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11.3 Pressure  (Page 2/3)

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Calculating force exerted by the air: what force does a pressure exert?

An astronaut is working outside the International Space Station where the atmospheric pressure is essentially zero. The pressure gauge on her air tank reads 6 . 90 × 10 6 Pa size 12{6 "." "90" times "10" rSup { size 8{6} } `"Pa"} {} . What force does the air inside the tank exert on the flat end of the cylindrical tank, a disk 0.150 m in diameter?

Strategy

We can find the force exerted from the definition of pressure given in P = F A size 12{P= { {F} over {A} } } {} , provided we can find the area A size 12{A} {} acted upon.

Solution

By rearranging the definition of pressure to solve for force, we see that

F = PA . size 12{F= ital "PA"} {}

Here, the pressure P size 12{P} {} is given, as is the area of the end of the cylinder A size 12{A} {} , given by A = πr 2 size 12{A=πr rSup { size 8{2} } } {} . Thus,

F = 6.90 × 10 6 N/m 2 3.14 0.0750 m 2 = 1.22 × 10 5 N. alignl { stack { size 12{F= left (6 "." "90" times "10" rSup { size 8{6} } `"N/m" rSup { size 8{2} } right ) left (3 "." "14" right ) left (0 "." "0750"`m right ) rSup { size 8{2} } } {} #=1 "." "22" times "10" rSup { size 8{5} } `N "." {} } } {}

Discussion

Wow! No wonder the tank must be strong. Since we found F = PA size 12{F= ital "PA"} {} , we see that the force exerted by a pressure is directly proportional to the area acted upon as well as the pressure itself.

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The force exerted on the end of the tank is perpendicular to its inside surface. This direction is because the force is exerted by a static or stationary fluid. We have already seen that fluids cannot withstand shearing (sideways) forces; they cannot exert shearing forces, either. Fluid pressure has no direction, being a scalar quantity. The forces due to pressure have well-defined directions: they are always exerted perpendicular to any surface. (See the tire in [link] , for example.) Finally, note that pressure is exerted on all surfaces. Swimmers, as well as the tire, feel pressure on all sides. (See [link] .)

The forces inside a tire are shown by arrow lines. An inset shows an enlarged view of the valve in the tire. Air pressure in the tire keeps the valve closed.
Pressure inside this tire exerts forces perpendicular to all surfaces it contacts. The arrows give representative directions and magnitudes of the forces exerted at various points. Note that static fluids do not exert shearing forces.
A man swimming underwater has many arrows pointing toward him to represent the directions and magnitudes of the forces exerted on him at various points.
Pressure is exerted on all sides of this swimmer, since the water would flow into the space he occupies if he were not there. The arrows represent the directions and magnitudes of the forces exerted at various points on the swimmer. Note that the forces are larger underneath, due to greater depth, giving a net upward or buoyant force that is balanced by the weight of the swimmer.

Making connections: pressure

[link] and [link] both show pressure at the barrier between an object and a fluid. Note that this pressure also exists within the fluid itself. Just as particles will create a force when colliding with the swimmer in [link] , they will do the same each time they strike each other. These forces can be represented by arrows, whose vectors show the resulting direction of particle movement. The same factors that determine the magnitude of pressure upon the fluid barrier will determine the magnitude of pressure within the fluid itself. These factors will be discussed in Chapter 13.

Phet explorations: gas properties

Pump gas molecules to a box and see what happens as you change the volume, add or remove heat, change gravity, and more. Measure the temperature and pressure, and discover how the properties of the gas vary in relation to each other.

Gas Properties

Test prep for ap courses

A cylindrical drum of radius 0.5 m is used to hold 400 liters of petroleum ether (density = .68 g/mL or 680 kg/m 3 ).

(Note: 1 liter = 0.001 m 3 )

  1. Determine the amount of pressure applied to the walls of the drum if the petroleum ether fills the drum to its top.
  2. Determine the amount of pressure applied to the floor of the drum if the petroleum ether fills the drum to its top.
  3. If the drum were redesigned to hold 800 liters of petroleum ether:
    1. How would the pressure on the walls change?

      Would it increase, decrease, or stay the same?

    2. How would the pressure on the floor change?

      Would it increase, decrease, or stay the same?

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Section summary

  • Pressure is the force per unit perpendicular area over which the force is applied. In equation form, pressure is defined as
    P = F A . size 12{P= { {F} over {A} } "." } {}
  • The SI unit of pressure is pascal and 1 Pa = 1 N/m 2 size 12{1`"Pa"=1`"N/m" rSup { size 8{2} } } {} .

Conceptual questions

How is pressure related to the sharpness of a knife and its ability to cut?

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Why does a dull hypodermic needle hurt more than a sharp one?

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The outward force on one end of an air tank was calculated in [link] . How is this force balanced? (The tank does not accelerate, so the force must be balanced.)

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Why is force exerted by static fluids always perpendicular to a surface?

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In a remote location near the North Pole, an iceberg floats in a lake. Next to the lake (assume it is not frozen) sits a comparably sized glacier sitting on land. If both chunks of ice should melt due to rising global temperatures (and the melted ice all goes into the lake), which ice chunk would give the greatest increase in the level of the lake water, if any?

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How do jogging on soft ground and wearing padded shoes reduce the pressures to which the feet and legs are subjected?

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Toe dancing (as in ballet) is much harder on toes than normal dancing or walking. Explain in terms of pressure.

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How do you convert pressure units like millimeters of mercury, centimeters of water, and inches of mercury into units like newtons per meter squared without resorting to a table of pressure conversion factors?

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Problems&Exercises

As a woman walks, her entire weight is momentarily placed on one heel of her high-heeled shoes. Calculate the pressure exerted on the floor by the heel if it has an area of 1 . 50 cm 2 size 12{1 "." "50"`"cm" rSup { size 8{2} } } {} and the woman's mass is 55.0 kg. Express the pressure in Pa. (In the early days of commercial flight, women were not allowed to wear high-heeled shoes because aircraft floors were too thin to withstand such large pressures.)

3.59 × 10 6 Pa ; or 521 lb/in 2 size 12{"521"`"lb/in" rSup { size 8{2} } } {}

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The pressure exerted by a phonograph needle on a record is surprisingly large. If the equivalent of 1.00 g is supported by a needle, the tip of which is a circle 0.200 mm in radius, what pressure is exerted on the record in N/m 2 size 12{"N/m" rSup { size 8{2} } } {} ?

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Nail tips exert tremendous pressures when they are hit by hammers because they exert a large force over a small area. What force must be exerted on a nail with a circular tip of 1.00 mm diameter to create a pressure of 3 . 00 × 10 9 N/m 2 ? (This high pressure is possible because the hammer striking the nail is brought to rest in such a short distance.)

2.36 × 10 3 N size 12{2 "." "36" times "10" rSup { size 8{3} } `N} {}

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Source:  OpenStax, College physics for ap® courses. OpenStax CNX. Nov 04, 2016 Download for free at https://legacy.cnx.org/content/col11844/1.14
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