Projects per year
Abstract
Designing modern wind turbine blades is challenging due to the large scale and advanced materials utilized. Structural optimization has been shown to provide substantial benefits to both the design process and resulting design, however its application to blades is non-trivial, because of the required computational cost of solving optimization problems. Moreover, it is desirable to assess all structural failure criteria as part of the optimization, which is currently not possible, herein notably fatigue damage.
The present work hence aims to further the structural optimization capabilities in application to wind turbine blades. Initial work concerns development of a fatigue optimization approach for general laminated composite structures within a gradient-based framework. The developed approach is later applied to optimize a blade root section model, along with buckling and static failure criteria, in context of both a thickness and multi-material and thickness parametrization. Significant reductions in material from the initial design accompany the attained variable-thickness laminates, emphasizing the potential of using the developed methods in the design process.
The present work hence aims to further the structural optimization capabilities in application to wind turbine blades. Initial work concerns development of a fatigue optimization approach for general laminated composite structures within a gradient-based framework. The developed approach is later applied to optimize a blade root section model, along with buckling and static failure criteria, in context of both a thickness and multi-material and thickness parametrization. Significant reductions in material from the initial design accompany the attained variable-thickness laminates, emphasizing the potential of using the developed methods in the design process.
| Translated title of the contribution | Strukturel Optimering af Vindmøllevinger med Udmattelsesbibetingelser |
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| Original language | English |
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| Electronic ISBNs | 978-87-7573-578-5 |
| Publication status | Published - 2023 |
Fingerprint
Dive into the research topics of 'Structural Optimization of Wind Turbine Blades Including Fatigue Constraints'. Together they form a unique fingerprint.Projects
- 1 Finished
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MADEBLADES: Manufacture and Design of Large Offshore Wind Turbine Blades
Lund, E. (Project Participant), Lindgaard, E. (Project Participant), Bak, B. L. V. (Project Participant), Jakobsen, J. (Project Participant), Krogh, C. (Project Participant), Kepler, J. A. (Project Participant), Broberg, P. H. (Project Participant), Olesen, A. M. (Project Participant) & Hermansen, S. M. (Project Participant)
01/03/2020 → 31/12/2023
Project: Research
Research output
- 3 Journal article
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Gradient-based structural optimization of a wind turbine blade root section including high-cycle fatigue constraints
Hermansen, S. M., Macquart, T. & Lund, E., 10 Jan 2025, (E-pub ahead of print) In: Engineering Optimization. 32 p.Research output: Contribution to journal › Journal article › Research › peer-review
Open Access -
Multi-material and thickness optimization of a wind turbine blade root section
Hermansen, S. M. & Lund, E., Jul 2024, In: Structural and Multidisciplinary Optimization. 67, 7, 107.Research output: Contribution to journal › Journal article › Research › peer-review
Open AccessFile8 Citations (Scopus)22 Downloads (Pure) -
Multi-material and thickness optimization of laminated composite structures subject to high-cycle fatigue
Hermansen, S. M. & Lund, E., Dec 2023, In: Structural and Multidisciplinary Optimization. 66, 12, 259.Research output: Contribution to journal › Journal article › Research › peer-review
Open AccessFile10 Citations (Scopus)66 Downloads (Pure)