Dynamic model assisted fault diagnostics of wind turbine gearbox. This project aims to develop novel condition monitoring methodologies for the gearbox of large horizontal-axis wind turbines which are widely installed in wind farms for generating renewable energy. This project expects to generate a new diagnostic framework by integrating dynamic model assisted simulations and digital twin-based approaches. Expected outcomes of this project include new vibration-based methods for fault diagnostic ....Dynamic model assisted fault diagnostics of wind turbine gearbox. This project aims to develop novel condition monitoring methodologies for the gearbox of large horizontal-axis wind turbines which are widely installed in wind farms for generating renewable energy. This project expects to generate a new diagnostic framework by integrating dynamic model assisted simulations and digital twin-based approaches. Expected outcomes of this project include new vibration-based methods for fault diagnostics and predictions of the remaining useful life of turbine gearboxes. This should provide significant benefits to the Australian Wind Industry by ensuring reliable operation of wind turbines, reducing turbine downtime and reducing operation and maintenance costs; ultimately lowering the cost of energy from wind.Read moreRead less
An innovative wind power system primarily for urban environments. The project aims to develop a novel rotor vane array wind power system that can be used as a roof fence or balcony on existing or new buildings. Traditional wind turbines cannot fully realise the potential of excellent wind speed in tall buildings because of space efficiency, visual impact, and danger or noise issues. The system to be developed in the project incorporates advanced active flow control that addresses these issues. T ....An innovative wind power system primarily for urban environments. The project aims to develop a novel rotor vane array wind power system that can be used as a roof fence or balcony on existing or new buildings. Traditional wind turbines cannot fully realise the potential of excellent wind speed in tall buildings because of space efficiency, visual impact, and danger or noise issues. The system to be developed in the project incorporates advanced active flow control that addresses these issues. The project plans to conduct a structured program of numerical and experimental studies, the intended outcomes of which will contribute to energy security, progress towards zero emissions and sustainable living, and lead to innovative architecture of the future.Read moreRead less
Energy capture from polymer based synthetic foliage. Wind powered renewable energy technologies are rejected in urban or natural environments because of their noise and perceived danger to avian wildlife from conventional rotary wind turbines. The synthetic foliage will be used as a device for low energy applications which is expected to be more socially acceptable in urban settings. We anticipate that this will lead to increased adoption of renewable energy by the Australian public. Success of ....Energy capture from polymer based synthetic foliage. Wind powered renewable energy technologies are rejected in urban or natural environments because of their noise and perceived danger to avian wildlife from conventional rotary wind turbines. The synthetic foliage will be used as a device for low energy applications which is expected to be more socially acceptable in urban settings. We anticipate that this will lead to increased adoption of renewable energy by the Australian public. Success of the project will lead to long term benefits for Australia including reduction of greenhouse gas emissions and the creation of jobs in the sustainable energy sector.Read moreRead less