Hull geometry optimisation of wave energy converters: On the choice of the optimisation algorithm and the geometry definition

Garcia-Teruel, Anna; DuPont, Bryony; Forehand, David

doi:10.1016/j.apenergy.2020.115952

Cited by 34 publications

(48 citation statements)

References 23 publications

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“…For categories not mentioned here, no geometry studies were available to the knowledge of the authors. point absorbersingle bodyfloating [33], [34], [35], [36], [37], [38], [39], [40], [41], [42], [43], [26], [44], [45], [46], [47], [48], [49], [50] [51], [52], [53], [54], [55], [56], [57], [58], [59], [60], [61], [62], [63] B point absorbersingle bodysubmerged [64], [65], [66] [67], [68], [69] C point absorbertwo body [70], [71], [72] [73], [74], [56],…”

Section: Wave Energy Converter Typesmentioning

confidence: 99%

A review of geometry optimisation of wave energy converters

Garcia-Teruel

Forehand

2021

Renewable and Sustainable Energy Reviews

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Section: Wave Energy Converter Typesmentioning

confidence: 99%

A review of geometry optimisation of wave energy converters

Garcia-Teruel

Forehand

2021

Renewable and Sustainable Energy Reviews

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“…However, in order to define a single curve (instead of a piece-wise composition of three curves), a Bezier curve has been fitted to the profile. Bezier curves are generic parametric curves and a flexible tool to represent complex geometries (Garcia-Teruel et al 2020).…”

Section: Heave-pitch Device: Direct Pitch Extractionmentioning

confidence: 99%

“…The novel contribution of this paper is to provide a fast NLFK force computation framework, based on the analytical representation of the wetted surface of generic prismatic floaters. State-of-the-art mesh-based NLFK models, although able to handle geometries of arbitrary complexity, are too slow to be applied for computationally demanding tasks, such as power production assessment and control; moreover, mesh-based approaches are less transparent then fully-analytical models: based on a closed-form analytical description of the wetted surface, it is possible to apply advanced model-order reduction techniques (Faedo et al 2020a) and geometry-based optimizations (Garcia-Teruel et al 2020). The modelling approach has been validated against experimental data for an application based on an axisymmetric wave energy converter (Giorgi et al 2020b), providing confidence that such a mathematical framework is appropriate to describe the dynamics also of a pitching wave energy converter under operational conditions, excluding extreme events.…”

Section: Introductionmentioning

confidence: 99%

Fast nonlinear Froude–Krylov force calculation for prismatic floating platforms: a wave energy conversion application case

Giorgi

Sirigu

Bonfanti

et al. 2021

J. Ocean Eng. Mar. Energy

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Computationally fast and accurate mathematical models are essential for effective design, optimization, and control of wave energy converters. However, the energy-maximising control strategy, essential for reaching economic viability, inevitably leads to the violation of linearising assumptions, so the common linear models become unreliable and potentially unrealistic. Partially nonlinear models based on the computation of Froude–Krylov forces with respect to the instantaneous wetted surface are promising and popular alternatives, but they are still too slow when floaters of arbitrary complexity are considered; in fact, mesh-based spatial discretisation, required by such geometries, becomes the computational bottle-neck, leading to simulations 2 orders of magnitude slower than real-time, unaffordable for extensive iterative optimizations. This paper proposes an alternative analytical approach for the subset of prismatic floating platforms, common in the wave energy field, ensuring computations 2 orders of magnitude faster than real-time, hence 4 orders of magnitude faster than state-of-the-art mesh-based approaches. The nonlinear Froude–Krylov model is used to investigate the nonlinear hydrodynamics of the floater of a pitching wave energy converter, extracting energy either from pitch or from an inertially coupled internal degree of freedom, especially highlighting the impact of state constraints, controlled/uncontrolled conditions, and impact on control parameters’ optimization, sensitivity and effectiveness.

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“…A more adaptable method able of generating diverse shapes was developed by McCabe et al [9,10], which employs bi-cubic Bspline surfaces to represent the submerged hull. This approach was expanded by Garcia-Teruel et al to be applicable in multiple degrees-of-freedom [11] and to ensure robustness of the method for a number of applications [12]. In these latter studies, costs were represented through the hull's submerged surface area and submerged volume, but reliability was not considered.…”

Section: Previous Workmentioning

confidence: 99%

“…We assume the PTO system is composed of a moving rod welded to the floating body and a fixed component. The geometry is defined so that diverse shapes can be generated through the optimisation approach introduced by McCabe FIGURE 3 Polyhedron with numbered vertices v n and example representations of the interpolated control points in grey [26] et al [10]. The results of the optimisation are compared to a static non-optimised barge shape with dimensions chosen so that its draft (10 m) and characteristic width (20 m) are comparable to the generated, optimal hull shapes.…”

Section: Wec System and Hull Geometry Definitionmentioning

confidence: 99%

Reliability‐based hull geometry optimisation of a point‐absorber wave energy converter with power take‐off structural reliability objectives

Garcia-Teruel

Clark

2021

IET Renewable Power Gen

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Recent studies have focused on optimising wave energy converter (WEC) designs, maximising their power performance and techno‐economic feasibility. Reliability has yet to be fully considered in these formulations, despite its impact on cost and performance. In this study, this gap is addressed by developing a reliability‐based design optimisation framework for WEC hull geometries to explore the trade‐off between power performance and power take‐off (PTO) system damage equivalent loading (DEL). Optimised hull geometries for two sites are considered (from the centre of the North Sea and off the west coast of Norway), and two directions of motions (heave and surge). Results indicate that site characteristics affect the potential power production and DEL for an optimal WEC design. These are also affected by the direction of motion for power extraction, which also significantly changes optimal hull shape characteristics. Optimal surging WEC designs have edges facing oncoming wave directions, while heaving WECs have pointed bottoms, both to streamline movement. Larger, more convex WECs result in greater power production and DEL, while smaller, more concave WECs result in lesser power production and DEL. These findings underline the importance of considering WEC hull geometry in early design processes to optimise cost, power production, and reliability.

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Hull geometry optimisation of wave energy converters: On the choice of the optimisation algorithm and the geometry definition

Cited by 34 publications

References 23 publications

A review of geometry optimisation of wave energy converters

A review of geometry optimisation of wave energy converters

Fast nonlinear Froude–Krylov force calculation for prismatic floating platforms: a wave energy conversion application case

Reliability‐based hull geometry optimisation of a point‐absorber wave energy converter with power take‐off structural reliability objectives

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