Engineering Fundamentals: An Introduction to Engineering, 4th ed.c

172 Chapter 7 Length and Length-Related Parameters

surfaces, or fins as shown in Figure 7.7. If you look closely inside buildings around your cam-

pus, you will also see heat exchangers or radiators with extended surfaces under windows and

against some walls. As you know, these heat exchangers or radiators supply heat to rooms and

hallways during the winter. For another example, have you ever thought about why crushed ice

cools a drink faster than ice cubes? It is because given the same amount of ice, the crushed ice

has more surface exposed to the liquid. You may have also noticed that given the same amount

of meat, it takes longer for a roast of beef to cook than it takes stew. Again, it is because the stew

has more surface area exposed to the liquid in which it is being cooked. So next time you are

planning to make some mashed potatoes, make sure you first cut the potatoes into smaller

pieces. The smaller the pieces, the sooner they will cook. Of course, the reverse is also true.

That is, if you want to reduce the heat loss from something, one way of doing this would be to

reduce the exposed surface area. For example, when we feel cold we naturally try to curl up,

which reduces the surface area exposed to the cold surroundings. You can tell by observing

nature that trees take advantage of the effect and importance of surface area. Why do trees have

lots of leaves rather than one big leaf? It is because they can absorb more solar radiation that

way. Surface area is also important in engineering problems related to mass transfer. Your par-

ents or grandparents perhaps recall when they used to hang out clothes to dry. The clothes were

hung over the clothesline in such way that they had a maximum area exposed to the air. Bed-

sheets, for example, were stretched out fully across the clothesline.

Let us now investigate the relationship between a given volume and exposed surface area. Con-

sider a 1 m 1 m 1 m cube. What is the volume? 1 m

3

. What is the exposed surface area of this
cube? 6 m
2
. If we divide each dimension of this cube by half, we get 8 smaller cubes with the
dimensions of 0.5 m 0.5 m 0.5 m, as shown in Figure 7.8. What is the total volume of the 8
smaller cubes? It is still 1 m
3
. What is the total exposed surface area of the cubes? Each cube now
has an exposed surface area of 1.5 m
2
, which amounts to a total exposed surface area of 12 m
2
.
Let us proceed with dividing the dimensions of our 1 m 1 m 1 m original cube into
even smaller cubes with the dimensions of 0.25 m 0.25 m 0.25 m. We will now have
64 smaller cubes, and we note that the total volume of the cubes is still 1 m
3
. However, the
surface area of each cube is 0.375 m
2
, leading to a total surface area of 24 m
2
. Thus, the same
cube divided into 64 smaller cubes now has an exposed surface area that is four times the origi-
nal surface area.

■Figure 7.7

The important role of area in the

design of various systems.

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