In downhill alpine skiing, racers often exceed speeds of 120 km/h, with air resistance substantially affecting the overall race times. To date, studies on air resistance in alpine skiing have used wind tunnels and actual skiers to examine the relationship between the gliding posture and magnitude of drag, as well as for the design of skiing equipment. However, these studies have not revealed the flow velocity distribution and vortex structure around the skier. In the present study, we used computational fluid dynamics with the lattice Boltzmann method to derive the relationship between flow velocity in the full tuck position (the downhill racer's speed) and total drag. Furthermore, we visualized the flow around the downhill racer and examined its vortex structure. The results show that the total drag force in the downhill racer model is 27.0 N at a flow velocity of 15 m/s, increasing to 185.8 N at 40 m/s. Moreover, the visualization of the flow field indicates that the primary drag locations at a flow velocity of 40 m/s are the head, upper arms, lower legs, and thighs (including the buttocks).
展开▼
机译:在下坡高山滑雪中,赛车手经常超过120 km / h的速度,具有大量影响整体竞赛时间的空气阻力。迄今为止,高山滑雪中耐火性的研究已经使用了风隧道和实际的滑雪者来检查滑动姿势和拖曳幅度之间的关系,以及滑雪设备的设计。然而,这些研究没有揭示滑雪者周围的流速分布和涡旋结构。在本研究中,我们使用与晶格Boltzmann方法的计算流体动力学来导出完全折叠位置(下坡赛车速度)和总阻力之间的流速之间的关系。此外,我们可视化下坡赛车周围的流动,并检查了其涡旋结构。结果表明,下坡赛车模型中的总阻力为27.0 n,流速为15米/秒,增加到40米/秒的185.8 n。此外,流场的可视化指示在40m / s的流速下的主拖曳位置是头部,上臂,下腿和大腿(包括臀部)。
展开▼
