The doi above is for this specific version of this dataset, which is currently the latest. Newer versions may be published in the future. For a link that will always point to the latest version, please use
doi: 10.4121/14828544

Alexander Spoelstra; Andrea Sciacchitano; Scarano, F. (Fulvio); Mahalingesh, Nikhil (2021): Data underlying the research of: On-site drag analysis of drafting cyclists. Version 1. 4TU.ResearchData. dataset. https://doi.org/10.4121/14828544.v1

Dataset

• Aerospace Engineering
• Human Movement and Sports Science

Control volume approach, Cycling aerodynamics, Drafting, Helium filled soap bubbles, HFSB, particle image velocimetry (PIV), PIV

CC BY 4.0

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by Alexander Spoelstra , Andrea Sciacchitano , F. (Fulvio) Scarano , Nikhil Mahalingesh

The aerodynamic drag of two cyclists in peloton formation is investigated at different lateral and longitudinal separations. A Ring of Fire (RoF) experiment is conducted at the Tom Dumoulin bike park of Sittard-Geleen in the Netherlands. The method is based on stereoscopic Particle Image Velocimetry (Stereo-PIV) measurements followed by invoking the conservation of momentum expressed in a control volume to evaluate the drag force of the cyclists. The cyclists perform a series of individual tests as well as 4 different drafting tests, varying their order in the group. All tests were performed at nominal riding speed of 45 km/h; the longitudinal and lateral displacements of the drafters varied respectively between 0.32 m and 0.85 m and between ±0.20 m among different runs. The results from the RoF measurements show the flow field interactions between the two drafting cyclists as well as the wake of the second cyclist. It is observed that the amount of drag reduction for the trailing rider is mainly caused by the change in inflow conditions. The drag reductions of the trailing cyclist are in the range from 27% to 66% depending on the longitudinal and lateral separation from the leading rider. The aerodynamic advantage of the drafting rider decreases with increasing lateral and longitudinal separation between riders, with the lateral separation found to be more relevant. Furthermore, based on the analysis of the individual wakes, the drag reductions found by the RoF, and the drag reduction measured by Barry et al. (2014), a model is introduced that predicts the aerodynamic gain of the trailing rider based on his or her position with respect to the leading rider. Validation of the model with data from literature shows that in the near wake the model gives a realistic prediction of the drag reduction, with an overestimation of the drag reduction when the longitudinal distance is between 0.1 m and 0.3m.

• 2021-06-24 first online, published, posted

4TU.ResearchData

matlab .fig

• Enabling on-site sport aerodynamics with "the ring of fire" (grant code 15583) [more info...] Dutch Research Council

TU Delft, Faculty of Aerospace Engineering, Department of Aerodynamics, Wind Energy & Propulsion