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Investigation of the audio spotlight for active noise control. The focus of this project is to investigate a new technology - the audio spotlight - with the aim of developing an active noise control (ANC) system that incorporates the audio spotlight as a control source. The audio spotlight offers the potential to overcome or significantly modify the fundamental physical constraints that limit the performance of ANC systems that use conventional loudspeakers as control sources. Just as audio spot ....Investigation of the audio spotlight for active noise control. The focus of this project is to investigate a new technology - the audio spotlight - with the aim of developing an active noise control (ANC) system that incorporates the audio spotlight as a control source. The audio spotlight offers the potential to overcome or significantly modify the fundamental physical constraints that limit the performance of ANC systems that use conventional loudspeakers as control sources. Just as audio spotlights may be the most radical technological development in acoustics since the invention of the coil loudspeaker, successful incorporation of an audio spotlight into an active noise control system will revolutionise active noise control.Read moreRead less
Advancements in Belt Conveying. Belt conveyors are of considerable importance in bulk material handling operations worldwide. This research will be undertaken in collaboration with three industry partners and will develop fundamental models to predict and improve the performance and reliability in the areas of belt cleaning, belt weighing and belt indentation resistance. A collective approach to the research will significantly enhance the project outcomes due to the strong interrelation of funda ....Advancements in Belt Conveying. Belt conveyors are of considerable importance in bulk material handling operations worldwide. This research will be undertaken in collaboration with three industry partners and will develop fundamental models to predict and improve the performance and reliability in the areas of belt cleaning, belt weighing and belt indentation resistance. A collective approach to the research will significantly enhance the project outcomes due to the strong interrelation of fundamental parameters. The research outcomes will significantly enhance the fundamental knowledge of belt conveying, and strengthen Australia's international standing in the field of bulk materials handling research and industrial application.Read moreRead less
Special Research Initiatives - Grant ID: SR0354722
Funder
Australian Research Council
Funding Amount
$20,000.00
Summary
Research Network for Multi-Scale Manufacturing and Characterisation. Manufacturing has always been the cornerstone of long-term economic growth. With the recent development in micro/nano-technologies, the manufacture of devices with functional properties across multiple scales has become a central challenge. In Australia, individual research teams have had significant impact on the manufacture of single scale elements, but owing to their limited infrastructure and specialised expertise, integrat ....Research Network for Multi-Scale Manufacturing and Characterisation. Manufacturing has always been the cornerstone of long-term economic growth. With the recent development in micro/nano-technologies, the manufacture of devices with functional properties across multiple scales has become a central challenge. In Australia, individual research teams have had significant impact on the manufacture of single scale elements, but owing to their limited infrastructure and specialised expertise, integrated multi-scale manufacturing has been unattainable. Through collaboration and sharing of expertise and infrastructure, the proposed Research Network, composed of the major Australian teams in manufacturing and leading divisions overseas, will foster innovation in multi-scale manufacturing and characterization in Australia.Read moreRead less
Sensor Integration for Low-Cost Robust Machine Automation. Machine automation (MA) radically improves efficiency of mining and construction operataions. When used for farming, it makes Australia more competitive with subsidised competitors in Europe and USA. In one case, a 50% reduction in tractor fleet resulted when night plowing was made possible using MA techniques. The systems developed in this project will make MA far more attractive to Australian agriculture, mining and construction indust ....Sensor Integration for Low-Cost Robust Machine Automation. Machine automation (MA) radically improves efficiency of mining and construction operataions. When used for farming, it makes Australia more competitive with subsidised competitors in Europe and USA. In one case, a 50% reduction in tractor fleet resulted when night plowing was made possible using MA techniques. The systems developed in this project will make MA far more attractive to Australian agriculture, mining and construction industries, by making it more robust and less susceptible to difficult conditions, such as under trees.Read moreRead less
An investigation of granular stress fields and permeability interactions in gas-solid flow. This project will provide the fundamental theoretical basis for a completely new approach to the design of dense phase pneumatic conveying systems. This will lead to improved energy efficiency, significantly greater operational reliability and reduced wear of system components for the transport of bulk solids in the resource and process industries.
A surface modification techniques for wafers of semiconductor materials. The research will develop an innovative technique for producing large wafers of semiconductor materials with a superfine surface finish. This technique will combine the advantages of ultra-precision grinding and polishing into a single operation. An effective superfinishing technique for the new generation of large-size wafers of semiconductor materials is essential because they are one of the most important materials for i ....A surface modification techniques for wafers of semiconductor materials. The research will develop an innovative technique for producing large wafers of semiconductor materials with a superfine surface finish. This technique will combine the advantages of ultra-precision grinding and polishing into a single operation. An effective superfinishing technique for the new generation of large-size wafers of semiconductor materials is essential because they are one of the most important materials for information technology, integrated circuit technology and fabrication of micro-machines.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453561
Funder
Australian Research Council
Funding Amount
$336,706.00
Summary
Integrated Precision Machining of Complex Profiles. High precision and high speed machining is of central importance to the development of a wide range of frontier technologies such as precision manufacturing, nano-materials fabrication, semiconductor and composite processing, vehicle production and steel structure manufacturing. The research significance has been well established by the world-leading projects and achievements. The proposed facility has distinct features and capability of high l ....Integrated Precision Machining of Complex Profiles. High precision and high speed machining is of central importance to the development of a wide range of frontier technologies such as precision manufacturing, nano-materials fabrication, semiconductor and composite processing, vehicle production and steel structure manufacturing. The research significance has been well established by the world-leading projects and achievements. The proposed facility has distinct features and capability of high loop-stiffness, high repeatability, universal profiling, organic integration of key machining operations, and great flexibility of both low and high speeds. These unique characteristics will enable the innovative development of many research programs which will otherwise be impossible to achieve.Read moreRead less
Modelling of Bypass Pneumatic Conveying Systems. Many of the physical items we use in our daily lives have at some point required transport and handling as powdered or granular materials during the manufacturing process. Be it food (sugar, flour), chemicals (soap powders, detergents) or power generation (coal and ash); each of these industries uses the flexibility of pipelines as a transport mechanism. However, not all materials will convey reliably in conventional pipelines. This project will ....Modelling of Bypass Pneumatic Conveying Systems. Many of the physical items we use in our daily lives have at some point required transport and handling as powdered or granular materials during the manufacturing process. Be it food (sugar, flour), chemicals (soap powders, detergents) or power generation (coal and ash); each of these industries uses the flexibility of pipelines as a transport mechanism. However, not all materials will convey reliably in conventional pipelines. This project will provide the fundamental understanding of how bypass systems can overcome this problem by conditioning the material along the pipeline length. The results will lead to better pipeline design outcomes that will ultimately expand the use of the cost effective process of pneumatic pipeline conveying. Read moreRead less
Hydrodynamic Stability of the VentrAssist Blood Pump, an Experimental and Numerical Investigation. This project will investigate, both numerically and experimentally, the stability of the impeller-bearing system of a rotary blood pump and will make recommendations about the optimum bearing configurations. Findings from this project will contribute to the commercialisation of the blood pump undertaken by the research Group formed by the staff from UTS, UNSW and VentrAssist Pty Ltd - the first of ....Hydrodynamic Stability of the VentrAssist Blood Pump, an Experimental and Numerical Investigation. This project will investigate, both numerically and experimentally, the stability of the impeller-bearing system of a rotary blood pump and will make recommendations about the optimum bearing configurations. Findings from this project will contribute to the commercialisation of the blood pump undertaken by the research Group formed by the staff from UTS, UNSW and VentrAssist Pty Ltd - the first of its kind in Australia. Rotary blood pumps are at the leading edge of cardiac assist technology worldwide and an investigation of the impeller dynamics will add greatly to the understanding of the related important factors in blood pump design.Read moreRead less
Properties and Characterisation of Magneto-Rheological Materials under Rotating Magnetic Field Excitation. Through the proposed theoretical and experimental studies, new electro-magneto-mechanical phenomena of the MR materials under various vectorial magnetisations will be observed. Based on the in-depth understanding of the complex vectorial magneto-rheological mechanisms, an accurate coupled model will be developed for design and analysis of novel dampers. These outcomes will greatly enhance t ....Properties and Characterisation of Magneto-Rheological Materials under Rotating Magnetic Field Excitation. Through the proposed theoretical and experimental studies, new electro-magneto-mechanical phenomena of the MR materials under various vectorial magnetisations will be observed. Based on the in-depth understanding of the complex vectorial magneto-rheological mechanisms, an accurate coupled model will be developed for design and analysis of novel dampers. These outcomes will greatly enhance the design capacity of Australian industry in smart structures, i.e. using novel dampers to reduce harmful vibrations and protect people in vehicles, buildings, and bridges. This will help Australians to live in a safer and healthier environment, and could save billions of dollars per year nationwide for treatment, recovery, and insurance claims.Read moreRead less