Un- and reloading stiffness of monopile foundations in sand

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Martin Achmus
  • Klaus Thieken
  • Jann Eike Saathoff
  • Mauricio Terceros
  • Johannes Albiker

Organisationseinheiten

Externe Organisationen

  • ACP Grundbau GmbH
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Seiten (von - bis)62-73
Seitenumfang12
FachzeitschriftApplied Ocean Research
Jahrgang84
Frühes Online-Datum11 Jan. 2019
PublikationsstatusVeröffentlicht - März 2019

Abstract

The eigenfrequency of offshore wind turbine structures is a crucial design parameter, since it determines the dynamic behavior of the structure and with that the fatigue loads for the structural design. For offshore wind turbines founded on monopiles, the rotational stiffness of the monopile-soil system for un- and reloading states strongly affects the eigenfrequency. A numerical model for the calculation of the monopile's behavior under un- and reloading is established and validated by back-calculation of model and field tests. With this model, a parametric study is conducted in which pile geometry, soil parameters and load conditions are varied. It is shown that of course the rotational stiffness varies with mean load and magnitude of the considered un- and reloading span, but that for most relevant load situations the initial rotational stiffness of the monopile system, i.e. the initial slope of the moment-rotation curve for monotonic loading, gives a good estimate of the actual stiffness. Comparisons of different p–y approaches show that the ordinary API approach considerably underestimates the initial stiffness, whereas the recently developed ‘Thieken’ approach and also the ‘Kallehave’ approach give a much better prediction and thus might be used in the design of monopiles in sand.

ASJC Scopus Sachgebiete

Zitieren

Un- and reloading stiffness of monopile foundations in sand. / Achmus, Martin; Thieken, Klaus; Saathoff, Jann Eike et al.
in: Applied Ocean Research, Jahrgang 84, 03.2019, S. 62-73.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Achmus, M, Thieken, K, Saathoff, JE, Terceros, M & Albiker, J 2019, 'Un- and reloading stiffness of monopile foundations in sand', Applied Ocean Research, Jg. 84, S. 62-73. https://doi.org/10.1016/j.apor.2019.01.001
Achmus, M., Thieken, K., Saathoff, J. E., Terceros, M., & Albiker, J. (2019). Un- and reloading stiffness of monopile foundations in sand. Applied Ocean Research, 84, 62-73. https://doi.org/10.1016/j.apor.2019.01.001
Achmus M, Thieken K, Saathoff JE, Terceros M, Albiker J. Un- and reloading stiffness of monopile foundations in sand. Applied Ocean Research. 2019 Mär;84:62-73. Epub 2019 Jan 11. doi: 10.1016/j.apor.2019.01.001
Achmus, Martin ; Thieken, Klaus ; Saathoff, Jann Eike et al. / Un- and reloading stiffness of monopile foundations in sand. in: Applied Ocean Research. 2019 ; Jahrgang 84. S. 62-73.
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abstract = "The eigenfrequency of offshore wind turbine structures is a crucial design parameter, since it determines the dynamic behavior of the structure and with that the fatigue loads for the structural design. For offshore wind turbines founded on monopiles, the rotational stiffness of the monopile-soil system for un- and reloading states strongly affects the eigenfrequency. A numerical model for the calculation of the monopile's behavior under un- and reloading is established and validated by back-calculation of model and field tests. With this model, a parametric study is conducted in which pile geometry, soil parameters and load conditions are varied. It is shown that of course the rotational stiffness varies with mean load and magnitude of the considered un- and reloading span, but that for most relevant load situations the initial rotational stiffness of the monopile system, i.e. the initial slope of the moment-rotation curve for monotonic loading, gives a good estimate of the actual stiffness. Comparisons of different p–y approaches show that the ordinary API approach considerably underestimates the initial stiffness, whereas the recently developed {\textquoteleft}Thieken{\textquoteright} approach and also the {\textquoteleft}Kallehave{\textquoteright} approach give a much better prediction and thus might be used in the design of monopiles in sand.",
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Download

TY - JOUR

T1 - Un- and reloading stiffness of monopile foundations in sand

AU - Achmus, Martin

AU - Thieken, Klaus

AU - Saathoff, Jann Eike

AU - Terceros, Mauricio

AU - Albiker, Johannes

PY - 2019/3

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N2 - The eigenfrequency of offshore wind turbine structures is a crucial design parameter, since it determines the dynamic behavior of the structure and with that the fatigue loads for the structural design. For offshore wind turbines founded on monopiles, the rotational stiffness of the monopile-soil system for un- and reloading states strongly affects the eigenfrequency. A numerical model for the calculation of the monopile's behavior under un- and reloading is established and validated by back-calculation of model and field tests. With this model, a parametric study is conducted in which pile geometry, soil parameters and load conditions are varied. It is shown that of course the rotational stiffness varies with mean load and magnitude of the considered un- and reloading span, but that for most relevant load situations the initial rotational stiffness of the monopile system, i.e. the initial slope of the moment-rotation curve for monotonic loading, gives a good estimate of the actual stiffness. Comparisons of different p–y approaches show that the ordinary API approach considerably underestimates the initial stiffness, whereas the recently developed ‘Thieken’ approach and also the ‘Kallehave’ approach give a much better prediction and thus might be used in the design of monopiles in sand.

AB - The eigenfrequency of offshore wind turbine structures is a crucial design parameter, since it determines the dynamic behavior of the structure and with that the fatigue loads for the structural design. For offshore wind turbines founded on monopiles, the rotational stiffness of the monopile-soil system for un- and reloading states strongly affects the eigenfrequency. A numerical model for the calculation of the monopile's behavior under un- and reloading is established and validated by back-calculation of model and field tests. With this model, a parametric study is conducted in which pile geometry, soil parameters and load conditions are varied. It is shown that of course the rotational stiffness varies with mean load and magnitude of the considered un- and reloading span, but that for most relevant load situations the initial rotational stiffness of the monopile system, i.e. the initial slope of the moment-rotation curve for monotonic loading, gives a good estimate of the actual stiffness. Comparisons of different p–y approaches show that the ordinary API approach considerably underestimates the initial stiffness, whereas the recently developed ‘Thieken’ approach and also the ‘Kallehave’ approach give a much better prediction and thus might be used in the design of monopiles in sand.

KW - Eigenfrequency

KW - Monopile

KW - Offshore wind

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