1. Conceptual Physics Fundamentals
Chapter 7:
FLUID MECHANICS

2. This lecture will help you understand:
Density
Pressure
Pressure in a Liquid
Buoyancy in a Liquid
Archimedes’ Principle
Pressure in a Gas
Atmospheric Pressure
Pascal’s Principle
Buoyancy in a Gas
Bernoulli’s Principle

3. Fluid Mechanics
“Men never do evil so cheerfully and completely as when they do so from religious conviction.” —Blaise Pascal

4. Density
Density
important property of materials (solids, liquids, gases)
measure of compactness of how much mass an object occupies
“lightness” or “heaviness” of materials of the same size

5. Density
in equation form:
units: grams or kilograms
volume: cm3 or m3
example: density of mercury is 13.6 g/cm3, so mercury has 13.6 times as much mass as an equal volume of water (density 1 g/cm3)

6. The volume of 1000 kg of water is _______________.
Density
CHECK YOUR NEIGHBOR
The volume of 1000 kg of water is _______________.
A. 1 liter
slightly less than 1 liter
more than 1 liter
None of the above
A. 1 liter

7. The volume of 1000 kg of water is _______________.
Density
CHECK YOUR ANSWER
The volume of 1000 kg of water is _______________.
A. 1 liter
slightly less than 1 liter
more than 1 liter
None of the above
A. 1 liter

8. Density Weight density in equation form:
example: density of salt water is 64 lb/ft3, more dense than fresh water (density 62.4 lb/ft3)

9. Which of these has the greatest density?
CHECK YOUR NEIGHBOR
Which of these has the greatest density?
A. 100 kg of lead
100 kg of water
Both are the same
None of the above
A. 100 kg of lead

10. Which of these has the greatest density?
CHECK YOUR ANSWER
Which of these has the greatest density?
A. 100 kg of lead
100 kg of water
Both are the same
None of the above
Explanation:
They have the same mass and weight, but any amount of lead is more dense than any amount of water.
A. 100 kg of lead

11. Density CHECK YOUR NEIGHBOR
When water freezes, it expands. This tells us that the density of ice is _______________.
A. less than the density of water
equal to the density of water
more than the density of water
None of the above
A. less than the density of water

12. Density CHECK YOUR ANSWER
When water freezes, it expands. This tells us that the density of ice is _______________
A. less than the density of water
equal to the density of water
more than the density of water
None of the above
A. less than the density of water

13. Density CHECK YOUR NEIGHBOR
Compared with the weight of water, the weight of a liter of ice is _______________.
A. more
less
the same
None of the above
B. less

14. Density CHECK YOUR ANSWER
Compared with the weight of water, the weight of a liter of ice is _______________.
A. more
less
the same
None of the above
Explanation
When a liter of water freezes, its volume increases. To get a liter of ice you’d have to shave part of it off to be the same size. So there is less water in a liter of ice.
B. less

15. Pressure the force per unit area that one object exerts on another
in equation form:
depends on area over which force is distributed
units: N/m2, lb/ft2, or Pa (Pascals)

16. Pressure
example: The teacher between nails is unharmed because force is applied over many nails. Combined surface area of the nails results in a tolerable pressure that does not puncture the skin.

17. Pressure CHECK YOUR NEIGHBOR
When you stand on one foot instead of two, the force you exert on the floor is __________.
A. less
the same
more
None of the above
B. the same

18. Pressure CHECK YOUR ANSWER
When you stand on one foot instead of two, the force you exert on the floor is ___________.
A. less
the same
more
None of the above
Explanation:
Distinguish between force and pressure!
B. the same

19. Pressure CHECK YOUR NEIGHBOR
When you stand on one foot instead of two, the pressure you exert on the floor is _____________.
A. less
the same
more
None of the above
C. more

20. Pressure CHECK YOUR ANSWER
When you stand on one foot instead of two, the pressure you exert on the floor is _____________.
A. less
the same
more
None of the above
Explanation:
Twice as much, in fact!
C. more

21. Pressure in a Liquid
force per unit area that a liquid exerts on an object
depth dependent and not volume dependent
example: swim twice as deep, then twice as much weight of water above you produces as much pressure on you

22. Pressure in a Liquid acts equally in all directions example:
your ears feel the same amount of pressure under water no matter how you tip your head
bottom of a boat is pushed upward by water pressure
pressure acts upward when pushing a beach ball under water

23. Pressure in a Liquid independent of shape of container
whatever the shape of a container, pressure at any particular depth is the same
in equation form:

24. Pressure in a Liquid CHECK YOUR NEIGHBOR
Water pressure provided by a water tower is greater if the tower __________.
A. is taller
holds more water
Both A and B
None of the above
A. is taller

25. Pressure in a Liquid CHECK YOUR ANSWER
Water pressure provided by a water tower is greater if the tower ____________.
A. is taller
holds more water
Both A and B
None of the above
Explanation:
Only depth, not amount of water, contributes to pressure.
A. is taller

26. Pressure in a Liquid Effects of water pressure
acts perpendicular to surfaces of a container
liquid spurts at right angles from a hole in the surface curving downward
The greater the depth, the greater the exiting speed

27. Buoyancy in a Liquid Buoyancy
apparent loss of weight of a submerged object
amount equals the weight of water displaced

28. Buoyancy in a Liquid Displacement rule:
A completely submerged object always displaces a volume of liquid equal to its own volume.
example: Place a stone in a container that is brim- full of water, and the amount of water overflow equals the volume of the stone

29. Buoyancy in a Liquid CHECK YOUR NEIGHBOR
A cook who measures a specific amount of butter by placing it in a measuring cup with water in it is using the ___________.
A. principle of buoyancy
displacement rule
concept of density
All of the above
B. displacement rule

30. Buoyancy in a Liquid CHECK YOUR ANSWER
A cook who measures a specific amount of butter by placing it in a measuring cup with water in it is using the __________.
A. principle of buoyancy
displacement rule
concept of density
All of the above
B. displacement rule

31. Buoyancy in a Liquid Buoyant force
net upward force that a fluid exerts on an immersed object = weight of water displaced
example: the difference in the upward and downward forces acting on the submerged block is the same at any depth

32. How many forces act on a submerged body at rest in a fluid?
Buoyancy in a Liquid
CHECK YOUR NEIGHBOR
How many forces act on a submerged body at rest in a fluid?
A. One—buoyancy
Two—buoyancy and the force due to gravity
None—in accord with the equilibrium rule, F = 0
None of the above
B. Two—buoyancy and the force due to gravity

33. How many forces act on a submerged body at rest in a fluid?
Buoyancy in a Liquid
CHECK YOUR ANSWER
How many forces act on a submerged body at rest in a fluid?
A. One—buoyancy
Two—buoyancy and the force due to gravity
None—in accord with the equilibrium rule, F = 0
None of the above
B. Two—buoyancy and the force due to gravity

34. Buoyancy in a Liquid Sink or float?
sink when weight of submerged object is greater than the buoyant force
neither sink nor float when weight of a submerged object is equal to buoyant force—object will remain at any level
float when weight of submerged object is less than the buoyant force it would have when submerged—when floating, buoyant force = weight of floating object

35. Archimedes’ Principle
discovered by Greek scientist Archimedes
relates buoyancy to displaced liquid
states that an immersed body (completely or partially) is buoyed up by a force equal to the weight of the fluid it displaces
applies to gases and liquids

36. Archimedes’ Principle
Apparent weight of a submerged object
weight out of water—buoyant force
example: If a 3-kg block submerged in water apparently “weighs” 2 kg, then the buoyant force or weight of water displaced is 1 kg.

37. Archimedes’ Principle
CHECK YOUR NEIGHBOR
On which of these blocks submerged in water is the buoyant force greatest?
A. 1 kg of lead
1 kg of aluminum
1 kg of uranium
All the same
B. 1 kg of aluminum

38. Archimedes’ Principle
CHECK YOUR ANSWER
On which of these blocks submerged in water is the buoyant force greatest?
A. 1 kg of lead
1 kg of aluminum
1 kg of uranium
all the same
Explanation:
The largest block is the aluminum one. It displaces more water and therefore experiences the greatest buoyant force.
B. 1 kg of aluminum

39. Archimedes’ Principle
CHECK YOUR NEIGHBOR
When a fish expands its air bladder, the density of the fish ________________.
A. decreases
increases
remains the same
None of the above
A. decreases

40. Archimedes’ Principle
CHECK YOUR ANSWER
When a fish expands its air bladder, the density of the fish _____________.
A. decreases
increases
remains the same
None of the above
A. decreases

41. Archimedes’ Principle
CHECK YOUR NEIGHBOR
When a fish makes itself less dense, the buoyant force on it ______________.
A. decreases
increases
remains the same
None of the above
B. increases

42. Archimedes’ Principle
CHECK YOUR ANSWER
When a fish makes itself less dense, the buoyant force on it ______________.
A. decreases
increases
remains the same
None of the above
B. increases

43. Archimedes’ Principle
CHECK YOUR NEIGHBOR
When a fish decreases the size of its air bladder, the density of the fish ___________.
A. decreases
increases
remains the same
None of the above
B. increases

44. Archimedes’ Principle
CHECK YOUR ANSWER
When a fish decreases the size of its air bladder, the density of the fish _____________.
A. decreases
increases
remains the same
None of the above
B. increases

45. Archimedes’ Principle
CHECK YOUR NEIGHBOR
When a submarine takes water into its ballast tanks, its density __________.
A. decreases
increases
remains the same
None of the above
B. increases

46. Archimedes’ Principle
CHECK YOUR ANSWER
When a submarine takes water into its ballast tanks, its density ______________.
A. decreases
increases
remains the same
None of the above
B. increases

47. Archimedes’ Principle
CHECK YOUR NEIGHBOR
When a submerged submarine expels water from its ballast tanks, its density __________.
A. decreases
increases
remains the same
None of the above
A. decreases

48. Archimedes’ Principle
CHECK YOUR ANSWER
When a submerged submarine expels water from its ballast tanks, its density __________.
A. decreases
increases
remains the same
None of the above
Explanation:
This is how a submerged submarine is able to surface.
A. decreases

49. Archimedes’ Principle
Flotation
Principle of flotation
a floating object displaces a weight of fluid equal to its own weight
example: A solid iron 1-ton block may displace 1/8 ton of water and sink. The same 1 ton of iron in a bowl shape displaces a greater volume of water—the greater buoyant force allows it to float.

50. Archimedes’ Principle
CHECK YOUR NEIGHBOR
The reason a person finds it easier to float in salt water, compared with fresh water, is that in salt water __________.
A. the buoyant force is greater
a person feels less heavy
Neither of these
C. neither of these

51. Archimedes’ Principle
CHECK YOUR ANSWER
The reason a person finds it easier to float in salt water, compared with fresh water, is that in salt water __________.
A. the buoyant force is greater
a person feels less heavy
Neither of these
Explanation:
A floating person has the same buoyant force whatever the density of water. A person floats higher because a smaller volume of the denser salt water is displaced.
C. neither of these

52. Archimedes’ Principle
CHECK YOUR NEIGHBOR
On a boat ride, the skipper gives you a life preserver filled with lead pellets. When he sees the skeptical look on your face, he says that you’ll experience a greater buoyant force if you fall overboard than your friends who wear Styrofoam-filled preservers.
A. He apparently doesn’t know his physics.
He is correct.
B. He is correct.

53. Archimedes’ Principle
CHECK YOUR ANSWER
On a boat ride, the skipper gives you a life preserver filled with lead pellets. When he sees the skeptical look on your face, he says that you’ll experience a greater buoyant force if you fall overboard than your friends who wear Styrofoam-filled preservers.
A. He apparently doesn’t know his physics.
He is correct.
Explanation:
He’s correct, but what he doesn’t tell you is you’ll drown! Your life preserver will submerge and displace more water than those of your friends who float at the surface. Although the buoyant force on you will be greater, the net force downward is greater still!
B. He is correct.

54. Archimedes’ Principle
Denser fluids will exert a greater buoyant force on a body than less dense fluids of the same volume.
example: ship will float higher in salt water (density = 1.03 g/cm3) than in fresh water (density = 1.00 g/cm3)

55. Archimedes’ Principle
applies in air
The more air an object displaces, the greater the buoyant force on it.
If an object displaces its weight, it hovers at a constant altitude,
If an object displaces less air, it descends,

56. As you sit in class, is there a buoyant force acting on you?
Archimedes’ Principle
CHECK YOUR NEIGHBOR
As you sit in class, is there a buoyant force acting on you?
A. No, as evidenced by an absence of lift
Yes, due to displacement of air
B. Yes, due to displacement of air

57. As you sit in class, is there a buoyant force acting on you?
Archimedes’ Principle
CHECK YOUR ANSWER
As you sit in class, is there a buoyant force acting on you?
A. No, as evidenced by an absence of lift
Yes, due to displacement of air
Explanation:
There is a buoyant force on you due to air displacement, but much less than your weight.
B. Yes, due to displacement of air

58. Pressure in a Gas
greater distance between molecules in a gas than in a liquid
molecules in a gas are free from the cohesive forces
Molecular motion of gas exerts pressure against a container.
For large volumes of gas, gravitational forces limit size and determine shape.

59. Pressure in a Gas Relationship between pressure and density
gas pressure is proportional to density
example:
Air pressure and air density inside an inflated tire are greater than the atmospheric pressure and density outside.
twice as many molecules in the same volume  air density doubled
for molecules moving at the same speed (same temperature), collisions are doubled  pressure doubled

60. Pressure in a Gas Double density of air by doubling the amount of air
decreasing the volume to half

61. Pressure in a Gas Boyle’s Law
relationship between pressure and volume for ideal gases
an ideal gas is one in which intermolecular forces play no role
states that pressure volume is a constant for a given mass of confined gas regardless of changes in pressure or volume (with temperature remaining unchanged)
pressure volume = constant means that
P1V1 = P2V2

62. Pressure in a Gas CHECK YOUR NEIGHBOR
When you squeeze a party balloon to 0.8 its volume, the pressure in the balloon __________.
A. is 0.8 its former pressure
remains the same if you squeeze it slowly
is 1.25 times greater
is 8 times greater
C. is 1.25 times greater

63. Pressure in a Gas CHECK YOUR ANSWER
When you squeeze a party balloon to 0.8 its volume, the pressure in the balloon __________.
A. is 0.8 its former pressure
remains the same if you squeeze it slowly
is 1.25 times greater
is 8 times greater
Explanation:
Boyle’s law, sweet and simple: P(1.0 V) = 1.25 P(0.8 V).
C times greater

64. Earth’s Atmosphere Atmosphere ocean of air exerts pressure
The Magdeburg-hemispheres demonstration in 1654 by Otto von Guericke showed the large magnitude of atmosphere’s pressure.

65. Atmospheric Pressure Atmospheric pressure caused by weight of air
varies from one locality to another
not uniform
measurements are used to predict weather conditions

66. Atmospheric Pressure
Pressure exerted against bodies immersed in the atmosphere result from the weight of air pressing from above.
at sea level is 101 kilopascals (101 kPa)
weight of air pressing down on 1 m2 at sea level ~ 100,000 N, so atmospheric pressure is ~ 105 N/m2

67. Atmospheric Pressure
Pressure at the bottom of a column of air reaching to the top of the atmosphere is the same as the pressure at the bottom of a column of water 10.3 m high.
Consequence: The highest the atmosphere can push water up into a vacuum pump is 10.3 m.
Mechanical pumps that don’t depend on atmospheric pressure don’t have the 10.3-m limit.

68. Atmospheric Pressure Barometer Aneroid barometer
device to measure atmospheric pressure
also determines elevation
Aneroid barometer
small portable instrument that measures
atmospheric pressure
calibrated for altitude, then an altimeter

69. Atmospheric Pressure CHECK YOUR NEIGHBOR
The maximum height to which water can be drunk through a straw __________.
A. is 10.3 m
is about 76 cm
has no limit
None of the above
A. is 10.3 m

70. Atmospheric Pressure CHECK YOUR ANSWER
The maximum height to which water can be drunk through a straw __________.
A. is 10.3 m
is about 76 cm
has no limit
None of the above
Explanation:
However strong your lungs may be, or whatever device you use to make a vacuum in the straw, at sea level, the water could not be pushed up by the atmosphere higher than 10.3 m.
A. is 10.3 m.

71. Pascal’s Principle Pascal’s principle
discovered by Blaise Pascal, a scientist and theologian in the 17th century
states that a change in pressure at any point in an enclosed fluid at rest is transmitted undiminished to all points in the fluid
applies to all fluids—gases and liquids

72. Pascal’s Principle example: application in hydraulic press
pressure applied to the left piston is transmitted to the right piston
a 10-kg load on small piston (left) lifts a load of 500 kg on large piston (right)

73. Pascal’s Principle application for gases and liquids
seen in everyday hydraulic devices used in construction
in auto lifts in service stations
Increased air pressure produced by an air compressor is transmitted through the air to the
surface of oil in an
underground reservoir.
The oil transmits the
pressure to the piston,
which lifts the auto.

74. In a hydraulic device, it is impossible for the __________.
Pascal’s Principle
CHECK YOUR NEIGHBOR
In a hydraulic device, it is impossible for the __________.
A. output piston to move farther than the input piston
force output to exceed the force input
output piston’s speed to exceed the input piston’s speed
energy output to exceed energy input
D. energy output to exceed energy input

75. In a hydraulic device, it is impossible for the __________.
Pascal’s Principle
CHECK YOUR ANSWER
In a hydraulic device, it is impossible for the __________.
A. output piston to move farther than the input piston
force output to exceed the force input
output piston’s speed to exceed the input piston’s speed
energy output to exceed energy input
D. energy output to exceed energy input

76. Buoyancy in a Gas
Archimedes’ principle applies to air as well as liquids.
states that an object surrounded by air is buoyed up by a force equal to the weight of the air displaced

77. A dirigible that hovers in air __________.
Buoyancy in Gas
CHECK YOUR NEIGHBOR
A dirigible that hovers in air __________.
A. displaces its volume of air
displaces its weight of air
Both A and B
Neither A nor B
C. Both A and B

78. A dirigible that hovers in air __________.
Buoyancy in Gas
CHECK YOUR ANSWER
A dirigible that hovers in air __________.
A. displaces its volume of air
displaces its weight of air
Both A and B
Neither A nor B
Explanation:
Like a fish in water, both volume and weight of a fluid are displaced.
C. Both A and B

79. Buoyancy in Gas Rule for “lighter-than-air” objects:
When the weight of air displaced by an object is greater than the weight of the object, it rises.
When the weight of air displaced by an object equals the weight of the object, it hovers in air.
When the weight of air displaced by an object is less than the weight of the object, it is not supported by air.

80. Buoyancy in Gas Gas-filled balloons
gas prevents atmosphere from collapsing them
best buoyancy with hydrogen, the lightest gas (flammable, so seldom used)
next-best buoyancy with helium
heated air used in sports balloons
As balloons rise, atmosphere becomes less dense with altitude.

81. Buoyancy in Gas Gas-filled balloon will continue to rise until
the weight of displaced air equals the total weight of the balloon
the buoyant force on the balloon equals its weight (which says the same thing)

82. Buoyancy in Gas CHECK YOUR NEIGHBOR
As a balloon rises higher and higher into the atmosphere, its __________.
A. volume decreases
density increases
weight increases
None of the above
D. None of above

83. Buoyancy in Gas CHECK YOUR ANSWER
As a balloon rises higher and higher into the atmosphere, its __________.
A. volume decreases
density increases
weight increases
None of the above
D. None of the above

84. Fluid Flow continuous flow
Volume of fluid that flows past any cross-section of a pipe in a given time is the same as that flowing past any other section of the pipe even if the pipe widens or narrows.
Fluid speeds up when it flows from a wide to narrow pipe.
Motion of fluid follows imaginary streamlines.

85. Bernoulli’s Principle
discovered by Daniel Bernoulli, a 15th century Swiss scientist
states that where the speed of a fluid increases, internal pressure in the fluid decreases
applies to a smooth, steady flow

86. Bernoulli’s Principle
Streamlines
thin lines representing fluid motion
closer together, flow speed is greater and pressure within the fluid is less
wider, flow speed is less and pressure within the fluid is greater

87. Bernoulli’s Principle
Laminar flow
smooth steady flow of constant density fluid
Turbulent flow
flow speed above a critical point becomes chaotic

88. Bernoulli’s Principle
CHECK YOUR NEIGHBOR
The pressure in a stream of water is reduced as the stream speeds up. Can a stream of water from a fire hose actually knock a person off his or her feet?
A. It can’t, as Bernoulli’s principle illustrates.
It can, and is consistent with Bernoulli’s principle.
Bernoulli’s principle works only for laminar flow, which the stream is not.
None of the above
B. It can, and is consistent with Bernoulli’s principle.

89. Bernoulli’s Principle
CHECK YOUR ANSWER
The pressure in a stream of water is reduced as the stream speeds up. Can a stream of water from a fire hose actually knock a person off his or her feet?
A. It can’t, as Bernoulli’s principle illustrates.
It can, and is consistent with Bernoulli’s principle.
Bernoulli’s principle works only for laminar flow, which the stream is not.
None of the above
Explanation:
There’s a difference in the pressure within flowing water and the pressure it can exert when its momentum is changed. The pressure that knocks one off his or her feet is due to the change in the water’s momentum, not the pressure within the water.
B. It can, and is consistent with Bernoulli’s principle.

90. Bernoulli’s Principle
Applications of Bernoulli’s Principle
Blow on the top surface of a paper and the paper rises.
Reason: The pressure of the moving air is less than the atmospheric pressure beneath it.
Convertible car roof puffs upward as air moves over its top surface.
Reason: The pressure of air moving on the top surface is less than the atmospheric pressure inside the car.

91. Bernoulli’s Principle
Wind blowing across a peaked roof can lift the roof off the house.
Reason: Pressure is reduced as wind gains speed as it flows over the roof. The greater pressure inside the house lifts the roof up.
Perfume atomizer
Reason: Air rushes across the open end of the tube when you squeeze the bulb, reducing pressure in the tube. Atmospheric pressure on the liquid below pushes it up into the tube.

92. Bernoulli’s Principle
Trucks passing closely on a highway are drawn to each other.
Reason: Air pressure between the trucks is less than pressure on their outer sides pushing inward.
Risk of passing ships colliding sideways
Reason: Water pressure between the ships is less than pressure on their outer sides pushing inward.

93. Bernoulli’s Principle
CHECK YOUR NEIGHBOR
On a windy day, waves in a lake or the ocean are higher than their average height. What factor in Bernoulli’s principle contributes to the increased height?
A. Reduced pressure pulls water upward.
Pressure builds up over the crests.
Air travels faster over the crests than the troughs.
None of the above
C. Air travels faster over the crests than the troughs.

94. Bernoulli’s Principle
CHECK YOUR ANSWER
On a windy day, waves in a lake or the ocean are higher than their average height. What factor in Bernoulli’s principle contributes to the increased height?
A. Reduced pressure pulls water upward.
Pressure builds up over the crests.
Air travels faster over the crests than the troughs.
None of the above
Explanation:
The troughs of the waves are partially shielded from the wind, so air travels faster over the crests. Pressure there is thus lower than down below in the troughs. The greater pressure in the troughs pushes water into the even higher crests.
C. Air travels faster over the crests than the troughs.