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Control Strategies for Idle Speed of Automotive Engines. Reduction of engine idle speed will provide significant improvements in fuel efficiency. Current techniques are based on simplified models of a complex engine system and as a result do not fully exploit the possible controller capability. Therefore this project proposes new engine models and will provide novel controller methods to address this problem. This should contribute to increased engine stability and faster torque response to dist ....Control Strategies for Idle Speed of Automotive Engines. Reduction of engine idle speed will provide significant improvements in fuel efficiency. Current techniques are based on simplified models of a complex engine system and as a result do not fully exploit the possible controller capability. Therefore this project proposes new engine models and will provide novel controller methods to address this problem. This should contribute to increased engine stability and faster torque response to disturbances like air conditioner engagement, for both LPG and gasoline injected engines, thus allowing the engine idle speed to be lowered without risking stall or impairing the engine Noise, Vibration and Harshness quality.Read moreRead less
Laser-based dynamic measurements, model identification and error compensation for multi-arm robotic pre-fabrication of structural components. The aim is to establish methodologies for laser-based dynamic measurements, accurate model identification and error correction in multi-arm cooperative robotic manipulation systems. The expected outcomes include development of enabling technologies and the world's first automated fabrication system for structural timber components. The novel methodologi ....Laser-based dynamic measurements, model identification and error compensation for multi-arm robotic pre-fabrication of structural components. The aim is to establish methodologies for laser-based dynamic measurements, accurate model identification and error correction in multi-arm cooperative robotic manipulation systems. The expected outcomes include development of enabling technologies and the world's first automated fabrication system for structural timber components. The novel methodologies established will increase safety, and improve and automate the fabrication of wall frames, roof trusses, and floor and ceiling panels for housing, industrial and commercial projects within Australia and overseas. Other application areas include multi-arm manufacturing and handling of large components, materials handling in hazardous environments, and robotic servicing tasks in remote places.Read moreRead less
Autonomous service robots in a multi-agent based system for household and industrial environments. This project addresses fundamental research issues required to develop autonomous mobile robots for intelligent cleaning services. As an interdisciplinary project spanning the fields of robotics, mechatronics and AI, it offers potential benefits in bringing robots into less-structured human environments. Robots performing autonomous cleaning (including hazardous waste and spillage) and security tas ....Autonomous service robots in a multi-agent based system for household and industrial environments. This project addresses fundamental research issues required to develop autonomous mobile robots for intelligent cleaning services. As an interdisciplinary project spanning the fields of robotics, mechatronics and AI, it offers potential benefits in bringing robots into less-structured human environments. Robots performing autonomous cleaning (including hazardous waste and spillage) and security tasks in both household and industrial environments has tremendous national/community benefits in cost and time savings, improved efficiency and safety, and facilitating hazardous or labour intensive tasks. Other benefits include research training, strengthening Australia's R&D position in key innovative technologies, and creating jobs and exports.Read moreRead less
Parallel-Link Mechanism Control using new Concept and Techniques. The new knowledge and techniques, as a result of this research project, will have direct relevance to many Australian industries. In particular, they provide opportunities to improve Australia's competitiveness through innovations for the manufacturing sector. For this sector, increasing global competition and tariff reductions pose serious challenges to its continuing international competitiveness. There is an urgent need to deve ....Parallel-Link Mechanism Control using new Concept and Techniques. The new knowledge and techniques, as a result of this research project, will have direct relevance to many Australian industries. In particular, they provide opportunities to improve Australia's competitiveness through innovations for the manufacturing sector. For this sector, increasing global competition and tariff reductions pose serious challenges to its continuing international competitiveness. There is an urgent need to develop cost effective innovative products. The outcomes of this research will produce a faster, more accurate, cheaper and optimally controlled parallel-link robot than currently available. Read moreRead less
Development of an Intelligent Perception System for Electric Brakes. Electric braking is a vital component of the drive by-wire systems whose development is currently being supported worldwide by many automobile manufacturers. The aim of this project is to contribute to the development of an efficient fully functional electrically operated braking system. The main focus is on development of the intelligent perceptual sensors required for optimum performance of a by-wire braking system (to be com ....Development of an Intelligent Perception System for Electric Brakes. Electric braking is a vital component of the drive by-wire systems whose development is currently being supported worldwide by many automobile manufacturers. The aim of this project is to contribute to the development of an efficient fully functional electrically operated braking system. The main focus is on development of the intelligent perceptual sensors required for optimum performance of a by-wire braking system (to be commercialised by 2007). This project will also facilitate the development of professional courses for by-wire technology. Such courses will play a crucial role in maintaining the competitiveness of the Australian car component industry as by-wire technology emerges.Read moreRead less
Zero Defect Manufacturing of Complex Assemblies. The aim of this research project is to develop the tools required to design and implement zero defect manufacturing systems. It is intended that generic guidelines will be developed for achieving zero defect manufacturing of complex assemblies in a cost effective manner. Methodologies and techniques derived from these guidelines will be tested and validated on an existing door trim assembly production line. This project with its emphasis on utilis ....Zero Defect Manufacturing of Complex Assemblies. The aim of this research project is to develop the tools required to design and implement zero defect manufacturing systems. It is intended that generic guidelines will be developed for achieving zero defect manufacturing of complex assemblies in a cost effective manner. Methodologies and techniques derived from these guidelines will be tested and validated on an existing door trim assembly production line. This project with its emphasis on utilising manufacturing systems involving a mix of human and robot based operations and in process inspection techniques to achieve defect free manufacturing is particularly relevant to medium size component suppliers.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347024
Funder
Australian Research Council
Funding Amount
$140,000.00
Summary
Research facility in micromanipulation. The aim of the program is to establish a unique joint facility between Monash and Deakin for micromanipulation research. The proposed facility will consist of complex/intelligent micromanipulation systems capable of motion accuracy of 0.01-0.1 micrometer (10-100 nm). This will be the only facility of its kind in Australia and will provide a key enabling technology in the research and development of advanced micromanipulation systems, robotic-assisted mic ....Research facility in micromanipulation. The aim of the program is to establish a unique joint facility between Monash and Deakin for micromanipulation research. The proposed facility will consist of complex/intelligent micromanipulation systems capable of motion accuracy of 0.01-0.1 micrometer (10-100 nm). This will be the only facility of its kind in Australia and will provide a key enabling technology in the research and development of advanced micromanipulation systems, robotic-assisted microsurgery, sensory-based and intelligent control of complex systems, micro assembly/manufacturing, telerobotics/telesurgery, kinematics and dynamics of micromanipulators, laser-based control, and biotechnology. The facility will support and enhance a number of high-quality, current and future research projects with recognised potential.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883093
Funder
Australian Research Council
Funding Amount
$285,000.00
Summary
A Haptically enabled Universal Motion Simulator Research Facility. The proposed universal motion simulator research facility will enable to develop a better understanding of issues involved in ergonomic and safe vehicle designs and provides opportunities to improve Australia's international competitiveness and economic sustainability through innovations in the manufacturing and transport sectors. This universal motion simulator will provide opportunity to extend our understanding of operator con ....A Haptically enabled Universal Motion Simulator Research Facility. The proposed universal motion simulator research facility will enable to develop a better understanding of issues involved in ergonomic and safe vehicle designs and provides opportunities to improve Australia's international competitiveness and economic sustainability through innovations in the manufacturing and transport sectors. This universal motion simulator will provide opportunity to extend our understanding of operator controlled devices, such as cars and mining machinery, and to develop effective strategies to reduce the risk of vehicle accidents.Read moreRead less
Micromanipulation system. Many frontier areas such as micromanufacturing, microsurgery, biotechnology, and nanotechnology require high precision micromanipulation systems. This project aims to investigate fundamental issues in micromanipulation systems using an ARC-LIEF funded research facility, and establish methodologies for modelling and analysis, together with their experimental verification to evaluate the influence of various parameters in such systems. The findings will be utilised to e ....Micromanipulation system. Many frontier areas such as micromanufacturing, microsurgery, biotechnology, and nanotechnology require high precision micromanipulation systems. This project aims to investigate fundamental issues in micromanipulation systems using an ARC-LIEF funded research facility, and establish methodologies for modelling and analysis, together with their experimental verification to evaluate the influence of various parameters in such systems. The findings will be utilised to establish sensory-based control techniques to solve problems associated with predictability, control, and efficiency for future advancement of such novel systems. The outcomes will include acquiring new knowledge in micromanipulation systems for potential utilization of the innovative concepts in the frontier areas.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775692
Funder
Australian Research Council
Funding Amount
$430,000.00
Summary
Micro/nano optomechatronics sensing, measurement, and control research facility. This project aims to establish a facility that enhances the capabilities for sensing, positioning, and manipulating of micro/nano scale objects and environment, and as such constitutes the building block for many frontier technologies such as nanotechnology, bio/nano medicine, microsurgery and neurosurgery, biotechnology, microbiology, microfluidics, and micro/nano manufacturing, all of which are still in their infa ....Micro/nano optomechatronics sensing, measurement, and control research facility. This project aims to establish a facility that enhances the capabilities for sensing, positioning, and manipulating of micro/nano scale objects and environment, and as such constitutes the building block for many frontier technologies such as nanotechnology, bio/nano medicine, microsurgery and neurosurgery, biotechnology, microbiology, microfluidics, and micro/nano manufacturing, all of which are still in their infancy and promise to be the challenging areas of research for the next two decades. The outcomes will strengthen Australia's position in world-class innovative scientific research. It also strengthens collaboration between major engineering institutions and medical experts for innovative research and training of researchers.Read moreRead less