Natural Frequency and Damping Estimation of an Offshore Wind Turbine Structure

Mads Damgaard; Jacob K. F.  Andersen; Lars Bo Ibsen; Lars Vabbersgaard Andersen

Natural Frequency and Damping Estimation of an Offshore Wind Turbine Structure

Mads Damgaard, Jacob K. F. Andersen, Lars Bo Ibsen, Lars Vabbersgaard Andersen

Research output: Contribution to book/anthology/report/conference proceeding › Article in proceeding › Research › peer-review

57 Citations (Scopus)

Abstract

During the last years, offshore wind turbines have increased significantly in size with larger rotors and more powerful generators. The costs are kept as low as possible by reducing the overall weight, which leads to very slender and flexible structures. An improper design may cause resonance due to the excitation from wind and waves, leading to immature failure in the fatigue limit state. This in turn necessitates a correct estimate of the basic dynamic properties of the entire wind turbine structure. The paper presents experimental investigations of the first natural bending frequency and damping ratio of an offshore wind turbine located in the North Sea. Simple Fourier Transformation and least square fitting to the vibration decay of ten “rotor stop” tests make it possible to evaluate the dynamic properties of the wind turbine structure. Based on the traditionally p-y curve method (Winkler type approach), a numerical modal analysis of the wind turbine structure is conducted in order to compare the computational first natural bending frequency of the structure and the contribution of soil damping with experimental results.

Original language	English
Title of host publication	Proceedings of the Twenty-second (2012) International Offshore and Polar Engineering Conference
Number of pages	8
Publisher	International Society of Offshore & Polar Engineers
Publication date	2012
Pages	300-307
ISBN (Electronic)	978-1-880653-94−4
Publication status	Published - 2012
Event	International Ocean and Polar Engineering Conference 2012 - Ixia, Rhodes, Greece Duration: 17 Jun 2012 → 23 Jun 2012 Conference number: 22

Conference

Conference	International Ocean and Polar Engineering Conference 2012
Number	22
Country/Territory	Greece
City	Ixia, Rhodes
Period	17/06/2012 → 23/06/2012

Series	Proceedings of the International Offshore and Polar Engineering Conference
Number	22
ISSN	1098-6189

Keywords

Fourier Transformation
Natural Frequency
P-Y Curve Method
Soil Damping Ratio
Winkler Approach

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Damgaard, M., Andersen, J. K. F., Ibsen, L. B., & Andersen, L. V. (2012). Natural Frequency and Damping Estimation of an Offshore Wind Turbine Structure. In Proceedings of the Twenty-second (2012) International Offshore and Polar Engineering Conference (pp. 300-307). International Society of Offshore & Polar Engineers. http://www.scopus.com/record/display.url?eid=2-s2.0-84866133053&origin=resultslist&sort=plf-f&src=s&st1=Natural+Frequency+and+Damping+Estimation+of+an+Offshore+Wind+Turbine+Structure&sid=0103731E7D1855AAD0D9274B1B071683.WXhD7YyTQ6A7Pvk9AlA%3a390&sot=b&sdt=b&sl=93&s=TITLE-ABS-KEY%28Natural+Frequency+and+Damping+Estimation+of+an+Offshore+Wind+Turbine+Structure%29&relpos=0&relpos=0&searchTerm=TITLE-ABS-KEY%28Natural+Frequency+and+Damping+Estimation+of+an+Offshore+Wind+Turbine+Structure%29

Damgaard, Mads ; Andersen, Jacob K. F. ; Ibsen, Lars Bo et al. / Natural Frequency and Damping Estimation of an Offshore Wind Turbine Structure. Proceedings of the Twenty-second (2012) International Offshore and Polar Engineering Conference. International Society of Offshore & Polar Engineers, 2012. pp. 300-307 (Proceedings of the International Offshore and Polar Engineering Conference; No. 22).

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title = "Natural Frequency and Damping Estimation of an Offshore Wind Turbine Structure",

abstract = "During the last years, offshore wind turbines have increased significantly in size with larger rotors and more powerful generators. The costs are kept as low as possible by reducing the overall weight, which leads to very slender and flexible structures. An improper design may cause resonance due to the excitation from wind and waves, leading to immature failure in the fatigue limit state. This in turn necessitates a correct estimate of the basic dynamic properties of the entire wind turbine structure. The paper presents experimental investigations of the first natural bending frequency and damping ratio of an offshore wind turbine located in the North Sea. Simple Fourier Transformation and least square fitting to the vibration decay of ten “rotor stop” tests make it possible to evaluate the dynamic properties of the wind turbine structure. Based on the traditionally p-y curve method (Winkler type approach), a numerical modal analysis of the wind turbine structure is conducted in order to compare the computational first natural bending frequency of the structure and the contribution of soil damping with experimental results.",

keywords = "Fourier Transformation, Natural Frequency, P-Y Curve Method, Soil Damping Ratio, Winkler Approach, Fourier Transformation, Natural Frequency, P-Y Curve Method, Soil Damping Ratio, Winkler Approach",

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year = "2012",

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series = "Proceedings of the International Offshore and Polar Engineering Conference",

publisher = "International Society of Offshore & Polar Engineers",

number = "22",

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note = "International Ocean and Polar Engineering Conference 2012, ISOPE 2012 ; Conference date: 17-06-2012 Through 23-06-2012",

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Damgaard, M, Andersen, JKF, Ibsen, LB & Andersen, LV 2012, Natural Frequency and Damping Estimation of an Offshore Wind Turbine Structure. in Proceedings of the Twenty-second (2012) International Offshore and Polar Engineering Conference. International Society of Offshore & Polar Engineers, Proceedings of the International Offshore and Polar Engineering Conference, no. 22, pp. 300-307, International Ocean and Polar Engineering Conference 2012, Ixia, Rhodes, Greece, 17/06/2012. <http://www.scopus.com/record/display.url?eid=2-s2.0-84866133053&origin=resultslist&sort=plf-f&src=s&st1=Natural+Frequency+and+Damping+Estimation+of+an+Offshore+Wind+Turbine+Structure&sid=0103731E7D1855AAD0D9274B1B071683.WXhD7YyTQ6A7Pvk9AlA%3a390&sot=b&sdt=b&sl=93&s=TITLE-ABS-KEY%28Natural+Frequency+and+Damping+Estimation+of+an+Offshore+Wind+Turbine+Structure%29&relpos=0&relpos=0&searchTerm=TITLE-ABS-KEY%28Natural+Frequency+and+Damping+Estimation+of+an+Offshore+Wind+Turbine+Structure%29>

Natural Frequency and Damping Estimation of an Offshore Wind Turbine Structure. / Damgaard, Mads; Andersen, Jacob K. F. ; Ibsen, Lars Bo et al.
Proceedings of the Twenty-second (2012) International Offshore and Polar Engineering Conference. International Society of Offshore & Polar Engineers, 2012. p. 300-307 (Proceedings of the International Offshore and Polar Engineering Conference; No. 22).

Research output: Contribution to book/anthology/report/conference proceeding › Article in proceeding › Research › peer-review

TY - GEN

T1 - Natural Frequency and Damping Estimation of an Offshore Wind Turbine Structure

AU - Damgaard, Mads

AU - Andersen, Jacob K. F.

AU - Ibsen, Lars Bo

AU - Andersen, Lars Vabbersgaard

N1 - Conference code: 22

PY - 2012

Y1 - 2012

N2 - During the last years, offshore wind turbines have increased significantly in size with larger rotors and more powerful generators. The costs are kept as low as possible by reducing the overall weight, which leads to very slender and flexible structures. An improper design may cause resonance due to the excitation from wind and waves, leading to immature failure in the fatigue limit state. This in turn necessitates a correct estimate of the basic dynamic properties of the entire wind turbine structure. The paper presents experimental investigations of the first natural bending frequency and damping ratio of an offshore wind turbine located in the North Sea. Simple Fourier Transformation and least square fitting to the vibration decay of ten “rotor stop” tests make it possible to evaluate the dynamic properties of the wind turbine structure. Based on the traditionally p-y curve method (Winkler type approach), a numerical modal analysis of the wind turbine structure is conducted in order to compare the computational first natural bending frequency of the structure and the contribution of soil damping with experimental results.

AB - During the last years, offshore wind turbines have increased significantly in size with larger rotors and more powerful generators. The costs are kept as low as possible by reducing the overall weight, which leads to very slender and flexible structures. An improper design may cause resonance due to the excitation from wind and waves, leading to immature failure in the fatigue limit state. This in turn necessitates a correct estimate of the basic dynamic properties of the entire wind turbine structure. The paper presents experimental investigations of the first natural bending frequency and damping ratio of an offshore wind turbine located in the North Sea. Simple Fourier Transformation and least square fitting to the vibration decay of ten “rotor stop” tests make it possible to evaluate the dynamic properties of the wind turbine structure. Based on the traditionally p-y curve method (Winkler type approach), a numerical modal analysis of the wind turbine structure is conducted in order to compare the computational first natural bending frequency of the structure and the contribution of soil damping with experimental results.

KW - Fourier Transformation

KW - Natural Frequency

KW - P-Y Curve Method

KW - Soil Damping Ratio

KW - Winkler Approach

KW - Fourier Transformation

KW - Natural Frequency

KW - P-Y Curve Method

KW - Soil Damping Ratio

KW - Winkler Approach

UR - http://www.scopus.com/inward/record.url?scp=84866133053&partnerID=8YFLogxK

M3 - Article in proceeding

T3 - Proceedings of the International Offshore and Polar Engineering Conference

SP - 300

EP - 307

BT - Proceedings of the Twenty-second (2012) International Offshore and Polar Engineering Conference

PB - International Society of Offshore & Polar Engineers

T2 - International Ocean and Polar Engineering Conference 2012

Y2 - 17 June 2012 through 23 June 2012

ER -

Damgaard M, Andersen JKF, Ibsen LB, Andersen LV. Natural Frequency and Damping Estimation of an Offshore Wind Turbine Structure. In Proceedings of the Twenty-second (2012) International Offshore and Polar Engineering Conference. International Society of Offshore & Polar Engineers. 2012. p. 300-307. (Proceedings of the International Offshore and Polar Engineering Conference; No. 22).

Natural Frequency and Damping Estimation of an Offshore Wind Turbine Structure

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Keywords

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