Cartographing dynamic stall with machine learning
<p>Once stall has set in, lift collapses, drag increases and then both of these forces will fluctuate strongly. The result is higher fatigue loads and lower energy yield. In dynamic stall, separation first develops from the trailing edge up the leading edge. Eventually the shear layer rolls up...
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Copernicus Publications
2020-06-01
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| Series: | Wind Energy Science |
| Online Access: | https://wes.copernicus.org/articles/5/819/2020/wes-5-819-2020.pdf |
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doaj-6545632183634041921e04ba1aea287a2020-11-25T03:31:52ZengCopernicus PublicationsWind Energy Science2366-74432366-74512020-06-01581983810.5194/wes-5-819-2020Cartographing dynamic stall with machine learningM. Lennie0J. Steenbuck1B. R. Noack2C. O. Paschereit3Technische Universität Berlin, Institut für Strömungsmechanik und Technische Akustik, Berlin, GermanyTechnische Universität Berlin, Institut für Strömungsmechanik und Technische Akustik, Berlin, GermanyLIMSI, CNRS, Université Paris-Saclay, Bât 507, rue du Belvédère, Campus Universitaire, 91403 Orsay, FranceTechnische Universität Berlin, Institut für Strömungsmechanik und Technische Akustik, Berlin, Germany<p>Once stall has set in, lift collapses, drag increases and then both of these forces will fluctuate strongly. The result is higher fatigue loads and lower energy yield. In dynamic stall, separation first develops from the trailing edge up the leading edge. Eventually the shear layer rolls up, and then a coherent vortex forms and then sheds downstream with its low-pressure core causing a lift overshoot and moment drop. When 50<span class="inline-formula">+</span> experimental cycles of lift or pressure values are averaged, this process appears clear and coherent in flow visualizations. Unfortunately, stall is not one clean process but a broad collection of processes. This means that the analysis of separated flows should be able to detect outliers and analyze cycle-to-cycle variations. Modern data science and machine learning can be used to treat separated flows. In this study, a clustering method based on dynamic time warping is used to find different shedding behaviors. This method captures the fact that secondary and tertiary vorticity vary strongly, and in static stall with surging flow the flow can occasionally reattach. A convolutional neural network was used to extract dynamic stall vorticity convection speeds and phases from pressure data. Finally, bootstrapping was used to provide best practices regarding the number of experimental repetitions required to ensure experimental convergence.</p>https://wes.copernicus.org/articles/5/819/2020/wes-5-819-2020.pdf |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
M. Lennie J. Steenbuck B. R. Noack C. O. Paschereit |
| spellingShingle |
M. Lennie J. Steenbuck B. R. Noack C. O. Paschereit Cartographing dynamic stall with machine learning Wind Energy Science |
| author_facet |
M. Lennie J. Steenbuck B. R. Noack C. O. Paschereit |
| author_sort |
M. Lennie |
| title |
Cartographing dynamic stall with machine learning |
| title_short |
Cartographing dynamic stall with machine learning |
| title_full |
Cartographing dynamic stall with machine learning |
| title_fullStr |
Cartographing dynamic stall with machine learning |
| title_full_unstemmed |
Cartographing dynamic stall with machine learning |
| title_sort |
cartographing dynamic stall with machine learning |
| publisher |
Copernicus Publications |
| series |
Wind Energy Science |
| issn |
2366-7443 2366-7451 |
| publishDate |
2020-06-01 |
| description |
<p>Once stall has set in, lift collapses, drag increases and then both of these forces will fluctuate strongly. The result is higher fatigue loads and lower energy yield. In dynamic stall, separation first develops from the trailing edge up the leading edge. Eventually the shear layer rolls up, and then a coherent vortex forms and then sheds downstream with its low-pressure core causing a lift overshoot and moment drop. When 50<span class="inline-formula">+</span> experimental cycles of lift or pressure values are averaged, this process appears clear and coherent in flow visualizations. Unfortunately, stall is not one clean process but a broad collection of processes.
This means that the analysis of separated flows should be able to detect outliers and analyze cycle-to-cycle variations. Modern data science and machine learning can be used to treat separated flows. In this study, a clustering method based on dynamic time warping is used to find different shedding behaviors. This method captures the fact that secondary and tertiary vorticity vary strongly, and in static stall with surging flow the flow can occasionally reattach. A convolutional neural network was used to extract dynamic stall vorticity convection speeds and phases from pressure data. Finally, bootstrapping was used to provide best practices regarding the number of experimental repetitions required to ensure experimental convergence.</p> |
| url |
https://wes.copernicus.org/articles/5/819/2020/wes-5-819-2020.pdf |
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