Optimization of ski jumping in-run posture using computational fluid dynamics

Optimization of ski jumping in-run posture using computational fluid dynamics

Abstract While aerodynamic optimization during ski jumping flight phases is well-studied, critical knowledge gaps persist regarding posture-fluid interactions in the in-run phase – particularly the dominance of drag dynamics over lift enhancement for speed maximization. This study establishes an ath...

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Bibliographic Details
Main Authors: Wenhan Liu, Feixiang Lu, Xiang Suo, Weidi Tang
Format: Article
Language:English
Published: Nature Portfolio 2025-07-01
Series:Scientific Reports
Subjects:
Computational fluid dynamics
Ski jumping
In-run stage
Aerodynamic characteristics
Posture optimization
Online Access:https://doi.org/10.1038/s41598-025-00710-2
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Summary:Abstract While aerodynamic optimization during ski jumping flight phases is well-studied, critical knowledge gaps persist regarding posture-fluid interactions in the in-run phase – particularly the dominance of drag dynamics over lift enhancement for speed maximization. This study establishes an athlete-specific 3D model to investigate posture-dependent resistance through high-resolution CFD simulations. Systematically analyzing four key posture parameters – torso attack angle (α), thigh attack angle (β), ankle joint angle (γ), and hip abduction angle (ε) – reveals α as the governing factor influencing aerodynamic resistance during acceleration. The optimized configuration ( $$\:\alpha\:\in\:\left[0^\circ\:,2^\circ\:\right]$$ , $$\:\beta\:\in\:\left[20^\circ\:,22^\circ\:\right]$$ , $$\:\gamma\:\in\:\left[43^\circ\:,45^\circ\:\right]$$ , and $$\:\epsilon\:\in\:\left[-2^\circ\:,0^\circ\:\right]$$ ) reduces cumulative air resistance by approximately 5% compared to conventional postures, demonstrating that marginal angular adjustments in torso positioning significantly outweigh other joints’ contributions to drag reduction. Contrary to flight-phase strategies emphasizing lift generation, the results establish drag minimization as the primary in-run optimization objective. These findings provide evidence-based posture guidelines for athletes while advancing a paradigm shift from empirical to physics-driven training methodologies – particularly through computational fluid dynamics with practical sports biomechanics. The work positions CFD as an indispensable tool for quantifying millimeter-scale posture adaptations in winter sports equipment-athlete system optimization.
ISSN:2045-2322

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