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7-3 WORK DONE BY THE GRAVITATIONAL FORCE 157

If the displacement is vertically downward (Fig. 7-7b), then f 0 and the work
done by the applied force equals mgd.
Equations 7-16 and 7-17 apply to any situation in which an object is lifted or
lowered, with the object stationary before and after the lift. They are independent
of the magnitude of the force used. For example, if you lift a mug from the floor
to over your head, your force on the mug varies considerably during the lift. Still,
because the mug is stationary before and after the lift, the work your force does
on the mug is given by Eqs. 7-16 and 7-17, where, in Eq. 7-17,mgis the weight of
the mug and dis the distance you lift it.

The angle fbetween the displacement and this force com-

ponent is 180. So we can apply Eq. 7-7 to write

Sample Problem 7.04 Work in pulling a sleigh up a snowy slope

In this problem an object is pulled along a ramp but the ob-

ject starts and ends at rest and thus has no overall change in

its kinetic energy (that is important). Figure 7-8ashows the

situation. A rope pulls a 200 kg sleigh (which you may know)

up a slope at incline angle u 30 , through distance d20 m.

The sleigh and its contents have a total mass of 200 kg. The

snowy slope is so slippery that we take it to be frictionless.

How much work is done by each force acting on the sleigh?

KEY IDEAS

(1) During the motion, the forces are constant in magnitude

and direction and thus we can calculate the work done by

each with Eq. 7-7 (WFdcosf) in which fis the angle be-

tween the force and the displacement. We reach the same

result with Eq. 7-8 (W  ) in which we take a dot prod-

uct of the force vector and displacement vector. (2) We can

relate the net work done by the forces to the change in

kinetic energy (or lack of a change, as here) with the

work–kinetic energy theorem of Eq. 7-10 (KW).

Calculations:The first thing to do with most physics prob-

lems involving forces is to draw a free-body diagram to organ-

ize our thoughts. For the sleigh, Fig.7-8bis our free-body dia-

gram, showing the gravitational force , the force Tfrom the

:

F

:

g

d

:

F

:

rope, and the normal force from the slope.

Work WNby the normal force.Let’s start with this easy cal-

culation. The normal force is perpendicular to the slope and

thus also to the sleigh’s displacement. Thus the normal force

does not affect the sleigh’s motion and does zero work. To

be more formal, we can apply Eq. 7-7 to write

WNFNdcos 90  0. (Answer)

Work Wgby the gravitational force.We can find the work

done by the gravitational force in either of two ways (you

pick the more appealing way). From an earlier discussion

about ramps (Sample Problem 5.04 and Fig. 5-15), we know

that the component of the gravitational force along the

slope has magnitude mgsinuand is directed down the

slope. Thus the magnitude is

Fgxmgsinu(200 kg)(9.8 m/s^2 ) sin 30

 980 N.

FN

:

WgFgxdcos 180(980 N)(20 m)(1)

Figure 7-8(a) A sleigh is pulled up a snowy slope. (b) The free-

body diagram for the sleigh.

θ

d

FN

T

Fg

mg cosu

mg sinu

(b)

(a)

u

Does

Does negative work positive work

x

1.96 104 J. (Answer)

The negative result means that the gravitational force re-

moves energy from the sleigh.

The second (equivalent) way to get this result is to use

the full gravitational force F instead of a component. The

:

g

angle between and dis 120 (add the incline angle 30

:

F

:

g

to 90). So, Eq. 7-7 gives us

WgFgdcos 120mgdcos 120

(200 kg)(9.8 m/s^2 )(20 m) cos 120

1.96 104 J. (Answer)

Work WTby the rope’s force.We have two ways of calculat-

ing this work. The quickest way is to use the work–kinetic en-

ergy theorem of Eq. 7-10 (KW), where the net work W

done by the forces is WNWgWTand the change Kin the

kinetic energy is just zero (because the initial and final kinetic

energies are the same—namely, zero). So, Eq. 7-10 gives us

0 WNWgWT 0 1.96 104 JWT

and WT1.96l0^4 J. (Answer)