| A computational method for sharp interface advection J Roenby, H Bredmose, H Jasak Royal Society open science 3 (11), 160405, 2016 | 468 | 2016 |
| IEA wind TCP task 37: definition of the IEA 15-megawatt offshore reference wind turbine E Gaertner, J Rinker, L Sethuraman, F Zahle, B Anderson, GE Barter, ... National Renewable Energy Lab.(NREL), Golden, CO (United States), 2020 | 461* | 2020 |
| Violent breaking wave impacts. Part 1: Results from large-scale regular wave tests on vertical and sloping walls GN Bullock, C Obhrai, DH Peregrine, H Bredmose Coastal Engineering 54 (8), 602-617, 2007 | 380 | 2007 |
| Forcing of a bottom-mounted circular cylinder by steep regular water waves at finite depth BT Paulsen, H Bredmose, HB Bingham, NG Jacobsen Journal of fluid mechanics 755, 1-34, 2014 | 213 | 2014 |
| An efficient domain decomposition strategy for wave loads on surface piercing circular cylinders BT Paulsen, H Bredmose, HB Bingham Coastal Engineering 86, 57-76, 2014 | 194 | 2014 |
| Violent breaking wave impacts. Part 2: modelling the effect of air H Bredmose, DH Peregrine, GN Bullock Journal of Fluid Mechanics 641, 389-430, 2009 | 141 | 2009 |
| Breaking wave impacts on offshore wind turbine foundations: focused wave groups and CFD H Bredmose, NG Jacobsen International Conference on Offshore Mechanics and Arctic Engineering 49118 …, 2010 | 126 | 2010 |
| Experimental investigation and numerical modelling of steep forced water waves H Bredmose, M Brocchini, DH Peregrine, L Thais Journal of Fluid Mechanics 490, 217-249, 2003 | 120 | 2003 |
| Definition of the IEA wind 15-megawatt offshore reference wind turbine E Gaertner, J Rinker, L Sethuraman, F Zahle, B Anderson, G Barter, ... National Renewable Energy Laboratory, 2020 | 109 | 2020 |
| Violent breaking wave impacts. Part 3. Effects of scale and aeration H Bredmose, GN Bullock, AJ Hogg Journal of Fluid Mechanics 765, 82-113, 2015 | 106 | 2015 |
| An efficient frequency-domain model for quick load analysis of floating offshore wind turbines A Pegalajar-Jurado, M Borg, H Bredmose Wind Energy Science 3 (2), 693-712, 2018 | 84 | 2018 |
| The Triple Spar campaign: Model tests of a 10MW floating wind turbine with waves, wind and pitch control H Bredmose, F Lemmer, M Borg, A Pegalajar-Jurado, RF Mikkelsen, ... Energy procedia 137, 58-76, 2017 | 84 | 2017 |
| A new volume-of-fluid method in OpenFOAM J Roenby, BE Larsen, H Bredmose, H Jasak Marine vi: Proceedings of the vi international conference on computational …, 2017 | 76 | 2017 |
| Extreme wave forces and wave run-up on offshore wind turbine foundations ED Christensen, H Bredmose, EA Hansen Proceedings of Copenhagen Offshore Wind, 1-10, 2005 | 74 | 2005 |
| Improved tank test procedures for scaled floating offshore wind turbines K Müller, F Sandner, H Bredmose, J Azcona, A Manjock, R Pereira | 68 | 2014 |
| Grand challenges in the design, manufacture, and operation of future wind turbine systems P Veers, CL Bottasso, L Manuel, J Naughton, L Pao, J Paquette, ... Wind Energy Science 8 (7), 1071-1131, 2023 | 67 | 2023 |
| State-of-the-art model for the LIFES50+ OO-Star Wind Floater Semi 10MW floating wind turbine A Pegalajar-Jurado, H Bredmose, M Borg, JG Straume, T Landbø, ... Journal of Physics: Conference Series 1104 (1), 012024, 2018 | 66 | 2018 |
| The influence of fully nonlinear wave forces on aero-hydro-elastic calculations of monopile wind turbines S Schløer, H Bredmose, HB Bingham Marine Structures 50, 162-188, 2016 | 66 | 2016 |
| Water wave impact on walls and the role of air DH Peregrine, H Bredmose, G Bullock, C Obrhai, G Müller, G Wolters Coastal Engineering 2004: (In 4 Volumes), 4005-4017, 2005 | 63 | 2005 |
| The ideal flip-through impact: experimental and numerical investigation H Bredmose, A Hunt-Raby, R Jayaratne, GN Bullock Journal of engineering mathematics 67, 115-136, 2010 | 58 | 2010 |
