Abstract
This work presents a new measurement technique with potential to remotely measure turbulence processes based on their linkages with the dynamicwater surface. Previouswork has demonstrated these linkages, but accurate 3D measurement of turbulence-generated rough water surfaces is problematic. Microsoft Kinect sensors have previously been used for measuring gravity waves in coloured (opaque) water. Here the sensor is applied to clear water surfaces, and data is validated against a conductance-based wave probe. These data show that the Kinect sensor can characterise relatively large gravity waves in clear water via the principle of refraction. The same principle is able to capture the dominant components of turbulence-generated water surfaces, though discrete features can be ambiguous. It is postulated that a flat bed would result in an unambiguous measurement. Application of this technique to turbulent flows could lead to new applications in flood studies, river monitoring, and sewer flow measurement.
Original language | English |
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Title of host publication | Sustainable Hydraulics in the Era of Global Change |
Subtitle of host publication | Proceedings of the 4th European Congress of the International Association of Hydroenvironment engineering and Research, IAHR 2016 |
Editors | Sebastien Erpicum, Benjamin Dewals, Pierre Archambeau, Michel Pirotton |
Publisher | CRC Press/Balkema |
Pages | 186-192 |
Number of pages | 7 |
Edition | 1 |
ISBN (Electronic) | 9781315375069 |
ISBN (Print) | 9781138029774 |
DOIs | |
Publication status | Published - 7 Jul 2016 |
Externally published | Yes |
Event | 4th European Congress of the International Association of Hydroenvironment engineering and Research - Liege, Belgium Duration: 27 Jul 2016 → 29 Jul 2016 http://www.iahr2016.ulg.ac.be/ |
Conference
Conference | 4th European Congress of the International Association of Hydroenvironment engineering and Research |
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Abbreviated title | IAHR 2016 |
Country/Territory | Belgium |
City | Liege |
Period | 27/07/16 → 29/07/16 |
Internet address |
Bibliographical note
This research has been supported by the EPSRC Pennine Water Group Platform Grant (EP/I029346/1) and The University of Sheffield’s Early Career Researcher Scheme.Publisher Copyright:
© 2016 Taylor & Francis Group, London.
ASJC Scopus subject areas
- Ecology
- Environmental Engineering