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A platform for research: civil engineering, architecture and urbanism
Breaking wave-induced response of composite breakwater and liquefaction in seabed foundation
Abstract In the practice of engineering, breaking wave is much more dangerous for the stability of composite breakwater built on porous seabed than non-breaking wave in offshore area. In previous investigations or design codes, the empirical formulations generally were adopted to estimate the wave impact acting on the lateral side of caisson. The interaction between breaking wave, seabed foundation and composite breakwater is not taken into consideration. In this study, adopting the integrated numerical model PORO-WSSI 2D developed by (Ye, 2012a) and (Jeng et al., 2013), the interaction mechanism between breaking wave, seabed foundation and composite breakwater is investigated numerically. In PORO-WSSI 2D,the Volume-Averaged Reynolds Averaged Navier–Stokes (VARANS) equations govern the wave motion and the porous flow in seabed foundation and in rubble mound; and the dynamic Biot's equations (known as “u-p” approximation) govern the dynamic behaviors of seabed foundation and composite breakwater under breaking wave loading. Numerical analysis indicates that the turbulent energy of breaking wave is significant, and the wave impact on caisson applied by breaking wave is much greater than non-breaking wave. The composite breakwater and its seabed foundation respond to the breaking wave loading intensively. The maximum horizontal vibration magnitude of the composite breakwater is up to 5mm; the maximum liquefaction depth in the seabed in front of the composite breakwater reaches up to 1.2 to 1.6m. The parametric study shows that the permeability and saturation of seabed, wave height are three dominant factors for the wave-induced liquefaction in seabed foundation.
Highlights Interaction between breaking wave-breakwater-porous seabed is investigated. Biot's dynamic “u-p” formulation is used for dynamic soil behaviour. Breaking wave-induced impact on breakwater is determined by VARANS equation. Breaking wave-induced dynamics of breakwater and its foundation is determined quantitatively. Breaking wave-induced transient liquefaction in seabed foundation is captured effectively.
Breaking wave-induced response of composite breakwater and liquefaction in seabed foundation
Abstract In the practice of engineering, breaking wave is much more dangerous for the stability of composite breakwater built on porous seabed than non-breaking wave in offshore area. In previous investigations or design codes, the empirical formulations generally were adopted to estimate the wave impact acting on the lateral side of caisson. The interaction between breaking wave, seabed foundation and composite breakwater is not taken into consideration. In this study, adopting the integrated numerical model PORO-WSSI 2D developed by (Ye, 2012a) and (Jeng et al., 2013), the interaction mechanism between breaking wave, seabed foundation and composite breakwater is investigated numerically. In PORO-WSSI 2D,the Volume-Averaged Reynolds Averaged Navier–Stokes (VARANS) equations govern the wave motion and the porous flow in seabed foundation and in rubble mound; and the dynamic Biot's equations (known as “u-p” approximation) govern the dynamic behaviors of seabed foundation and composite breakwater under breaking wave loading. Numerical analysis indicates that the turbulent energy of breaking wave is significant, and the wave impact on caisson applied by breaking wave is much greater than non-breaking wave. The composite breakwater and its seabed foundation respond to the breaking wave loading intensively. The maximum horizontal vibration magnitude of the composite breakwater is up to 5mm; the maximum liquefaction depth in the seabed in front of the composite breakwater reaches up to 1.2 to 1.6m. The parametric study shows that the permeability and saturation of seabed, wave height are three dominant factors for the wave-induced liquefaction in seabed foundation.
Highlights Interaction between breaking wave-breakwater-porous seabed is investigated. Biot's dynamic “u-p” formulation is used for dynamic soil behaviour. Breaking wave-induced impact on breakwater is determined by VARANS equation. Breaking wave-induced dynamics of breakwater and its foundation is determined quantitatively. Breaking wave-induced transient liquefaction in seabed foundation is captured effectively.
Breaking wave-induced response of composite breakwater and liquefaction in seabed foundation
Jianhong, Ye (author) / Dongsheng, Jeng (author) / Liu, P.L.-F. (author) / Chan, A.H.C. (author) / Ren, Wang (author) / Changqi, Zhu (author)
Coastal Engineering ; 85 ; 72-86
2013-08-10
15 pages
Article (Journal)
Electronic Resource
English
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