OC7 Phase I: Toward Practical Sea-State-Dependent Modeling of Hydrodynamic Viscous Drag and Damping: Article No. 121745

Lu Wang; Amy Robertson; Jason Jonkman; Yingqian Liao; Petter Andreas Berthelsen; Serag-Eldin Abdelmoteleb; Peter Rohrer; Vishnu Ramachandran Nair Rajasree; Erin Bachynski-Polic; Constance Clement; Cedric Le Cunff; Prokopios Vlachogiannis; Christophe Peyrard; Dam Thanh Pham; Paul Leahy; Valerie Bouysses; Cedric Brun; Lizhong Wang; Lilin Wang; Long Teng; Wei Shi; Yushun Fu; Ali Abid; Zhengshun Cheng; Peng Chen; Zhirong Hu; Haozhe Bai; Kun Xu; Tuhin Das; Doyal Sarker; Tri Ngo; Pau Trubat Casal; Climent Molins; Francesco Niosi; Oronzo Dell'Edera; Bruno Paduano; Andrea Bertozzi; Giovanni Bracco; Bonaventura Tagliafierro; Abdolmajid Moghtadaei; Christopher Wright

doi:10.1016/j.oceaneng.2025.121745

OC7 Phase I: Toward Practical Sea-State-Dependent Modeling of Hydrodynamic Viscous Drag and Damping: Article No. 121745

Lu Wang
, Amy Robertson
, Jason Jonkman
, Yingqian Liao
, Petter Andreas Berthelsen
, Serag-Eldin Abdelmoteleb
, Peter Rohrer
, Vishnu Ramachandran Nair Rajasree
, Erin Bachynski-Polic
, Constance Clement
, Cedric Le Cunff
, Prokopios Vlachogiannis
, Christophe Peyrard
, Dam Thanh Pham
, Paul Leahy
, Valerie Bouysses
, Cedric Brun
, Lizhong Wang
, Lilin Wang
, Long Teng

Wei Shi, Yushun Fu, Ali Abid, Zhengshun Cheng, Peng Chen, Zhirong Hu, Haozhe Bai, Kun Xu, Tuhin Das, Doyal Sarker, Tri Ngo, Pau Trubat Casal, Climent Molins, Francesco Niosi, Oronzo Dell'Edera, Bruno Paduano, Andrea Bertozzi, Giovanni Bracco, Bonaventura Tagliafierro, Abdolmajid Moghtadaei, Christopher Wright

National Wind Technology Center

SINTEF
Norwegian University of Science & Technology
PRINCIPIA Group
Electricite de France
University College Cork
Bureau Veritas
Zhejiang University
Dalian University of Technology
Shanghai Jiao Tong University
Ocean University of China
University of Central Florida
Universitat Politecnica de Catalunya
Polytechnic University of Turin
University of Salerno
Gavin & Doherty Geosolutions

Research output: Contribution to journal › Article › peer-review

12 Scopus Citations

Abstract

This article presents a collaborative research campaign under the OC7 project on refining the engineering modeling approach for hydrodynamic viscous drag and damping on floating wind platforms, focusing on the adjustment of hydrodynamic drag and damping coefficients for different sea states. The participant simulation results show significant improvements over the previous OC6 project in predicting the low-frequency resonance motion under nonoperational conditions. The improvements are mainly due to enhanced modeling, including the adoption of wave stretching, and directly tuning the coefficients to measured platform motion in waves instead of free decay. For accurate predictions of mean- and slow-drift motion, the better performing models use a decreasing column splash zone drag coefficient and increasing surge damping/drag with increasing wave height. The model tuning for heave and pitch resonance shows less consistency. Generally, both quadratic drag and additional heave or pitch damping are needed for accurate predictions. Alternatively, a quadratic drag formulation with velocity filtering for the rectangular pontoons leads to improved predictions without additional damping. This model is also potentially more predictive, requiring minimal adjustment to its parameters for different conditions.

Original language	American English
Number of pages	25
Journal	Ocean Engineering
Volume	336
DOIs	https://doi.org/10.1016/j.oceaneng.2025.121745
State	Published - 2025

NLR Publication Number

NREL/JA-5000-93371

Keywords

drag
hydrodynamics
low frequency
OC7
resonance
sea state
validation
viscous
WINDMOOR

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10.1016/j.oceaneng.2025.121745

Cite this

Wang, L., Robertson, A., Jonkman, J., Liao, Y., Berthelsen, P. A., Abdelmoteleb, S.-E., Rohrer, P., Ramachandran Nair Rajasree, V., Bachynski-Polic, E., Clement, C., Le Cunff, C., Vlachogiannis, P., Peyrard, C., Pham, D. T., Leahy, P., Bouysses, V., Brun, C., Wang, L., Wang, L., ... Wright, C. (2025). OC7 Phase I: Toward Practical Sea-State-Dependent Modeling of Hydrodynamic Viscous Drag and Damping: Article No. 121745. Ocean Engineering, 336. https://doi.org/10.1016/j.oceaneng.2025.121745

@article{d5c4c5aa4d424026b1b8c8b0bb22b0c9,

title = "OC7 Phase I: Toward Practical Sea-State-Dependent Modeling of Hydrodynamic Viscous Drag and Damping: Article No. 121745",

abstract = "This article presents a collaborative research campaign under the OC7 project on refining the engineering modeling approach for hydrodynamic viscous drag and damping on floating wind platforms, focusing on the adjustment of hydrodynamic drag and damping coefficients for different sea states. The participant simulation results show significant improvements over the previous OC6 project in predicting the low-frequency resonance motion under nonoperational conditions. The improvements are mainly due to enhanced modeling, including the adoption of wave stretching, and directly tuning the coefficients to measured platform motion in waves instead of free decay. For accurate predictions of mean- and slow-drift motion, the better performing models use a decreasing column splash zone drag coefficient and increasing surge damping/drag with increasing wave height. The model tuning for heave and pitch resonance shows less consistency. Generally, both quadratic drag and additional heave or pitch damping are needed for accurate predictions. Alternatively, a quadratic drag formulation with velocity filtering for the rectangular pontoons leads to improved predictions without additional damping. This model is also potentially more predictive, requiring minimal adjustment to its parameters for different conditions.",

keywords = "drag, hydrodynamics, low frequency, OC7, resonance, sea state, validation, viscous, WINDMOOR",

author = "Lu Wang and Amy Robertson and Jason Jonkman and Yingqian Liao and Berthelsen, \{Petter Andreas\} and Serag-Eldin Abdelmoteleb and Peter Rohrer and \{Ramachandran Nair Rajasree\}, Vishnu and Erin Bachynski-Polic and Constance Clement and \{Le Cunff\}, Cedric and Prokopios Vlachogiannis and Christophe Peyrard and Pham, \{Dam Thanh\} and Paul Leahy and Valerie Bouysses and Cedric Brun and Lizhong Wang and Lilin Wang and Long Teng and Wei Shi and Yushun Fu and Ali Abid and Zhengshun Cheng and Peng Chen and Zhirong Hu and Haozhe Bai and Kun Xu and Tuhin Das and Doyal Sarker and Tri Ngo and \{Trubat Casal\}, Pau and Climent Molins and Francesco Niosi and Oronzo Dell'Edera and Bruno Paduano and Andrea Bertozzi and Giovanni Bracco and Bonaventura Tagliafierro and Abdolmajid Moghtadaei and Christopher Wright",

year = "2025",

doi = "10.1016/j.oceaneng.2025.121745",

language = "American English",

volume = "336",

journal = "Ocean Engineering",

issn = "0029-8018",

publisher = "Elsevier B.V.",

}

Wang, L, Robertson, A, Jonkman, J, Liao, Y, Berthelsen, PA, Abdelmoteleb, S-E, Rohrer, P, Ramachandran Nair Rajasree, V, Bachynski-Polic, E, Clement, C, Le Cunff, C, Vlachogiannis, P, Peyrard, C, Pham, DT, Leahy, P, Bouysses, V, Brun, C, Wang, L, Wang, L, Teng, L, Shi, W, Fu, Y, Abid, A, Cheng, Z, Chen, P, Hu, Z, Bai, H, Xu, K, Das, T, Sarker, D, Ngo, T, Trubat Casal, P, Molins, C, Niosi, F, Dell'Edera, O, Paduano, B, Bertozzi, A, Bracco, G, Tagliafierro, B, Moghtadaei, A & Wright, C 2025, 'OC7 Phase I: Toward Practical Sea-State-Dependent Modeling of Hydrodynamic Viscous Drag and Damping: Article No. 121745', Ocean Engineering, vol. 336. https://doi.org/10.1016/j.oceaneng.2025.121745

TY - JOUR

T1 - OC7 Phase I: Toward Practical Sea-State-Dependent Modeling of Hydrodynamic Viscous Drag and Damping

T2 - Article No. 121745

AU - Wang, Lu

AU - Robertson, Amy

AU - Jonkman, Jason

AU - Liao, Yingqian

AU - Berthelsen, Petter Andreas

AU - Abdelmoteleb, Serag-Eldin

AU - Rohrer, Peter

AU - Ramachandran Nair Rajasree, Vishnu

AU - Bachynski-Polic, Erin

AU - Clement, Constance

AU - Le Cunff, Cedric

AU - Vlachogiannis, Prokopios

AU - Peyrard, Christophe

AU - Pham, Dam Thanh

AU - Leahy, Paul

AU - Bouysses, Valerie

AU - Brun, Cedric

AU - Wang, Lizhong

AU - Wang, Lilin

AU - Teng, Long

AU - Shi, Wei

AU - Fu, Yushun

AU - Abid, Ali

AU - Cheng, Zhengshun

AU - Chen, Peng

AU - Hu, Zhirong

AU - Bai, Haozhe

AU - Xu, Kun

AU - Das, Tuhin

AU - Sarker, Doyal

AU - Ngo, Tri

AU - Trubat Casal, Pau

AU - Molins, Climent

AU - Niosi, Francesco

AU - Dell'Edera, Oronzo

AU - Paduano, Bruno

AU - Bertozzi, Andrea

AU - Bracco, Giovanni

AU - Tagliafierro, Bonaventura

AU - Moghtadaei, Abdolmajid

AU - Wright, Christopher

PY - 2025

Y1 - 2025

N2 - This article presents a collaborative research campaign under the OC7 project on refining the engineering modeling approach for hydrodynamic viscous drag and damping on floating wind platforms, focusing on the adjustment of hydrodynamic drag and damping coefficients for different sea states. The participant simulation results show significant improvements over the previous OC6 project in predicting the low-frequency resonance motion under nonoperational conditions. The improvements are mainly due to enhanced modeling, including the adoption of wave stretching, and directly tuning the coefficients to measured platform motion in waves instead of free decay. For accurate predictions of mean- and slow-drift motion, the better performing models use a decreasing column splash zone drag coefficient and increasing surge damping/drag with increasing wave height. The model tuning for heave and pitch resonance shows less consistency. Generally, both quadratic drag and additional heave or pitch damping are needed for accurate predictions. Alternatively, a quadratic drag formulation with velocity filtering for the rectangular pontoons leads to improved predictions without additional damping. This model is also potentially more predictive, requiring minimal adjustment to its parameters for different conditions.

AB - This article presents a collaborative research campaign under the OC7 project on refining the engineering modeling approach for hydrodynamic viscous drag and damping on floating wind platforms, focusing on the adjustment of hydrodynamic drag and damping coefficients for different sea states. The participant simulation results show significant improvements over the previous OC6 project in predicting the low-frequency resonance motion under nonoperational conditions. The improvements are mainly due to enhanced modeling, including the adoption of wave stretching, and directly tuning the coefficients to measured platform motion in waves instead of free decay. For accurate predictions of mean- and slow-drift motion, the better performing models use a decreasing column splash zone drag coefficient and increasing surge damping/drag with increasing wave height. The model tuning for heave and pitch resonance shows less consistency. Generally, both quadratic drag and additional heave or pitch damping are needed for accurate predictions. Alternatively, a quadratic drag formulation with velocity filtering for the rectangular pontoons leads to improved predictions without additional damping. This model is also potentially more predictive, requiring minimal adjustment to its parameters for different conditions.

KW - drag

KW - hydrodynamics

KW - low frequency

KW - OC7

KW - resonance

KW - sea state

KW - validation

KW - viscous

KW - WINDMOOR

U2 - 10.1016/j.oceaneng.2025.121745

DO - 10.1016/j.oceaneng.2025.121745

M3 - Article

SN - 0029-8018

VL - 336

JO - Ocean Engineering

JF - Ocean Engineering

ER -

OC7 Phase I: Toward Practical Sea-State-Dependent Modeling of Hydrodynamic Viscous Drag and Damping: Article No. 121745

Abstract

NLR Publication Number

Keywords

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