Mid-Career Industry Fellowships - Grant ID: IM230100079
Funder
Australian Research Council
Funding Amount
$1,019,275.00
Summary
Bio-inspired Sustainable Materials for Self-powered Environmental Sensing . This project aims to address the industry need for self-powered, light-weight and durable Internet of Things (IoT) devices for environmental sensing applications. The goal will be achieved by designing high power moisture-driven electric generators with a bi-layer interfacial architecture, developing non-flammable energy storage devices with cost-effective electrodes, and printing low power environmental sensors with he ....Bio-inspired Sustainable Materials for Self-powered Environmental Sensing . This project aims to address the industry need for self-powered, light-weight and durable Internet of Things (IoT) devices for environmental sensing applications. The goal will be achieved by designing high power moisture-driven electric generators with a bi-layer interfacial architecture, developing non-flammable energy storage devices with cost-effective electrodes, and printing low power environmental sensors with hetero-structured materials. The key outcome will be a new class of IoT devices with high power density, sustainable output, and real time environmental monitoring capabilities, that will directly benefit Australian industry by providing cost-effective, yet efficient ways to monitor and support safe working environments.Read moreRead less
A Novel Inline High-Efficiency Motor/Pump System. Around 19% of the world’s and 30% of the Australia’s electric energy is consumed by pump technologies. Significant energy savings are possible if the major components of pump systems, including inverter, motor and pump, operate at their maximum possible efficiency under varying loads. A novel pump design in this project accommodates integrated electronics in a submersible housing. A seal-less design helps mitigate several aspects of pump failure ....A Novel Inline High-Efficiency Motor/Pump System. Around 19% of the world’s and 30% of the Australia’s electric energy is consumed by pump technologies. Significant energy savings are possible if the major components of pump systems, including inverter, motor and pump, operate at their maximum possible efficiency under varying loads. A novel pump design in this project accommodates integrated electronics in a submersible housing. A seal-less design helps mitigate several aspects of pump failure and its in-line structure reduces assembly cost. Accurately measured efficiency maps will be utilised to demonstrate the non-linear relationship between motor and pump quantities as well as developing models for indirectly estimating feedback quantities and achieving the highest system efficiency.Read moreRead less