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Part A

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A person pushes a box of mass 15 kg along a floor by applying a force F at an angle of 30° below the horizontal. There is friction between the box and the floor characterized by a coefficient of kinetic friction of 0.45. The box accelerates horizontally at a rate of 2.0 m/s2. What is the magnitude of F?

System: Box as point particle subject to external influences from the person (applied force) the earth (gravity) and the floor (normal force and friction).

Model: Point Particle Dynamics.

Approach: We begin with a free body diagram:

FBD

With the free body diagram as a guide, we write the equations of Newton's 2nd Law:

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\begin

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[ \sum F_

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= F\cos\theta - F_

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= ma_

]
[ \sum F_

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= N - F\sin\theta - mg = ma_

] \end

We can now use the fact that the box is sliding over level ground to tell us that ay = 0 (the box is not moving at all in the y-direction). Thus:

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\begin

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[ N = F\sin\theta + mg ]\end

Now, we can write the friction force in terms of F and known quantities:

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\begin

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[ F_

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= \mu_

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N = \mu_

\left(F\sin\theta + mg\right)]\end

Substituting into the x-component equation yields:

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\begin

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[ F\cos\theta - \mu_

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\left(F\sin\theta + mg\right) = ma_

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]\end

which is solved to obtain:

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\begin

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[ F = \frac{ma_

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+\mu_

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mg}{\cos\theta - \mu_

\sin\theta} = \mbox

Unknown macro: {150 N}

]\end

Part B

A person pulls a box of mass 15 kg along a floor by applying a force F at an angle of 30° above the horizontal. There is friction between the box and the floor characterized by a coefficient of kinetic friction of 0.45. The box accelerates horizontally at a rate of 2.0 m/s2. What is the magnitude of F?

System: Box as point particle subject to external influences from the person (applied force) the earth (gravity) and the floor (normal force and friction).

Model: Point Particle Dynamics.

Approach: We again begin with a free body diagram:

FBD

Which implies the form of Newton's 2nd Law:

Unknown macro: {latex}

\begin

Unknown macro: {large}

[ \sum F_

Unknown macro: {x}

= F\cos\theta - F_

Unknown macro: {f}

= ma_

]
[ \sum F_

Unknown macro: {y}

= N + F\sin\theta - mg = ma_

] \end

Again using the fact that ay is zero if the box is moving along the level floor gives us:

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\begin

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[ N = mg - F\sin\theta]\end

so

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\begin

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[ F_

Unknown macro: {f}

= \mu_

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\left(mg - F\sin\theta\right)]\end

which is substituted into the x-component equation and solved to give:

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\begin

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[ F = \frac{ma_

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+\mu_

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mg}{\cos\theta + \mu_

\sin\theta} = \mbox

Unknown macro: {88 N}

]\end

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