Work-Energy Theorem EX 5

(a) We choose the x-axis pointing to the right in the direction of the displacement. The x-component of the displacement is ${\displaystyle \Delta x=10m}$ in this coordinate system. Then we draw a free body diagram which includes these forces: ${\displaystyle F_{G}}$, ${\displaystyle F_{N}}$, ${\displaystyle F_{R}}$ and the force exerted by the man ${\displaystyle F}$ - see the diagram below:

Now we are ready to compute the work done by each force. The x-component of ${\displaystyle F_{G}}$, as well as the x-component of the normal force ${\displaystyle F_{N}}$, are zero and therefore the work done by these forces is equal to zero. Remember that whenever a force is perpendicular to the displacement the work done by this force is always zero.

The x-component of the force exerted by the man is ${\displaystyle F_{x}=80\cos(-20^{\circ })=75.2N}$. The work done by this force is ${\displaystyle W_{F}=(75.2)(10)=752J}$.

The x-component of the resistive force exerted on the lawnmower is ${\displaystyle {F_{R}}_{x}=10\cos(180^{\circ })=-10N}$. The work done by this force is ${\displaystyle W_{F_{R}}=(-10)(10)=-100J}$.

The total work done on the lawnmower is

${\displaystyle W_{total}=752+(-100)=652J}$

(b) The sum of the y-components of forces is equal to zero. The sum of the x-components is equal ${\displaystyle F_{net}=75.2-10=65.2N}$. The work done by the net force is

${\displaystyle W_{total}=(65.2)(10)=652J}$

We note that both methods yield the same result.