An experimental investigation of vortex-induced vibration of a curved flexible pipe in shear flows

Vortex-induced vibration (VIV) of a curved flexible pipe in shear flows was studied experimentally in the concave configuration. The curved pipe was fully immersed into the water with the aspect ratio of 108 and mass-damping ratio of 0.11. The high speed imaging technology was employed to record the...

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Published inOcean engineering Vol. 121; pp. 62 - 75
Main Authors Zhu, Hongjun, Lin, Pengzhi, Yao, Jie
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 15.07.2016
Subjects
Curved
Curved flexible pipe
Fluid dynamics
High speed imaging
Marine
Pipe
Position (location)
Shear flow
Vibration
Vortex shedding
Vortex-induced vibration
Vortex-induced vibrations
Wakes
Vortex shedding
Curved flexible pipe
Shear flow
High speed imaging
Vortex-induced vibration
Online AccessGet full text
ISSN0029-8018
1873-5258
DOI10.1016/j.oceaneng.2016.05.025

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Abstract Vortex-induced vibration (VIV) of a curved flexible pipe in shear flows was studied experimentally in the concave configuration. The curved pipe was fully immersed into the water with the aspect ratio of 108 and mass-damping ratio of 0.11. The high speed imaging technology was employed to record the pipe's vibration displacements in both in-line and cross-flow directions subject to the shear flows with 15 different velocities. Both amplitude and frequency are presented versus the reduced velocity for a Reynolds number ranging from 165 and 1129. The results reveal that different vibration frequencies exist at different positions of the pipe with the presentation of multi-mode-response, and the excited modes vary with the incoming speed. The highest mode in the in-line direction is the third mode, while it is the second mode in the cross-flow direction. Eight-shape trajectories are presented in the middle part of the pipe, while the trajectories evolve to half-moon format at the two ends of pipe. Flow visualizations show that 2P or P+S wake pattern presents at the locations corresponding to the two peaks of the second-order response, while 2S pattern mainly appears at the position corresponding to the trough. The wake mainly presents a P+S mode at the location corresponding to the peak of the first-order response, while 2S mode is the main pattern in other locations. •The overall response of a curved pipe under log-law shear flows is studied.•The non-intrusive technique of high speed imaging method is employed.•Fifteen shear flow profiles with Re ranges from 165 to 1129 are considered.•Multi-mode-response presents with different frequencies existing at different positions.•The trajectories along the length of the pipe indicate key vibration characteristics.
AbstractList Vortex-induced vibration (VIV) of a curved flexible pipe in shear flows was studied experimentally in the concave configuration. The curved pipe was fully immersed into the water with the aspect ratio of 108 and mass-damping ratio of 0.11. The high speed imaging technology was employed to record the pipe's vibration displacements in both in-line and cross-flow directions subject to the shear flows with 15 different velocities. Both amplitude and frequency are presented versus the reduced velocity for a Reynolds number ranging from 165 and 1129. The results reveal that different vibration frequencies exist at different positions of the pipe with the presentation of multi-mode-response, and the excited modes vary with the incoming speed. The highest mode in the in-line direction is the third mode, while it is the second mode in the cross-flow direction. Eight-shape trajectories are presented in the middle part of the pipe, while the trajectories evolve to half-moon format at the two ends of pipe. Flow visualizations show that 2P or P+S wake pattern presents at the locations corresponding to the two peaks of the second-order response, while 2S pattern mainly appears at the position corresponding to the trough. The wake mainly presents a P+S mode at the location corresponding to the peak of the first-order response, while 2S mode is the main pattern in other locations. •The overall response of a curved pipe under log-law shear flows is studied.•The non-intrusive technique of high speed imaging method is employed.•Fifteen shear flow profiles with Re ranges from 165 to 1129 are considered.•Multi-mode-response presents with different frequencies existing at different positions.•The trajectories along the length of the pipe indicate key vibration characteristics.
Vortex-induced vibration (VIV) of a curved flexible pipe in shear flows was studied experimentally in the concave configuration. The curved pipe was fully immersed into the water with the aspect ratio of 108 and mass-damping ratio of 0.11. The high speed imaging technology was employed to record the pipe's vibration displacements in both in-line and cross-flow directions subject to the shear flows with 15 different velocities. Both amplitude and frequency are presented versus the reduced velocity for a Reynolds number ranging from 165 and 1129. The results reveal that different vibration frequencies exist at different positions of the pipe with the presentation of multi-mode-response, and the excited modes vary with the incoming speed. The highest mode in the in-line direction is the third mode, while it is the second mode in the cross-flow direction. Eight-shape trajectories are presented in the middle part of the pipe, while the trajectories evolve to half-moon format at the two ends of pipe. Flow visualizations show that 2P or P+S wake pattern presents at the locations corresponding to the two peaks of the second-order response, while 2S pattern mainly appears at the position corresponding to the trough. The wake mainly presents a P+S mode at the location corresponding to the peak of the first-order response, while 2S mode is the main pattern in other locations.
Author Lin, Pengzhi
Yao, Jie
Zhu, Hongjun
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  givenname: Jie
  surname: Yao
  fullname: Yao, Jie
  organization: State Key Laboratory of Oil and Gas Reservoir Geology and Exploitation, Southwest Petroleum University, Chengdu 610500, China
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Keywords Vortex shedding
Curved flexible pipe
Shear flow
High speed imaging
Vortex-induced vibration
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Snippet Vortex-induced vibration (VIV) of a curved flexible pipe in shear flows was studied experimentally in the concave configuration. The curved pipe was fully...
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SubjectTerms Curved
Curved flexible pipe
Fluid dynamics
High speed imaging
Marine
Pipe
Position (location)
Shear flow
Vibration
Vortex shedding
Vortex-induced vibration
Vortex-induced vibrations
Wakes
Title An experimental investigation of vortex-induced vibration of a curved flexible pipe in shear flows
URI https://dx.doi.org/10.1016/j.oceaneng.2016.05.025
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