| Oppgave | Student | Hovedveileder | Biveileder | Partner |
|---|---|---|---|---|
Probabilistic modelling of ice ridge actions on Offshore wind turbines |
| Knut V. Høyland | Ilija Samardzija | Norconsult |
| Knut V. Høyland | Sigurd Teigen, Nicolas Serré | Equinor, Multiconsult | |
Ice conditions and ice actions on offshore wind turbines in the Baltic |
| Knut V. Høyland | Sigurd Teigen, Nicolas Serré | Equinor, Multiconsult |
| Knut V. Høyland | Ilija Samardzija, | Norconsult, SVV | |
| Knut V. Høyland |
| SVV | |
| Knut V. Høyland |
| NPI, UNIS | |
| Knut V. Høyland | H. Skourup | UNIS, UiT, DTU | |
| Knut V. Høyland | Knut Alfredsen | SVV | |
| Knut V. Høyland | Janne Søreide, Eero Rinne | UNIS | |
| Knut V. Høyland | Wenjun Lu and Sönke Maus | ||
| Knut V. Høyland | Jose Rafael Meza Padilla | Vattenfall (Copehagen) | |
Simulations of ice ridge interaction with buried power cable from offshore wind turbines |
| Knut V. Høyland / Gudmund Eiksund | Jose Rafael Meza Padilla | Vattenfall (Copehagen) |
Metocean design basis for offshore and coastal structures |
| Raed Lubbad |
|
|
Breakwaters – Conventional, Floating, living, Artificial Reefs |
| Raed Lubbad |
|
|
| Multi-fraction Sediment Transport Modelling |
| Raed Lubbad |
|
|
| Raed Lubbad |
|
| |
| Modelling river-ice break-up, run-off, jamming and consequent flooding |
| Raed Lubbad |
|
|
Modelling of sea-ice and iceberg drift |
| Raed Lubbad |
|
|
Numerical Simulations of ice actions on fixed and floating structures |
| Raed Lubbad |
|
|
| Raed Lubbad |
|
| |
Characterizing the size and shape of sea ice floes based on onboard sensors |
| Wenjun Lu |
|
|
Accelerating numerical modelling with physics informed Neural Networks |
| Wenjun Lu |
|
|
Numerical simulation of ice loads on offshore wind farms in the Baltic Sea |
| Wenjun Lu |
|
|
Sea Spray Icing on Structures in Cold Climate |
| Wenjun Lu |
|
|
Investigating the predictability of operational safety with NextSIM |
| Wenjun Lu |
|
|
Developing a location estimation algorithm with Marine radar images and satellite images |
| Wenjun Lu |
|
|
Multifractality of sea ice fracture and fragmentation |
| Wenjun Lu |
|
|
Design iceberg impact energy |
| Wenjun Lu |
|
|
Detailed structural optimization of wind turbine jacket joints |
| Michael Muskulus |
| |
Estimation of bath-tub failure rate curve from observed wind turbine component failures |
| Michael Muskulus |
| |
Efficient simulation of floating offshore wind turbines |
| Michael Muskulus |
| |
Design and optimization of power cables for floating wind turbines |
| Michael Muskulus |
| |
Detailed analysis of a simplified ice-structure interaction model |
| Michael Muskulus |
| |
Detailed modeling of wave forces on jacket joints with CFD |
| Michael Muskulus |
| |
Local flexibility of jacket joints – developing a best practice for including this effect into beam FE models |
| Michael Muskulus |
| |
Accurate stress concentration factors for offshore wind jacket structures |
| Michael Muskulus |
| |
Transition piece design for an offshore wind turbine on a jacket |
| Michael Muskulus |
| |
Analytic approach to fatigue damage for stationary Gaussian processes |
| Michael Muskulus |
| |
Damage-conscious curtailment / de-rating strategies for wind turbines |
| Michael Muskulus |
| |
An efficient model for wind turbine wake meandering in the time domain |
| Michael Muskulus |
| |
Extending quasi-static design sensitivity analysis to include wave forces |
| Michael Muskulus |
| |
Designing an offshore wind turbine with a spreadsheet – how accurate can we get? |
| Michael Muskulus |
| |
Improving the Dirlik approach to fatigue damage with machine learning |
| Michael Muskulus |
| |
Designing a hydraulic locking system for a vertical axis wind turbine - saving main bearing maintenance costs |
| Michael Muskulus |
| |
“Be a wind turbine controller” – designing a serious computer game for educational purposes |
| Michael Muskulus |
| |
Aerodynamic damping for vertical axis wind turbines |
| Michael Muskulus |
| |
Extending an elastic multibody solver for wind turbine design and analysis |
| Michael Muskulus |
| |
Harbors: Wave conditions and Breakwaters |
| Hans Bihs | Widar Wang |
|
Integrated Cascade Modeling - Ocean to Structure |
| Hans Bihs | Widar Wang | Norwegian Meteorology Institute |
Ericeira - Surf Wave Modeling |
| Hans Bihs | Widar Wang | blueOASIS |
E39 - Floating Bridges |
| Hans Bihs | Widar Wang | Norconsult |
Ship Wave Modeling with SFLOW or NHFLOW |
| Hans Bihs | Widar Wang, Carlos Dempwolff | TU Braunschweig, Federal Waterways Engineering Research Institute (BAW) Hamburg - Germany |
Coastal Protection - Nature Based Solutions |
| Hans Bihs | Widar Wang | JBA Consulting |
Offshore Wind - Wave Modeling |
| Hans Bihs | Widar Wang | SINTEF Ocean, Metrological Institute of Norway, Equinor, Aker Solutions, DNV, COWI |
Generation Of Synthetic Wind And Wave Data Series At A Port Site For OWT Marshalling Based On Geographically Spread Existing Databases. |
| Hans Bihs | Widar Wang, Marit Reiso | Dr.techn. Olav Olsen AS |
Offshore Wind Substructures: Near-field Hydrodynamics and Scour with CFD |
| Hans Bihs | Widar Wang |
|
Floating Offshore Wind |
| Hans Bihs | Widar Wang |
|
Aquaculture Structures |
| Hans Bihs | Widar Wang |
|
Elevated Structures at the Coast |
| Hans Bihs | Widar Wang |
|
Coastal Dynamics / Sediment Transport |
| Hans Bihs | Widar Wang |
|
Oppdatert 22.04.2022