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Using difference modelling and computational fluid dynamics to investigate the evolution of complex, tidally influenced shipwreck sites
Majcher, J.; Quinn, R.; Smyth, T.; Plets, R.; McGonigle, C.; Westley, K.; Sacchetti, F.; Coughlan, M. (2022). Using difference modelling and computational fluid dynamics to investigate the evolution of complex, tidally influenced shipwreck sites. Ocean Eng. 246: 110625. https://dx.doi.org/10.1016/j.oceaneng.2022.110625
In: Ocean Engineering. Pergamon: Elmsford. ISSN 0029-8018; e-ISSN 1873-5258
Peer reviewed article  

Available in  Authors 
    Vlaams Instituut voor de Zee: Open access 378060 [ download pdf ]

Keyword
    Marine/Coastal
Author keywords
    Multibeam echosounder; Computational fluid dynamics; Shipwreck; Hydro-dynamics; Sediment-dynamics

Authors  Top 
  • Majcher, J.
  • Quinn, R.
  • Smyth, T.
  • Plets, R.
  • McGonigle, C.
  • Westley, K.
  • Sacchetti, F.
  • Coughlan, M.

Abstract
    The large number of historic metal-hulled shipwrecks on the seabed is a major consideration for the marine environment, heritage management and spatial planning. Their stability is driven by linked hydro- and sediment-dynamics, which in turn influence chemical corrosion and biological encrustation. The dynamism at underwater sites is frequently expressed in elaborate patterns of depositional and erosional features developed due to seabed scour. These settings are complex, due to the variable morphologies of the wrecks, and diverse types of seabed geology and geomorphology. Not only are the flow patterns and geomorphic changes at shipwreck sites not fully understood, but how these influence the wreck structures remains under-researched. Here we combine high-resolution multibeam echosounder, ocean current and sediment data with 3D Computational Fluid Dynamics (CFD) to investigate interrelations between hydro- and sediment-dynamics and the deterioration of two complex, fully submerged tidally-influenced shipwrecks. Intricate patterns of wake and horseshoe vortices are observed, and modelled wall shear stresses predict geomorphic changes recorded in 4-year and one-week interval difference models. Moreover, substantial damage is detected on the wrecks, correlated with areas of elevated wall shear stress and pressure in CFD simulations. The combined approach aids site management and provides analogies for offshore engineering.

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