Biomechanics of the bobsleigh push phase

Marvin Zedler; Bjoern Braunstein; Wolfgang Potthast; Jan-Peter Goldmann

doi:10.1080/02640414.2025.2458983

Biomechanics of the bobsleigh push phase

Marvin Zedler, Bjoern Braunstein, Wolfgang Potthast, Jan-Peter Goldmann

Publication: Contribution to journal › Journal articles › Research › peer-review

Abstract

The purpose of this work was to provide a fundamental, in-depth analysis of kinematics and kinetics of the bobsleigh push phase to establish a basis for performance analysis and enhancement. Fifteen elite male athletes performed maximal effort push starts, while ground reaction forces (GRF) and 3D marker trajectories were simultaneously recorded for ground contacts of different sub-sections of the push phase (start acceleration phase: first and second ground contact after the initial push-off from the start block, acceleration phase: 10 m and high-velocity phase: 30 m). To obtain a comprehensive view of the push phase, whole-body kinematics as well as joint kinetics were analysed and compared across the push phase. The results showed that propulsion during the start acceleration was hip extensor dominant. With increasing running speed, the contribution to propulsion increased at the ankle and decreased at the knee. In contrast to unresisted sprinting, bobsleigh athletes relied more on mechanical energy generation at the hip than at the ankle, especially during start acceleration. These findings should be considered for the strength and conditioning of bobsleigh athletes and further investigated in relation to a suitable performance measure.

Original language	English
Journal	Journal of Sports Sciences
Volume	2015
Pages (from-to)	1-10
Number of pages	10
ISSN	0264-0414
DOIs	https://doi.org/10.1080/02640414.2025.2458983
Publication status	Electronically/ online published ahead of print - 28.01.2025

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10.1080/02640414.2025.2458983

4 Conference contribution - Published abstract for conference with selection process
2 Conference contribution - Other conference contributions
1 Conference contribution - Article for conference

Evaluating performance measures for the bobsleigh push start
Zedler, M., Braunstein, B., Potthast, W. & Goldmann, J-P., 2023, ISBS 2023 Conference Proceedings: 41st Conference of the International Society of Biomechanics in Sports. Milwaukee: International Society of Biomechanics in Sports, Vol. 41. p. 1-4 4 p.
Publication: Chapter in Book/Report/Conference proceeding › Conference contribution - Article for conference › Research › peer-review

Open Access
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Biomechanics of the Bobsleigh Start - The importance of Powerful Hip Extensors and Ankle Plantarflexors
Goldmann, J-P., Zedler, M. & Braunstein, B., 02.02.2022, eProceedings of the International Society of Biomechanics in Sports: ISBS-MidYearSymposium-2022.
Publication: Chapter in Book/Report/Conference proceeding › Conference contribution - Other conference contributions › Research › peer-review
Specific Biomechanical Aspects of the Skeleton Start
Zedler, M., Goldmann, J-P. & Braunstein, B., 02.02.2022, eProceedings of the International Society of Biomechanics in Sports: ISBS-MidYearSymposium-2022.
Publication: Chapter in Book/Report/Conference proceeding › Conference contribution - Other conference contributions › Research › peer-review

1 Not started
1 Active
4 Finished

Collaboration project: Bob- und Schlittenverband für Deutschland (BSD)
Goldmann, J., Braunstein, B., Spiess, R. & Sander, A.
01.06.08 → …
Project: Funded by third parties
Bob- und Schlittenverband für Deutschland (BSD)
Engelmeyer, E.
Project: Funded by third parties
Diagnostic camp: Bob- und Schlittenverband für Deutschland
Goldmann, J., Braunstein, B., Zedler, M., Ratnikov, A., Preece, A., Angermeyer, J., Dannhauer, N. & Spiess, R.
01.06.24 → 08.06.24
Project: Funded by third parties

Bob: Wie Anschieber Fleischhauer seine Start-Qualitäten verbessert
Jan-Peter Goldmann, Marvin Zedler, Abigail Preece, Aleksei Ratnikov & Björn Braunstein
26.12.24
1 item of Media coverage
Press/Media

Citation

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abstract = "The purpose of this work was to provide a fundamental, in-depth analysis of kinematics and kinetics of the bobsleigh push phase to establish a basis for performance analysis and enhancement. Fifteen elite male athletes performed maximal effort push starts, while ground reaction forces (GRF) and 3D marker trajectories were simultaneously recorded for ground contacts of different sub-sections of the push phase (start acceleration phase: first and second ground contact after the initial push-off from the start block, acceleration phase: 10 m and high-velocity phase: 30 m). To obtain a comprehensive view of the push phase, whole-body kinematics as well as joint kinetics were analysed and compared across the push phase. The results showed that propulsion during the start acceleration was hip extensor dominant. With increasing running speed, the contribution to propulsion increased at the ankle and decreased at the knee. In contrast to unresisted sprinting, bobsleigh athletes relied more on mechanical energy generation at the hip than at the ankle, especially during start acceleration. These findings should be considered for the strength and conditioning of bobsleigh athletes and further investigated in relation to a suitable performance measure.",

author = "Marvin Zedler and Bjoern Braunstein and Wolfgang Potthast and Jan-Peter Goldmann",

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N2 - The purpose of this work was to provide a fundamental, in-depth analysis of kinematics and kinetics of the bobsleigh push phase to establish a basis for performance analysis and enhancement. Fifteen elite male athletes performed maximal effort push starts, while ground reaction forces (GRF) and 3D marker trajectories were simultaneously recorded for ground contacts of different sub-sections of the push phase (start acceleration phase: first and second ground contact after the initial push-off from the start block, acceleration phase: 10 m and high-velocity phase: 30 m). To obtain a comprehensive view of the push phase, whole-body kinematics as well as joint kinetics were analysed and compared across the push phase. The results showed that propulsion during the start acceleration was hip extensor dominant. With increasing running speed, the contribution to propulsion increased at the ankle and decreased at the knee. In contrast to unresisted sprinting, bobsleigh athletes relied more on mechanical energy generation at the hip than at the ankle, especially during start acceleration. These findings should be considered for the strength and conditioning of bobsleigh athletes and further investigated in relation to a suitable performance measure.

AB - The purpose of this work was to provide a fundamental, in-depth analysis of kinematics and kinetics of the bobsleigh push phase to establish a basis for performance analysis and enhancement. Fifteen elite male athletes performed maximal effort push starts, while ground reaction forces (GRF) and 3D marker trajectories were simultaneously recorded for ground contacts of different sub-sections of the push phase (start acceleration phase: first and second ground contact after the initial push-off from the start block, acceleration phase: 10 m and high-velocity phase: 30 m). To obtain a comprehensive view of the push phase, whole-body kinematics as well as joint kinetics were analysed and compared across the push phase. The results showed that propulsion during the start acceleration was hip extensor dominant. With increasing running speed, the contribution to propulsion increased at the ankle and decreased at the knee. In contrast to unresisted sprinting, bobsleigh athletes relied more on mechanical energy generation at the hip than at the ankle, especially during start acceleration. These findings should be considered for the strength and conditioning of bobsleigh athletes and further investigated in relation to a suitable performance measure.

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Biomechanics of the bobsleigh push phase

Abstract

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Publications

Evaluating performance measures for the bobsleigh push start

Biomechanics of the Bobsleigh Start - The importance of Powerful Hip Extensors and Ankle Plantarflexors

Specific Biomechanical Aspects of the Skeleton Start

Projects

Collaboration project: Bob- und Schlittenverband für Deutschland (BSD)

Bob- und Schlittenverband für Deutschland (BSD)

Diagnostic camp: Bob- und Schlittenverband für Deutschland

Press/Media

Bob: Wie Anschieber Fleischhauer seine Start-Qualitäten verbessert

Citation