Bones, on the whole; do not fracture due to tension or compression. Rather they generally fracture due to sideways impact or bending, resulting in bone shearing or snapping. fracture due to tension or compression. Also, they generally fracture due to sideways impact or bending, resulting in bone shearing or snapping. do not fracture due to tension or compression. Rather they generally they also do not fracture due to sideways impact or bending. fracture due to tension only. Also, they generally fracture due to sideways impact or bending, resulting in bone shearing or snapping. fracture due to compression only. Rather they generally fracture due to sideways impact or bending, resulting in bone shearing or snapping.

Bones, on the whole; do not fracture due to tension or compression. Rather they generally fracture due to sideways impact or bending, resulting in bone shearing or snapping. fracture due to tension or compression. Also, they generally fracture due to sideways impact or bending, resulting in bone shearing or snapping. do not fracture due to tension or compression. Rather they generally they also do not fracture due to sideways impact or bending. fracture due to tension only. Also, they generally fracture due to sideways impact or bending, resulting in bone shearing or snapping. fracture due to compression only. Rather they generally fracture due to sideways impact or bending, resulting in bone shearing or snapping.

College Physics

1st Edition

ISBN:9781938168000

Author:Paul Peter Urone, Roger Hinrichs

Publisher:Paul Peter Urone, Roger Hinrichs

Chapter9: Statics And Torque

Section: Chapter Questions

Problem 18CQ: Suppose the biceps muscle was attached through tendons to the upper arm dose to the elbow and the...

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