Acknowledgement
본 연구는 선박해양플랜트연구소(KRISO) 주요사업인 "일체형 해양그린수소 생산시스템 핵심기술 개발"의 지원으로 수행되었으며, 연구비 지원에 감사드립니다(PES4361).
References
- Martin, H.R., Kimball, R.W., Viselli, A.M., and Goupee, A.J., 2014, Methodology for Win/Wave Basin Testing of Floating Offshore Wind Turbines, Journal of Offshore Mechanics and Arctic Engineering, 136, 020905-1
- Cermelli, C., Leroux, C., Diaz Dominguez, S., and Peiffer, A., 2018, "Experimental Measurements of WindFloat 1 Prototype Responses and Comparison with Numerical Model.
- Browning, J., Jonkman, J., Robertson, A., and Goupee, A., 2014, "Calibration and Validation of a Spar-type Floating Offshore Wind Turbine Model using the Fast Dynamic Simulation Tool", J. Phys. Conf.
- Castro, I.R., 2017, Desing of a 10MW Wind Turbine Rotor Blade for Testing of a Scaled-down Floating Offshore Support Structure, MSc. Thesis TUDelft
- De Ridder, E.-J., Otto, W., Zondervan, G.-J., Huijs, F., and Vaz, G., 2014, "Development of a Scaled-down Floating Wind Turbine for Offshore Basin Testing", Proceedings of the International Conference on Offshore Mechanics and Arctic Engineering - OMAE
- Fowler, M., Kimball, R., Thomas, D., and Goupee, A., 2013, "Design and Testing of Scale Model Wind Turbines for Used in Wind/Wave Basin Model Tests of Floating Offshore Wind Turbines", In:Proceedings of the International Conference on Offshroe Mechanics and Arctic Engineering - OMAE
- McElman, S., Joop, A., De Ridder, E.-J., and Goupee, A., 2016, "Simulation and Development of a Wind-Wave Facility for Scale Testing of offshore Floating Wind Turbines", In: Proceedings of the International Conference on Offshore Mechanics and Arctic Engineering -OMAE
- Ward, J., Fowler, M., Viselli, A., Goupee, A., and Dagher, H., 2018, "Design and Validation of a Multi-scale Model Floating Offshore Test Wind Turbine", In: ASME 2018 1 st International Offshore Wind Technical Conference, IOWTC
- Armesto, J.A., Jurado, A., Guanche, R., Counago, B., Urbano, J., and Serna, J., 2018, "Telwind. Numerical Analysis of a Floating Wind Turbine Supported by a Two Bodies Platform", In: Preceedings of the International Conference on Offshore Mechanics and Arctic Engineering - OMAE
- Azcona, J., Bourchotrouch, F., Conzalez, M., Garciandia, J., Munduate, X., Kelberlau, F., and Nygaard, T., 2014, "Aerodynamic Thrust Modelling in Wave Tank Tests of Offshore Floating Wind Turbines using a Ducted Fan", J. Phys. Conf.
- Bachynski, E., Thys, M., Sauder, T., Chabaud, V., and Saether, L., 2016, "Real-Time Hybrid Model Testing of a Braceless Semi-Submersible Wind Turbine. Part-II: Experimental Results", Proceedings of the International Conference on Offshore Mechanics and Arctic Engineering - OMAE
- Defor, A., Heurtier, J., Cunff, C., Antonutti, R., Weyne, P., and Marseille : 16eme Journees de I'Hydrodynamique.
- Demond, C., Hinrichs, J.-C., and Murphy, J., 2019, Uncertainty in the Physical Testing of Floating Wind Energy Platforms' Accuracy versus Precision, Energies.
- Gueydon, S., Lindeboom, R., VanKampen, W., and De Ridder, E-J., 2018, "Comparison of Two Wind turbine Loading Emulation Techniques Based on Tests of a TLP-FOWT in Combined Wind, Waves and Current", In: ASME 2018 1st International Offshore Wind Technical Conference, IOWTC
- Gueydon, S. and Bayati, I., 2020, Report of a New Hybrid SiL System for Offshore Basin Tests of Floating Offshore Wind Turbines, MARIN ARD - Internal R&D Project
- Hall, M. and Goupee, A., 2018, Validation of a Hybrid Modeling Approach to Floating Wind Turbine Basin Testing, Wind Energy.
- Kvittem, M., Berthelsen, P., Eliassen, L., and Thys, M., 2018, "Calibration of Hydrodynamic Coefficients for a Semi-Submersible 10MW Wind Turbine", In; Proceedings of the International Conference on Offshore Mechanics and Arctic Engineering - OMAE
- Oguz, E., Clelland, D., Day, A., Incecik, A., Lopez, J., Sanchez, G., and Almeria, G., 2018, Experimental and Numeircal Analysis of a TLP Floating Offshore Wind Turbine, Ocean Engineering, 147, 591-605
- Cummins, W.E., 1962, The Impulse Response Function and Ship Motions, Schiffstechnik, 47, 101-109
- Vittori, F., Bouchotrouch, F., Lemmer, F., and Azcona, J., 2018, "Hybrid Scaled Testing of a 5MW Floating Wind Turbine using the SiL Method Compared with Numerical Models", In: Proceedings of the International Conference on Offshore Mechanics and Arctic Engineering - OMAE
- www.youtube.com/watch?v=iMwcAstXyLM
- aviation.stackexchange.com/questions/9682/where-can-i-find-data-tables-for-lift-and-drag-coefficients-of-airliners
- Azcona, J., Bouchotrouch, F., and Vittori, F., 2019, Low-frequency Dynamics of a Floating Wind Turbine in Wave Tank-scaled Experiments with SiL Hybrid Method, Wind Energy, 22, 1402-1413.
- https://en.wikipedia.org/wiki/Law_of_the_wall
- DNVGL-ST-0119 Floating Wind Turbine Structures
- DNV-RP-0286 Coupled Analysis of Floating Wind Turbines
- ITTC-Recommended Procedures and Guidelines, 7.5-02-07-03.8
- LIFES50+ Project Report - D3.2 Wind Turbine Scaled Model
- https://docplayer.net/4931341-Depth-independentsolution-for-offshore-wind-the-windfloat.html
- DeepCwind Consortium National Research Program Final Project Report Vol. I
- http://www.gicon-sof.de/en/sof-chronik.html
- Ha, Y.J., Roh, C., Park, S.W., Ahn, H.J., Jung, D.W., Park, B.W., and Kim, K.H., 2021 "Development of Real-Time Hybrid Model Testing Technique for Performance Evaluation of a Floating Offshore Wind Turbine", The 2021 Fall Conference of Korea Wind Energy Association, Gwangju, Korea, 11/10~11/12 (in Korean).
- Chabaud, V., Eliassen, L., Thys, M., and Sauder, T., 2018, Multiple-Degree-of-Freedom Actuation of Rotor Loads in Model Testing of Floating Wind Turbines using Calbe-Driven Parallel Robots, Journal of Physics Conference Series, 1104(1), 012021
- Ha, Y.J., Park, S.W., Park, J.Y., Ahn, H.J., Kim, D.H., and Kim, K.H., 2022 "An Experimental Evaluation for Performance of a 15MW Class Floating Offshore Wind TUrbine System using Real-Time Hybrid Model Testing Technique", The 2022 Spring Conference of Korea Wind Energy Association, Jeju, Korea, 6/20~6/22 (in Korean).