Gold coast seaway smartrelease decision support system: optimising recycled water release in a sub tropical estuarine environment.

Gold Coast Water is responsible for the management of the water, recycled water and wastewater assets of the City of the Gold Coast on Australia's east coast. Excess treated recycled water is released at the Gold Coast Seaway, a man-made channel connecting the Broadwater Estuary with the Pacific Ocean, on an outgoing tide in order for the recycled water to be dispersed before the tide changes and re-enters the Broadwater estuary. Rapid population growth has placed increasing demands on the city's recycled water release system and an investigation of the capacity of the Broadwater to assimilate a greater volume of recycled water over a longer release period was undertaken in 2007. As an outcome, Gold Coast Water was granted an extension of the existing release licence from 10.5 hours per day to 13.3 hours per day from the Coombabah wastewater treatment plant (WWTP). The Seaway SmartRelease Project has been designed to optimise the release of the recycled water from the Coombabah WWTP in order to minimise the impact to the receiving estuarine water quality and maximise the cost efficiency of pumping. In order achieve this; an optimisation study that involves intensive hydrodynamic and water quality monitoring, numerical modelling and a web-based decision support system is underway. An intensive monitoring campaign provided information on water levels, currents, winds, waves, nutrients and bacterial levels within the Broadwater. This data was then used to calibrate and verify numerical models using the MIKE by DHI suite of software. The Decision Support System will then collect continually measured data such as water levels, interact with the WWTP SCADA system, run the numerical models and provide the optimal time window to release the required amount of recycled water from the WWTP within the licence specifications.

The dynamic aortic root. Its role in aortic valve function.

By attaching appropriate measuring devices to the wall of an intact aortic root at the level of leaflet coaptation, we have measured a 16 per cent diameter change during each cardiac cycle. The dimensional changes observed can by themselves explain aortic valve function and obviate the postulation that the leaflets shorten and lengthen during each cardiac cycle. The tissue composition of the aortic root and leaflets is more compatible with this theory than with other postulations. Such a dynamic aortic root may explain the longevity of the actual aortic leaflets, in that leaflet fatigue stress is minimized by changes in aortic root dimension.