TY - GEN
T1 - Wind tunnel testing of power maximization control strategies applied to a multi-turbine floating wind power platform
AU - Campagnolo, Filippo
AU - Petrović, Vlaho
AU - Nanos, Emmanouil M.
AU - Tan, Chun Wei
AU - Bottasso, Carlo L.
AU - Paek, Insu
AU - Kim, Hyungyu
AU - Kim, Kwansoo
N1 - Publisher Copyright:
© Copyright 2016 by the International Society of Offshore and Polar Engineers (ISOPE).
PY - 2016
Y1 - 2016
N2 - Large-scale offshore floating wind turbines represent one of the most significant engineering challenges in wind energy at present. Since current fixed-bottom technology can support deployment up to water depths of about 30 m (shallow waters), the technology is now moving towards deeper waters, where the wind resource is extremely abundant. In this regard, single and multi-turbine floating platforms are now being actively investigated. This paper presents the results of a wind tunnel experimental campaign conducted with the scaled model of a square-shaped floating platform equipped with four wind turbine models located at its corners. The scaled wind turbines feature pitch, torque and yaw control, and are equipped with sensors measuring all main operational parameters, including rotor and tower loads. The models also provide a realistic energy conversion process, due to similar rotor aerodynamic performance, loads, and wake characteristics between the scaled and full scale machines. The pitch floating motion of the scaled platform is obtained by a custom-designed one degree-of-freedom actuator, capable of performing specific motion laws simulating different wave conditions. Measurements are taken to characterize the wake, including the quantification of wake interference on downstream machines. The potential effect of yawing and derating the upstream wind turbines is then investigated in terms of overall power production.
AB - Large-scale offshore floating wind turbines represent one of the most significant engineering challenges in wind energy at present. Since current fixed-bottom technology can support deployment up to water depths of about 30 m (shallow waters), the technology is now moving towards deeper waters, where the wind resource is extremely abundant. In this regard, single and multi-turbine floating platforms are now being actively investigated. This paper presents the results of a wind tunnel experimental campaign conducted with the scaled model of a square-shaped floating platform equipped with four wind turbine models located at its corners. The scaled wind turbines feature pitch, torque and yaw control, and are equipped with sensors measuring all main operational parameters, including rotor and tower loads. The models also provide a realistic energy conversion process, due to similar rotor aerodynamic performance, loads, and wake characteristics between the scaled and full scale machines. The pitch floating motion of the scaled platform is obtained by a custom-designed one degree-of-freedom actuator, capable of performing specific motion laws simulating different wave conditions. Measurements are taken to characterize the wake, including the quantification of wake interference on downstream machines. The potential effect of yawing and derating the upstream wind turbines is then investigated in terms of overall power production.
KW - Multi-turbine floating wind power platforms
KW - Power maximization control strategies
KW - Scaled wind turbine models
KW - Wind tunnel testing
UR - http://www.scopus.com/inward/record.url?scp=84987892688&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:84987892688
T3 - Proceedings of the International Offshore and Polar Engineering Conference
SP - 309
EP - 316
BT - Proceedings of the 26th International Ocean and Polar Engineering Conference, ISOPE 2016
A2 - Wang, Alan M.
A2 - Chung, Jin S.
A2 - Kokkinis, Ted
A2 - Muskulus, Michael
PB - International Society of Offshore and Polar Engineers
T2 - 26th Annual International Ocean and Polar Engineering Conference, ISOPE 2016
Y2 - 26 June 2016 through 1 July 2016
ER -