Numerical study of transient aerodynamic forces acting on a ski jumper considering dynamic posture change from takeoff to landing.

IF 2 3区医学 Q3 ENGINEERING, BIOMEDICAL

Sports Biomechanics Pub Date : 2025-03-01 Epub Date: 2022-12-12 DOI:10.1080/14763141.2022.2154256

Keizo Yamamoto, Takahiro Nishino, Rahul Bale, Tokimasa Shimada, Naoto Miyamoto, Makoto Tsubokura

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引用次数: 0

Abstract

This study was designed to develop a computational fluid dynamics (CFD) method for unsteady analysis of a series of ski jump movements with attitude changes, and to analyse the aerodynamic characteristics of an expert jumper over the entire ski jump movement. Two ski jumpers participated in this study. A sensor-based motion capture suit was used to capture the jumper's posture during the actual ski jump. A three-dimensional computer graphics animation was created by superimposing the joint angles obtained from the motion measurements of the 3D shape of the athlete. The unsteady aerodynamic forces acting on the ski jumper, from the takeoff to the landing, were then calculated using CFD. A time-varying spatially uniform flow was specified as the inflow boundary condition of the computational domain. The results indicated that both the lift and drag forces of the expert jumper increase rapidly during the initial flight when the jumper's posture changes drastically. Thereafter, drag force decreased considerably, but the decrease in the lift force was less drastic. Later in the flight phase, the lift force acting on the expert jumper increased, and throughout the flight phase, the lift-drag ratio of the expert jumper remained higher than that of the unskilled jumper.

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考虑到从起飞到着陆的动态姿势变化，对作用在跳台滑雪运动员身上的瞬态空气动力进行数值研究。

本研究旨在开发一种计算流体动力学（CFD）方法，用于对一系列具有姿态变化的跳台滑雪动作进行非稳态分析，并分析一名跳台滑雪高手在整个跳台滑雪动作中的空气动力特性。两名跳台滑雪运动员参与了这项研究。在实际跳台滑雪过程中，使用基于传感器的动作捕捉服捕捉跳台滑雪者的姿态。通过将运动测量获得的关节角度与运动员的三维形状叠加，制作出三维计算机图形动画。然后使用 CFD 计算了跳台滑雪运动员从起跳到着地的不稳定空气动力。时变空间均匀流被指定为计算域的流入边界条件。结果表明，在初始飞行时，当跳伞者的姿势发生急剧变化时，跳伞高手的升力和阻力都会迅速增加。此后，阻力显著减小，但升力的减小幅度较小。在飞行阶段的后期，作用在专业跳远运动员身上的升力有所增加，在整个飞行阶段，专业跳远运动员的升阻比一直高于非专业跳远运动员。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Sports Biomechanics 医学-工程：生物医学

CiteScore

5.70

自引率

9.10%

发文量

135

审稿时长

>12 weeks

期刊介绍： Sports Biomechanics is the Thomson Reuters listed scientific journal of the International Society of Biomechanics in Sports (ISBS). The journal sets out to generate knowledge to improve human performance and reduce the incidence of injury, and to communicate this knowledge to scientists, coaches, clinicians, teachers, and participants. The target performance realms include not only the conventional areas of sports and exercise, but also fundamental motor skills and other highly specialized human movements such as dance (both sport and artistic). Sports Biomechanics is unique in its emphasis on a broad biomechanical spectrum of human performance including, but not limited to, technique, skill acquisition, training, strength and conditioning, exercise, coaching, teaching, equipment, modeling and simulation, measurement, and injury prevention and rehabilitation. As well as maintaining scientific rigour, there is a strong editorial emphasis on ''reader friendliness''. By emphasising the practical implications and applications of research, the journal seeks to benefit practitioners directly. Sports Biomechanics publishes papers in four sections: Original Research, Reviews, Teaching, and Methods and Theoretical Perspectives.