Simultaneous wake- and vortex-induced vibrations of a cylinder with two degrees of freedom in each direction
Simultaneous wake- and vortex-induced vibrations of a cylinder with two degrees of freedom in each direction
The flow-induced vibration of one cylinder in the wake of another is the subject of continuing interest in connection with interactions between vertical tension risers in deep water. When one riser is downstream of another it is likely to be subject to wake-induced and vortex-induced excitations at different frequencies simultaneously. Both are complex mechanisms, and it is reasonable to assume that they interact. To begin to understand this complicated process it is desirable that any modelling should incorporate some features of a multi-degree-of-freedom structural response. With this aim, this paper describes experiments in which one cylinder was free to undergo simultaneous wake- and vortex-induced vibrations downstream of a similar but stationary cylinder in a steady flow. The downstream cylinder was mounted on an elastic system that had two natural frequencies in both the in-line and cross-flow directions. Mass ratios were almost the same in all four modes. Measurements are presented of simultaneous wake- and vortex-induced vibrations for cylinder separations of 5 and 10 diameters in the in-line direction, and up to 4 diameters transversely. At a reduced velocity of 83 (based on the cylinder’s lower submerged natural frequency) and a separation of 5 diameters, excursions of wake-induced vibrations peaked at almost 5 diameters, when the downstream cylinder was near the edge of the upstream cylinder’s wake
31101
Chaplin, J.R.
d5ed2ba9-df16-4a19-ab9d-32da7883309f
Batten, W.M.J.
8a6a68c7-b614-4f62-9d56-54eb38a45a94
19 May 2014
Chaplin, J.R.
d5ed2ba9-df16-4a19-ab9d-32da7883309f
Batten, W.M.J.
8a6a68c7-b614-4f62-9d56-54eb38a45a94
Chaplin, J.R. and Batten, W.M.J.
(2014)
Simultaneous wake- and vortex-induced vibrations of a cylinder with two degrees of freedom in each direction.
Journal of Offshore Mechanics and Arctic Engineering, 136 (3), .
(doi:10.1115/1.4027523).
Abstract
The flow-induced vibration of one cylinder in the wake of another is the subject of continuing interest in connection with interactions between vertical tension risers in deep water. When one riser is downstream of another it is likely to be subject to wake-induced and vortex-induced excitations at different frequencies simultaneously. Both are complex mechanisms, and it is reasonable to assume that they interact. To begin to understand this complicated process it is desirable that any modelling should incorporate some features of a multi-degree-of-freedom structural response. With this aim, this paper describes experiments in which one cylinder was free to undergo simultaneous wake- and vortex-induced vibrations downstream of a similar but stationary cylinder in a steady flow. The downstream cylinder was mounted on an elastic system that had two natural frequencies in both the in-line and cross-flow directions. Mass ratios were almost the same in all four modes. Measurements are presented of simultaneous wake- and vortex-induced vibrations for cylinder separations of 5 and 10 diameters in the in-line direction, and up to 4 diameters transversely. At a reduced velocity of 83 (based on the cylinder’s lower submerged natural frequency) and a separation of 5 diameters, excursions of wake-induced vibrations peaked at almost 5 diameters, when the downstream cylinder was near the edge of the upstream cylinder’s wake
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Published date: 19 May 2014
Organisations:
Energy & Climate Change Group
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Local EPrints ID: 365528
URI: http://eprints.soton.ac.uk/id/eprint/365528
ISSN: 0892-7219
PURE UUID: 0b1c404f-b086-4cd7-bbab-3f4a405b118d
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Date deposited: 09 Jun 2016 10:53
Last modified: 15 Mar 2024 03:04
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W.M.J. Batten
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