Field Research and Numerical CFD Analysis of Humpback Whale-Inspired Shortboard Fins

Compared to other Olympic sports, little research exists on competitive shortboard surfing—especially research comparing field and numerical data. In this paper, GPS sensors with 9-axis motion sensors were used to collect data on nearly 2000 surfed waves. Data were collected from four surfers of dif...

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Published in:	The 13th Conference of the International Sports Engineering Association
Main Authors:	Shormann, Panhuis, Oggiano
Format:	Text
Language:	English
Published:	Multidisciplinary Digital Publishing Institute 2020
Subjects:	shortboard fin performance STAR-CCM+ CFD GPS tracking humpback whale tubercled leading edge cutback maneuver passive flow control biomimetics Humpback Whale
Online Access:	https://doi.org/10.3390/proceedings2020049158

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spelling	ftmdpi:oai:mdpi.com:/2504-3900/49/1/158/ 2023-08-20T04:07:05+02:00 Field Research and Numerical CFD Analysis of Humpback Whale-Inspired Shortboard Fins Shormann Panhuis Oggiano 2020-06-15 application/pdf https://doi.org/10.3390/proceedings2020049158 EN eng Multidisciplinary Digital Publishing Institute https://dx.doi.org/10.3390/proceedings2020049158 https://creativecommons.org/licenses/by/4.0/ Proceedings; Volume 49; Issue 1; Pages: 158 shortboard fin performance STAR-CCM+ CFD GPS tracking humpback whale tubercled leading edge cutback maneuver passive flow control biomimetics Text 2020 ftmdpi https://doi.org/10.3390/proceedings2020049158 2023-07-31T23:38:16Z Compared to other Olympic sports, little research exists on competitive shortboard surfing—especially research comparing field and numerical data. In this paper, GPS sensors with 9-axis motion sensors were used to collect data on nearly 2000 surfed waves. Data were collected from four surfers of differing skill levels, ranging from intermediate/advanced (Level 6) to top-ranked professional (Level 9). The results revealed a positive correlation between surfer skill level and roll/pitch/yaw rates during a cutback. Some surfers used two different fin types: a standard commercial fin (C), and a 3D-printed, humpback whale-inspired fin (RW). Statistically significant cutback performance improvements were seen when surfers used the RW fin. Because of the skill level differences suggested by the field data, dynamic computational fluid dynamics (CFD) analysis was performed to simulate cutback maneuvers at three different rotation rates (roll/pitch/yaw). Sustained resultant forces relative to the rider direction were lower for RW fins during the turn, suggesting a less-skilled surfer could generate faster and more powerful turns using RW fins. Field results also confirmed that a skill Level 8 surfer performed closer to skill Level 9 when using RW fins, but not control fins. Surfers experienced more stability using RW fins, and CFD results confirmed RW’s ability to dampen the effects of turbulent flow. Text Humpback Whale MDPI Open Access Publishing The 13th Conference of the International Sports Engineering Association 158
institution	Open Polar
collection	MDPI Open Access Publishing
op_collection_id	ftmdpi
language	English
topic	shortboard fin performance STAR-CCM+ CFD GPS tracking humpback whale tubercled leading edge cutback maneuver passive flow control biomimetics
spellingShingle	shortboard fin performance STAR-CCM+ CFD GPS tracking humpback whale tubercled leading edge cutback maneuver passive flow control biomimetics Shormann Panhuis Oggiano Field Research and Numerical CFD Analysis of Humpback Whale-Inspired Shortboard Fins
topic_facet	shortboard fin performance STAR-CCM+ CFD GPS tracking humpback whale tubercled leading edge cutback maneuver passive flow control biomimetics
description	Compared to other Olympic sports, little research exists on competitive shortboard surfing—especially research comparing field and numerical data. In this paper, GPS sensors with 9-axis motion sensors were used to collect data on nearly 2000 surfed waves. Data were collected from four surfers of differing skill levels, ranging from intermediate/advanced (Level 6) to top-ranked professional (Level 9). The results revealed a positive correlation between surfer skill level and roll/pitch/yaw rates during a cutback. Some surfers used two different fin types: a standard commercial fin (C), and a 3D-printed, humpback whale-inspired fin (RW). Statistically significant cutback performance improvements were seen when surfers used the RW fin. Because of the skill level differences suggested by the field data, dynamic computational fluid dynamics (CFD) analysis was performed to simulate cutback maneuvers at three different rotation rates (roll/pitch/yaw). Sustained resultant forces relative to the rider direction were lower for RW fins during the turn, suggesting a less-skilled surfer could generate faster and more powerful turns using RW fins. Field results also confirmed that a skill Level 8 surfer performed closer to skill Level 9 when using RW fins, but not control fins. Surfers experienced more stability using RW fins, and CFD results confirmed RW’s ability to dampen the effects of turbulent flow.
format	Text
author	Shormann Panhuis Oggiano
author_facet	Shormann Panhuis Oggiano
author_sort	Shormann
title	Field Research and Numerical CFD Analysis of Humpback Whale-Inspired Shortboard Fins
title_short	Field Research and Numerical CFD Analysis of Humpback Whale-Inspired Shortboard Fins
title_full	Field Research and Numerical CFD Analysis of Humpback Whale-Inspired Shortboard Fins
title_fullStr	Field Research and Numerical CFD Analysis of Humpback Whale-Inspired Shortboard Fins
title_full_unstemmed	Field Research and Numerical CFD Analysis of Humpback Whale-Inspired Shortboard Fins
title_sort	field research and numerical cfd analysis of humpback whale-inspired shortboard fins
publisher	Multidisciplinary Digital Publishing Institute
publishDate	2020
url	https://doi.org/10.3390/proceedings2020049158
genre	Humpback Whale
genre_facet	Humpback Whale
op_source	Proceedings; Volume 49; Issue 1; Pages: 158
op_relation	https://dx.doi.org/10.3390/proceedings2020049158
op_rights	https://creativecommons.org/licenses/by/4.0/
op_doi	https://doi.org/10.3390/proceedings2020049158
container_title	The 13th Conference of the International Sports Engineering Association
container_start_page	158
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Field Research and Numerical CFD Analysis of Humpback Whale-Inspired Shortboard Fins

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