Reprint

Assessment and Nonlinear Modeling of Wave, Tidal and Wind Energy Converters and Turbines

Edited by
September 2020
290 pages
  • ISBN978-3-03936-912-6 (Hardback)
  • ISBN978-3-03936-913-3 (PDF)

This is a Reprint of the Special Issue Assessment and Nonlinear Modeling of Wave, Tidal and Wind Energy Converters and Turbines that was published in

Chemistry & Materials Science
Engineering
Environmental & Earth Sciences
Physical Sciences
Summary
The Special Issue “Assessment and Nonlinear Modeling of Wave, Tidal, and Wind Energy Converters and Turbines” contributes original research to stimulate the continuing progress of the offshore renewable energy (ORE) field, with a focus on state-of-the-art numerical approaches developed for the design and analysis of ORE devices. Particularly, this collection provides new methodologies, analytical/numerical tools, and theoretical methods that deal with engineering problems in the ORE field of wave, wind, and current structures. This Special Issue covers a wide range of multidisciplinary aspects, such as the 1) study of generalized interaction wake model systems with elm variation for offshore wind farms; 2) a flower pollination method based on global maximum power point tracking strategy for point-absorbing type wave energy converters; 3) performance optimization of a Kirsten–Boeing turbine using a metamodel based on neural networks coupled with CFD; 4) proposal of a novel semi-submersible floating wind turbine platform composed of inclined columns and multi-segmented mooring lines; 5) reduction of tower fatigue through blade back twist and active pitch-to-stall control strategy for a semi-submersible floating offshore wind turbine; 6) assessment of primary energy conversion of a closed-circuit OWC wave energy converter; 7) development and validation of a wave-to-wire model for two types of OWC wave energy converters; 8) assessment of a hydrokinetic energy converter based on vortex-induced angular oscillations of a cylinder; 9) application of wave-turbulence decomposition methods on a tidal energy site assessment; 10) parametric study for an oscillating water column wave energy conversion system installed on a breakwater; 11) optimal dimensions of a semisubmersible floating platform for a 10 MW wind turbine; 12) fatigue life assessment for power cables floating in offshore wind turbines.
Format
  • Hardback
License and Copyright
© 2020 by the authors; CC BY-NC-ND license
Keywords
off-shore wind farms (OSWFs); wake model; wind turbine (WT); Extreme Learning Machine (ELM); wind power (WP); large-eddy simulation (LES); point-absorbing; wave energy converter (WEC); maximum power point tracking (MPPT); flower pollination algorithm (FPA); power take-off (PTO); hill-climbing method; Kirsten–Boeing; vertical axis turbine; optimization; neural nets; Tensorflow; ANSYS CFX; metamodeling; FOWT; multi-segmented mooring line; inclined columns; semi-submersible; AFWT; floating offshore wind turbine (FOWT); pitch-to-stall; blade back twist; tower fore–aft moments; negative damping; blade flapwise moment; tower axial fatigue life; wave energy; oscillating water column; tank testing; valves; air compressibility; wave energy; oscillating water column; air turbine; valves; wave-to-wire model; energy harnessing; energy converter; flow-induced oscillations; vortex-induced vibration; flow–structure interaction; hydrodynamics; vortex shedding; cylinder wake; tidal energy; site assessment; wave-current interaction; turbulence; integral length scales; wave-turbulence decomposition; OWC; wave energy; wave power converting system; parametric study; caisson breakwater application; floating offshore wind turbines; frequency domain model; semisubmersible platform; 10 MW wind turbines; large floating platform; platform optimization; wind energy; floating offshore wind turbine; dynamic analysis; fatigue life assessment; flexible power cables

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