Abstract
A floater serve in volleyball is a technique of serving a non-rotating or low-rotating ball, which is difficult to return because the flight path of the ball changes irregularly. On the other hand, the randomness of the trajectory makes it difficult for the ball to fall on the target. Players are required to serve taking into account the variability of the trajectory. In previous studies using wind tunnels, it was shown that aerodynamic characteristics such as drag force and lateral force applied to the ball vary depending on the type of ball and the orientation of the panel. Therefore, in order to control the flight trajectory, it is necessary to understand the aerodynamic characteristics of each ball. Since the velocity of the ball and the fluid force applied to the ball changes during flight, it is important to measure not only the fluid force at a steady state in the wind tunnel but also the actual flight distance of the ball. In this study, to provide valuable information for precise control of floater serves, we measured the drag force applied to the ball in a wind tunnel and the flight distance of the ball using an ejection machine, and clarified the effects of the type of ball and the panel face. In the drag force measurement, the drag force on three types of balls, V200W, MVA200, and FLISTATEC, was measured in the wind speed range of 4 m/s to 30 m/s. In the ejection measurement, the ball flight distances were measured while changing the orientation of the panel using an ejection machine. Basically, the FLISTATEC, MVA200, and V200W, in that order, were more likely to increase the distance and the variability, but it was shown that the drop point could be adjusted slightly by selecting the panel face. This result was also obtained when a human player actually served the ball, indicating the tactical importance of the player consciously controlling the direction of the panel. The tactical importance of the player’s conscious control of the direction of the panel was demonstrated. We also proposed receiver positions that would be effective based on the characteristics of each ball.
Highlights
Volleyball is one of the most popular sports in the world
The relationship between the flow velocity and the drag coefficient was measured while changing the direction of the panel volleyball d = 0.21 [m], U is the velocity of wind, ν is the kinematic viscosity of the air, Dis the drag applied on the ball, ρ is the density of the air, and A is the cross-sectional area of the volleyball (A = πd2 /4 ≈ 0.0346 [m2 ])
Drag force measurements using a wind tunnel and drop point measurements using an ejection machine were performed on three types of balls, MVA200, V200W, and FLISTATEC, to clarify the effects of ball type and panel surface orientation on the distance and variability of serve balls
Summary
Volleyball is one of the most popular sports in the world. The key factors to victory are the skills and strategies of blocking, attacking, serving and receiving. Measurements using a wind tunnel showed that the drag coefficient, the magnitude of lateral force, and the speed range at which drag crisis occurs differs depending on the type of ball and the panel surface. This indicates that the type of ball used in a game influences the tactics of the players. In order to clarify more directly the effects of the ball type and panel surface on the actual flight of the serve, we measured the drag coefficient using a wind tunnel and the flight distance using an ejection machine for three types of balls used in competitions: MVA200, V200W, and FLISTATEC.
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