Improving the process modelling capability for manufacturing large composite structures used on passenger aircraft. This proposal aims to reduce manufacturing costs by developing innovative simulation tools for the production of future lightweight composite aerostructures.The development of a reliable predictive tool to simulate the cost-effective production of resin-infused composite aerostructures, will represent a significant technical advance. The successful transfer of this technology to Bo ....Improving the process modelling capability for manufacturing large composite structures used on passenger aircraft. This proposal aims to reduce manufacturing costs by developing innovative simulation tools for the production of future lightweight composite aerostructures.The development of a reliable predictive tool to simulate the cost-effective production of resin-infused composite aerostructures, will represent a significant technical advance. The successful transfer of this technology to Boeing Aerostructures Australia would give it a distinct competitive edge when bidding for participation in future international development programmes and will yield substantial economic benefits whilst further strengthening and developing local expertise. Lightweight aircraft structures will also contribute towards reducing the environmental impact of aviation. Read moreRead less
Optimisation of self-healing repair systems in aerospace composite structures. Design and manufacture of composite structures for civilian and military aircraft is a multi-billion dollar export business for Boeing Aerostructures Australia and other Australian aerospace companies. To remain globally competitive, Australian industry must develop new expertise for next-generation composite aerostructures that are lighter, cheaper, more damage tolerant and easily repaired. Autonomic self-healing of ....Optimisation of self-healing repair systems in aerospace composite structures. Design and manufacture of composite structures for civilian and military aircraft is a multi-billion dollar export business for Boeing Aerostructures Australia and other Australian aerospace companies. To remain globally competitive, Australian industry must develop new expertise for next-generation composite aerostructures that are lighter, cheaper, more damage tolerant and easily repaired. Autonomic self-healing of composites is an innovative repair technology with many future potential applications for damaged aerostructures. This project will develop analytical tools and data to enable the Australian aerospace industry to take advantage of the economic benefits offered by self-healing repair systems in aircraft composite structures.Read moreRead less
Onset Theory: Pushing the design envelope for textile composite structures. This study aims to exploit an innovative physics-based approach to predict the strength of textile composites. This is particularly important in areas such as aircraft design, where drastic weight savings are needed to allow designers to remain competitive in a low-carbon future. Improved theory and design tools will remove conservatism and account for a large part of these weight savings. The new approach is the first t ....Onset Theory: Pushing the design envelope for textile composite structures. This study aims to exploit an innovative physics-based approach to predict the strength of textile composites. This is particularly important in areas such as aircraft design, where drastic weight savings are needed to allow designers to remain competitive in a low-carbon future. Improved theory and design tools will remove conservatism and account for a large part of these weight savings. The new approach is the first to be consistent at all length scales — from atoms to aeroplanes — ensuring relevance for new and evolving composite material systems. A novel understanding of crack initiation in textile laminates is intended to reduce design and certification effort for new aircraft and help to design more efficient airframes at a lower cost.Read moreRead less
Thermoforming Mechanisms for Cost-effective Manufacturing of Advanced Composite Structures. The cost barrier in thermoforming, due to the lack of understanding of shear deformation and wrinkling, has inhibited the large-scale application of fibre-reinforced composite structures in aerospace and automobile industries. This project aims to develop a cost-effective diaphragm thermoforming process through an in-depth understanding of the thermoforming mechanisms. The outcomes will include novel theo ....Thermoforming Mechanisms for Cost-effective Manufacturing of Advanced Composite Structures. The cost barrier in thermoforming, due to the lack of understanding of shear deformation and wrinkling, has inhibited the large-scale application of fibre-reinforced composite structures in aerospace and automobile industries. This project aims to develop a cost-effective diaphragm thermoforming process through an in-depth understanding of the thermoforming mechanisms. The outcomes will include novel theories for thermoforming, a standard method for material property characterization and new finite element models compatible with the most popular software available for industry. The project will form the basis for establishing the effective production window and enhance greatly the competitive edge of the Australian manufacturing industry.Read moreRead less
AM of MAX Phase parts for applications in extreme environments. This project aims to develop techniques to synthesize MAX Phase compound materials in-situ using laser additive manufacturing. The project expects to increase jet engine fuel efficiency and thrust, and to fabricate longer-lasting parts for supersonic speed applications. The expected outcomes include well-developed additive manufacturing processes to make high performance engineering components with shape complexity for extreme envir ....AM of MAX Phase parts for applications in extreme environments. This project aims to develop techniques to synthesize MAX Phase compound materials in-situ using laser additive manufacturing. The project expects to increase jet engine fuel efficiency and thrust, and to fabricate longer-lasting parts for supersonic speed applications. The expected outcomes include well-developed additive manufacturing processes to make high performance engineering components with shape complexity for extreme environment applications, and new methods to increase the 3D printability of brittle materials. This should provide significant benefits to aerospace and defense industries through solving their long standing bottleneck material and processing problems. The outcomes also enhance Australia’s manufacturing capacity.Read moreRead less
Optimised flush repairs for dissimilar composite material systems. The outcome of this research project will overcome a major technological challenge when designing repairs for dissimilar composite material systems, which are being utilised at an increasing pace in a multitude of industries. This new technological capability will help to improve the competitiveness of the Australian aerospace industry.
Designer microstructures through cold spray powder deposition. Additive manufacturing routes are very attractive in terms of reduced material usage and shorter lead times. This project will look at opportunities for the expansion of one such process (cold spray) from surfacing using a single powder feedstock to three-dimensional construction of multi-powder mixtures into high performance components.
Experimental validation of the strain invariant failure theory for carbon/epoxy composites. The project will be of national and international benefit, through providing a validated, enhanced design capability for advanced composite materials. Greater depth of understanding of such materials will allow more efficient structures to be designed in applications requiring high strength and stiffness, low weight, and resistance to corrosion and fatigue. Such applications include the aerospace, offshor ....Experimental validation of the strain invariant failure theory for carbon/epoxy composites. The project will be of national and international benefit, through providing a validated, enhanced design capability for advanced composite materials. Greater depth of understanding of such materials will allow more efficient structures to be designed in applications requiring high strength and stiffness, low weight, and resistance to corrosion and fatigue. Such applications include the aerospace, offshore and mining industries. There are, therefore, far-reaching benefits in industries important to Australia. In addition, the reputation of the Australian aerospace research industry will be promoted through a collaborative association with Boeing, a world leader in development of commercial aircraft.Read moreRead less
Photochemical Design of Microstructured Aerospace Materials. Commercial aviation and shipping spend over US$300 billion on fuel and emit almost 3 billion tonnes of carbon dioxide annually at an enormous environmental cost. This project will provide the material chemistry innovation basis for the production of drag reduction surfaces that can be applied to enable a more effective airflow over an aircraft, thus reducing fuel consumption. Critically, the material design approach will not only deliv ....Photochemical Design of Microstructured Aerospace Materials. Commercial aviation and shipping spend over US$300 billion on fuel and emit almost 3 billion tonnes of carbon dioxide annually at an enormous environmental cost. This project will provide the material chemistry innovation basis for the production of drag reduction surfaces that can be applied to enable a more effective airflow over an aircraft, thus reducing fuel consumption. Critically, the material design approach will not only deliver a high performance coating for the production of drag reduction surfaces, but allow these surfaces to be tailored to specific application profiles including UV resistance and anti-fouling properties. The project will place an Australian company at the forefront of drag reduction technologyRead moreRead less
Hybrid additive manufacturing of critical metallic components. This project aims to combine world-class expertise and facilities to deliver on-demand and advanced alloy components produced by revolutionary hybrid additive manufacturing technology, along with applicable processing parameters and post-process schemes for fabricating high-performance metal products for space and aerospace applications. The intended outcomes of this project include the delivery of a knowledge platform for fabricatin ....Hybrid additive manufacturing of critical metallic components. This project aims to combine world-class expertise and facilities to deliver on-demand and advanced alloy components produced by revolutionary hybrid additive manufacturing technology, along with applicable processing parameters and post-process schemes for fabricating high-performance metal products for space and aerospace applications. The intended outcomes of this project include the delivery of a knowledge platform for fabricating alloy parts that have unprecedented high-temperature mechanical properties and environmental performance and providing significant benefits for the industry partner to establish its international portfolio of high-profit products.Read moreRead less