Response of a Porous Seabed around an Immersed Tunnel under Wave Loading: Meshfree Model

Han, Shuang; Jeng, Dong‐Sheng; Tsai, Chia‐Cheng

doi:10.3390/jmse7100369

Cited by 13 publications

(5 citation statements)

References 47 publications

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“…The phenomenon of the fluid-seabed interactions has been analytically investigated under various conditions without a structure (Yamamoto et al, 1978;Madsen, 1978;Hsu and Jeng, 1994;Zhang et al, 2013). When a structure is considered, the complicated boundary conditions make the numerical analyses indispensable, such as submarine pipelines (Jeng and Lin, 1999;Gao et al, 2003;Zhao et al, 2014;Zhao and Jeng, 2016;Lin et al, 2016;Duan et al, 2017;Li et al, 2019;Liang et al, 2020;Liang and Jeng, 2021), breakwaters (Jeng et al, 2013;Zhang et al, 2018a;Celli et al, 2019), coastal slopes (Young et al, 2009), offshore wind turbine foundations (Chang and Jeng, 2014;Qi and Gao, 2014;Sui et al, 2016;Lin et al, 2017;Zhao et al, 2017;Li et al, 2018) and immersed tunnels (Han et al, 2019;Chen et al, 2021) etc. The structure-seabed interactions may introduce additional complexities, e.g.…”

Section: Introductionmentioning

confidence: 99%

A non-Darcy flow model for a non-cohesive seabed involving wave-induced instantaneous liquefaction

Zhou

Jeng

et al. 2021

Ocean Engineering

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Section: Introductionmentioning

confidence: 99%

A non-Darcy flow model for a non-cohesive seabed involving wave-induced instantaneous liquefaction

Zhou

Jeng

et al. 2021

Ocean Engineering

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“…Han et al [4] investigate the flow field dynamics and corresponding response of a porous seabed around an immersed tunnel under wave loading combined current with various velocities. They developed a 2D numerical model, which is composed of two sub-models: The flow model with OpenFOAM and the seabed model with a Meshfree method, to simulate the fluid-structure-seabed interaction.…”

Section: Papers Detailsmentioning

confidence: 99%

“…The issue collected 14 papers that cover different aspects of marine engineering geology and geotechnics using different approaches. Some of them used numerical simulations [1][2][3][4][5], some conducted laboratory experiments [6][7][8][9][10], and others acquired and analyzed field or laboratory tests to establish a theoretical modeling framework for predicting marine sediment properties and the potential hazards [11][12][13][14]. Moreover, with a timely and well-organized publication, it is believed that the state-of-the-art data, analyses, and methodologies presented in this Special Issue could be of great interest to all readers of Journal of Marine Science and Engineering.…”

Section: Introductionmentioning

confidence: 99%

New Advances in Marine Engineering Geology

Liu

Yang

Wang

et al. 2021

JMSE

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“…For the case of a pure seabed without a structure, several analytical solutions have been developed under various conditions [12][13][14][15]. However, for a seabed including structures such as submarine pipelines [16][17][18][19][20][21][22][23][24][25][26], breakwaters [27][28][29], coastal slopes [30], offshore wind turbine foundations [31][32][33][34][35][36][37], gravity-based structure (GBS) offshore platforms [38], dumbbell-shaped cofferdams [39], and immersed tunnels [40,41], the presence of the structures complicates the boundary conditions, generally requiring numerical methods for analyses. Recently, Li et al [42] developed an open-source numerical toolbox for simulating the interaction between a porous seabed, waves, and structures.…”

Section: Introductionmentioning

confidence: 99%

Wave-Induced Instantaneous Liquefaction of a Non-Cohesive Seabed around Buried Pipelines: A Liquefaction-Associated Non-Darcy Flow Model Approach

Han,

Zhou,

Zhang

et al. 2024

JMSE

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In complex marine environments, the wave-induced instantaneous liquefaction of the seabed is a key issue for the long-term safety control of marine structures. Existing computational frameworks for instantaneous liquefaction result in unreasonable tensile stresses in a non-cohesive seabed. To address this issue, a liquefaction-associated non-Darcy flow model has been proposed, but it has only been applied to the scenario of a pure seabed without a structure. In this study, we applied the previously proposed non-Darcy flow model to investigate the mechanism of wave–seabed–structure interactions under extreme wave loading considering a pipeline fully buried in a non-cohesive seabed. By comparing the liquefaction depths in the presence and absence of structures, it was found that the existence of structures weakens the attenuation of the pore pressure amplitude and influences the overall pore pressure distribution. Parametric studies were conducted. It was found that the liquefaction depth from the non-Darcy model is approximately 0.73 times that from the traditional Darcy model, regardless of whether or not a pipeline is involved. A quantitative relationship between the wave loading and structural size was established. The liquefied zone above the buried pipeline was found to be smaller than that in a pure seabed without a structure. A tentative explanation is provided for this phenomenon.

show abstract

Response of a Porous Seabed around an Immersed Tunnel under Wave Loading: Meshfree Model

Cited by 13 publications

References 47 publications

A non-Darcy flow model for a non-cohesive seabed involving wave-induced instantaneous liquefaction

A non-Darcy flow model for a non-cohesive seabed involving wave-induced instantaneous liquefaction

New Advances in Marine Engineering Geology

Wave-Induced Instantaneous Liquefaction of a Non-Cohesive Seabed around Buried Pipelines: A Liquefaction-Associated Non-Darcy Flow Model Approach

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