The last segment of the triple jump track-and-field event is the jump, in which the athlete makes a final leap, landing in a sand-filled pit. Assuming that the velocity of an 84-kg athlete just before landing is 9.14 m/s at an angle of 35° with the horizontal and that the athlete comes to a complete stop in 0.22 s after landing, determine the horizontal component of the average impulsive force exerted on his feet during binding. 9.14 m/s 35° Landing pit Fig. P13.196

The last segment of the triple jump track-and-field event is the jump, in which the athlete makes a final leap, landing in a sand-filled pit. Assuming that the velocity of an 84-kg athlete just before landing is 9.14 m/s at an angle of 35° with the horizontal and that the athlete comes to a complete stop in 0.22 s after landing, determine the horizontal component of the average impulsive force exerted on his feet during binding. 9.14 m/s 35° Landing pit Fig. P13.196

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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Concept explainers

Types of loading

In mechanical terminology, the term load indicates that external force/weight, either constant or variable, acts on a mechanical member/structure. The weight of an object of a specific material is also an external load, and the external force that works on a structure comes under the categories of loading. The external load generates its effects as stress and strain in the structure.

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This problem has been solved:
CH13
196RP
The last segment of the triple jump track-and-field
event is the jump, in which the athlete makes a final
leap, landing in a sand-filled pit. Assuming that the
velocity of an 84-kg athlete just before landing is 9.14
m/s at an angle of 35° with the horizontal and that the
athlete comes to a complete stop in 0.22 s after
landing, determine the horizontal component of the
average impulsive force exerted on his feet during
binding.
9.14 m/s
35°
Landing pit
Fig. P13.196
Step-by-step solution:
G
อังกฤษ
ไทย

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