7.1 Work (Page 2/11)

University physics volume 1 Page 2 / 11

Work done by constant forces and contact forces

The simplest work to evaluate is that done by a force that is constant in magnitude and direction. In this case, we can factor out the force; the remaining integral is just the total displacement, which only depends on the end points A and B , but not on the path between them:

W_{A B} = \vec{F} \cdot \int_{A}^{B} d \vec{r} = \vec{F} \cdot ({\vec{r}}_{B} - {\vec{r}}_{A}) = | \vec{F} | | {\vec{r}}_{B} - {\vec{r}}_{A} | cos θ (constant force).

We can also see this by writing out [link] in Cartesian coordinates and using the fact that the components of the force are constant:

\begin{matrix} W_{A B} & = \int_{path A B} \vec{F} \cdot d \vec{r} = \int_{path A B} (F_{x} d x + F_{y} d y + F_{z} d z) = F_{x} \int_{A}^{B} d x + F_{y} \int_{A}^{B} d y + F_{z} \int_{A}^{B} d z \\ = F_{x} (x_{B} - x_{A}) + F_{y} (y_{B} - y_{A}) + F_{z} (z_{B} - z_{A}) = \vec{F} \cdot ({\vec{r}}_{B} - {\vec{r}}_{A}) . \end{matrix}

[link] (a) shows a person exerting a constant force $\vec{F}$ along the handle of a lawn mower, which makes an angle $θ$ with the horizontal. The horizontal displacement of the lawn mower, over which the force acts, is $\vec{d} .$ The work done on the lawn mower is $W = \vec{F} \cdot \vec{d} = F d cos θ$ , which the figure also illustrates as the horizontal component of the force times the magnitude of the displacement.

Figure a shows a person pushing a lawn mower with a constant force. The displacement is a horizontal vector d pointing to the right. The force F is a vector pointing down and to the right, along the handle of the lawn mower, at an angle theta below the horizontal. The component of the force parallel to the displacement is F cosine theta. The equation W equals F d cosine theta is shown in the figure. Figure b shows a person holding a briefcase. The force F is upward. The displacement is zero. Figure c shows the person in b walking horizontally while holding the briefcase. The force F is upward, as in b. The displacement d is horizontal to the right. Theta equals ninety degrees and cosine theta equals zero. — Work done by a constant force. (a) A person pushes a lawn mower with a constant force. The component of the force parallel to the displacement is the work done, as shown in the equation in the figure. (b) A person holds a briefcase. No work is done because the displacement is zero. (c) The person in (b) walks horizontally while holding the briefcase. No work is done because $cos θ$ is zero.

[link] (b) shows a person holding a briefcase. The person must exert an upward force, equal in magnitude to the weight of the briefcase, but this force does no work, because the displacement over which it acts is zero. So why do you eventually feel tired just holding the briefcase, if you’re not doing any work on it? The answer is that muscle fibers in your arm are contracting and doing work inside your arm, even though the force your muscles exert externally on the briefcase doesn’t do any work on it. (Part of the force you exert could also be tension in the bones and ligaments of your arm, but other muscles in your body would be doing work to maintain the position of your arm.)

In [link] (c), where the person in (b) is walking horizontally with constant speed, the work done by the person on the briefcase is still zero, but now because the angle between the force exerted and the displacement is $90 °$ ( $\vec{F}$ perpendicular to $\vec{d}$ ) and $cos 90 ° = 0$ .

Calculating the work you do to push a lawn mower

How much work is done on the lawn mower by the person in [link] (a) if he exerts a constant force of 75.0 N at an angle

35 °

below the horizontal and pushes the mower 25.0 m on level ground?

Strategy

We can solve this problem by substituting the given values into the definition of work done on an object by a constant force, stated in the equation

W = F d cos θ

. The force, angle, and displacement are given, so that only the work W is unknown.

Solution

The equation for the work is

W = F d cos θ .

Substituting the known values gives

W = (75.0 N) (25.0 m) cos (35.0 °) = 1.54 \times 10^{3} J .

Significance

Even though one and a half kilojoules may seem like a lot of work, we will see in Potential Energy and Conservation of Energy that it’s only about as much work as you could do by burning one sixth of a gram of fat.

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Source: OpenStax, University physics volume 1. OpenStax CNX. Sep 19, 2016 Download for free at http://cnx.org/content/col12031/1.5

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