Hydroelastic performance of a flexible pontoon-type floating breakwater embedded with multiple oscillating-water-column devices

Hu, Yinong and Cheng, Yong and Dai, Saishuai and Yuan, Zhiming and Incecik, Atilla (2026) Hydroelastic performance of a flexible pontoon-type floating breakwater embedded with multiple oscillating-water-column devices. Renewable Energy, 259. 125065. ISSN 0960-1481 (https://doi.org/10.1016/j.renene.2025.125065)

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Abstract

Combining Wave Energy Converters (WECs) with a long-flexible floating breakwater is a plausible pathway to the engineering application of wave energy technologies, which not only enhances energy capture capability but also improves structural stability of breakwater. This study proposes a multi-module flexible pontoon-type floating breakwater integrated with oscillating water column (OWC) units. Each chamber features an independent power take-off (PTO) system for energy capture. A coupled fluid-structure interaction model, integrating Computational Fluid Dynamics (CFD) with Finite Element Method (FEM), is developed to investigate the hydroelastic response. The bi-directional coupled process is realized by satisfying constant boundary conditions between fluid velocity and pressure, and structural node displacements at each time step. Parametric studies demonstrate that flexible structures offer superior adaptability to wave loading compared to rigid counterparts, effectively reducing wave-induced forces while maintaining energy capture. Further analysis reveal that increased structural stiffness enhances internal resonance within chambers, significantly improving capture factors, whereas excessive flexibility can trigger complex multimode radiated wave interactions, adversely affecting energy conversion efficiency. Additionally, incorporating a bottom opening strengthens wave resonance within the chamber, thereby increasing energy dissipation. These findings highlight practical advantages of multi-module flexible floating breakwaters, providing valuable guidelines for design and optimization in engineering applications.

ORCID iDs

Dai, Saishuai ORCID: https://orcid.org/0000-0002-9666-6346

Yuan, Zhiming ORCID: https://orcid.org/0000-0001-9908-1813

Incecik, Atilla ORCID: https://orcid.org/0009-0006-8895-1717

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• Item metadata

  Item type:	Article
  ID code:	95548
  Dates:	Date Event 1 March 2026 Published 20 December 2025 Published Online 16 December 2025 Accepted 25 April 2025 Submitted
  Subjects:	Technology > Hydraulic engineering. Ocean engineering Technology > Electrical engineering. Electronics Nuclear engineering > Production of electric energy or power
  Department:	Faculty of Engineering > Naval Architecture, Ocean & Marine Engineering Faculty of Engineering
  Depositing user:	Pure Administrator
  Date deposited:	13 Feb 2026 10:18
  Last modified:	10 Mar 2026 17:11
  Related URLs:	Strathprints record
  URI:	https://strathprints.strath.ac.uk/id/eprint/95548