TY - JOUR

T1 - Influence of structural design variations on economic viability of offshore wind turbines

T2 - An interdisciplinary analysis

AU - Hübler, Clemens

AU - Piel, Jan Hendrik

AU - Stetter, Chris

AU - Gebhardt, Cristian G.

AU - Breitner, Michael H.

AU - Rolfes, Raimund

N1 - Funding Information: We gratefully acknowledge the financial support of the European Commission (research project IRP Wind, funded from the European Union's Seventh Framework Programme for research, technological development and demonstration under grant agreement number 609795 ) that enabled this work.

PY - 2020/1

Y1 - 2020/1

N2 - Offshore wind energy is a seminal technology to achieve the goals set for renewable energy deployment. However, today's offshore wind energy projects are mostly not yet sufficiently competitive. The optimization of offshore wind turbine substructures with regard to costs and reliability is a promising approach to increase competitiveness. Today, interdisciplinary analyses considering sophisticated engineering models and their complex economic effects are not widespread. Existing approaches are deterministic. This research gap is addressed by combining an aero-elastic wind turbine model with an economic viability model for probabilistic investment analyses. The impact of different monopile designs on the stochastic cost-efficiency of an offshore wind farm is investigated. Monopiles are varied with regard to diameters and wall thicknesses creating designs with increased lifetimes but higher capital expenditures (durable designs) and vice versa (cheaper designs). For each substructure, the aero-elastic wind turbine model yields distributions for the fatigue lifetime and electricity yield and different capital expenditures, which are applied to the economic viability model. For other components, e.g. blades, constant lifetimes and costs are assumed. The results indicate that the gain of increased stochastic lifetimes exceeds the benefit of reduced initial costs, if the overall lifetime is not governed by other turbine components' lifetimes.

AB - Offshore wind energy is a seminal technology to achieve the goals set for renewable energy deployment. However, today's offshore wind energy projects are mostly not yet sufficiently competitive. The optimization of offshore wind turbine substructures with regard to costs and reliability is a promising approach to increase competitiveness. Today, interdisciplinary analyses considering sophisticated engineering models and their complex economic effects are not widespread. Existing approaches are deterministic. This research gap is addressed by combining an aero-elastic wind turbine model with an economic viability model for probabilistic investment analyses. The impact of different monopile designs on the stochastic cost-efficiency of an offshore wind farm is investigated. Monopiles are varied with regard to diameters and wall thicknesses creating designs with increased lifetimes but higher capital expenditures (durable designs) and vice versa (cheaper designs). For each substructure, the aero-elastic wind turbine model yields distributions for the fatigue lifetime and electricity yield and different capital expenditures, which are applied to the economic viability model. For other components, e.g. blades, constant lifetimes and costs are assumed. The results indicate that the gain of increased stochastic lifetimes exceeds the benefit of reduced initial costs, if the overall lifetime is not governed by other turbine components' lifetimes.

KW - Economic viability

KW - Lifetime distribution

KW - Offshore wind energy

KW - Stochastic cost-efficiency

KW - Substructure design

UR - http://www.scopus.com/inward/record.url?scp=85067969134&partnerID=8YFLogxK

U2 - 10.1016/j.renene.2019.06.113

DO - 10.1016/j.renene.2019.06.113

M3 - Article

AN - SCOPUS:85067969134

VL - 145

SP - 1348

EP - 1360

JO - Renewable energy

JF - Renewable energy

SN - 0960-1481

ER -