure is catastrophic to the downstream community. The project brings together a number of industry partners committed to assisting with verification and adoption of characterisation and designed tools develop ....Evaluating potential static liquefaction of tailings to prevent failures. This project aims to reduce risk in the mining industry from failing mine tailings by producing a methodology for predicting the susceptibility of these tailings to static liquefaction. The impact of a mine tailing failure is catastrophic to the downstream community. The project brings together a number of industry partners committed to assisting with verification and adoption of characterisation and designed tools development in this project. This proposal will integrate results from laboratory element, centrifuge and calibration chamber tests with numerical modelling and in-situ tests to produce a methodology for predicting the susceptibility to static liquefaction.Read moreRead less
Fatigue life and biodegradation of biomass waste composites in roads. This project aims to develop a new low-carbon pavement stabilisation technology by utilising biomass waste composites in road subgrades and bases. This research expects to generate new knowledge on the performance of biomass composites in roads, when subjected to high traffic loads using experimental, numerical approaches and field trials. Expected project outcomes include evaluating the long-term performance of this new road ....Fatigue life and biodegradation of biomass waste composites in roads. This project aims to develop a new low-carbon pavement stabilisation technology by utilising biomass waste composites in road subgrades and bases. This research expects to generate new knowledge on the performance of biomass composites in roads, when subjected to high traffic loads using experimental, numerical approaches and field trials. Expected project outcomes include evaluating the long-term performance of this new road construction material, developing predictive models and building enduring collaborations with industry. Benefits include: diversion of wastes from landfills, reduction in greenhouse gas emissions and the potential for commercial applications of biomass waste composites in future roads.Read moreRead less
Harnessing renewable energy from low-carbon geothermal pavements. This project aims to investigate the extraction of renewable energy from new pavements constructed with low-carbon recycled demolition wastes. The proposed research will generate new knowledge on the thermo-geomechanical responses of pavements when harvesting heat energy under dynamic loads, using experimental and numerical approaches, including field trials. The outcomes and benefits will include strategic long-term collaboration ....Harnessing renewable energy from low-carbon geothermal pavements. This project aims to investigate the extraction of renewable energy from new pavements constructed with low-carbon recycled demolition wastes. The proposed research will generate new knowledge on the thermo-geomechanical responses of pavements when harvesting heat energy under dynamic loads, using experimental and numerical approaches, including field trials. The outcomes and benefits will include strategic long-term collaboration with industry to develop ‘Geothermal Pavements’, with potential for commercial applications. The translation of this research will contribute to meeting future energy needs, while significantly reducing carbon emissions and diverting demolition wastes from landfills.Read moreRead less