Skin friction control using engineering and biological surface coatings. The development of techniques to reduce skin friction in water conveying assets will increase renewable energy production from existing hydro-electric plant and improve the energy efficiency of water conveying utilities. There is also potential for application to marine biofouling problems and reducing fuel usage by shipping. Passive (non-chemical) and biological control methods to reduce fouling and friction will be sought ....Skin friction control using engineering and biological surface coatings. The development of techniques to reduce skin friction in water conveying assets will increase renewable energy production from existing hydro-electric plant and improve the energy efficiency of water conveying utilities. There is also potential for application to marine biofouling problems and reducing fuel usage by shipping. Passive (non-chemical) and biological control methods to reduce fouling and friction will be sought to minimise environmental impact and maintain potable water quality. This multidisciplinary project combining engineering, photogrammetry and biological sciences will provide valuable training for the project team members and develop a pool of skilled personnel available to Australian industries.Read moreRead less
Improvement of water conveying efficiency in hydroelectric power generation systems by optimising pipe friction losses. The growth of bacterial and algal slimes on the surface of water conveying system significantly reduces the net electricity generation from Tasmania's hydroelectric system.
The aim of this project is to develop an optimal maintenance strategy to control this growth which will balance maintenance downtime against the potential increase in electricity production. The growth resp ....Improvement of water conveying efficiency in hydroelectric power generation systems by optimising pipe friction losses. The growth of bacterial and algal slimes on the surface of water conveying system significantly reduces the net electricity generation from Tasmania's hydroelectric system.
The aim of this project is to develop an optimal maintenance strategy to control this growth which will balance maintenance downtime against the potential increase in electricity production. The growth response to cleaning techniques and surface coatings will be investigated.
The potential for increased power production from this renewable energy source will have considerable economic benefit for Tasmania.Read moreRead less