A nonlinear model of vortex-induced forces on an oscillating cylinder in a fluid flow

J. Decuyper; T. De Troyer; K. Tiels; J. Schoukens; M. C. Runacres

doi:10.1016/j.jfluidstructs.2020.103029

A nonlinear model of vortex-induced forces on an oscillating cylinder in a fluid flow

J. Decuyper, T. De Troyer, K. Tiels, J. Schoukens, M. C. Runacres

Onderzoeksoutput: Article › peer review

9 Citaten (Scopus)

91 Downloads (Pure)

Samenvatting

A nonlinear model relating the imposed motion of a circular cylinder, submerged in a fluid flow, to the transverse force coefficient is presented. The nonlinear fluid system, featuring vortex shedding patterns, limit cycle oscillations and synchronisation, is studied both for swept sine and multisine excitation. A nonparametric nonlinear distortion analysis (FAST) is used to distinguish odd from even nonlinear behaviour. The information which is obtained from the nonlinear analysis is explicitly used in constructing a nonlinear model of the polynomial nonlinear state-space (PNLSS) type. The latter results in a reduction of the number of parameters and an increased accuracy compared to the generic modelling approach where typically no such information of the nonlinearity is used. The obtained model is able to accurately simulate time series of the transverse force coefficient over a wide range of the frequency–amplitude plane of imposed cylinder motion.

Originele taal-2	English
Artikelnummer	103029
Tijdschrift	Journal of Fluids and Structures
Volume	96
DOI's	https://doi.org/10.1016/j.jfluidstructs.2020.103029
Status	Published - jul. 2020

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© 2020

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10.1016/j.jfluidstructs.2020.103029

Decuyper_reviewAccepted author manuscript, 1,69 MBLicentie: CC BY-NC-ND

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1 Afgelopen

SRP60: SRP-Groeifinanciering: A system identification framework for multi-fidelity modelling
De Troyer, T., Runacres, M., Blondeau, J., Bram, S., Bellemans, A. & Contino, F.
1/03/19 → 29/02/24
Project: Fundamenteel

9 Citaties
1 Conference paper

Modelling Vortex-Induced Loads Using Recurrent Neural Networks
Foster, J. A., Decuyper, J. R., Runacres, M. & De Troyer, T., 25 okt. 2021, Modeling, Estimation and Control Conference MECC 2021. Wang, J., Fathy, H., Wang, Q. & Ren, B. (redactie). 20 redactie Austin, Texas, USA: IFAC - PapersOnLine, Vol. 54. blz. 32-37 6 blz. (IFAC Proceedings Volumes; vol. 54, nr. 20).
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3 Citaten (Scopus)

127 Downloads (Pure)

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title = "A nonlinear model of vortex-induced forces on an oscillating cylinder in a fluid flow",

abstract = "A nonlinear model relating the imposed motion of a circular cylinder, submerged in a fluid flow, to the transverse force coefficient is presented. The nonlinear fluid system, featuring vortex shedding patterns, limit cycle oscillations and synchronisation, is studied both for swept sine and multisine excitation. A nonparametric nonlinear distortion analysis (FAST) is used to distinguish odd from even nonlinear behaviour. The information which is obtained from the nonlinear analysis is explicitly used in constructing a nonlinear model of the polynomial nonlinear state-space (PNLSS) type. The latter results in a reduction of the number of parameters and an increased accuracy compared to the generic modelling approach where typically no such information of the nonlinearity is used. The obtained model is able to accurately simulate time series of the transverse force coefficient over a wide range of the frequency–amplitude plane of imposed cylinder motion.",

keywords = "Forced cylinder oscillations, Nonlinear black-box modelling, Polynomial nonlinear state-space model, Signal processing, System identification, Vortex-induced vibrations",

author = "J. Decuyper and {De Troyer}, T. and K. Tiels and J. Schoukens and Runacres, {M. C.}",

note = "Funding Information: This work was supported in part by the Fund for Scientific Research (FWO-Vlaanderen), Belgium, the ERC advanced grant SNLSID, Belgium, under contract 320378, the Swedish Research Council (VR) via the project NewLEADS \u2014 New Directions in Learning Dynamical Systems (contract number: 621-2016-06079), and by the Swedish Foundation for Strategic Research (SSF) via the project ASSEMBLE (contract number: RIT15-0012). The authors would like to thank the reviewers for their valuable comments. Publisher Copyright: {\textcopyright} 2020",

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AU - Tiels, K.

AU - Schoukens, J.

AU - Runacres, M. C.

N1 - Funding Information: This work was supported in part by the Fund for Scientific Research (FWO-Vlaanderen), Belgium, the ERC advanced grant SNLSID, Belgium, under contract 320378, the Swedish Research Council (VR) via the project NewLEADS \u2014 New Directions in Learning Dynamical Systems (contract number: 621-2016-06079), and by the Swedish Foundation for Strategic Research (SSF) via the project ASSEMBLE (contract number: RIT15-0012). The authors would like to thank the reviewers for their valuable comments. Publisher Copyright: © 2020

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N2 - A nonlinear model relating the imposed motion of a circular cylinder, submerged in a fluid flow, to the transverse force coefficient is presented. The nonlinear fluid system, featuring vortex shedding patterns, limit cycle oscillations and synchronisation, is studied both for swept sine and multisine excitation. A nonparametric nonlinear distortion analysis (FAST) is used to distinguish odd from even nonlinear behaviour. The information which is obtained from the nonlinear analysis is explicitly used in constructing a nonlinear model of the polynomial nonlinear state-space (PNLSS) type. The latter results in a reduction of the number of parameters and an increased accuracy compared to the generic modelling approach where typically no such information of the nonlinearity is used. The obtained model is able to accurately simulate time series of the transverse force coefficient over a wide range of the frequency–amplitude plane of imposed cylinder motion.

AB - A nonlinear model relating the imposed motion of a circular cylinder, submerged in a fluid flow, to the transverse force coefficient is presented. The nonlinear fluid system, featuring vortex shedding patterns, limit cycle oscillations and synchronisation, is studied both for swept sine and multisine excitation. A nonparametric nonlinear distortion analysis (FAST) is used to distinguish odd from even nonlinear behaviour. The information which is obtained from the nonlinear analysis is explicitly used in constructing a nonlinear model of the polynomial nonlinear state-space (PNLSS) type. The latter results in a reduction of the number of parameters and an increased accuracy compared to the generic modelling approach where typically no such information of the nonlinearity is used. The obtained model is able to accurately simulate time series of the transverse force coefficient over a wide range of the frequency–amplitude plane of imposed cylinder motion.

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KW - Nonlinear black-box modelling

KW - Polynomial nonlinear state-space model

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KW - Vortex-induced vibrations

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A nonlinear model of vortex-induced forces on an oscillating cylinder in a fluid flow

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Bibliografische nota

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Andere bestanden en links

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Projecten

SRP60: SRP-Groeifinanciering: A system identification framework for multi-fidelity modelling

Onderzoekersoutput

Modelling Vortex-Induced Loads Using Recurrent Neural Networks

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