Abstract
Cook Inlet in Alaska has been identified as a prime site in the U.S. for potential tidal energy development, because of its enormous tidal power potential that accounts for nearly one-third of the national total. As one important step to facilitate tidal energy development, a tidal hydrodynamic model based on the unstructured-grid, finite-volume community ocean model (FVCOM) was developed for Cook Inlet to characterize the tidal stream energy resource. The model has a grid resolution that varies from about 1000 m at the open boundary to 100–300 m inside the Inlet. Extensive model validation was achieved by comparing model predictions with field observations for tidal elevation and velocity at various locations in Cook Inlet. The error statistics confirmed the model performs reasonably well in capturing the tidal dynamics in the system, e.g., R2 > 0.98 for tidal elevation and generally > 0.9 for velocity. Model results suggest that tides in Cook Inlet evolve from progressive waves at the entrance to standing waves at the upper Inlet, and that semi-diurnal tidal constituents are amplified more rapidly than diurnal constituents. The model output was used to identify hotspots that have high energy potential and warrant additional velocity and turbulence measurements such as East Foreland, where averaged power density exceeds 5 kw/m2. Lastly, a tidal energy extraction simulation was conducted for a hypothetical turbine farm configuration at the Forelands cross section to evaluate tidal energy extraction and resulting changes in far-field hydrodynamics.
Highlights
In recent decades, the interest in harnessing energy directly from tidal streams with marine hydrokinetic (MHK) devices has been renewed in many countries [1,2]
Since this study is focused on tidal-driven hydrodynamics in Cook Inlet, model calibration was achieved by adjusting user-specified parameter values that directly control tidal wave propagation in the system through a series of iterative model runs
Summary In this study, an unstructured-grid based tidal hydrodynamic model was developed for Cook
Summary
The interest in harnessing energy directly from tidal streams with marine hydrokinetic (MHK) devices has been renewed in many countries [1,2]. Compared to other renewable energy sources, such as wind and solar power, tidal energy is highly predictable in time and space [3]. It can potentially serve as a dependable, clean energy resource for suitable tidal systems. Most other efforts have been largely focused on the earlier stage of tidal energy development, such as characterizing available tidal energy resources using computational models and testing MHK devices in the laboratory and at representative field-testing sites [13,14,15,16]
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