Optimal cycling time trial position models D.M. Fintelman 1, F-X. Li 1, M. Sterling 2 & H. Hemida 2 1: School of Sport and Exercise Sciences, 2: School.

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Optimal cycling time trial position models D.M. Fintelman 1, F-X. Li 1, M. Sterling 2 & H. Hemida 2 1: School of Sport and Exercise Sciences, 2: School of Civil Engineering, University of Birmingham Optimal cycling time trial position models D.M. Fintelman 1, F-X. Li 1, M. Sterling 2 & H. Hemida 2 1: School of Sport and Exercise Sciences, 2: School of Civil Engineering, University of Birmingham References [1] Belluye, N., et al. (2001). Science & Sports, 16: p [2] Chowdhury H., et al. (2012). Sports Eng., 15(2): p [3] Jobson S.A., et al. (2008). Journal of Sports Sciences, 26(12): p Future research Measurement of the air resistance of all participants in a windtunnel and implementing the effect of side wind. Conclusion & recommendations Despite some limitations, the models give valuable information about the optimal TT cycling position at different speeds. Introduction Every cyclist has to overcome air resistance. At cycling speeds of 50 km/h, approximately 90% of the total power is used to overcome air resistance [1]. This resistance is strongly influenced by the torso angle [2] and increases with cycling speed. Therefore, to minimise air resistance, cyclists adopt a time trial (TT) position and lower their torso angle to become more aerodynamic. However, the cyclists’ power output and gross efficiency (GE) drops accordingly [3]. Consequently there should be a trade off between gaining aerodynamics and losing power output. The aim of this study is to predict the optimal torso angle for different speeds by using TT position models. Power Output Model Maximizing the difference between the peak power output and the power losses due to air and rolling resistance. Metabolic Energy Model Minimizing the required cycling energy, based on workload and GE. Optimal position models Method Results Optimal torso angle is dependent on cycling velocity. The Power Output Model curve is shifted to a higher velocity, which could be explained by the different approach of the models. Air resistance outweigh the power losses for velocities above 45km/h. A fully horizontal torso is not optimal. Main input parameters Experimental data of 19 trained competitive TT cyclists (peak power output, GE, frontal area of cyclist) in 4 different torso angles, β: 0, 8, 16 and 24°. Model predictions Based on physics laws, the models predict the optimal torso angle for speeds between km/h. Outside this range the data is extrapolated (shaded area in result Figure). Main assumptions Cycling on flat road, no wind and constant cycling speed. Power Output Model Metabolic Energy Model Cycling speed [km/h] Torso angle [°] Model applications The Metabolic Energy Model could be applied for endurance events, while the Power Output Model is more suitable in sprinting or in variable conditions (wind, undulating course, etc). For speeds < 30 km/h: ride in a more upright position For speeds of km/h in endurance event: decrease the torso angle. In sprinting or in variable conditions: more upright position. For speeds > 40 km/h: decrease the torso angle.