Peña-Sanchez, Yerai (2020) Hydrodynamic excitation force estimation and forecasting for wave energy applications. PhD thesis, National University of Ireland Maynooth.
Preview
Thesis_YeraiPeñaSanchez.pdf
Download (12MB) | Preview
Abstract
Ocean waves represent a significant energy resource which can complement other
renewable energy technologies during the transition to a low-carbon energy mix.
Despite the large number of concepts suggested for the conversion of wave energy,
none of the technologies has yet demonstrated economic viability. To this end,
several solutions have been proposed in the literature, such as deploying Wave Energy
Converters (WECs) in large arrays or optimal control of WECs.
The majority of WEC optimal control strategies require knowledge of the previous,
current, and future excitation force acting on the device. However, for the WEC
case, the excitation force is an unmeasurable quantity and, therefore, must first be
estimated, based on available measurements, and then predicted in the future. The
main objective of this thesis is to analyse the estimation/prediction techniques proposed
for wave energy applications and to evaluate whether such techniques are ready to
be applied for real WEC control strategies. To this end, a critical comparison of the
available excitation force estimators is presented. Additionally, the performance of the
autoregressive model as a predictor is analysed, showing that, the obtained prediction
accuracy can get close to the theoretically best achievable prediction accuracy.
Based on the errors observed from the analysis of excitation force estimation/prediction
techniques, a sensitivity analysis of an optimal control strategy to such errors is
performed. As a result, this thesis provides an overview of the aspects which should be
considered at the stage of tuning estimation/prediction techniques, to not affect
the controller performance.
Since the estimation/prediction problem becomes more challenging for WEC arrays,
due to the hydrodynamic interactions, an important question is whether the extra
measurements from the array are sufficient to compensate for the greater complexity
of the wave field. Thus, a global estimator/predictor, considering information from
all the devices of the array, is developed and compared to a set of independent
estimators/predictors.
Finally, this thesis introduces an identification strategy to obtain a parametric model
of both the force-to-motion dynamics and/or the radiation force convolution term of
the device. The strategy allows for the identification of low-order parametric models
of WECs, which will simplify the implementation of optimal control strategies in
real-time. Additionally, the proposed strategy is compared to the other approaches
available in the literature.
Item Type: | Thesis (PhD) |
---|---|
Keywords: | Hydrodynamic; excitation force estimation; forecasting; wave energy; applications; |
Academic Unit: | Faculty of Science and Engineering > Electronic Engineering Faculty of Science and Engineering > Research Institutes > Centre for Ocean Energy Research |
Item ID: | 13532 |
Depositing User: | IR eTheses |
Date Deposited: | 05 Nov 2020 16:17 |
URI: | https://mu.eprints-hosting.org/id/eprint/13532 |
Use Licence: | This item is available under a Creative Commons Attribution Non Commercial Share Alike Licence (CC BY-NC-SA). Details of this licence are available here |
Repository Staff Only (login required)
Downloads
Downloads per month over past year