Modeling the ski–snow contact in skiing turns using a hypoplastic vs an elastic force–penetration relation

Mössner, Martin; Heinrich, D.; Schindelwig, Kurt; Kaps, Peter; Schretter, Herwig; Nachbauer, Werner

doi:10.1111/sms.12035

Cited by 16 publications

(32 citation statements)

References 33 publications

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“…Among them, recreational skiers (intermediate and expert levels) and racing athletes try to create a larger edging angle by increasing the COM inclination using knee and hip angulations to perform faster speeds and shorter radius turns Mössner et al, 2014). At this time, most skiers prefer counter-rotation position for greater variation of angulation, COM inclination, and edging angle (LeMaster, 2010, Lind & Sanders, 2004.…”

Section: Discussionmentioning

confidence: 99%

“…Conversely, hip angulation is affected not only by the radius of the slope or turn, but also by the counter-rotation position. Therefore, the skier must slide by increasing the hip angulation through the counter-rotation position to effectively transmit force to the inner edge of the outer ski, which is in contact with the snow surface and acts on the reaction force Mössner et al, 2014).…”

Section: Discussionmentioning

confidence: 99%

“…Because of the experimental difficulties and characteristics of the sport, such as high-speed and wide range of motion, as well as environmental factors, such as cold and sloping snow, kinematic studies of alpine skiing have been conducted through the studies using a ski simulator (Koo, Lee, Kweon, Hyun, & Eun, 2014;Lee, Roh, & Kim, 2016;Nam & Woo, 2007), or using a robot Mössner et al, 2014;Yoneyama et al, 2009) or through the studies that simulate Alpine skiing in a laboratory setting to generalize the results to actual situations (Böhm & Senner, 2008;Demšar, Duhovnik, Lešnik, & Supej, 2015;Nedergaard et al, 2014). The purpose of this study was to investigate the differences of segments rotation movement between 3 different positions and their effects on knee and hip angulation, COM inclination and edging angle changes.…”

Section: Introductionmentioning

confidence: 99%

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Effects of Counter-rotation Position on Knee/Hip Angulation, Center of Mass Inclination, and Edging Angle in Simulated Alpine Skiing

Yoon¹,

Kim²,

Park³

et al. 2017

Korean Journal of Sport Biomechanics

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Objective: To investigate rotation movement of segment for performing each position and its effect on knee/hip angulation, COM inclination, and edging angle changes.Method: Twelve Alpine skiers (age: 25.8±4.8 years, height: 173.8±5.9 cm, weight: 71.4±7.4 kg, length of career: 9.9±4.6 years) participated in this study. Each skier was asked to perform counter-rotation, neutral, and rotation positions.Results: Shank and thigh were less rotated in the counter-rotation position than in other positions, whereas the trunk and pelvis were more counter-rotated (p<.05). Hip angulation, COM inclination, and edging angle were significantly greater in the counter-rotation position than in other positions (p<.05). Conclusion:Our finding proved that the counter-rotation position increases hip angulation, COM inclination, and edging angle. Consequently, we suggest that skiers should perform counter-rotation of the trunk and pelvis relative to the ski direction in the vertical axis for the counter-rotation position. Further analysis will continue to investigate the effects of the counter-rotation position in real ski slope with kinetic analysis.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Effects of Counter-rotation Position on Knee/Hip Angulation, Center of Mass Inclination, and Edging Angle in Simulated Alpine Skiing

Yoon¹,

Kim²,

Park³

et al. 2017

Korean Journal of Sport Biomechanics

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“…The plowing force is generated when skidding occurs on the side of the ski plate, which can be defined as the friction force. The friction force is generated in between the ski plate edge and the snow surface, and can be divided into penetration and shear forces (Mössner et al, 2014;Figure 6). When skidding occurs, the penetration depth increases as the edging angle increases because the penetration force of the ski plate acting vertically on the snow surface becomes larger.…”

Section: Discussionmentioning

confidence: 99%

“…Therefore, the shear force increases as well owing to the coefficient of friction (μ) increasing proportionally to the penetration force (Mössner, Nachbauer, Innerhofer & Schretter, 2003). In , friction force; ε, penetration depth of the ski edge; θ, edging angle; α, attack angle of the ski; V, the displaced volume of snow by the ski; and A, contact area between the ski and the snow projected to the undisturbed snow surface of the hill (Mössner et al, 2014). rotation axis, we can infer that the shorter the braking distance during snowplow, the greater the contribution of the ankle joint to the snowplow angle than to the edging angle.…”

Section: Discussionmentioning

confidence: 99%

Comparison of Three-dimensional Kinematic Changes of the Lower Extremity between the Two Different Braking Distances of Snowplow in Alpine Skiing

Kim¹,

Hae²,

Ryu³

et al. 2016

Korean Journal of Sport Biomechanics

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Objective: The aim of this study was to compare three-dimensional kinematic changes of the lower extremity between the two different braking distances during snowplow in alpine skiing.Method: Six alpine ski instructors (age: 25.3 ± 1.5 yr, height: 169.3 ± 2.9 cm, weight: 66.2 ± 5.9 kg, career: 4.2 ± 2.9 yr) participated in this study. Each skier was asked to perform snowplow on the two different braking distances (2 and 4 m).Results: Snowplow and edging angles (p = .006 and p = .005), ankle adduction and inversion (p = .033 and p = .002), knee extension (p = .003), and hip abduction and internal rotation (p = .043 and p = .006) were significantly greater in the 2 m than in the 4 m braking distance. Conclusion:Based on our results, we suggest that skiers should make greater snowplow and edging angles on the shorter braking distance. In this situation, ankle joint adduction/inversion angle and hip joint internal-rotation make greater snowplow angle, and hip joint abduction make greater edging angle. In addition, greater knee joint extension angle may lead to more posteriorly positioned center of mass.

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Cross-Country Ski

Carlsson

Ainegren

Tinnsten

et al. 2016

The Engineering Approach to Winter Sports

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Modeling the ski–snow contact in skiing turns using a hypoplastic vs an elastic force–penetration relation

Cited by 16 publications

References 33 publications

Effects of Counter-rotation Position on Knee/Hip Angulation, Center of Mass Inclination, and Edging Angle in Simulated Alpine Skiing

Effects of Counter-rotation Position on Knee/Hip Angulation, Center of Mass Inclination, and Edging Angle in Simulated Alpine Skiing

Comparison of Three-dimensional Kinematic Changes of the Lower Extremity between the Two Different Braking Distances of Snowplow in Alpine Skiing

Cross-Country Ski

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