Individual aerodynamic and physiological data are critical to optimise cycling time trial performance: one size does not fit all

Cycling time trials are characterised by riders adopting positions to lessen the impact of aerodynamic drag. Aerodynamic positions likely impact the power a rider is able to produce due to changes in oxygen consumption, blood flow, muscle activation and economy. Therefore, the gain from optimising a...

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Bibliographic Details
Published inSports engineering Vol. 27; no. 1
Main Authors Faulkner, Steve H., Jobling, Philippa, Griggs, Katy E., Siegkas, Petros
Format Journal Article
LanguageEnglish
Published London Springer London 01.06.2024
Springer Nature B.V
Subjects
Aerodynamic drag
Biomedical Engineering and Bioengineering
Blood flow
Consumption
Cycles
Drag coefficients
Energy costs
Engineering
Engineering Design
Materials Science
Measuring instruments
Optimization
Oxygen consumption
Physiology
Rehabilitation Medicine
Research Paper
Sports Medicine
Theoretical and Applied Mechanics
Modelling
Endurance
Performance
Metabolism
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Summary:Cycling time trials are characterised by riders adopting positions to lessen the impact of aerodynamic drag. Aerodynamic positions likely impact the power a rider is able to produce due to changes in oxygen consumption, blood flow, muscle activation and economy. Therefore, the gain from optimising aerodynamics must outweigh the potential physiological cost. The aim was to establish the relationship between energy expenditure and aerodynamic drag, with a secondary aim to determine the reliability of a commercially available handlebar mounted aero device for measuring aerodynamic drag. Nine trained male cyclists volunteered for the study. They completed 4 × 3200 m on an outdoor velodrome where stack height was adjusted in 1 cm integers. The drag coefficient ( C d A ), oxygen consumption and aerodynamic-physiological economy (APE) were determined at each stack height, with data used to model 40 km TT performance. Small to moderate effect sizes (ES) in response to stack height change were found for C d A , APE and energy cost. The change in TT time was correlated to ∆aerodynamic drag and ∆APE. Meaningful impacts of change in stack height on C d A , APE, energy cost and predicted TT performance, are apparent with highly individualised responses to positional changes.
ISSN:1369-7072
1460-2687
DOI:10.1007/s12283-023-00446-0