Abstract
Wave tank tests aiming to reproduce realistic or site specific conditions will commonly involve using directionally spread, short-crested sea states. The measurement of these directional characteristics is required for the purposes of calibrating and validating the modelled sea state. Commonly used methods of directional spectrum reconstruction, based on directional spreading functions, have an inherent level of uncertainty associated with them. In this paper we aim to reduce the uncertainty in directional spectrum validation by introducing the SPAIR (Single-summation PTPD Approach with In-line Reflections) method, in combination with a directional wave gauge array. A variety of wave conditions were generated in the FloWave Ocean Energy Research Facility, Edinburgh, UK, to obtain a range of sea state and reflection scenarios. The presented approach is found to provide improved estimates of directional spectra over standard methods, reducing the mean apparent directional deviation down to below 6% over the range of sea states. Additionally, the method isolates incident and reflected spectra in both the frequency and time domain, and can separate these wave systems over 360°. The accuracy of the method is shown to be only slightly sensitive to the level of in-line reflection present, but at present cannot deal with oblique reflections. The SPAIR method, as presented or with slight modification, will allow complex directional sea states to be validated more effectively, enabling multidirectional wave basins to simulate realistic wave scenarios with increased confidence.
Highlights
Wave tank tests facilitate the understanding of how complex sea conditions influence the dynamics of man-made structures
In general the deviation is much lower for sea states with lower peak frequency, suggesting that, as expected, the tank's generating and absorbing effectiveness reduces above a certain frequency threshold
To demonstrate that this deviation isn't a function of the method, and to allow comparisons to be made in Section 3.5.1, the frequency spectra outputs for the Bayesian Directional Method (BDM) and Extended Maximum Entropy Principal (EMEP) approaches are been shown
Summary
Wave tank tests facilitate the understanding of how complex sea conditions influence the dynamics of man-made structures. A key requirement for any test programme is the ability to create these conditions in a highly controlled and repeatable manner. To have such control, it is vital to be able to measure and validate the desired test conditions. The facility consists of a circular 25 m diameter, 2 m depth combined wave and current test basin which is encircled by 168 active-absorbing force-feedback wavemakers. This geometry and design are intended to remove any inherent limitation on wave direction and allow the recreation of highly spread and highly complex directional spectra. It presents an ideal environment to explore and demonstrate directional measurement methodologies
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