The aim of this study was to analyze the effect of depth on the hydrodynamic drag coefficient during the passive underwater gliding after the starts and turns. The swimmer hydrodynamics performance was studied by the application of computational fluid dynamics (CFD) method. The steady-state CFD simulations were performed by the application of k - omega turbulent model and volume of fluid method to obtain two-phase flow around a three-dimensional swimmer model when gliding near water surface and at different depths from the water surface. The simulations were conducted for four different swimming pool size, each with different depth, i.e., 1.0, 1.5, 2.0 and 3.0 m for three different velocities, i.e., 1.5, 2.0 and 2.5 m/s, with swimmer gliding at different depths with intervals of 0.25 m, each starting from the water surface, respectively. The numerical results of pressure drag and total coefficients at individual average race velocities were obtained. The results showed that the drag coefficient decreased as depth increased, with a trend toward reduced fluctuation after 0.5m depth from the water surface. The selection of the appropriate depth during the gliding phase should be a main concern of swimmers and coaches.
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机译:这项研究的目的是分析启动和转弯后深度对被动水下滑行过程中水动力阻力系数的影响。通过计算流体动力学(CFD)方法研究了游泳者的流体力学性能。通过应用k-ω湍流模型和流体体积法进行稳态CFD仿真,以在靠近水面和距水面不同深度的情况下在三维游泳模型周围获得两相流。针对四个不同的游泳池大小进行了模拟,每个游泳池都有不同的深度,即三个不同的速度(即1.5、2.0和2.5 m / s)的深度分别为1.0、1.5、2.0和3.0 m,游泳者在间隔不同的深度滑行0.25 m,分别从水面开始。获得了在单个平均种族速度下的压力阻力和总系数的数值结果。结果表明,阻力系数随着深度的增加而减小,在距水面0.5m处具有减小的波动趋势。滑行阶段选择合适的深度应该是游泳者和教练员的主要考虑因素。
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