Modelling the stability and efficiency of ring spinning. This research will benefit the animal fibre industry, particularly the multi-billion dollar wool industry. Low spinning efficiency adds a significant cost to the conversion of animal fibres into textile products, which reduces the competitive position of these natural fibres. The proposed research will lead to improvement in the efficiency of ring spinning. It has been estimated that a 1% improvement in spinning efficiency will add about $ ....Modelling the stability and efficiency of ring spinning. This research will benefit the animal fibre industry, particularly the multi-billion dollar wool industry. Low spinning efficiency adds a significant cost to the conversion of animal fibres into textile products, which reduces the competitive position of these natural fibres. The proposed research will lead to improvement in the efficiency of ring spinning. It has been estimated that a 1% improvement in spinning efficiency will add about $16 million to the wool industry alone. Read moreRead less
Modelling and minimising energy consumption in ring spinning. Australia's 4-billion dollar natural fibre production is spun into yarns via ring spinning mainly. A major drawback of this spinning system is its high energy consumption. This project will examine, theoretically and experimentally, the key factors contributing to energy consumption in ring spinning. It will generate new knowledge on the relationship between yarn hairiness and the air drag on a rapidly rotating yarn package and on a b ....Modelling and minimising energy consumption in ring spinning. Australia's 4-billion dollar natural fibre production is spun into yarns via ring spinning mainly. A major drawback of this spinning system is its high energy consumption. This project will examine, theoretically and experimentally, the key factors contributing to energy consumption in ring spinning. It will generate new knowledge on the relationship between yarn hairiness and the air drag on a rapidly rotating yarn package and on a ballooning yarn, and predict how this air drag affects the energy consumption during package build-up in ring spinning. This will lead to ways of minimising energy consumption in this most important spinning process.Read moreRead less
Understanding the Drafting-against-Untwisting Process for Engineering Fine and Soft Yarns of Low Hairiness. This research will lead to much improved understanding of a very novel yarn engineering process to achieve fine, soft and low-hairiness yarns from natural fibres. It will demonstrate that Australia not only provides quality wool and cotton fibres, but also leads the world in innovative textile engineering technologies that can enhance the competitive positions of its natural fibres in the ....Understanding the Drafting-against-Untwisting Process for Engineering Fine and Soft Yarns of Low Hairiness. This research will lead to much improved understanding of a very novel yarn engineering process to achieve fine, soft and low-hairiness yarns from natural fibres. It will demonstrate that Australia not only provides quality wool and cotton fibres, but also leads the world in innovative textile engineering technologies that can enhance the competitive positions of its natural fibres in the global fibre market. This research promotes value adding in Australian fibre products by developing advanced yarn engineering technology, which will be of significant national benefit to the multi-billion natural fibre industries in Australia.Read moreRead less
Reducing the hairiness and improving the quality of wool yarns. The fibre ends that protrude from the surface of wool yarns make the yarns hairy. Yarn hairiness leads to reduced efficiency in spinning, knitting and weaving. Excessive yarn hairiness also adversely affects other important yarn properties as well as the quality of wool garments. This project aims at reducing the hairiness and improving the quality of yarns made from Australian merino wool. It will generate new knowledge on the mech ....Reducing the hairiness and improving the quality of wool yarns. The fibre ends that protrude from the surface of wool yarns make the yarns hairy. Yarn hairiness leads to reduced efficiency in spinning, knitting and weaving. Excessive yarn hairiness also adversely affects other important yarn properties as well as the quality of wool garments. This project aims at reducing the hairiness and improving the quality of yarns made from Australian merino wool. It will generate new knowledge on the mechanism of hairiness formation and its reduction. This research will also help enhance the quality image of Australian merino wool and wool garments, adding value to the multi-billion dollar wool industry.
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Understanding the interaction between wool fibre surface and ionic liquids. This project will advance the knowledge on wool surface/ionic liquid interaction, which has the potential to revolutionize the traditional and environmentally unfriendly wool shrinkage-proof treatment technology. This will have significant industry wide benefit for the multi-billion dollar animal fibre industry.
Controlling and Predicting the Pilling Propensity of Fabrics. Pilling adversely affects the appearance of fabrics and garments. It is one of the most serious quality problems for the textile industry, particularly the wool industry. This project will examine and control the key factors that contribute to fabric pilling in the fibre-to-fabric conversion processes. It also aims to predict fabric pilling performance from these factors. This will help the industry, along the fibre to fabric chain, t ....Controlling and Predicting the Pilling Propensity of Fabrics. Pilling adversely affects the appearance of fabrics and garments. It is one of the most serious quality problems for the textile industry, particularly the wool industry. This project will examine and control the key factors that contribute to fabric pilling in the fibre-to-fabric conversion processes. It also aims to predict fabric pilling performance from these factors. This will help the industry, along the fibre to fabric chain, to understand the mechanism of pilling and to work together to manage and control this long-standing problem for the benefit of the textile industry as well as textile consumers.Read moreRead less
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
Engineering a silk fibroin based ear drum with optimum acoustic properties. This project will use new silk fibroin materials to develop ear drums with improved acoustic properties. This will lead to significant improvement in the quality of life of nearly 2.5 million people in Australia who are affected by hearing loss and further strengthen Australia's leading position in this area.
The characterization and pocessing of Australian grown hemp fibres. This project will, for the first time, systematically examine the characteristics and processing behaviour of Australian grown hemp fibres. The hemp industry is an emerging new industry in rural Australia. This research will tackle a number of complex problems concerning characterization, degumming, and processing of Australian grown hemp, and will engineer the finest and softest yarns as well as industrial products from this he ....The characterization and pocessing of Australian grown hemp fibres. This project will, for the first time, systematically examine the characteristics and processing behaviour of Australian grown hemp fibres. The hemp industry is an emerging new industry in rural Australia. This research will tackle a number of complex problems concerning characterization, degumming, and processing of Australian grown hemp, and will engineer the finest and softest yarns as well as industrial products from this hemp. This will position the local hemp industry as well fibre processing industry in a very strong position to meet the growing demand world wide on this "green" fibre.Read moreRead less