Demonstration and uncertainty analysis of synchronised scanning lidar measurements of 2-D velocity fields in a boundary-layer wind tunnel
This paper combines the research methodologies of scaled wind turbine model experiments in wind tunnels with short-range WindScanner lidar measurement technology. The wind tunnel at the Politecnico di Milano was equipped with three wind turbine models and two short-range WindScanner lidars to de...
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Copernicus Publications
2017-06-01
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| Series: | Wind Energy Science |
| Online Access: | https://www.wind-energ-sci.net/2/329/2017/wes-2-329-2017.pdf |
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doaj-c7332761c9754df5b346aee06ad61c4e2020-11-24T22:46:43ZengCopernicus PublicationsWind Energy Science2366-74432366-74512017-06-01232934110.5194/wes-2-329-2017Demonstration and uncertainty analysis of synchronised scanning lidar measurements of 2-D velocity fields in a boundary-layer wind tunnelM. F. van Dooren0F. Campagnolo1M. Sjöholm2N. Angelou3T. Mikkelsen4M. Kühn5ForWind, University of Oldenburg, Institute of Physics, Oldenburg, GermanyWind Energy Institute, Technical University of Munich, Garching, GermanyDepartment of Wind Energy, Technical University of Denmark, Roskilde, DenmarkDepartment of Wind Energy, Technical University of Denmark, Roskilde, DenmarkDepartment of Wind Energy, Technical University of Denmark, Roskilde, DenmarkForWind, University of Oldenburg, Institute of Physics, Oldenburg, GermanyThis paper combines the research methodologies of scaled wind turbine model experiments in wind tunnels with short-range WindScanner lidar measurement technology. The wind tunnel at the Politecnico di Milano was equipped with three wind turbine models and two short-range WindScanner lidars to demonstrate the benefits of synchronised scanning lidars in such experimental surroundings for the first time. The dual-lidar system can provide fully synchronised trajectory scans with sampling timescales ranging from seconds to minutes. First, staring mode measurements were compared to hot-wire probe measurements commonly used in wind tunnels. This yielded goodness of fit coefficients of 0.969 and 0.902 for the 1 Hz averaged <i>u</i> and <i>v</i> components of the wind speed, respectively, validating the 2-D measurement capability of the lidar scanners. Subsequently, the measurement of wake profiles on a line as well as wake area scans were executed to illustrate the applicability of lidar scanning to the measurement of small-scale wind flow effects. An extensive uncertainty analysis was executed to assess the accuracy of the method. The downsides of lidar with respect to the hot-wire probes are the larger measurement probe volume, which compromises the ability to measure turbulence, and the possible loss of a small part of the measurements due to hard target beam reflection. In contrast, the benefits are the high flexibility in conducting both point measurements and area scanning and the fact that remote sensing techniques do not disturb the flow during measuring. The research campaign revealed a high potential for using short-range synchronised scanning lidars to measure the flow around wind turbines in a wind tunnel and increased the knowledge about the corresponding uncertainties.https://www.wind-energ-sci.net/2/329/2017/wes-2-329-2017.pdf |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
M. F. van Dooren F. Campagnolo M. Sjöholm N. Angelou T. Mikkelsen M. Kühn |
| spellingShingle |
M. F. van Dooren F. Campagnolo M. Sjöholm N. Angelou T. Mikkelsen M. Kühn Demonstration and uncertainty analysis of synchronised scanning lidar measurements of 2-D velocity fields in a boundary-layer wind tunnel Wind Energy Science |
| author_facet |
M. F. van Dooren F. Campagnolo M. Sjöholm N. Angelou T. Mikkelsen M. Kühn |
| author_sort |
M. F. van Dooren |
| title |
Demonstration and uncertainty analysis of synchronised scanning lidar measurements of 2-D velocity fields in a boundary-layer wind tunnel |
| title_short |
Demonstration and uncertainty analysis of synchronised scanning lidar measurements of 2-D velocity fields in a boundary-layer wind tunnel |
| title_full |
Demonstration and uncertainty analysis of synchronised scanning lidar measurements of 2-D velocity fields in a boundary-layer wind tunnel |
| title_fullStr |
Demonstration and uncertainty analysis of synchronised scanning lidar measurements of 2-D velocity fields in a boundary-layer wind tunnel |
| title_full_unstemmed |
Demonstration and uncertainty analysis of synchronised scanning lidar measurements of 2-D velocity fields in a boundary-layer wind tunnel |
| title_sort |
demonstration and uncertainty analysis of synchronised scanning lidar measurements of 2-d velocity fields in a boundary-layer wind tunnel |
| publisher |
Copernicus Publications |
| series |
Wind Energy Science |
| issn |
2366-7443 2366-7451 |
| publishDate |
2017-06-01 |
| description |
This paper combines the research methodologies of scaled wind
turbine model experiments in wind tunnels with short-range WindScanner lidar
measurement technology. The wind tunnel at the Politecnico di Milano was
equipped with three wind turbine models and two short-range WindScanner
lidars to demonstrate the benefits of synchronised scanning lidars in such
experimental surroundings for the first time. The dual-lidar system can
provide fully synchronised trajectory scans with sampling timescales ranging
from seconds to minutes. First, staring mode measurements were compared to
hot-wire probe measurements commonly used in wind tunnels. This yielded
goodness of fit coefficients of 0.969 and 0.902 for the 1 Hz averaged <i>u</i>
and <i>v</i> components of the wind speed, respectively, validating the 2-D
measurement capability of the lidar scanners. Subsequently, the measurement
of wake profiles on a line as well as wake area scans were executed to
illustrate the applicability of lidar scanning to the measurement of small-scale wind flow effects. An extensive uncertainty analysis was executed to
assess the accuracy of the method. The downsides of lidar with respect to the
hot-wire probes are the larger measurement probe volume, which compromises
the ability to measure turbulence, and the possible loss of a small part of
the measurements due to hard target beam reflection. In contrast, the
benefits are the high flexibility in conducting both point measurements and
area scanning and the fact that remote sensing techniques do not disturb the
flow during measuring. The research campaign revealed a high potential for
using short-range synchronised scanning lidars to measure the flow around
wind turbines in a wind tunnel and increased the knowledge about the
corresponding uncertainties. |
| url |
https://www.wind-energ-sci.net/2/329/2017/wes-2-329-2017.pdf |
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