Wake and structure model for simulation of cross-flow/in-line vortex induced vibration of marine risers

The purpose of this paper is to present a method that has been developed to identify if vortex induced vibration (VIV) occurs in well jumper systems. Moreover, a method has been developed to determine when VIV mitigation measures such as strakes are required. The method involves determining the in-plane and out-of-plane natural frequencies and mode shapes. The natural frequencies are then used, in conjunction with the maximum bottom current expected at a given location to determine if suppression is required. The natural frequency of a jumper system is a function of many variables, e.g. span length, leg height, pipe diameter and thickness, buoyancy placement, buoyancy uplift, buoyancy OD, insulation thickness, and contents of the jumper. The suppression requirement is based upon calculating a lower bound lock-in current speed based upon an assumed velocity bandwidth centered about the lock-in current. The out-of-plane VIV cross-flow response is produced by a current in the plane of the jumper; whereas the in-plane VIV cross-flow response is produced by the out-of-plane current. Typically, the out-of-plane natural frequency is smaller than the in-plane natural frequency. Jumpers with small spans have higher natural frequencies; thus small span jumpers may require no suppression or suppression on the vertical legs. Whereas, larger span jumpers may require no suppression, suppression on the vertical legs or suppression on all the legs. The span of jumper systems (i.e. production, water injection, gas lift/injection ...) may vary in one given field; it has become apparent that not all jumper systems require suppression. This technique has allowed us to recognize when certain legs of a given jumper system may require suppression, thus leading to a jumper design whose safety is not compromised while in the production mode, as well as minimizing downtime and identifying potential savings from probable fatigue failures.

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Fatigue Analysis of Free Spanning Pipelines Subjected to Vortex Induced Vibrations

Volume 7: CFD and VIV ◽

10.1115/omae2013-10625 ◽

2013 ◽

Cited By ~ 1

Author(s):

F. Van den Abeele ◽

F. Boël ◽

M. Hill

Keyword(s):

Fatigue Damage ◽

Oil And Gas ◽

Flow Direction ◽

Cross Flow ◽

Fatigue Analysis ◽

Sensitivity Analyses ◽

Vortex Induced Vibration ◽

Vortex Induced Vibrations ◽

Offshore Industry ◽

Girth Welds

Vortex induced vibration is a major cause of fatigue failure in submarine oil and gas pipelines and steel catenary risers. Even moderate currents can induce vortex shedding, alternately at the top and bottom of the pipeline, at a rate determined by the flow velocity. Each time a vortex sheds, a force is generated in both the in-line and cross-flow direction, causing an oscillatory multi-mode vibration. This vortex induced vibration can give rise to fatigue damage of submarine pipeline spans, especially in the vicinity of the girth welds. In this paper, an integrated numerical framework is presented to predict and identify free spans that may be vulnerable to fatigue damage caused by vortex induced vibrations (VIV). An elegant and efficient algorithm is introduced to simulate offshore pipeline installation on an uneven seabed. Once the laydown simulation has been completed, the free spans can be automatically detected. When the fatigue screening for both inline and cross-flow VIV indicates that a particular span may be prone to vortex induced vibrations, a detailed fatigue analysis is required. Amplitude response models are constructed to predict the maximum steady state VIV amplitudes for a given pipeline configuration (mechanical properties) and sea state (hydrodynamic parameters). The vibration amplitudes are translated into corresponding stress ranges, which then provide an input for the fatigue analysis. A case study from the offshore industry is presented, and sensitivity analyses are performed to study the influence of the seabed conditions, where special emphasis is devoted on the selection of pipe soil interaction parameters.

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A nonlinear vortex induced vibration model of marine risers

Journal of Ocean University of China ◽

10.1007/s11802-013-1894-5 ◽

2013 ◽

Vol 12 (1) ◽

pp. 32-36 ◽

Cited By ~ 4

Author(s):

Juan Liu ◽

Weiping Huang

Keyword(s):

Vortex Induced Vibration ◽

Marine Risers ◽

Vibration Model

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On the Vortex-Induced Vibration Response of a Model Riser and Location of Sensors for Fatigue Damage Prediction

29th International Conference on Ocean, Offshore and Arctic Engineering: Volume 6 ◽

10.1115/omae2010-20991 ◽

2010 ◽

Author(s):

C. Shi ◽

L. Manuel ◽

M. A. Tognarelli ◽

T. Botros

Keyword(s):

Fatigue Damage ◽

Traveling Waves ◽

Wavelet Transforms ◽

Cross Flow ◽

Waveform Analysis ◽

Flexible Cylinder ◽

Vortex Induced Vibration ◽

Damage Prediction ◽

Time Frequency ◽

Damage Rate

This study is concerned with vortex-induced vibration (VIV) of deepwater marine risers. Riser response measurements from model tests on a densely instrumented long, flexible riser in uniform and sheared currents offer an almost ideal set-up for our work. Our objectives are two-fold: (i) we use the measured data to describe complexities inherent in riser motions accompanying VIV; and (ii) we discuss how such data sets (and even less spatially dense monitoring) can be used effectively in predicting fatigue damage rates which is of critical interest for deepwater risers. First, we use mathematical tools including Hilbert and wavelet transforms to estimate instantaneous amplitudes and phases of cross-flow (CF) and in-line (IL) displacements for the model riser as well as scalograms to understand time-frequency characteristics of the response; this work confirms that the motion of a long flexible cylinder is far more complex than that of a rigid cylinder, and that non-stationary characteristics, higher harmonics, and traveling waves are evident in the riser response. Second, a well-established empirical procedure, which we refer to as Weighted Waveform Analysis (WWA), is employed to estimate the fatigue damage rate at various locations along the length of the riser from strain measurements at only eight sensors. By iterating over numerous different combinations of these eight strain sensors as inputs (from among all the twenty-four available locations on the riser), optimal locations for the eight sensors on the riser are identified by cross-validation, whereby predicted strains and fatigue damage rates at locations of instrumented sensors are compared with strains and fatigue damage rates based on actual recorded measurements there. We find that, if properly placed, as few as eight sensors can provide reasonably accurate estimates of the fatigue damage rate over the entire riser length. Finally, we demonstrate how more accurate fatigue damage prediction can result when non-stationary response characteristics are considered and a modified WWA method (that more effectively accounts for traveling waves than the WWA method alone does) is employed.

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Cross-flow vortex-induced vibration of a flexible riser transporting an internal flow from subcritical to supercritical

Ocean Engineering ◽

10.1016/j.oceaneng.2017.04.039 ◽

2017 ◽

Vol 139 ◽

pp. 74-84 ◽

Cited By ~ 16

Author(s):

Shuai Meng ◽

Xiaoqing Zhang ◽

Chidong Che ◽

Weijing Zhang

Keyword(s):

Cross Flow ◽

Internal Flow ◽

Flexible Riser ◽

Vortex Induced Vibration ◽

Flow Vortex

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