Leading-edge tubercles delay flow separation for a tapered swept-back wing at very low Reynolds number
Flow separation characteristics for two tapered swept-back wings, one with straight leading-edge (LE) and the other with tubercled LE, were investigated in a water tunnel using time-resolved particle image velocimetry (TR-PIV) technique. The two wings were based on the SD7032 aerofoil profile, with...
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sg-ntu-dr.10356-1430722023-03-04T17:22:01Z Leading-edge tubercles delay flow separation for a tapered swept-back wing at very low Reynolds number Wei, Zhaoyu New, Tze How Lian, Lian Zhang, Yanni School of Mechanical and Aerospace Engineering Engineering::Mechanical engineering SD7032 Leading-edge Tubercles Flow separation characteristics for two tapered swept-back wings, one with straight leading-edge (LE) and the other with tubercled LE, were investigated in a water tunnel using time-resolved particle image velocimetry (TR-PIV) technique. The two wings were based on the SD7032 aerofoil profile, with Reynolds number Re = 1.4 × 104, close to the working condition for common underwater gliders. The LE tubercles were designed such that the amplitude decreased linearly from the wing root to wing tip, while retaining constant wavelength. Results indicate that the baseline wing shows significantly separated flow in the outboard region at pitch angle of 10° and 20°, and the flow remains attached in the inboard region due to relatively larger local Reynolds number. Implementation of LE tubercles can mitigate flow separation downstream of both troughs and peaks. At higher pitch angles, the separated flows cover most of the baseline wing surface, whereas flow remains attached downstream most of tubercle peaks. Streamwise aligned counter-rotating vortex pairs (CVPs) formed over the tubercles are significantly tilted and asymmetrical due to the sweep and amplitude difference between the two sides of tubercle. Consequently, weaker vortices in CVPs close to the wing root are rapidly dissipated, allowing the CVPs to evolve into a series of co-rotating vortices (CVs), which exerted significant impact on flow separation characteristics downstream of the tubercles. Nanyang Technological University Accepted version This study was supported by the National Natural Science Foundation of China (grants 11702173 and 41527901). The authors also thank Nanyang Technological University, Singapore, for providing the PIV facilities and water tunnel for the present experiments. 2020-07-28T02:50:40Z 2020-07-28T02:50:40Z 2019 Journal Article Wei, Z., New, T. H., Lian, L., & Zhang, Y. (2019). Leading-edge tubercles delay flow separation for a tapered swept-back wing at very low Reynolds number. Ocean Engineering, 181, 173-184. doi:10.1016/j.oceaneng.2019.04.018 0029-8018 https://hdl.handle.net/10356/143072 10.1016/j.oceaneng.2019.04.018 2-s2.0-85064457908 181 173 184 en Ocean Engineering © 2019 Elsevier Ltd. All rights reserved. This paper was published in Ocean Engineering and is made available with permission of Elsevier Ltd. application/pdf |
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Engineering::Mechanical engineering SD7032 Leading-edge Tubercles Wei, Zhaoyu New, Tze How Lian, Lian Zhang, Yanni Leading-edge tubercles delay flow separation for a tapered swept-back wing at very low Reynolds number |
| description |
Flow separation characteristics for two tapered swept-back wings, one with straight leading-edge (LE) and the other with tubercled LE, were investigated in a water tunnel using time-resolved particle image velocimetry (TR-PIV) technique. The two wings were based on the SD7032 aerofoil profile, with Reynolds number Re = 1.4 × 104, close to the working condition for common underwater gliders. The LE tubercles were designed such that the amplitude decreased linearly from the wing root to wing tip, while retaining constant wavelength. Results indicate that the baseline wing shows significantly separated flow in the outboard region at pitch angle of 10° and 20°, and the flow remains attached in the inboard region due to relatively larger local Reynolds number. Implementation of LE tubercles can mitigate flow separation downstream of both troughs and peaks. At higher pitch angles, the separated flows cover most of the baseline wing surface, whereas flow remains attached downstream most of tubercle peaks. Streamwise aligned counter-rotating vortex pairs (CVPs) formed over the tubercles are significantly tilted and asymmetrical due to the sweep and amplitude difference between the two sides of tubercle. Consequently, weaker vortices in CVPs close to the wing root are rapidly dissipated, allowing the CVPs to evolve into a series of co-rotating vortices (CVs), which exerted significant impact on flow separation characteristics downstream of the tubercles. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Wei, Zhaoyu New, Tze How Lian, Lian Zhang, Yanni |
| format |
Article |
| author |
Wei, Zhaoyu New, Tze How Lian, Lian Zhang, Yanni |
| author_sort |
Wei, Zhaoyu |
| title |
Leading-edge tubercles delay flow separation for a tapered swept-back wing at very low Reynolds number |
| title_short |
Leading-edge tubercles delay flow separation for a tapered swept-back wing at very low Reynolds number |
| title_full |
Leading-edge tubercles delay flow separation for a tapered swept-back wing at very low Reynolds number |
| title_fullStr |
Leading-edge tubercles delay flow separation for a tapered swept-back wing at very low Reynolds number |
| title_full_unstemmed |
Leading-edge tubercles delay flow separation for a tapered swept-back wing at very low Reynolds number |
| title_sort |
leading-edge tubercles delay flow separation for a tapered swept-back wing at very low reynolds number |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/143072 |
| _version_ |
1759854166001319936 |