1. Investigation of Response Amplitude Operators for Floating Offshore Wind Turbines
Gireesh Ramachandran
Amy Robertson
Jason Jonkman
Marco Masciola
23rd ISOPE - Anchorage, AK - July 3, 2013

2. Overview
FAST, a tool for modeling horizontal-axis wind systems, was recently expanded to include capabilities for modeling offshore systems.
Wanted a methodology for verifying the hydrodynamic behavior of an offshore wind system model built in FAST
Response amplitude operators (RAOs) are commonly used by offshore companies to assess system behavior.
This paper examined the ability to verify a FAST model of an offshore wind system by comparison of its RAOs to those computed from WAMIT.
Reviews the process of how to compute RAOs from FAST
Highlights the differences between the FAST and WAMIT modeling approaches

3. FAST Modeling Approach
OC4 DeepCwind Semisubmersible
Coupled aero-hydro-servo elastic code that computes the loads and responses of both land-based and offshore wind turbines
Uses WAMIT output to compute the hydrodynamic loading on the structure
This means that FAST models the structural dynamics of an offshore wind system, the influence of the turbine control system, and the forcing from wind, waves, and current.
As part of the computation of the hydrodynamic forces, output from the offshore structure code, WAMIT, is needed.
RAOs calculated through a nonlinear time-domain simulation approach using white noise wave excitation

4. WAMIT Modeling Approach
OC4 DeepCwind Semisubmersible
3D panel code used to compute wave radiation and diffraction forcing on an offshore structure in the frequency domain
Can be used to model offshore wind systems
Models only underwater portion of the structure
System is considered rigid
Influences of turbine and mooring are supplied through external mass, stiffness, and damping matrices (created by FAST)
Directly outputs RAOs
As you can see there is inter-dependency between FAST and WAMIT for generating offshore wind system RAOs

5. RAO Computation Flow Chart
CG at SWL => WAMIT neglects body gravity term in hydrostatic stiffness in pitch and roll and avoids double-booking in FAST

6. WAMIT RAO Computation
External M, C, K matrices from FAST provide influence of:
Mass/inertia of turbine/tower
Aerodynamic loading
Gyroscopic loading
Hydrostatics
Mooring stiffness
But, does not include:
Flexibility of turbine/tower
Controller dynamics
Nonlinear mooring behavior
Turbulent wind

7. FAST RAO Computation FAST RAOs calculated through a time simulation
Wave excitation is a white noise signal – broad-banded
Only linear excitation of system, and does not allow for second-order hydrodynamics
Can use narrow-banded white noise signal to only provide excitation at wave frequencies
Wind excitation can be varied
Six simulations run for 8000 seconds
System flexibility
Platform is rigid
Turbine/tower can be flexible and controller enabled (not possible in WAMIT)
RAOs computed by dividing averaged cross-spectral density (waves*output response) by auto-spectral density of waves
𝑅𝐴𝑂= 𝐻 𝜔 = 𝑆 𝑥𝑦 𝜔 𝑆 𝑥𝑥 𝜔

8. Case Study: OC3-Hywind Spar Buoy
Rigid Turbine (FAST and WAMIT):
No wind (no aerodynamic loads)
Below-rated steady wind, V = 8 m/s
Rated steady wind, V = 11.4 m/s
Above-rated wind, V = 18 m/s
Flexible Turbine with Control (only in FAST):
The next step is to examine how these RAOs change due to both wind and flexibility of the turbine or tower
OC3 Hywind Spar

9. RAO comparison (no-wind, rigid turbine)
Only motion in-line with waves shown since little off-axis motion
Platform natural frequencies evident
Frequency shift present between FAST/WAMIT in heave/pitch could be due to slight stiffening of mooring lines in FAST
Mooring force linearized in WAMIT, but not FAST
Surge
Pitch
Heave
Pitch
Surge

10. RAO comparison (all cases): Surge Response
Surge response similar at surge natural frequency
Less response with rated and just below wind speeds
Surge/Heave coupling (not seen in V0 case)
Surge/Pitch coupling
WAMIT again a bit higher frequency for pitch
Larger response for no wind due to absence of aerodynamic damping
Surge/heave coupling – why is not seen for no wind? Displaced surge offset creating more coupling to heave

11. RAO comparison: Sway Response
Sway natural freq.
Roll natural freq.
No sway response when no wind present (V0)
Increase in response for increased wind speed due to increased torque
Sway minimal with no wind, since response is excited by rotor torque, which is not present
Roll natural frequency shifted for WAMIT result
Rated (green) shows largest response, except for the FAST rigid – strange large results for the FAST rigid, V18
Torque highest at highest wind speeds, which is why you get largest response at 18

12. RAO comparison: Heave Response
Heave response not affected significantly by wind or modeling approach
Anti resonance at surge natural frequency – not present without wind due to surge/heave coupling
What is the cause of the anti-resonance? Don’t see a peak??

13. RAO comparison: Roll Response
No roll response when no wind present (V0)
Increase in response for increased wind speed due to increased torque

14. RAO comparison: Pitch Response
Pitch motion heavily damped by wind
Slightly less response for flexible case
Heave/pitch coupling apparent for all but no-wind case
0.47 Hz peak due to fore/aft tower bending frequency – visible in flexible case (out of range on this plot)

15. RAO comparison: Yaw Response
No yaw response for non wind cases – gyroscopic loading from rotating rotor induces yaw motion
Roll natural frequency
Yaw natural frequency
Why no yaw nat freq response for WAMIT?
Rotor induced response (3P) for flexible system

16. Conclusions Presented a methodology for computing RAOs within FAST
Used RAOs to verify offshore solution between FAST/WAMIT
Presence of platform DOF coupling
Influence of aerodynamic damping and gyroscopic loading
WAMIT solution does not capture:
Flexible turbine and control properties –> extra frequencies
Non-linear behavior, especially mooring lines –> shifted freq.
Turbulent wind (not demonstrated here)
Results are presented for just a spar system, it is suspected that the lack of flexible properties will have more of an impact on other platform designs, such as a TLP (strong tower bending / platform pitch coupling)
Aerodynamic damping decreased surge/pitch responses
Gyroscopic loading increased yaw response
Flexible turbine properties – didn’t see certain frequencies excited
Non-linear mooring behavior – shift in frequency for WAMIT

17. Thank You!