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Journal of Sports Sciences Volume 25, 2007 - Issue 13
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Paper

Optimization of oar blade design for improved performance in rowing

Nicholas Caplan School of Psychology and Sport Sciences, Northumbria University, Newcastle upon TyneCorrespondence[email protected]
&
Trevor N. Gardner Biomechanics Research Group, School of Sport and Exercise Sciences, University of Birmingham, Birmingham, UK
Pages 1471-1478 | Accepted 06 Jan 2007, Published online: 21 Sep 2007

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Dušan Perić, Nebojša Ilić & Zlatko Ahmetovićvić. (2019) Kinematic and dynamic stroke variables of elite and sub-elite rowers. International Journal of Performance Analysis in Sport 19:1, pages 65-75.
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Mathijs Hofmijster, Jos De Koning & A.J. Van Soest. (2010) Estimation of the energy loss at the blades in rowing: Common assumptions revisited. Journal of Sports Sciences 28:10, pages 1093-1102.
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Joachim von Zitzewitz, Peter Wolf, Vladimir Novaković, Mathias Wellner, Georg Rauter, Andreas Brunschweiler & Robert Riener. (2008) Real‐time rowing simulator with multimodal feedback. Sports Technology 1:6, pages 257-266.
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Ricardo Cardoso, Pedro Fonseca, Márcio Goethel, JA Abraldes, Beatriz B. Gomes, João Paulo Vilas-Boas & Ricardo J. Fernandes. Effect of Randall foils on the rowing propulsive cycle. Sports Biomechanics 0:0, pages 1-10.
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Articles from other publishers (14)

Ricardo Cardoso, Manoel Rios, Diogo Carvalho, Ana Sofia Monteiro, Susana Soares, J. Arturo Abraldes, Beatriz B. Gomes, João Paulo Vilas-Boas & Ricardo J. Fernandes. (2022) Mechanics and Energetic Analysis of Rowing with Big Blades with Randall Foils. International Journal of Sports Medicine 44:14, pages 1043-1048.
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Ab Aziz Mohd Yusof, Hazim Sharudin, Wan Muhammad Syahmi Wan Fauzi & Muhamad Noor Harun. 2023. Innovation and Technology in Sports. Innovation and Technology in Sports 1 9 .
Ricardo Cardoso, Márcio Goethel, Pedro Fonseca, Beatriz Gomes, João Paulo Vilas-Boas & Ricardo J. Fernandes. 2023. Proceedings of the 10th Congress of the Portuguese Society of Biomechanics. Proceedings of the 10th Congress of the Portuguese Society of Biomechanics 589 593 .
Ab Aziz Mohd Yusof, Muhamad Noor Harun, Fakhrizal Azmi Nasruddin & Ardiyansyah Syahrom. (2020) Rowing Biomechanics, Physiology and Hydrodynamic: A Systematic Review. International Journal of Sports Medicine 43:07, pages 577-585.
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Yoann Robert, Alban Leroyer, Sophie Barré, Patrick Queutey & Michel Visonneau. (2018) Validation of CFD simulations of the flow around a full-scale rowing blade with realistic kinematics. Journal of Marine Science and Technology 24:4, pages 1105-1118.
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E. J. Grift, N. B. Vijayaragavan, M. J. Tummers & J. Westerweel. (2019) Drag force on an accelerating submerged plate. Journal of Fluid Mechanics 866, pages 369-398.
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A. M. Y. Aziz, M. N. Harun, Ardiyansyah Syahrom & A. H. Omar. Analysis of hydrodynamic force acting on commercialized rowing blades using computational fluid dynamics. Analysis of hydrodynamic force acting on commercialized rowing blades using computational fluid dynamics.
Marin Chirazi, Emil Budescu & Eugen Merticaru. (2014) Consideration Regarding the Inverse Kinematics of a Rowing Skiff under the Action of the Oars Movement. Applied Mechanics and Materials 658, pages 29-34.
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Dongyan Zhang & Weitao Zheng. (2011) International Development of the Research on the Hydrodynamic Performance of Rowing. International Development of the Research on the Hydrodynamic Performance of Rowing.
A. Sliasas & S. Tullis. (2010) A hydrodynamics-based model of a rowing stroke simulating effects of drag and lift on oar blade efficiency for various cant angles. Procedia Engineering 2:2, pages 2857-2862.
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A Sliasas & S Tullis. (2010) The dynamic flow behaviour of an oar blade in motion using a hydrodynamics-based shell-velocity-coupled model of a rowing stroke. Proceedings of the Institution of Mechanical Engineers, Part P: Journal of Sports Engineering and Technology 224:1, pages 9-24.
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N Caplan, A Coppel & T Gardner. (2009) A review of propulsive mechanisms in rowing. Proceedings of the Institution of Mechanical Engineers, Part P: Journal of Sports Engineering and Technology 224:1, pages 1-8.
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A Coppel, T N Gardner, N Caplan & D M Hargreaves. (2009) Simulating the fluid dynamic behaviour of oar blades in competition rowing. Proceedings of the Institution of Mechanical Engineers, Part P: Journal of Sports Engineering and Technology 224:1, pages 25-35.
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Andrew Sliasas & Stephen Tullis. (2009) Numerical modelling of rowing blade hydrodynamics. Sports Engineering 12:1, pages 31-40.
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