The role of submerged berms on the momentary liquefaction around conventional rubble mound breakwaters

•The influence of submerged berms on the seabed soil response and liquefaction occurrences around breakwaters foundations is investigated.•Wave-structure-seabed interaction has been evaluated by using two numerical tools, employing a one-way coupling algorithm.•A parametric study on the berm configu...

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Bibliographic Details
Published in:Applied ocean research 2019-04, Vol.85, p.1-11
Main Authors: Celli, Daniele, Li, Yuzhu, Ong, Muk Chen, Di Risio, Marcello
Format: Article
Language:English
Subjects:
Berm
Berms
Breakwaters
Elastic properties
Free surfaces
Height
Liquefaction
Momentary liquefaction
Numerical models
Ocean floor
Offshore
Porosity
Probability theory
Regular waves
Rubblemound breakwaters
Soil
Soil properties
Stability
SWASH
Water depth
Water waves
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Summary:•The influence of submerged berms on the seabed soil response and liquefaction occurrences around breakwaters foundations is investigated.•Wave-structure-seabed interaction has been evaluated by using two numerical tools, employing a one-way coupling algorithm.•A parametric study on the berm configuration has been carried out.•A comparison with straight sloped conventional breakwater is performed. Berms deployed at the toe of conventional rubble mound breakwaters can be very effective in improving the stability of the armor layer. Indeed, their design is commonly tackled by paying attention to armor elements dimensioning. Past research studies showed how submerged berms can increase the stability of the armor layer if compared to straight sloped conventional breakwaters without a berm. To fill the gap of knowledge related to the interaction between breakwaters with submerged berm, waves and soil, this research aims to evaluate how submerged berms configuration influences the seabed soil response and momentary liquefaction occurrences around and beneath breakwaters foundation, under dynamic wave loading. The effects of submerged berms on the incident waves transformation have been evaluated by means of a phase resolving numerical model for simulating non-hydrostatic, free-surface, rotational flows. The soil response to wave-induced seabed pressures has been evaluated by using an ad-hoc anisotropic poro-elastic soil solver. Once the evaluation of the seabed consolidation state due to the presence of the breakwater has been performed, the dynamic interaction among water waves, soil and structure has been analyzed by using a one-way coupling boundary condition. A parametric study has been carried out by varying the berm configuration (i.e. its height and its length), keeping constant the offshore regular wave condition, the berm and armor layer porosity values, the water depth and the elastic properties of the soil. Results indicate that the presence of submerged berms tends to mitigate the liquefaction probability if compared to straight sloped conventional breakwater without a berm. In addition, it appears that the momentary liquefaction phenomena are more influenced by changing the berm length rather than the berm height.
ISSN:0141-1187
1879-1549
DOI:10.1016/j.apor.2019.01.023