Research output per year
Research output per year
Project Details
Description
Wind turbine blade surfaces degrade over time leading to reduced Annual Energy Production and increased cost of energy. This project will develop techniques for performing in-situ, quantitative measurements of leading edge surface roughness, and methods for converting these measurements into a quantitative decision tool for turbine owners O&M plans
Layman's description
The leading edges of wind turbine blades erode due to colliding with dust and rain droplets at speeds in excess of 300 km/h. This erosion causes reduced aerodynamic performance and hence reduced energy production. Currently, the degree of erosion is visually inspected from the ground using powerful optics and a human determines whether the blade is "OK" or needs to undergo repair. In this project we will develop a system which uses a flying drone (UAV - Unmanned Aerial Vehicle) to image the blades, do high resolution 3D reconstruction of the blades' surface and exactly quantify the amount of erosion. Subsequently, these erosion measurements are turned into estimates of reduced Annual Energy Production (AEP). The turbine owner can then make a absolutely informed decision on whether to run the turbine for a while longer or to initiate repairs.
| Short title | LER BLades |
|---|---|
| Status | Finished |
| Effective start/end date | 01/10/2015 → 01/05/2019 |
Collaborative partners
- Technical University of Denmark (Project partner)
- Danish Fundamental Metrology Ltd., Matematiktorvet 307, DK-2800 Kgs. Lyngby (Project partner)
- PowerCurve (lead)
Keywords
- Wind energy
- 3d reconstruction
- drone
- uav
- unmanned aerial vehicle
- Wind Turbine Blades
Fingerprint
Explore the research topics touched on by this project. These labels are generated based on the underlying awards/grants. Together they form a unique fingerprint.
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Calculating Absolute Scale and Scale Uncertainty for SfM Using Distance Sensor Measurements: A Lightweight and Flexible Approach
Nikolov, I. A. & Madsen, C. B., 2020, Recent Advances in 3D Imaging, Modeling and Reconstruction. IGI global, p. 168-192 25 p.Research output: Contribution to book/anthology/report/conference proceeding › Book chapter › Research › peer-review
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High-Resolution Structure-from-Motion for Quantitative Measurement of Leading-Edge Roughness
Schou Nielsen, M., Nikolov, I. A., Kruse, E. K., Garnæs, J. & Madsen, C. B., 2020, In: Energies. 13, 15, 3916.Research output: Contribution to journal › Journal article › Research › peer-review
Open AccessFile7 Citations (Scopus)149 Downloads (Pure) -
Interactive Environment for Testing SfM Image Capture Configurations
Nikolov, I. A. & Madsen, C. B., 27 Feb 2019, VISIGRAPP 2019 - Proceedings of the 14th International Joint Conference on Computer Vision, Imaging and Computer Graphics Theory and Applications. Kerren, A., Hurter, C. & Braz, J. (eds.). SCITEPRESS Digital Library, p. 317-322 6 p.Research output: Contribution to book/anthology/report/conference proceeding › Article in proceeding › Research › peer-review
Open AccessFile96 Downloads (Pure)
Datasets
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Wind Turbine Blade SfM Image Capturing Setups
Nikolov, I. A. (Creator) & Madsen, C. B. (Creator), Mendeley Data, 1 Sept 2020
Dataset
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GGG-BenchmarkSfM: Dataset for Benchmarking Close-range SfM Software Performance under Varying Capturing Condition
Nikolov, I. A. (Creator) & Madsen, C. B. (Creator), Mendeley Data, 12 Aug 2020
DOI: doi: 10.17632/bzxk2n78s9.4
Dataset
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Wind Turbine Blade Surfaces Dataset
Nikolov, I. A. (Creator), Schou Nielsen, M. (Contributor), Garnæs, J. (Supervisor) & Madsen, C. B. (Creator), Mendeley Data, 12 Aug 2020
Dataset