Coupled Flow-Seepage-Elastoplastic Modeling for Competition Mechanism between Lateral Instability and Tunnel Erosion of a Submarine Pipeline

Abstract: The instability of a partially embedded pipeline under ocean currents involves complex fluid–pipe–soil interactions, which may induce two typical instability modes; i.e., the lateral instability of the pipe and the tunnel erosion of the underlying soil. In previous studies, such two instability modes were widely investigated, but separately. To reveal the competition mechanism between the lateral instability and the tunnel erosion, a coupled flow-seepage–elastoplastic modeling approach was proposed that could … Show more

“…To reveal the competition mechanism between the lateral instability and tunnel erosion of a submarine pipeline, a coupled flow-seepage-elastoplastic modeling approach was proposed [11]. The instability envelope for the flow-pipe-soil interaction was established, which could be described by three parameters, i.e., the critical flow velocity, the embedmentto-diameter ratio, and the non-dimensional submerged weight of the pipe.…”

Instability and Failure of Subsea Structures

“…To reveal the competition mechanism between the lateral instability and tunnel erosion of a submarine pipeline, a coupled flow-seepage-elastoplastic modeling approach was proposed [11]. The instability envelope for the flow-pipe-soil interaction was established, which could be described by three parameters, i.e., the critical flow velocity, the embedmentto-diameter ratio, and the non-dimensional submerged weight of the pipe.…”

Instability and Failure of Subsea Structures

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