TY - GEN

T1 - Advanced incorporation of soil-structure interaction into integrated load simulation

AU - Dubois, Jan

AU - Thieken, Klaus

AU - Terceros, Mauricio

AU - Schaumann, Peter

AU - Achmus, Martin

PY - 2016

Y1 - 2016

N2 - The optimization of monopiles for offshore wind turbines is closely linked to improved foundation models, particularly for large diameter structures. During the last years significant progress on geotechnical level has been made to assess foundation models of monopiles based on high fidelity finite element models. In contrast, integrated load simulation models for offshore wind turbines commonly incorporate soil-structure interaction on a simplified level. This paper presents an efficient coupling approach, suggesting a practical interface between the offshore wind turbine substructure and sophisticated foundation models on mudline level. The approach is applied for load simulations on fatigue load level. The monopile load spectrum has to be defined in advance. Then, a limited number of static foundation pre-simulations are performed to predict the response on interface level by use of loaddisplacement curves. The integration of these curves into the load simulation model is achieved by an extension to spatial loaddisplacement surfaces. For this purpose an interpolation technique has been particularly developed which works efficient and accurate. The test simulations conducted for this paper are limited to co-directional wind and wave direction and a pre-dominant lateral loaded foundation, but the method offers the flexibility to be evolved to spatially loaded pile or bucket foundations.

AB - The optimization of monopiles for offshore wind turbines is closely linked to improved foundation models, particularly for large diameter structures. During the last years significant progress on geotechnical level has been made to assess foundation models of monopiles based on high fidelity finite element models. In contrast, integrated load simulation models for offshore wind turbines commonly incorporate soil-structure interaction on a simplified level. This paper presents an efficient coupling approach, suggesting a practical interface between the offshore wind turbine substructure and sophisticated foundation models on mudline level. The approach is applied for load simulations on fatigue load level. The monopile load spectrum has to be defined in advance. Then, a limited number of static foundation pre-simulations are performed to predict the response on interface level by use of loaddisplacement curves. The integration of these curves into the load simulation model is achieved by an extension to spatial loaddisplacement surfaces. For this purpose an interpolation technique has been particularly developed which works efficient and accurate. The test simulations conducted for this paper are limited to co-directional wind and wave direction and a pre-dominant lateral loaded foundation, but the method offers the flexibility to be evolved to spatially loaded pile or bucket foundations.

KW - Integrated load simulation

KW - Monopile

KW - P-y method

KW - Simulation interface

KW - Soilstructure interaction

UR - http://www.scopus.com/inward/record.url?scp=84987903915&partnerID=8YFLogxK

M3 - Conference contribution

AN - SCOPUS:84987903915

T3 - Proceedings of the International Offshore and Polar Engineering Conference

SP - 754

EP - 762

BT - Proceedings of the 26th International Ocean and Polar Engineering Conference, ISOPE 2016

A2 - Wang, Alan M.

A2 - Chung, Jin S.

A2 - Kokkinis, Ted

A2 - Muskulus, Michael

PB - International Society of Offshore and Polar Engineers

T2 - 26th Annual International Ocean and Polar Engineering Conference, ISOPE 2016

Y2 - 26 June 2016 through 1 July 2016

ER -