32 research outputs found
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Wave Modeling Results: Baseline Observations and Modeling for the Reedsport Wave Energy Site
Offshore wave conditions along the Oregon coastline are measured at a handful of buoy
locations where directional wave information is available. Most of these buoys are located in
deep waters and incoming waves undergo changes as they travel from deep water onto the shelf
where wave energy conversion arrays are likely to be deployed. These changes can be in the
form of wave focusing or defocusing due to the presence of underwater banks, shoals, or
canyons. Also, wave dissipation mechanisms such as bottom friction or wave breaking can be at
play. Wave models can take into account such processes and produce predictions of the local
conditions at the site of a wave energy conversion (WEC) array. Knowledge of local conditions
can aid in the design of the devices for the specific local conditions to which they will be
subjected and can also provide advance knowledge of wave conditions to power companies once
a WEC array is in place.
The work performed herein was geared towards two goals. First, transformation of the wave field from
deep water to the site of the buoy deployment was assessed. Second, preliminary predictions about the
potential impact of the buoys on the wave field are made. The results are discussed separately below.
Note that model code used herein is freely available soft ware and can be obtained through
http://www.wldelft.nl/soft/swan/. Input files specific to this work can be obtained through the author
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Publisher's note: "Waves on unsteady currents" [Phys. Fluids 19, 126601 (2007)]
This article was originally published online and in print with an incorrect version of Fig. 1. AIP apologizes for this error. All online versions of the article have been corrected
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Waves on unsteady currents
Models for surface gravity wave propagation in the presence of currents often assume the current field to be quasi-stationary, which implies that the absolute wave frequency is time invariant. However, in the presence of unsteady currents or time-varying water depth, linear wave theory predicts a time variation of the absolute wave frequency (and wavenumber). Herein, observations of wave frequency modulations from a large-scale laboratory experiment are presented. In this case, the modulations are caused by both unsteady depths and unsteady currents due to the presence of low-frequency standing waves. These new observations allow a unique and detailed verification of the theoretical predictions regarding variations in the absolute wave frequency. In addition, analytic solutions for the variations in frequency and wave height induced by the unsteady medium are found through a perturbation analysis. These solutions clarify the dependency of the wave frequency/wave height modulations on the characteristics of the unsteady medium. We also find that analytic solutions for simplified basin configurations provide an order of magnitude estimate of the expected frequency modulation effect. Finally, the importance of this phenomenon in natural situations is discussed
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Effects of wave-current interaction on shear instabilities of longshore currents
We examine the effects of wave-current interaction on the dynamics of instabilities of
the surf zone longshore current. We utilize coupled models for the simulation of the
incident waves and the wave-induced nearshore circulation. The coupling between the
models occurs through radiation stress gradient terms (accounting for the generation of
nearshore circulation) and through wave-current interaction terms (leading to the
modification of the wave field by the generated circulation field). Simulations are carried
out with a realistic barred beach configuration and obliquely incident waves for two
frictional regimes. The results show that the shear instabilities of the longshore current
have a significantly altered finite amplitude behavior when wave-current interaction
effects are included for beaches with relatively high frictional damping. The primary
effects are a reduction of the offshore extent of the motions and a delay of the onset of
instabilities. In addition, the energy content of the motions within two surf zone widths is
reduced, the propagation speed increases, and tendency to form offshore directed jets is
reduced. The horizontal mixing induced by the instabilities is also reduced when wave-current
interaction is considered, leading to a larger peak mean longshore current and a
larger offshore current shear. These effects appear to be primarily linked to a feedback
mechanism, whereby the incident wave field gains energy at locations of offshore directed
currents. For more energetic shear instability fields that occur when frictional damping is
small, this feedback affects the propagation speed and energy content of the instabilities
near and onshore of the current peak only minimally. However, the offshore extent of
the motions and the tendency to shed vortices offshore are still reduced. A reduction in the
mixing due to the instabilities is evident offshore of the current peak, hence the mean
longshore current profile is only affected offshore of the current peak. The inclusion of
wave-current interaction significantly affects the shear instability signature observed in the
shoreline runup for either frictional regime. These results indicate that the energy content
and frequency extent of the shoreline response is increased markedly due to the wave-current
interaction process. This effect appears to be related to variations in the forcing of
the circulation that arise due to the refraction of the incident waves around offshore
directed features of the circulation.Keywords: longshore currents, hydrodynamic instability, wave-current interactions, surf zone circulationKeywords: longshore currents, hydrodynamic instability, wave-current interactions, surf zone circulatio
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Power Calculations for a Passively Tuned Point Absorber Wave Energy Converter on the Oregon Coast
A wave-structure interaction model is implemented, and power output estimates are made for a simplified wave energy converter operating in measured spectral wave conditions. In order to estimate power output from a wave energy converter, device response to hydrodynamic forces is computed using a boundary element method potential flow model. A method is outlined for using the hydrodynamic response to estimate power output. This method is demonstrated by considering an idealized non-resonating wave energy converter with one year of measured spectral wave conditions from the Oregon coast. The power calculation is performed in the frequency domain assuming a passive tuning system which is tuned at time scales ranging from hourly to annually. It is found that there is only a 3% gain in productivity by tuning hourly over tuning annually, suggesting that for a non-resonating wave energy converter, power output is not very sensitive to the value of the power take off damping. Interaction between wave energy converters in arrays is also considered, and results for an array of idealized point absorbers suggests that interactions are minimal when devices are placed 10 diameters apart from each other.Keywords: Annual power prediction, Wave Energy Converter Array, WAMIT, Tuning, Optimal dampin
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Nearshore Wind-Wave Forecasting at the Oregon Coast
This presentation was given as part of Oregon State University's College of Oceanographic and Atmospheric Sciences graduate student seminar series. It describes the basics of wave forecasting and then focuses on work implementing a wave forecasting system for the Oregon and Southwestern Washington Coast
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Data assimilation and bathymetric inversion in a two鈥恉imensional horizontal surf zone model
A methodology is described for assimilating observations in a steady state twodimensional
horizontal (2鈥怐H) model of nearshore hydrodynamics (waves and currents),
using an ensemble鈥恇ased statistical estimator. In this application, we treat bathymetry as a
model parameter, which is subject to a specified prior uncertainty. The statistical estimator
uses state augmentation to produce posterior (inverse, updated) estimates of bathymetry,
wave height, and currents, as well as their posterior uncertainties. A case study is presented,
using data from a 2鈥怐 array of in situ sensors on a natural beach (Duck, NC). The prior
bathymetry is obtained by interpolation from recent bathymetric surveys; however, the
resulting prior circulation is not in agreement with measurements. After assimilating data
(significant wave height and alongshore current), the accuracy of modeled fields is
improved, and this is quantified by comparing with observations (both assimilated and
unassimilated). Hence, for the present data, 2鈥怐H bathymetric uncertainty is an important
source of error in the model and can be quantified and corrected using data assimilation. Here
the bathymetric uncertainty is ascribed to inadequate temporal sampling; bathymetric
surveys were conducted on a daily basis, but bathymetric change occurred on hourly
timescales during storms, such that hydrodynamic model skill was significantly degraded.
Further tests are performed to analyze the model sensitivities used in the assimilation and to
determine the influence of different observation types and sampling schemes.Keywords: Two-dimensional horizontal surf zon
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Quantifying the length-scale dependence of surf zone advection
We investigate the momentum balance in the surf zone, in a setting which is weakly varying in the alongshore direction. Our focus is on the role of nonlinear advective terms. Using numerical experiments, we find that advection tends to counteract alongshore variations in momentum flux, resulting in more uniform kinematics. Additionally, advection causes a shifting of the kinematic response in the direction of flow. These effects are strongest at short alongshore length scales, and/or strong alongshore-mean velocity. The length-scale dependence is investigated using spectral analysis, where the effect of advective terms is treated as a transfer function applied to the solution to the linear (advection-free) equations of motion. The transfer function is then shown to be governed by a nondimensional parameter which quantifies the relative scales of advection and bottom stress, analogous to a Reynolds Number. Hence, this parameter can be used to quantify the length scales at which advective terms, and the resulting effects described above, are important. We also introduce an approximate functional form for the transfer function, which is valid asymptotically within a restricted range of length scales.Keywords: Rip currents, Models, Nearshore circulation, Barred beaches, Stresses, Longshore currents, Nonlinear shear instabilities, Incident sea waves, Shallow water, Alongshore current
Effects of wave鈥恈urrent interaction on shear instabilities of longshore currents
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/94870/1/jgrc8986.pd
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Mechanistic analysis of the wave-current interaction in the plume region of a partially mixed tidal inlet
In this research, a three-dimensional coupled wave-circulation model, including meteorological forcing, freshwater inflow and time varying open boundary conditions, for New River Inlet is validated. A mechanistic approach is taken to investigate how various wave-current interaction mechanisms affect the nearshore circulation, plume expansion and surface wave field in the plume region of a relatively small partially mixed tidal estuarine system. More specifically, focus is comparing four different modeling cases including: (1) a three-dimensional ocean circulation model (no wave effects), (2) a coupled wave-circulation model, (3) a coupled wave and circulation model including vertical mixing enhancement due to wave breaking, and (4) a wave model without surface current effects. Findings reveal forces are applied by incoming waves due to various wave-current interaction mechanisms. Wave momentum released by incoming waves pushes the outgoing freshwater ebb plume back to the shoreline and prevents the plume from expanding freely towards the open ocean. Findings also reveals that releasing wave-dissipated energy in the expanding plume region enhances vertical mixing, mixes down freshwater, and therefore thickens the plume. These results are congruent with observations at the mouth of the Columbia River