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05. Applying Newton's Second Law to Rolling Motion

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    569
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    Applying Newton's Second Law to Rolling Motion

    pic

    The child at the top is pretending to be a steamroller by pushing a 24 kg, 0.60 m radius cylindrical object around his backyard. The boy pushes horizontally with a force of 70 N. The coefficient of friction between the cyclinder and the ground is (0.5, 0.4).

    Let's draw a free-body diagram and write Newton's second law in the x-, y-, and q-directions.

    pic

    x-direction y-direction q-direction

    pic and pic and pic

    Note that the description does not specify whether the cylinder rolls or skids when the child pushes it. We will have to make an assumption, continue with the calculation, and then check our assumption for validity. Let's assume that the bottom of the cyclinder does not slip in its contact with the ground, which means the cylinder rolls without slipping around the backyard.

    If the cyclinder bottom does not slip in its contact with the ground, the horizontal acceleration (and velocity) of the cyclinder bottom must equal zero. Since the acceleration of the cylinder bottom is the sum of the acceleration due to translation of the CM and the acceleration due to rotation about the CM, for the bottom to have zero horizontal acceleration means that the acceleration due to rotation,

    pic

    must be equal in magnitude, and opposite in direction, to the translational acceleration of the CM. Thus,

    pic

    Combining this with our y- and q-equations yields:

    pic

    This pair of equation has the solution

    pic

    Now we must check the validity of our assumption. If the cylinder rolls without slipping, the frictional force is static. Thus,

    pic

    Since our calculated value for Ffriction is less than 118 N, the cyclinder does remain in static contact with the ground during its motion, our assumption is validated, and our numerical results are correct.


    This page titled 05. Applying Newton's Second Law to Rolling Motion is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by Paul D'Alessandris via source content that was edited to the style and standards of the LibreTexts platform.