Validation of a lumped-mass mooring line model with DeepCwind semisubmersible model test data

In advance of building moored floating offshore platforms, in recent years, there has been a greater demand for two-way coupled simulations between a motion solver based on the viscous flow theory and a mooring line model, including cable dynamics. This paper introduces open-source libraries such as MoorDyn (the lumped-mass mooring line model) and OpenFOAM (the computational fluid dynamics libraries). It describes the methods by which they can be coupled bi-directionally. In each time step, the platform motions calculated by OpenFOAM are transferred to MoorDyn as the boundary conditions for the mooring system analysis. In contrast, MoorDyn calculates the restoring force and moment due to the mooring system and transfers them to OpenFOAM. The restoring force and moment act on the platform as the external force and moment for the platform motions in the next time step. The static tension and profile of the mooring system, dynamic tension of the mooring system, and free decay motions of the floating buoy in the still water were simulated to check the accuracy of OpenFOAM and MoorDyn. The coupled solver was used to produce simulations of the moored decay motions of the floating buoy in the still water and the moored motions with the Stokes 5th order wave. All simulation results were compared and showed good agreement with the numerical solution and experiment results. In addition, the characteristics of each solver were investigated.

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Joint High Speed Sealift (JHSS) Segmented Model Test Data Analysis and Validation of Numerical Simulations

10.21236/ada576106 ◽

2012 ◽

Cited By ~ 2

Author(s):

Dominic Piro ◽

Kyle A. Brucker ◽

Thomas T. O'Shea ◽

Donald Wyatt ◽

Douglas Dommermuth ◽

...

Keyword(s):

Data Analysis ◽

Numerical Simulations ◽

Test Data ◽

Model Test ◽

High Speed ◽

Segmented Model

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The Anchor-Last Deployment Problem for Inextensible Mooring Lines

Journal of Engineering for Industry ◽

10.1115/1.3438654 ◽

1975 ◽

Vol 97 (3) ◽

pp. 1046-1052 ◽

Cited By ~ 2

Author(s):

Robert C. Rupe ◽

Robert W. Thresher

Keyword(s):

Numerical Model ◽

Equations Of Motion ◽

Simultaneous Equations ◽

Mooring Line ◽

Integration Scheme ◽

Lumped Mass ◽

Mooring Lines ◽

Concentrated Masses ◽

Predictor Corrector ◽

Lagrange’S Method

A lumped mass numerical model was developed which predicts the dynamic response of an inextensible mooring line during anchor-last deployment. The mooring line was modeled as a series of concentrated masses connected by massless inextensible links. A set of angles was used for displacement coordinates, and Lagrange’s Method was used to derive the equations of motion. The resulting formulation exhibited inertia coupling, which, for the predictor-corrector integration scheme used, required the solution of a set of linear simultaneous equations to determine the acceleration of each lumped mass. For the selected cases studied the results show that the maximum tension in the cable during deployment will not exceed twice the weight of the cable and anchor in water.

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Guidelines for CFD Simulations of Spar VIM

Volume 7: CFD and VIV ◽

10.1115/omae2013-10333 ◽

2013 ◽

Cited By ~ 8

Author(s):

Charles Lefevre ◽

Yiannis Constantinides ◽

Jang Whan Kim ◽

Mike Henneke ◽

Robert Gordon ◽

...

Keyword(s):

Reynolds Number ◽

Test Data ◽

Model Test ◽

Model Tests ◽

Full Scale ◽

Mooring System ◽

Time Step ◽

Cfd Simulations ◽

Scaled Model ◽

Sway Motion

Vortex-Induced Motion (VIM), which occurs as a consequence of exposure to strong current such as Loop Current eddies in the Gulf of Mexico, is one of the critical factors in the design of the mooring and riser systems for deepwater offshore structures such as Spars and multi-column Deep Draft Floaters (DDFs). The VIM response can have a significant impact on the fatigue life of mooring and riser components. In particular, Steel Catenary Risers (SCRs) suspended from the floater can be sensitive to VIM-induced fatigue at their mudline touchdown points. Industry currently relies on scaled model testing to determine VIM for design. However, scaled model tests are limited in their ability to represent VIM for the full scale structure since they are generally not able to represent the full scale Reynolds number and also cannot fully represent waves effects, nonlinear mooring system behavior or sheared and unsteady currents. The use of Computational Fluid Dynamics (CFD) to simulate VIM can more realistically represent the full scale Reynolds number, waves effects, mooring system, and ocean currents than scaled physical model tests. This paper describes a set of VIM CFD simulations for a Spar hard tank with appurtenances and their comparison against a high quality scaled model test. The test data showed considerable sensitivity to heading angle relative to the incident flow as well as to reduced velocity. The simulated VIM-induced sway motion was compared against the model test data for different reduced velocities (Vm) and Spar headings. Agreement between CFD and model test VIM-induced sway motion was within 9% over the full range of Vm and headings. Use of the Improved Delayed Detached Eddy Simulation (IDDES, Shur et al 2008) turbulence model gives the best agreement with the model test measurements. Guidelines are provided for meshing and time step/solver setting selection.

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A Joint-Industry Effort to Develop and Verify CFD Modeling Practice for Vortex-Induced Motion of a Deep-Draft Semi-Submersible

10.1115/omae2021-63785 ◽

2021 ◽

Author(s):

Hyunchul Jang ◽

Dae-Hyun Kim ◽

Madhusuden Agrawal ◽

Sebastien Loubeyre ◽

Dongwhan Lee ◽

...

Keyword(s):

Test Data ◽

Model Test ◽

Working Group ◽

Cfd Modeling ◽

Physical Model Test ◽

Mooring Lines ◽

Cfd Models ◽

Induced Motion ◽

Modeling Practice ◽

Decay Tests

Abstract Platform Vortex Induced Motion (VIM) is an important cause of fatigue damage on risers and mooring lines connected to deep-draft semi-submersible floating platforms. The VIM design criteria have been typically obtained from towing tank model testing. Recently, computational fluid dynamics (CFD) analysis has been used to assess the VIM response and to augment the understanding of physical model test results. A joint industry effort has been conducted for developing and verifying a CFD modeling practice for the semi-submersible VIM through a working group of the Reproducible Offshore CFD JIP. The objectives of the working group are to write a CFD modeling practice document based on existing practices validated for model test data, and to verify the written practice by blind calculations with five CFD practitioners acting as verifiers. This paper presents the working group’s verification process, consisting of two stages. In the initial verification stage, the verifiers independently performed free-decay tests for 3-DOF motions (surge, sway, yaw) to check if the mechanical system in the CFD model is the same as in the benchmark test. Additionally, VIM simulations were conducted at two current headings with a reduced velocity within the lock-in range, where large sway motion responses are expected,. In the final verification stage, the verifiers performed a complete set of test cases with small revisions of their CFD models based on the results from the initial verification. The VIM responses from these blind calculations are presented, showing close agreement with the model test data.

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Experimental study of hydrodynamic forces acting on ship bow during wave capture

TRANSACTIONS OF THE KRYLOV STATE RESEARCH CENTRE ◽

10.24937/2542-2324-2019-1-s-i-146-152 ◽

2019 ◽

pp. 146-152

Author(s):

Pavel Burakovskiy

Keyword(s):

Experimental Study ◽

Test Data ◽

Model Test ◽

Hydrodynamic Forces ◽

Hydrodynamic Loads ◽

Test Tank ◽

Head Waves ◽

Negative Effect

This paper studies behavior of ship in head waves, when her bow dips under water, which leads to hydrodynamic forces and moments to be assessed. This paper presents model test data obtained in the test tank on the model of ship bow (hydrodynamic loads on forecastle deck during wave capture) as well as updates the coefficient of flow around the bow. The study also shows that bulwark has negative effect upon safety in these conditions because it significantly increases hydrodynamic loads on the deck.

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