Ting Zhou scite author profile

Ting Zhou

5Publications

3Citation Statements Received

73Citation Statements Given

How they've been cited

How they cite others

179

Affiliations

Dalian University of Technology, Chongqing Three Gorges University

Publications

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Simulation on tsunami-like solitary wave run-up around a conical island using a modified mass source method

Zhou

Sun

et al. 2019

Engineering Applications of Computational Fluid Mechanics

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Predicting the maximum run-up height and inundated area caused by tsunami events has been a hotly debated topic recently. Nevertheless, the wave height-to-depth ratios (nonlinearity) adapted previously tended to be conservative, considering the fact that a tsunami wave is an extreme wave condition with large wave height. In the present study, a mass source wave-generating approach for highly nonlinear waves is presented using our in-house solver, DUT-FOAM, which is a hydrodynamic solver developed using the open source code library OpenFOAM. By fully considering the mass output from the source region, a more reasonable mass source function has been obtained to compensate for the inadequacy of original method in simulating highly nonlinear waves. A newly designed numerical wave tank is performed for different nonlinearities. Numerical simulations of tsunami wave propagating to a conical island are carried. Fairly good agreements are obtained from the qualitative and quantitative comparisons between numerical results (Liu, Cho, Briggs, Kanoglu, & Synolakis, 1995) and laboratory data (Briggs, Synolakis, Harkins, & Green, 1995) regarding run-up maps around the island. The comparison reveals that present model offers a fast and accurate way to simulate highly nonlinear waves and is potentially useful and efficient for forecasting the run-up heights.

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Numerical study of the run-up of a solitary wave after propagation over a saw-tooth-shaped submerged breakwater

Sun

Wang

et al. 2020

International Journal of Naval Architecture and Ocean Engineeri

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Comparison of impulsive wave forces on a semi-submerged platform deck, with and without columns and considering air compressibility effects, under regular wave actions

Zhai

Zhou

et al. 2021

Engineering Applications of Computational Fluid Mechanics

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Numerical investigation of breaking waves impact on vertical breakwater with impermeable and porous foundation

Zhou

Yin

et al. 2023

Ocean Engineering

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A Comprehensive Study of the Wave Impact Loads on an Inclined Plate

Zhou

Ren

et al. 2019

JMSE

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Water wave impact on a wet deck is an important issue in ocean engineering, and the plate-shaped structure in the splash zone tends to suffer tremendous impact loads. This work presents a method for predicting the wave slamming uplift force on a fixed plate with different inclined angles. Both numerical simulation and the scale model test of the wave impact loads on an inclined plate were performed, and a good agreement was obtained. In addition, the influence of three important wave parameters on the slamming uplift force was systematically investigated: relative deck width B/LS, relative wave height Δh/H1/3, and the plate’s inclined angle α. The results indicate that the three parameters can significantly influence the wave slamming uplift force. Finally, a developed empirical equation is proposed for estimating the wave slamming uplift force on the inclined plate.

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Ting Zhou

Simulation on tsunami-like solitary wave run-up around a conical island using a modified mass source method

Numerical study of the run-up of a solitary wave after propagation over a saw-tooth-shaped submerged breakwater

Comparison of impulsive wave forces on a semi-submerged platform deck, with and without columns and considering air compressibility effects, under regular wave actions

Numerical investigation of breaking waves impact on vertical breakwater with impermeable and porous foundation

A Comprehensive Study of the Wave Impact Loads on an Inclined Plate

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