Dynamic behavior of wind turbines influenced by aerodynamic damping and earthquake intensity

Yang, Yang; Kehua, Ye; Li, Chun; Michailides, Constantine; Zhang, Wanfu

doi:10.1002/we.2163

Cited by 26 publications

(11 citation statements)

References 29 publications

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“…It can be argued that the SSI effect is better addressed with the use of the AF model than the CS model. maximum bending moments decrease along with the support structure height, this result is consistent with the analogous results of the same wind turbine calculated using the boundary element method [10]. The maximum bending moment of the rigid model at the mudline is close to that of the DS model, while a significant difference is observed for the AF and CS models.…”

Section: Responses To An Earthquake Eventsupporting

confidence: 88%

“…Generally, the aerodynamic loads increase exponentially with the rotor diameter for large-scale wind turbines. The resulting aerodynamic effects have been determined to be unneglectable from a comparative study on operational and parked states [10]. Therefore, over-simplification of aerodynamic loads is never precise, thereby undermining the accuracy of results in the seismic analysis of large-scale wind turbines.…”

Section: Introductionmentioning

confidence: 99%

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Investigation on the sensitivity of flexible foundation models of an offshore wind turbine under earthquake loadings

Yang

Bashir

et al. 2019

Engineering Structures

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This paper presents an investigation on the sensitivity of flexible foundation models of offshore wind turbines subjected to earthquake loadings. A novel seismic analysis framework (SAF) is developed and implemented in an open source aero-hydro-elastic analysis tool, "FAST", for accurately modelling the effects of seismic loadings on offshore wind turbines. SAF has been validated through comparisons against experimentally validated numerical tools, GH Bladed and NREL Seismic. The behaviours of three flexible foundation models, namely, the apparent fixity (AF), coupled springs (CS) and distributed springs (DS) methods, subjected to earthquake loadings have been examined in relation to a fixed foundation. A total of 224 fully coupled nonlinear simulations of the foundation models are performed using a dataset of 28 earthquake records which are scaled using the target spectrum matching technique to represent the actual seismic effects of the selected sites. The results reveal that the AF model appropriately reflects realistic situations in comparison to the CS model. In addition, the amplitudes of vibration induced by the earthquake loadings are larger for

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Section: Responses To An Earthquake Eventsupporting

confidence: 88%

Section: Introductionmentioning

confidence: 99%

Investigation on the sensitivity of flexible foundation models of an offshore wind turbine under earthquake loadings

Yang

Bashir

et al. 2019

Engineering Structures

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“…In the parked state, the peaks of the towertop fore-aft displacement in the fixed and flexible conditions are 1.77 m and 2.25 m, respectively while the values in the operational state are 1.63 m and 2.10 m. This indicates that the aerodynamic damping has a positive effect in mitigating the vibration amplitude because of energy dissipation resulting from aerodynamic damping during earthquake event. This finding is consistent with the conclusion for a land based wind turbine under earthquake events[59].In the case of emergency shutdown condition induced by the earthquake, the generator is turned off at 808.468 s and 807.336 s for the fixed and flexible cases, respectively. The variations of the results in the emergency shutdown state are significantly different from those in the operational state, especially for the fore-aft responses.…”

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confidence: 90%

Analysis of seismic behaviour of an offshore wind turbine with a flexible foundation

Yang

Bashir

et al. 2019

Ocean Engineering

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Analysis of seismic behaviour of an offshore wind turbine with a flexible foundation http://researchonline.ljmu.ac.uk/id/eprint/10382/ Article LJMU has developed LJMU Research Online for users to access the research output of the University more effectively. , J (2019) Analysis of seismic behaviour of an offshore wind turbine with a flexible foundation. Ocean Engineering, 178. pp. 215-228. Abstract: This paper investigates the effects of nonlinear soil behaviours on the structural responses of offshore wind turbines (OWTs) subjected to wind, wave and earthquake loadings. A novel seismic analysis framework (SAF) is developed for the assessment of seismic behaviours of OWTs with flexible and fixed foundations. The SAF consists of an improved QuakeDyn module that is implemented into an open source tool (FAST). SAF has been validated through benchmark studies using numerical tools and the results show good agreements. Fully coupled nonlinear simulations have been performed for OWTs with fixed and flexible foundations under operational, parked and emergency shutdown states. The flexible foundation is modelled using nonlinear p-y curves obtained using LPILE. For all the examined operating conditions, notable differences of magnitude and variation in the responses between the flexible and fixed cases are observed, indicating the need for soil effects to be accounted in seismic behaviour analysis of wind turbines. It is further observed that the earthquake induces more severe vibrations on wind turbines with a flexible foundation compared to the one with a fixed base. Also, aerodynamic damping dissipates more energy from earthquake excitation resulting in a smaller tower-top fore-aft displacement. The shutdown triggered by the earthquake causes a 34% increase in the mudline bending moment for the flexible foundation case, while a decreasing trend is observed for the fixed foundation model. Similar observations are made  Corresponding author: lichun_usst@163.com 2 / 41regarding the tower-top displacements. The observations imply that ignoring the soil effect may lead to misjudgement of the consequence of an emergency shutdown. The relative orientation of the ground motion with respect to the wind direction causes significant difference in the seismic behaviour of the wind turbine. This confirms that it is necessary to interchange the horizontal components of an earthquake in order to consider the intersectional effect between ground motion and wind.

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“…2 Wind power and earthquake distribution in the South China Sea: (a) the average wind power density (Wan et al 2018) and (b) seismic epicenter distribution (BC1767-2018) (Li et al 2020) The existing research on WTs subjected to seismic loadings mainly includes three aspects. The first is the dynamic responses of onshore WTs under wind and earthquake loadings or offshore WTs under the wind, wave, and earthquake loading in consideration of aerodynamic damping, seismic loading conditions and types (Alati et al 2015;Huang et al 2021;Kjørlaug and Kaynia 2015;Patil et al 2016;Santangelo et al 2018;Santangelo et al 2016;Sigurðsson et al 2020;Yang et al 2018;Zafeirakos and Gerolymos 2013). Then, the second is the fragility analysis and collapse evaluation employing the nonlinear incremental dynamic analysis approach to assess the exceeding probability for various damage states (Asareh et al 2016;Fan et al 2019;Kim et al 2014; Martín del Campo and Pozos-Estrada 2020; Quilligan et al 2012).…”

Section: Introductionmentioning

confidence: 99%

Seismic Analysis of 10-MW Off Shore Wind Turbine with Large-Diameter Monopile in Consideration of Seabed Liquefaction

Zhang

Zhu

Yuan

et al. 2021

Preprint

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With the increasing construction of large-scale wind turbines in seismically active coastal areas, the survivability of these high-rated power offshore wind turbines (OWTs) in marine and geological conditions becomes extremely important. Although research on the dynamic behaviors of OWTs under earthquakes has been conducted in consideration of soil-structure interaction, attention paid to the impact of earthquake-induced seabed liquefaction on OWTs supported by large-diameter monopiles is limited. In view of this research gap, this study carries out dynamic analyses of a 10-MW OWT under the combined wind, wave, and earthquake loadings. This study uses a pressure-dependent multi-surface elastoplastic constitutive model to simulate the soil liquefaction phenomenon. Results indicate that the motion of the large-diameter monopile leads to more extensive soil liquefaction surrounding the monopile, specifically in the zone near the pile toe. Moreover, compared with earthquake loading alone, liquefaction becomes more severe under the coupled wind and earthquake loadings. Accordingly, the dynamic responses of the OWT are apparently amplified, demonstrating the importance of considering the coupling loadings. Compared with wind loading, the effect of wave loading on the dynamic response and liquefaction potential is relatively insignificant.

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Dynamic behavior of wind turbines influenced by aerodynamic damping and earthquake intensity

Cited by 26 publications

References 29 publications

Investigation on the sensitivity of flexible foundation models of an offshore wind turbine under earthquake loadings

Investigation on the sensitivity of flexible foundation models of an offshore wind turbine under earthquake loadings

Analysis of seismic behaviour of an offshore wind turbine with a flexible foundation

Seismic Analysis of 10-MW Off Shore Wind Turbine with Large-Diameter Monopile in Consideration of Seabed Liquefaction

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