Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100070
Funder
Australian Research Council
Funding Amount
$241,500.00
Summary
Automated Fibre Braiding Facility for Multifunctional Structural Materials. Automated fibre braiding facility for multifunctional structural materials:
This project seeks to establish an Australian automated braiding facility to create innovative fibrous materials with multiple functionalities. This facility aims to provide Australian researchers with the capabilities of high-speed, precision and versatility to radially braid single or multiple filament types including carbon, metal, optical, n ....Automated Fibre Braiding Facility for Multifunctional Structural Materials. Automated fibre braiding facility for multifunctional structural materials:
This project seeks to establish an Australian automated braiding facility to create innovative fibrous materials with multiple functionalities. This facility aims to provide Australian researchers with the capabilities of high-speed, precision and versatility to radially braid single or multiple filament types including carbon, metal, optical, natural, bio-inspired and bio-compatible fibres and filaments to create new materials with unique functional properties. The facility would be able to braid over multiple length scales spanning nanofibres to millimetre-sized filaments to create novel materials and shapes not possible using other processing techniques. Expected applications include new materials for building, self-healing, human protection and biomedicine. Read moreRead less
Modelling and Performance Evaluation of Stab and Ballistic Resistant Fabrics. The aims of the project are to model and design stab resistant fabrics, and evaluate their stab and ballistic performance under simulated end-use conditions. Bi-component ballistic and stab resistant wearable and concealable garments will be produced and comprehensively characterised. This program is a significant first step towards developing Australian owned intellectual property for specialised protective garments f ....Modelling and Performance Evaluation of Stab and Ballistic Resistant Fabrics. The aims of the project are to model and design stab resistant fabrics, and evaluate their stab and ballistic performance under simulated end-use conditions. Bi-component ballistic and stab resistant wearable and concealable garments will be produced and comprehensively characterised. This program is a significant first step towards developing Australian owned intellectual property for specialised protective garments for local and export markets. Results from this study will produce fundamental knowledge on stab and ballistic resistant fabrics and armours, and provide practical information on the preparation of commercially acceptable protective products.Read moreRead less
Multilayered Safety Clothing for Personal Protective Equipment. This project aims to improve multilayered firefighting protective garments and their thermal comfort by utilizing aerogel microparticles containing thermal regulation materials and flame-retardant agents. This research will create new multifunctional fabric designs and engineering techniques to integrate improved heat and flame protection, comfort and smart features into optimized multilayered garments. It will create novel clothing ....Multilayered Safety Clothing for Personal Protective Equipment. This project aims to improve multilayered firefighting protective garments and their thermal comfort by utilizing aerogel microparticles containing thermal regulation materials and flame-retardant agents. This research will create new multifunctional fabric designs and engineering techniques to integrate improved heat and flame protection, comfort and smart features into optimized multilayered garments. It will create novel clothing systems that will better protect wearers and allow them to effectively combat bushfires and save lives and assets. The successful completion will enable industrial capability in next generation advanced protective garments and functional uniforms for broad occupational health safety and well-being applications.Read moreRead less
Advanced three-dimensional fibrous structures for vascular graft applications. This project will combine advanced three-dimensional fabric structures, surface functionalisation and haemodynamic modelling to tackle critical issues in the design and manufacture of vascular graft materials. It will lead to the next generation of vascular grafts with much enhanced structural and biomedical performance.
Australian ultrafine wool dehairing and processing. A novel fibre separation process will be developed to achieve the finest merino wool for processing into luxurious items. This project will add significant value to our multi-billion dollar animal fibre industry, and further enhance Australia's international reputation as the source for the highest quality wool as well as wool research and development.
Elastic and biodegradable sponges/aerogels from exfoliated silk nanofibres . The aim of this project is to investigate methods to produce highly porous elastic sponges from silk protein nanofibres. These sponges will have optimal mechanical, insulation and degradation properties making them suitable for a wide range of applications including the biomedical and personal care sectors, where current products have significant drawbacks due to the use of non-biodegradable synthetic materials. Outco ....Elastic and biodegradable sponges/aerogels from exfoliated silk nanofibres . The aim of this project is to investigate methods to produce highly porous elastic sponges from silk protein nanofibres. These sponges will have optimal mechanical, insulation and degradation properties making them suitable for a wide range of applications including the biomedical and personal care sectors, where current products have significant drawbacks due to the use of non-biodegradable synthetic materials. Outcomes include new knowledge on controlling porous structures and tailoring properties to targeted applications. This project, by laying the groundwork for a new generation of bio-based materials, will benefit the Australian advanced manufacturing sector, and enhance Australia's standing in materials science and engineering.Read moreRead less
The true potential and limitations of fibres. This project aims to understand the fibre spinning process of nanomaterials to identify their true potential and limitations in wearable applications. The project is expected to lead to multifunctional materials that allow design and production of smart functional fibres and textiles that store and convert energy and sense, monitor and respond to human activities and external environments. The project outcomes are expected to accelerate the transform ....The true potential and limitations of fibres. This project aims to understand the fibre spinning process of nanomaterials to identify their true potential and limitations in wearable applications. The project is expected to lead to multifunctional materials that allow design and production of smart functional fibres and textiles that store and convert energy and sense, monitor and respond to human activities and external environments. The project outcomes are expected to accelerate the transformation of the fibre industry, which will have far reaching implications across research disciplines and sectors critical to technology, health, social, and economic future.Read moreRead less
Water-phase Assembly of Durable, Superamphiphobic, Self-cleaning Surfaces. Self-cleaning surfaces offer an easy to maintain, environmentally friendly way of keeping surfaces clean - important for daily life, healthcare and industry. Using a water-phase process to prepare durable, self-cleaning (based on superamphiphobicity) surfaces is highly promising for practical uses, but remains challenging to perform. The present work aims to develop new knowledge on how to create superamphiphobic, self-cl ....Water-phase Assembly of Durable, Superamphiphobic, Self-cleaning Surfaces. Self-cleaning surfaces offer an easy to maintain, environmentally friendly way of keeping surfaces clean - important for daily life, healthcare and industry. Using a water-phase process to prepare durable, self-cleaning (based on superamphiphobicity) surfaces is highly promising for practical uses, but remains challenging to perform. The present work aims to develop new knowledge on how to create superamphiphobic, self-cleaning surfaces using a marine-mussel-inspired dopamine underwater assembly principle. The new technology developed is expected to be useful for wide production of durable self-cleaning coatings for diverse applications.Read moreRead less
Optimizing the UV Protection of Textiles with Nano Zinc Oxide. Colour fading, due to poor fastness to light - especially ultraviolet light - is a critical problem that continues to plague the textile industry, especially for products such as flags, awnings and car upholstery that are used in outside applications and therefore exposed directly to sunlight. This research, in collaboration with Micronisers Pty Ltd, will develop improved nano zinc oxide formulations that will significantly reduce th ....Optimizing the UV Protection of Textiles with Nano Zinc Oxide. Colour fading, due to poor fastness to light - especially ultraviolet light - is a critical problem that continues to plague the textile industry, especially for products such as flags, awnings and car upholstery that are used in outside applications and therefore exposed directly to sunlight. This research, in collaboration with Micronisers Pty Ltd, will develop improved nano zinc oxide formulations that will significantly reduce the colour fading problems, and hence add value to the fledgling nano-tech (as well as traditional textile) industries in Australia. It could enable local production of a specialised textile finishing agent for export to major textile producers in South East Asia.Read moreRead less
Segmental fibres having periodically-repeating multicomponent segments from T-junction microfluidic electrospinning. Segmental fibres, which have periodically-repeating multi-component segments along their length, represent a new fibre type offering enormous potential in creating new fibre functions. The present work aims to develop a technical platform to prepare segmental fibres and new knowledge on how the fibre segments contribute to the property, functionality and inter-fibrous interaction ....Segmental fibres having periodically-repeating multicomponent segments from T-junction microfluidic electrospinning. Segmental fibres, which have periodically-repeating multi-component segments along their length, represent a new fibre type offering enormous potential in creating new fibre functions. The present work aims to develop a technical platform to prepare segmental fibres and new knowledge on how the fibre segments contribute to the property, functionality and inter-fibrous interaction of fibres. This will be achieved using a special microfluidic electrospinning technique. The segmental fibres developed will be useful for development of various new functional fibres for diverse applications. Read moreRead less