AI Article Synopsis
- Ocean energy extraction, especially from tides, is increasing, but challenges remain in reliably capturing tidal stream energy due to complex flow dynamics and environmental impacts.
- This study uses drones and acoustic profiling to analyze turbulent flow around an idled floating tidal turbine, measuring various flow characteristics with high spatial resolution.
- Findings include significant turbulence and velocity deficits near the turbine, which will help advance understanding of flow dynamics and their effects on offshore renewable energy technologies.
Article Abstract
Ocean energy extraction is on the rise. While tides are the most predictable amongst marine renewable resources, turbulent and complex flows still challenge reliable tidal stream energy extraction and there is also uncertainty in how devices change the natural environment. To ensure the long-term integrity of emergent floating tidal turbine technologies, advances in field measurements are required to capture multiscale, real-world flow interactions. Here we use aerial drones and acoustic profiling transects to quantify the site- and scale-dependent complexities of actual turbulent flows around an idled, utility-scale floating tidal turbine (20 m rotor diameter, D). The combined spatial resolution of our baseline measurements is sufficiently high to quantify sheared, turbulent inflow conditions (reversed shear profiles, turbulence intensity >20%, and turbulence length scales > 0.4D). We also detect downstream velocity deficits (approaching 20% at 4D) and trace the far-wake propagation using acoustic backscattering techniques in excess of 30D. Addressing the energy-environment nexus, our oceanographic lens on flow characterisation will help to validate multiscale flow physics around offshore energy platforms that have thus far only been simulated.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11415390 | PMC |
| http://dx.doi.org/10.1038/s41467-024-52578-x | DOI Listing |
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Article Synopsis
- Ocean energy extraction, especially from tides, is increasing, but challenges remain in reliably capturing tidal stream energy due to complex flow dynamics and environmental impacts.
- This study uses drones and acoustic profiling to analyze turbulent flow around an idled floating tidal turbine, measuring various flow characteristics with high spatial resolution.
- Findings include significant turbulence and velocity deficits near the turbine, which will help advance understanding of flow dynamics and their effects on offshore renewable energy technologies.
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