Microstructure effect on energy harvesting ability of electrospun fibres. This project aims to provide new knowledge about how to manipulate the energy harvesting ability of electrospun fibrous mats by changing the fibre structure, components and mat configuration. Expected outcomes of the project are new fibrous materials capable of efficiently converting small mechanical forces and sounds into electricity. These high performance energy harvesting fibres will be useful for developing new power ....Microstructure effect on energy harvesting ability of electrospun fibres. This project aims to provide new knowledge about how to manipulate the energy harvesting ability of electrospun fibrous mats by changing the fibre structure, components and mat configuration. Expected outcomes of the project are new fibrous materials capable of efficiently converting small mechanical forces and sounds into electricity. These high performance energy harvesting fibres will be useful for developing new power supplies, self-powered electronics, self-sustainable sensor networks and electronic textiles.Read moreRead less
High Temperature, Piezoelectric Polymer Membranes. This project aims to acquire new knowledge about the preparation of flexible polymer membranes that can convert mechanical energy into electricity (“piezoelectric” conversion) stably at high temperature (e.g. 200-500 °C). This will solve the current problem where only inorganic ceramic materials can be used for high-temperature piezoelectric conversion. The expected outcomes include a new approach to prepare polymer membranes capable of high-tem ....High Temperature, Piezoelectric Polymer Membranes. This project aims to acquire new knowledge about the preparation of flexible polymer membranes that can convert mechanical energy into electricity (“piezoelectric” conversion) stably at high temperature (e.g. 200-500 °C). This will solve the current problem where only inorganic ceramic materials can be used for high-temperature piezoelectric conversion. The expected outcomes include a new approach to prepare polymer membranes capable of high-temperature piezoelectric conversion using an electrostatic spinning technology. The new breakthrough materials will not only enhance performance and reliability at high temperature, but also offer novel applications in diverse fields such as “smart” protective clothing for firefighters. Read moreRead less
Self-powered active noise control via a nanofibre acoustoelectric converter. This project aims to investigate a new, active noise control system that can eliminate low frequency noise without the use of external electricity. This project will generate new knowledge about how to realise self-powering on active noise controllers using piezoelectric nanofibres as sound detector and power generator. Expected outcomes include an effective method to produce this novel noise controller and a systemic u ....Self-powered active noise control via a nanofibre acoustoelectric converter. This project aims to investigate a new, active noise control system that can eliminate low frequency noise without the use of external electricity. This project will generate new knowledge about how to realise self-powering on active noise controllers using piezoelectric nanofibres as sound detector and power generator. Expected outcomes include an effective method to produce this novel noise controller and a systemic understanding about materials, devices and performance. This will significantly benefit development of advanced noise controlling technology and products, benefiting industry and the environment.Read moreRead less