The fatigue assessment of support structures is one of the most significant challenges in the design of offshore wind turbines (OWT). Fatigue analysis can be conducted in either the time-domain or the frequency-domain. The advantage of frequency-domain analysis is its time efficiency. This paper shows how the frequency domain method can be used to dimension lattice-type OWT towers such that they meet the fatigue criteria in the preliminary design stage. Two types of lattice towers, a three-legged and four-legged version, were redesigned in the fatigue limit state for the NREL 5 MW baseline wind turbine sited at a water depth of 35 m. The wall thickness of the members was chosen as the only variable and varied during the design process until the towers could survive for at least 20 years. In comparison with designs based upon ultimate strength, the mass of both types of towers increased no more than 30% when the fatigue limit state was considered. It is concluded that the lattice type structure requires only half as much material as its tubular counterpart. The three-legged tower is promising because of its simple geometry, even though it displayed a lower torsional stiffness than the four-legged tower. All the analyses in this paper were performed by an in-house FE code, intended for the early design stage of lattice towers. Once the optimum configuration is found in the early design stage, integrated time-domain analyses for the entire OWT system might be required to refine the design, taking all the nonlinear parameters into account.

References

1.
Haiyan
,
L.
, and
Geir
,
M.
, 2007,
“Truss Type Towers in Offshore Wind Turbines,”
Proceeding of European Offshore Wind Energy Conference
,
Berlin, Germany
, Dec. 4–6.
2.
Haiyan
,
L.
,
Tim
,
F.
, and
Geir
,
M.
, 2009,
“Design Methodology and Optimization of Lattice Towers for Offshore Wind Turbines in 35 m Water,”
Proceeding of European Wind Energy Conference
,
Marseilles, France
, March 16–19.
3.
Kühn
,
M.
, 1998,
“Simplified Dynamics Analysis of a Monopile Support Structure for the TW 1.5 s at a Baltic Site,”
Report No. IW 98149 R.
4.
Camp
,
T. R.
,
Morris
,
M. J.
,
van Rooij
,
R.
,
van der Temple
,
J.
,
Zaaijer
,
M.
,
Henderson
,
A.
,
Argyriadis
,
K.
,
Schwartz
,
S.
,
Just
,
H.
,
Grainger
,
W.
, and
Pearce
,
D.
, 2003,
“Design Methods for Offshore Wind Turbines at Exposed Sites,”
Final report of the OWTES project, Report No. 2317/BR/22D.
5.
Kempers
,
M.
, 2003, “Design for OWEZ,” IC + E.
6.
Vugts
,
J. H.
,
Kinra
,
R. K.
, 1976,
“Probabilistic Fatigue Analysis of Fixed Offshore Structures,”
Proceeding of Offshore Technology Conference (OTC)
,
Houston, TX
, May 3–6.
7.
Kühn
,
M.
, 2001,
“Dynamics and Design Optimisation of Offshore Wind Energy Conversion Systems Institute for Wind Energy,”
Ph.D. thesis, Delft University of Technology, Delft, The Netherlands.
8.
van der Tempel
,
J.
, 2006,
“Design of Support Structures for Offshore Wind Turbines,”
Ph.D. thesis, Delft University of Technology, Delft, The Netherlands.
9.
Haiyan
,
L.
,
Tim
,
F.
, and
Geir
,
M.
, 2011,
“Lattice Towers for Bottom-fixed Offshore Wind Turbines in the Ultimate Limit State - Variation of Some Geometric Parameters,”
J. Offshore Mech. Arct. Eng., accepted.
10.
Eurocode 3, 2005, “Design of Steel Structure, Part1–1: General Rules and Rules for Buildings,” Institution of Civil Engineering.
11.
DNV, 2008, “DNV-RP-C203: Fatigue Design of Offshore Steel Structures,” Det Norske Veritas.
12.
Borgman
,
L. E.
, 1967,
“Random Hydrodyanmic Forces on Objects,”
Ann. Math. Stat.
,
38
(
1
), pp.
37
51
.
13.
Madugula
,
M. K. S.
, ed., 2001,
Dynamic Response of Lattice Tower and Guyed Masts
,
American Society of Civil Engineers
,
Reston, VA
.
14.
Kaiser
,
K.
, and
Gasch
,
R.
, 1996,
“The Influence of Aerodynamic Damping and Stiffness on the Vibrational Behavior of Wind Turbines,”
Proceeding of European Wind Energy Conference
,
Gothenburg, Sweden
, May 20–24.
15.
Agarwal
,
P.
, and
Manuel
,
L.
, 2009,
“On the Modeling of Nonlinear Waves for Prediction of Long-Term Offshore Wind Turbines,”
J. Offshore Mech. Arct. Eng.
,
131
(
4
), p.
041601
.
16.
Newland
,
D. E.
, 1993,
An Introduction to Random Vibrations, Spectral and Wavelet Analysis
,
Dover Publications
,
New York
.
17.
Hancock
,
J. W.
, and
Gall
,
D. S.
, 1985,
“Fatigue Under Narrow and Broad Band Stationary Loading,”
Final report of the cohesive program of research and development into fatigue of offshore structures.
18.
Xiaoyun
,
L.
, and
Pengmin
,
L.
, 1997,
“Analytical Solution of Equivalent Stress for Structure Fatigue Life Prediction Under Broad Band Random Loading,”
J. Mech. Struct. Mach.
,
25
(
2
), pp.
139
149
.
19.
Dirlik
,
T.
, 1985,
“Application of Fatigue.”
Ph.D. thesis, University of Warwick, Coventry, UK.
20.
Sutherland
,
H. J.
, 1999,
On the Fatigue Analysis of Wind Turbines
,
Sandia National Laboratories
,
Albuquerque, NM.
21.
Jonkman
,
J.
,
Butterfield
,
S.
,
Musial
,
W.
, and
Scott
,
G.
, 2009,
“Definition of a 5-MW Reference Wind Turbine for Offshore System Development,”
Report No. NREL/TIP-500-38060.
22.
Chakrabrati
,
S.K.
, 1987,
Hydrodynamics of Offshore Structures
,
WIT Press/Computational Mechanics
,
Southampton, UK
.
23.
Norsok Standard N-004, 2004, “Design of Steel Structure,” Norwegian Petroleum Industry, Norway.
You do not currently have access to this content.