| The effect of the elliptical front wall on energy conversion performance of the offshore OWC chamber: A numerical study |
Qu, M., Yu, D., Xu, Z. |
|
Journal Article |
Journal Article |
Wave, Oscillating Water Column |
Modeling |
Performance |
| The Blade Design of a Bionic Shark Fin Airfoil for a Horizontal Axis Tidal Current Turbine |
Zhang, K., Yang, S., Gao, Z. |
|
Journal Article |
Journal Article |
Current, Axial Flow Turbine |
Lab Data, Modeling |
Performance, Structural |
| Maximization of wave power extraction of a heave point absorber with a sea-state-based causal control algorithm |
Li, L., Gao, Z. |
|
Journal Article |
Journal Article |
Wave, Point Absorber |
Modeling |
Control, Performance |
| The surface wave effects on the performance and the loading of a tidal turbine |
Guo, X., Yang, J. , Gao, Z. |
|
Journal Article |
Journal Article |
Current, Tidal |
Lab Data, Modeling, Scale Device |
Hydrodynamics, Performance |
| Efficient determination of the long-term extreme responses by the modified environmental contour method for a combined wind turbine and wave energy converter system |
Li, Q., Ren, N., Gao, Z. |
|
Journal Article |
Journal Article |
Wave |
Modeling |
Hybrid Devices, Performance |
| Efficient determination of the long-term extreme responses by the modified environmental contour method for a combined wind turbine and wave energy converter system |
Li, Q., Ren, N., Gao, Z. |
|
Journal Article |
Journal Article |
Wave |
|
Hybrid Devices |
| A combined wind and wave energy-converter concept in survival mode: Numerical and experimental study in regular waves with a focus on water entry and exit |
Wan, L., Greco, M., Lugni, C. |
|
Journal Article |
Journal Article |
Wave, Oscillating Water Column |
Modeling |
Hybrid Devices, Hydrodynamics, Performance |
| Experimental and numerical study of the response of the offshore combined wind/wave energy concept SFC in extreme environmental conditions |
Michailides, C., Gao, Z., Moan, T. |
|
Journal Article |
Journal Article |
Wave |
Modeling |
|
| Experimental and numerical comparisons of hydrodynamic responses for a combined wind and wave energy converter concept under operational conditions |
Wan, L., Gao, Z., Moan, T. |
|
Journal Article |
Journal Article |
Wave, Point Absorber |
Modeling |
Hybrid Devices, Hydrodynamics, Power Take Off |
| Experimental study of the functionality of a semisubmersible wind turbine combined with flap-type Wave Energy Converters |
Michailides, C., Gao, Z., Moan, T. |
|
Journal Article |
Journal Article |
Wave |
Lab Data |
Hybrid Devices, Power Take Off |
| Comparative numerical and experimental study of two combined wind and wave energy concepts |
Gao, Z., Moan, T., Wan, L. |
|
Journal Article |
Journal Article |
Wave, Oscillating Water Column |
Modeling, Scale Device |
Hybrid Devices, Power Take Off |
| Comparative experimental study of the survivability of a combined wind and wave energy converter in two testing facilities |
Wan, L., Gao, Z., Moan, T. |
|
Journal Article |
Journal Article |
Wave |
Lab Data, Modeling, Scale Device |
Hybrid Devices |
| Experimental and numerical study of hydrodynamic responses of a combined wind and wave energy converter concept in survival modes |
Wan, L., Gao, Z., Moan, T. |
|
Journal Article |
Journal Article |
Wave |
Lab Data, Scale Device |
Hybrid Devices |
| Comparison of Experimental Data of a Moored Multibody Wave Energy Device With a Hybrid CFD and BIEM Numerical Analysis Framework |
Nematbakhsh, A., Michaelides, C., Gao, Z. |
|
Conference Paper |
Conference Paper |
Wave |
Modeling |
Mooring |
| Fatigue Analysis of a Wave Energy Converter Taking Into Account Different Control Strategies |
Zurkinden, A., Lambertsen, S., Damkilde, L. |
|
Conference Paper |
Conference Paper |
Wave, Point Absorber |
|
Control |
| Application of the Contour Line Method for Estimating Extreme Responses in the Mooring Lines of a Two-Body Floating Wave Energy Converter |
Muliawan, M., Gao, Z., Moan, T. |
|
Journal Article |
Journal Article |
Wave |
Modeling |
Mooring |
| Extreme responses of a combined spar-type floating wind turbine and floating wave energy converter (STC) system with survival modes |
Muliawan, M., Karimirad, M., Gao, Z. |
|
Journal Article |
Journal Article |
Wave |
Modeling |
Hybrid Devices |
| Analysis of a Two-Body Floating Wave Energy Converter With Particular Focus on the Effects of Power Take-Off and Mooring Systems on Energy Capture |
Muliawan, M., Gao, Z., Moan, T. |
|
Journal Article |
Journal Article |
Wave |
Modeling |
Mooring, Power Take Off |
| Comparison of Mooring Loads in Survivability Mode on the Wave Dragon Wave Energy Converter Obtained by a Numerical Model and Experimental Data |
Parmeggiani, S., Muliawan, M., Gao, Z. |
|
Conference Paper |
Conference Paper |
Wave, Overtopping |
Modeling |
Hydrodynamics, Mooring |
| Mooring system analysis of multiple wave energy converters in a farm configuration |
Gao, Z., Moan, T. |
|
Conference Paper |
Conference Paper |
Wave |
Modeling |
Mooring |
