Unit A - Mix and Flow of Matter (Pages 51-79) PDF

Summary

This document covers Unit A: Mix and Flow of Matter, which explores the properties of fluids, including density, viscosity, buoyancy, and compressibility. The document also discusses technologies that utilize these properties, such as pumps, valves, and submarines. The text includes examples and illustrations.

Full Transcript

Plimsoll Line Legend
TF tropical fresh water
A fully loaded cargo ship sails across the
F fresh water
Atlantic Ocean. As it enters the fresh water T tropical salt water
of the St. Lawrence River, it sinks S summer salt water
dangerously low. Why? It sinks because W winter salt water
fresh water is less dense than salt water. WNA winter North Atlantic
The ship floats lower in the less dense
water. The same thing happens when a
ship sails from cold northern water into
warm tropical water. Warm water is less
dense than cold water.
Because of density variations in the
world’s oceans and rivers, all cargo ships
have what is known as a Plimsoll line
painted on their hulls. The Plimsoll line
shows how heavily a ship can be safely
loaded in different water conditions. Look
at Figure 3.11. The marks on the left
indicate where the waterline should be in
fresh water. The marks on the right Figure 3.11 The Plimsoll line indicates how heavily loaded a
indicate where it should be in salt water. ship can be in different densities of water.

Hot Air Balloons
Another transportation technology where buoyancy is important
is in hot air ballooning. As the air in the balloon is heated, it
becomes less dense than the surrounding air. The buoyant force
pushes the balloon up into the air. The balloon stops rising when
the buoyant force equals the force of gravity. That’s the point
when the balloonist stops adding heat to the air in the balloon.

re SEARCH
Airships
Early airships looked something like the Goodyear blimp
that flies over sports events, but they were much larger.
These airships were called zeppelins, after their inventor,
Count Ferdinand von Zeppelin. The Graf Zeppelin airship
was 236 m long and could travel at 129 km/h.
Find out more about early airships. Why did these
balloon-like aircraft have to be so large? Why did the
Hindenburg, shown here, go up in flames?
The Hindenburg

The Properties of Gases and Liquids Can Be Explained by the Particle Model of Matter 51
 CHECK AND REFLECT
1. What units are usually used for measuring the density of solids?
of liquids?
2. Use the particle model of matter to describe what happens to the
density of a substance when it cools.
3. Look at Figure 3.12. Can you spot the mistake in the directions
for this water-play air mattress? Explain your answer.

This air mattress should not be
used by children without adult
supervision.
Do not inflate.
Keep away from sharp objects to
prevent punctures.

Figure 3.12 Question 3. Air mattress warning tag

Y This at Hom A C T I V I T Y

R e
T

SINK OR SWIM
You can make your own model of a diver at home using a plastic pop bottle
with a cap, water, and an eyedropper.

Fill a plastic pop bottle about three-quarters full of water.

Float an eyedropper on the surface of the water.

Use the cap to seal the bottle tightly.

Squeeze the bottle with your hands so the sides go in.

Can you explain what happens?

What would happen if you used a fluid other than water? Try it and see.

52 Unit A: Mix and Flow of Matter
3.4 Compression of Fluids
Another useful property of some fluids is compressibility.
When a force pushes on an object, the object is said to be under
compression. Objects under compression tend to deform in shape.
For example, when you kick a soccer ball, the force of your foot
compresses the ball and temporarily deforms it, as shown in
Figure 3.13. In this example, your foot is actually
compressing the fluid (air) that fills the ball.

Figure 3.13 Your foot
deforms the soccer
ball as you kick it.

info BIT
Compressing Solid Objects
A solid object can be compressed if a great
enough force is applied to it. The photo shows
that the force exerted by the baseball bat on
the baseball compresses and deforms the ball.

The effect of a baseball
bat on a baseball

The Properties of Gases and Liquids Can Be Explained by the Particle Model of Matter 53
Inquiry COMPRESSING FLUIDS
Activity The Question
What happens to air as it is compressed? Does water react in the same way?

Procedure
Materials & Equipment Part 1 Compressing Air
Part 1 1 Attach the latex tubing to the end of the syringe. Place the plunger of the
50-mL syringe syringe three-quarters of the way up the tube. Seal the tubing at the end of
5 cm of latex tubing the syringe with the bulldog clamp.
bulldog clamp 2 Before you press the plunger down, predict how far the plunger will go.
water Record your prediction. Test your prediction.
sink or bowl
3 Press down the plunger and record the change in volume in the syringe.
Part 2 4 Unclamp the tubing, and place the syringe in a sink or bowl of water. Pull up
2 burette clamps the plunger to draw in water until the syringe is filled to the same level as in
modified 50-mL syringe step 1. If you get air in your syringe, turn the syringe upside down so the
with platform
plunger points downward. Allow the air to rise to the top of the syringe. Then
5 cm of latex tubing
gently push the plunger up until all the air has escaped. Add more water if
bulldog clamp
necessary. Clamp the end of the tubing shut.
support stand
4 1-kg masses 5 Before you press the plunger down, predict how far you think the plunger will
water go. Record your prediction. Test your prediction.
empty container 6 Press down the plunger and record the change in volume in the syringe.

Part 2 Compressing Water
7 Use the burette clamps to attach a modified syringe (with platform) to a
support stand, as shown in Figure 3.15.
8 Attach the latex tubing to the end of
the syringe. Pull the plunger to the
50-mL mark. Seal the tubing with
the bulldog clamp.
9 Place a 1-kg mass on the centre of
the platform that is attached to the
syringe. (This applies a 10-N force.)
Measure and record the volume of
air in the syringe.
10 Repeat step 9 by adding another
1-kg mass so that you have a
Figure 3.14 Step 1. The plunger 2-kg mass (a 20-N force).
should be three-quarters of the
11 Repeat step 10 for the following
way up the tube.
masses (forces): 3 kg (30 N) and
4 kg (40 N). Place the masses in the
centre of the platform. Figure 3.15 Step 7. Be sure to follow safe
work procedures. Clamp the syringe
tightly at right angles to the stand.

54 Unit A: Mix and Flow of Matter
12 Remove all the masses.
13 Remove the syringe from the burette clamps and place it in a sink or bowl of
water. Fill the syringe to the 50-mL mark by pulling on the plunger, not the
platform. Remove any air bubbles as before. Reattach the syringe with the
burette clamps. Place an empty container under the syringe. Repeat steps 9,
10, and 11.
14 Clean and return your equipment to the appropriate location.

Collecting Data
Part 1
15 Record your predictions in your notebook.
16 Record the volume in the syringe before and after you push down the
plunger.

Part 2
17 Record your data in a table like the one shown below.

Force Acting on Fluid Volume of Air (mL) Volume of Water (mL)
in Syringe (N)

0
10

Analyzing and Interpreting
18 How did your predictions compare with your results?
19 Which fluid compressed more? Why do you think this happened?
20 How did the force affect the compression of the air and the water?
21 Draw a line graph of the compression of the air and water from Part 2 using a
different colour for each. Put the volume on the vertical axis, and the force on
the horizontal axis.

Forming Conclusions
22 Use the particle model to explain what happened when you compressed the
air and the water. Focus your explanation on the differences in the amount of
space between particles in air and water. Use your observations, and
remember to refer to your graph to support your explanation.

Applying and Connecting
The property of compressibility in fluids is useful to other living things, besides
humans. For example, starfish move by filling their tube feet with water. Figure 3.16 Starfish

The Properties of Gases and Liquids Can Be Explained by the Particle Model of Matter 55
re SEARCH DIFFERENCES IN COMPRESSIBILITY BETWEEN GASES AND LIQUIDS

One of the properties of fluids is that gases can be compressed
Engine Compression much more than liquids can. Think about squeezing a sealed plastic
Find out why
bottle when it’s full of juice and then when it’s empty. How much
compression is
more can you compress it when it’s empty than when it’s full? The
important in a car’s
particle model can explain this situation. Figure 3.17 shows that
engine.
there is much more space between particles in the gas than between
those in the liquid.

Figure 3.17 There is much more space between particles in a gas than there is
between particles in a liquid.

As a result, when a force is applied to the particles, much more
compression takes place in the gas than in the liquid. The gas
particles have more space to move. In fact, very little compression
occurs in liquids. Materials in a liquid state are said to be
incompressible; that is, they cannot be compressed easily. This
property of liquids is very useful. Can you think of any situations
where it would be used?

CHECK AND REFLECT
1. Use the particle model to explain the differences in
compressibility between liquids and gases.
2. Use your explanation in question 1 to identify which material in
each pair below would compress more than the other. Provide a
brief reason for each answer.
a) a helium balloon or a water balloon
b) a solid rubber bicycle tire and an inflated mountain bike tire
c) plastic bubble-wrap or a liquid-filled baby’s teething ring
d) a golf ball or a soccer ball

56 Unit A: Mix and Flow of Matter
3.5 Pressure in Fluids—Pascal’s Law
Fluids can be very useful in helping us perform tasks because of the info BIT
way they transmit pressure. For example, you may already know
something about hydraulics and pneumatics, where fluids are used Examples of Pressure
in devices. In this subsection, you’ll learn why this property makes The average air
fluids so useful. pressure at sea level
An important part of understanding how to use fluids in devices is 101.3 kPa
is knowing the relationship between force, area, and pressure. (kilopascals).
Pressure is the amount of force applied to a given area. It is The jaws of an ant
measured in pascals (Pa). A pascal equals the force of 1 N (newton) exert a pressure of
over an area of 1 m2 (1 Pa = ——1 N ). The more force you can apply to 0.005 kPa.
1 m2
a given area, the greater the pressure. You can write this A ballet dancer
relationship as an equation: p = F/A, where p is pressure, F is force, standing on the toes
and A is area. of one foot exerts a
pressure of 2500 kPa
Here is an example of how to calculate pressure. You have a
on the floor.
force of 10 N on an area of 2 m2. What would the pressure be?

Force (F ) 10 N 5 N
Pressure (p) = –––––––– = ––––2 = ––– = 5 Pa
Area (A) 2m m2
Look at the examples of pressure measurements in the infoBIT
on this page. They are all in kilopascals (1 kPa = 1000 Pa).
Scientists use kilopascals because 1 Pa is a very small amount of
pressure. It’s about the amount of pressure exerted on your desk by
a small sheet of paper lying on it. Note that pressure can also be
measured in newtons per square centimetre (N/cm2).

Blaise Pascal Investigates
In the mid-1600s, the French
mathematician Blaise Pascal was curious
about how pressure is exerted in a fluid.
In one of his first experiments, he
investigated the relationship between
water pressure and depth. Look at Figure
3.18, showing water flowing out of two
holes at the same level in a can. Working
with a partner, develop an explanation for
what you observe. Use the following
words in your explanation: pressure, sides
of the can, force, equal, and depth. Be
prepared to share your explanation with
your class. Figure 3.18 Why does the water flow out of the can in this way?

The Properties of Gases and Liquids Can Be Explained by the Particle Model of Matter 57
 PRESSURE AND DEPTH
From Figure 3.18, you and your class may have determined that the
pressure of the water on the sides of the can was equal at the same
depth. You could infer this because the water that came out of the
holes travelled the same distance outward before hitting the ground.
This observation leads to another question: How does pressure
change as the depth of the water changes? What do you think
would happen if you put holes in the can at different depths?

THE GREATER THE DEPTH, THE GREATER THE PRESSURE
In the introduction to this subsection, you saw that pressure forced
Figure 3.19 The water
exerts pressure in all
water out of holes in a container. The water was exerting pressure
directions in the container. on the walls of the container. The weight of water in the upper part
of the container also pressed down on the water in the lower part of
the container. The more water above a hole, the greater the
pressure, and the farther water will flow out of the container. So,
the greater the depth of water, the greater the pressure at that point.

PASCAL’S LAW
Pascal continued his investigations into pressure by studying
enclosed fluids. He wondered what would happen if a force was
applied to a fluid in a closed system. Through experimentation, he
found that the force created pressure that was transmitted equally
in all directions throughout the fluid. He developed a law to
describe his observations. Pascal’s law states that an enclosed fluid
transmits pressure equally in all directions. The examples of
applications of Pascal’s law below will help to explain it further.

HYDRAULIC DEVICES
Pascal’s discovery of this law led to the invention of many different
types of hydraulic and pneumatic devices. Hydraulic systems use a
liquid as the enclosed fluid. Pneumatic systems use air. Figure 3.20
shows a hydraulic device that is used for lifting cars. You may have
noticed these in car repair garages. Such a device uses two pistons
of different sizes to create pressure and to lift the car. A piston is a
disk that moves inside a cylinder. The small piston is the input
piston, which pushes down on the liquid to create pressure. This
pressure is then transmitted through the liquid where it pushes up
on the large piston, which is the output piston.
Recall that pressure equals force divided by area (p=F/A), and
look at Figure 3.20. You can see that the output piston has a much
larger area than the input piston does, but the pressure is the same
everywhere in the system. So, because p=F/A, the force of the larger
piston is greater than the force of the smaller piston.

58 Unit A: Mix and Flow of Matter
 The area of the output piston in this example is 16 times larger
than the area of the input piston. The result is an output force 16
times greater than the input force—a force strong enough to lift a
car! One of the benefits of a hydraulic system is that it can multiply
force. However, to move the large piston, the small piston must
move much farther that the large piston does. You will learn more
about hydraulic systems in Unit D: Mechanical Systems.

small
movable
Figure 3.20 A car lift or
piston
large movable piston hoist. The arrows in the
liquid indicate the pressure
closed transmitted throughout the
container system. Hoists are used in
repair garages so that
mechanics can work under
liquid cars more easily.

PNEUMATIC DEVICES
Pneumatic devices use compressed air to do tasks. Dentists’ drills,
jack hammers, paint sprayers, and air brakes on trucks are all
examples of pneumatic devices.
Reasonable cost and safety are two advantages of pneumatic
systems. Compressed air is cheap and safe, as the devices do not
create sparks within the system. This can be important if you are
working in a mine where a spark could cause an explosion.
Pneumatic devices are also free of electrical hazards, which is one
reason that dentists’ drills are pneumatic.

Figure 3.21 Compressed
air drives the mechanism
that makes the dentist’s
drill spin.

The Properties of Gases and Liquids Can Be Explained by the Particle Model of Matter 59
 re SEARCH MAINTAINING THE PRESSURE
For a pneumatic or hydraulic system to function properly, the entire
Ultrahigh-Pressure
system must be completely sealed. Even the smallest hole or leak
Water Systems
can cause the system to fail. For example, cars have hydraulic
An ultrahigh-pressure
water system forces brakes. If there is a leak in the hydraulic line, the brakes can fail.
water out of a hose at Pneumatic bus doors also depend on a sealed system, so that the
275 000 kPa of pressure. door can open and close. A leak in the system allows air to escape.
This water jet can be This loss of pressure means that the system can’t generate enough
used for cleaning, force to close the door if it’s already open, or to open the door if it’s
blasting, cutting, and already closed!
processing materials.
Using the library or the
Internet, research
applications of
ultrahigh-pressure
water systems.

Figure 3.22 Pneumatic
systems are used for bus
doors and for brakes in
large vehicles like buses
and trucks.

CHECK AND REFLECT
1. Describe how pressure is transferred in a fluid.
2. If 10 N of force is applied to an area of 1 m2, what is the
pressure?
3. What is the difference between a hydraulic and a pneumatic
system?
4. A hydraulic lift has 1000 N applied to an input piston that has
an area of 30 cm2.
a) What is the pressure exerted on the liquid by the input
piston?
b) If the force were doubled, what would be the pressure?
c) If the area were reduced to 15 cm2, what would be the
pressure?

60 Unit A: Mix and Flow of Matter
 SECTION REVIEW
Assess Your Learning
1. What is viscosity? Why is it an important property?
2. Use the particle model to describe why ketchup is more viscous
than liquid dish soap.
3. How does temperature affect the viscosity of a fluid?
4. What does density measure?
5. Describe how you find the density of an object.
6. a) What is the density of a shampoo if 13.2 g of the shampoo
fills a 5-mL container?
b) What is the density of vegetable oil if 50 g of the oil has a
volume of 8 mL?
c) What is the density of gasoline if 90 mL of it has a mass of
62 g?
d) If you had 50 mL of each of these substances, which one
would have the least mass?
7. How does the particle model of matter help you explain why
cold water is denser than hot water?
8. Why does a liquid compress much less than a gas does?
9. Describe Pascal’s law and give one example of its application.
10. A full juice can has a hole at the top and another hole near the
bottom. How will the juice flow out of the two holes? Why is
there a difference?
11. How does a car lift work? What problems does a car lift solve?

Focus SCIENCE AND TECHNOLOGY
On
Any scientific investigation or technological development leads to
new questions and problems. Think back to the information you
learned and the activities you did in this section.
1. After learning about viscosity, what two new questions do you
have about this property of fluids?
2. Identify one problem you encountered in this section and
describe how you solved it.
3. At the end of the unit, you will do a project to design a soft
drink with a grape floating in it. What did you learn about
density that would help you float the grape?

The Properties of Gases and Liquids Can Be Explained by the Particle Model of Matter 61
 4.0 Many technologies are based on
the properties of fluids.

Key Concepts
In this section, you will learn
about the following key
concepts:
properties of fluids
fluid technology applications

Learning Outcomes
When you have completed this
section, you will be able to:
describe examples of
technologies based on
solubility
describe examples of
technologies based on flow
rates and moving fluids
explain how to design and
construct a working model
of a fluid-using device

In this unit, you have had an opportunity to learn about the
properties of fluids. Now it is time to look at some applications of
this knowledge. Applied scientific knowledge results in new
technologies. Technology includes devices, systems, and processes
that meet people’s needs or wants. In this section, you will explore
technologies that meet needs to keep things clean, cure “the
bends,” move fluids, and explore uncharted waters where humans
have never gone before.

62 For Web links relating to 4.0, visit www.pearsoned.ca/scienceinaction
4.1 Technologies Based on Solubility
While you are eating a hamburger, a glob of mustard falls on your
favourite jeans. This could be a disaster but you’re sure that the
laundry detergent will get the stain out. What is it about detergents
that give them their special cleaning power?
A detergent is a substance that can remove dirt from fabric.
Most detergents are liquids or powders that can dissolve in water.
Detergents contain a cleaning agent called a surfactant. Surfactants
are particles that attach themselves to dirt and oil particles,
separating them from fabric or other material. Figure 4.1 illustrates
this process.

How Detergent Works

Dirt and grease on fabric

The mixture of water, detergent,
and clothes is agitated in the washing
machine. Dirt breaks off from the
clothes.

Surfactants in the detergent surround
the dirt particles so they can’t re-attach
to clothes.

Figure 4.1 Detergents use surfactants to carry away dirt.

In the past, manufacturers added chemicals called phosphates
to detergents. Phosphates made detergents work better in hard
water. However, the phosphates damaged the environment by
polluting the water. Today, most detergents do not include
phosphates.

info BIT
Ingredients in a Typical Laundry Detergent
Ingredient What It Does Ingredient What It Does

surfactant cleans clothes builder softens water to help surfactant clean
filler stops detergent from clumping corrosion inhibitor prevents washer from rusting
suspension agent stops dirt from re-attaching to material enzyme removes protein stains
bleach removes stains optical whitener adds brightness
fragrance adds scent colouring agent gives detergent colour

Many Technologies Are Based on the Properties of Fluids 63
Inquiry C L E A N I N G S O LV E N T S
Activity The Question
Which solvent is best for removing stains from clothing?

The Hypothesis
Materials & Equipment Write a hypothesis that predicts which solvent in this inquiry activity works best
3 250-mL beakers at removing stains.
water (at room
temperature)
Procedure
rubbing alcohol (at room 1 Pour 50 mL of water into one beaker, 50 mL of rubbing alcohol into another
temperature) beaker, and 50 mL of vinegar into a third beaker. Label the beakers.
vinegar (at room 2 Predict which solvent will be best for removing stains.
temperature) 3 Mark each piece of fabric with mud, lipstick, and chocolate.
graduated cylinder
4 Place one piece of soiled fabric into each beaker. Swirl the fabric around in
3 identical pieces of fabric
mud
each solution using the forceps. Leave for at least 10 min. Look at the stains.
lipstick 5 Add some laundry detergent to the beaker containing water. Use the forceps
chocolate to swirl the fabric around in the solution. Leave for at least 10 min. Look at
laundry detergent the stains.
pair of forceps or tweezers
Collecting Data
6 Make a chart of your observations.

Analyzing and Interpreting
7 Did the mud dissolve in each solvent? Explain.
8 Did the lipstick dissolve in each solvent? Explain.
9 Did the chocolate dissolve in each solvent? Explain.
10 Did the detergent help the water dissolve the stains?

Forming Conclusions
11 Describe the results from your investigation. Conclude which solvent did the
best cleaning job for each type of stain and which did the worst job. Support
your conclusions with your data. Also, include one new thing you learned in
this activity that you didn’t know before.

Figure 4.2 Step 4. Swirl the Applying and Connecting
fabric around in each Canadian researchers have been at the forefront of developing environmentally
solution using the forceps.
friendly inventions. Ragui Ghali of Ontario invented Spil-Kleen. Made from old
phone books, Spil-Kleen soaks up water, and cleans up oil spills.

Extending
Make a cleaner by mixing 50 mL of baking soda in 4 L of water and adding
125 mL of vinegar. Create a fair test to compare the cleaning ability of your
home-made cleaner with that of store-bought brands.

64 Unit A: Mix and Flow of Matter
DIVING AND DECOMPRESSION
People are able to dive deep below the surface of oceans and lakes
because of an invention that uses fluids. SCUBA stands for Self-
Contained Underwater Breathing Apparatus. It consists of air tanks
and regulators to maintain the flow of air. Another fluid-based
technology helps us deal with the stress on our bodies of deep
dives.
At greater water pressures, nitrogen gas dissolves in our blood
and tissues at a much higher concentration than normal. If a diver
ascends slowly to the surface, the extra gas leaves the body
gradually as the water pressure decreases.
A problem arises when the diver ascends too
quickly, so that the pressure decreases rapidly.
Decompression sickness, called “the bends,” can
result. The sudden change in pressure causes nitrogen
gas to bubble out of the blood and tissues. These
bubbles can collect in other body parts and cause
considerable pain. Death can occur if the condition is
left untreated.
One treatment for “the bends” is to place the
affected diver in a special chamber. This chamber
increases the pressure surrounding the diver’s body.
The greater pressure forces the gas bubbles to re-
dissolve back into the blood and tissues. By very
slowly decreasing the pressure back to normal, the gas
Figure 4.3 This person is in a hyperbaric
slowly leaves the body. chamber to cure a case of “the bends.”
Hyperbaric means high pressure.

CHECK AND REFLECT
1. Describe one new thing you learned about cleaners. re SEARCH
2. How does a detergent remove a stain?
Dry Cleaning
3. The following statements were taken from an advertisement for What is dry cleaning?
laundry detergents. What ingredients are being emphasized? Find out how clothes
a) “Now brighter and whiter than ever.” are dry-cleaned and
b) “Cleans your washing machine as it cleans your clothes.” what happens to the
c) “Removes the toughest stains.” chemicals after they
d) “Now in new ocean mist scent.” are used.
4. What do divers need to know about solubility?

Many Technologies Are Based on the Properties of Fluids 65
 4.2 Technologies Based on Flow Rates
and Moving Fluids
Imagine having to move a fluid from one place to another. Maybe
you are putting air in a basketball. Or maybe you want to filter the
water in your aquarium. What would you use?
For both examples, you probably thought that a pump would be
the solution. What exactly is a pump and how does it work? A
pump is a device that moves a fluid through or into something. To
fill up your basketball, you use a pump to force air into the ball.
Your aquarium pump moves water through a filter to clean it and
add air. Pumps also exist in nature. The most important one to you
is your heart—it pumps blood through your body.

Two Types of Pumps—Diaphragm and Archimedes Screw

flexible
piston
diaphragm
piston

fluid
fluid out
in

Upward stroke of Downward stroke forces
piston sucks liquid in. liquid out.

Figure 4.4 Diaphragm pumps are used for both liquids and gases, such as the air pumped into this aquarium.

low
terf
wa

Figure 4.5 The Archimedes screw is a pump supposedly invented by Archimedes to remove water
from the hold of a ship. Here it is used as a sand washer on a construction site.

66 Unit A: Mix and Flow of Matter
THE BICYCLE PUMP info BIT
There are many different kinds of pumps, but one of the most
Oil Sands Production
common is the bicycle pump. This kind of pump has a piston that
The oil in the oil sands
moves up and down in a cylinder. When you pull up the piston, air
is a thick, viscous
fills the cylinder. By pushing down on the piston, you apply a force substance called
to the air in the cylinder. This compresses the air. The pressure of bitumen. One method
the air in the pump therefore increases. If the opening at the bottom of extracting bitumen
of the cylinder is connected to an area of lower pressure, the air uses two wells. Steam
will move to that area. For example, the area of lower pressure is pumped down one
could be a flat bicycle tire or an uninflated soccer ball. well to heat the
bitumen in place. The
heated bitumen now
has a lower viscosity,
piston
so it flows into the
other well. It is
pumped out of there
and sent for
processing.

low
pressure

air
high
pressure

Figure 4.6 When force is applied to the air in the
cylinder, the pressure increases.

PIPELINE PIGS
The oil and natural gas that we depend on
for heat and transportation move across the
country in bulk through pipelines. Pumps
push these fluids along at a steady rate. In
large natural gas pipelines, the pressure of
this flow is used to help keep the pipeline
clean to ensure a clean fuel supply. A
computerized unit called a “pig” is placed
in the pipeline and pushed through it by
the moving gas. The “pig” cleans the pipe
with brushes as it moves through. At the
Figure 4.7 A pipeline “pig” relies on the flow of the fluid
same time, the “pig’s” sensors check the
to move it through the pipeline.
pipe and record its condition so any
necessary repairs can be made.

Many Technologies Are Based on the Properties of Fluids 67
re SEARCH VALVES
Valves are an important part of any system for moving fluids. They
Artificial Hearts
are devices to control or regulate the amount of flow, like the valves
Doctors and engineers
in your bathroom taps. Turning your tap one way allows water to
have been working
for many years to flow out. Turning it the other way closes off the flow of water.
develop artificial Valves can also be used to control the level of fluid in a container,
hearts that will help like the valve in the toilet tank. The float in the toilet tank is
save lives. Find out connected to a valve that closes off the flow of water when the
how valves and water reaches the right level. That’s why your toilet tank doesn’t
pumps are being overflow when you flush the toilet. Two other kinds of valves are
used in this shown in Figures 4.8 and 4.9.
technology.

Figure 4.8 A ball valve works by Figure 4.9 This type of valve allows you to
turning. In one direction, it allows water inflate a ball, but also keeps air from leaking
to flow through. If you turn it in another out. To open the valve, you insert a hollow
direction, it stops the flow. This ball pin. You inflate the ball by pumping air
valve is in a hose. through the pin. You deflate the ball by
allowing air to escape through the pin.

CHECK AND REFLECT
1. List and describe the different
types of pumps you have read
about.
2. Look at the drawing of the hand
pump in Figure 4.10. How does
the particle model help to explain
how a hand pump operates?
3. Identify the different functions of
valves. Give one example of a
valve application that has not
already been mentioned. Figure 4.10 Question 2. A hand pump

68 Unit A: Mix and Flow of Matter
4.3 Designing a Working Model of a
Fluid-Using Device
How could an understanding of the properties of fluids help you go info BIT
to the deepest spot on the planet? This spot is about 11 000 m
below sea level in the Marianas Trench in the Pacific Ocean, about Changing Buoyancy
330 km south of Guam. Humans cannot dive this deep by Naturally
themselves because the pressure is too great. To go this deep, you Most fish use a swim
need an underwater ship called a bathyscaph. The name comes bladder to change
from the Greek words bathos for “deep” and scaphos for “ship.” their buoyancy. This is
The Swiss scientist Auguste Piccard invented the bathyscaph and a gas-filled sac found
called his vessel the Trieste. just under the
Since the Trieste, many different types of submersible backbone. Dissolved
exploration ships have been designed and built. One example is the gases in the fish’s
Canadian submersible called the Remotely Operated Platform for blood move into the
Ocean Science (ROPOS) shown in Figure 4.12. sac to give it greater
buoyancy. The swim
bladder empties when
the fish wants to dive
deeper.

Figure 4.11 The bathyscaph
Trieste made it to the bottom of
the Marianas Trench in 1960. A
bathyscaph consists of a large
float with a metal sphere
underneath. The sphere is where
the people sit.

Figure 4.12 This submersible robot
ROPOS is equipped with two robotic
arms and can dive to 5000 m.

Many Technologies Are Based on the Properties of Fluids 69
Problem
Solving D I V I N G D E E P LY
Activity Recognize a Need
At the cottage, your cousin drops a precious gold necklace into the lake. It
disappears into about 5 m of murky water.

The Problem
Create a model of a bathyscaph that could carry a battery-operated video camera
to the bottom of the lake to search for the necklace.

Criteria for Success
For your model to be successful, it must meet the following criteria:
solve the problem described above
be designed first on paper
be built and tested as a prototype
be made of common materials
be controlled from the surface so it can travel to the bottom and back to the
surface by a transfer of fluid from or to it
be watertight
be usable more than once

Brainstorm Ideas
1 You will be working in teams. As a team, brainstorm possible solutions to the
problem. Once you have several solutions, choose the one you think will work
the best to meet the above criteria.

Build a Prototype
2 Create a plan for how you will build your bathyscaph. Include a diagram of
Figure 4.13 Step 3. Assemble the bathyscaph and a list of materials you require. Show your plan to your
your materials and build your teacher for approval.
prototype. 3 Assemble your materials and build your prototype. Remember that you may
need to modify or change your design as you build your prototype. Make
sure to note any changes you make to your original design.

Test and Evaluate
4 Once you have built your prototype, test it to see if it meets the criteria. After
your test, you may need to make some modifications or changes to the
bathyscaph and retest it.

Communicate
5 What do you have to do to make the bathyscaph go up and down in the
water?
6 Would this model work in the lake or would you have to make further
modifications? What would they be?

70 Unit A: Mix and Flow of Matter
HOW A SUBMARINE WORKS
How does a submarine move up and down in the water? A
submarine moves through three stages in the water: floating on the
surface, diving, and re-surfacing. Figure 4.14 shows how a
submarine operates. Notice that the submarine has air tanks called
ballast tanks between the inner and outer hulls of the submarine.
The submarine also carries compressed air in tanks to help it
re-surface.

air
compressed air

air

air

air
air

water water water
water

Figure 4.14a) On the Surface. Figure 4.14b) Diving. To dive, the Figure 4.14c) Re-surfacing. To
When the submarine is on the submarine releases air from the ballast surface, compressed air is forced
surface, its ballast tanks are full of tanks through valves on the top of the into the ballast tanks through the
air. The average density of the tanks. Other valves at the bottom of the valves at the top. This forces the
submarine is less dense than the tanks open and allow seawater to enter. seawater out of the bottom valves.
density of the water, and it floats. The density of the submarine with seawater The density of the submarine with air
in the tanks becomes greater than the in the tanks becomes less than the
density of water outside, so the submarine density of the water, so the
begins to sink. submarine rises to the surface.

CHECK AND REFLECT
1. What is a bathyscaph?
2. What is the difference between a bathyscaph and a submarine?
Hint: Read the caption for Figure 4.11.
3. Describe how a submarine can stay underwater and then move
up to the surface.

Many Technologies Are Based on the Properties of Fluids 71
 Experiment DESIGN AND BUILD A HYDRAULIC OR
ON YOUR OWN PNEUMATIC ELEVATOR

Before You Start... earlier in this unit, and hydraulic cherry pickers on
One of the most common ways to move people or repair vehicles.
things up and down is an elevator. Primitive elevators Now you’ll have an opportunity to design your
existed as early as the 3rd century B.C., but elevators own hydraulic or pneumatic elevator.
were put into buildings only in the 1800s. These early
The Question
devices were powered by steam engines or operated
with a hydraulic system. Their use was limited What would you have to do to design and build a
because of safety concerns. The main concern was hydraulic or pneumatic elevator that could lift a golf
that the rope or cable lifting the elevator could snap. ball 30 cm?
This changed when an inventor named Elisha Graves
Design and Conduct Your Experiment
Otis developed a “safety elevator” in 1852.
1 Working by yourself or in a small group, generate
By the late 1800s, motors began to replace
possible ideas on how you could design your
hydraulic systems in elevators. Today, the limitations
device.
of an elevator are more human than technological.
2 Create a plan for how you will build your device.
Some people feel sick if an elevator moves too fast.
Include a detailed sketch of your device and a list
Other types of elevators or lifts include hydraulic
of equipment you will need. Show your plan to
ladders, such as those on firetrucks, which you saw
your teacher for approval.
3 Build your device. Be prepared to demonstrate
how your device works to your class.
4 Compare your device with others in the class.
How successful were the other devices?

Figure 4.16
A cherry picker
makes it easier for
workers to do tasks
in high places where
they need to be able
to use both hands.

Figure 4.15 Elisha Graves Otis and his
“safety elevator”

72 Unit A: Mix and Flow of Matter
 SECTION REVIEW
Assess Your Learning
1. How can a detergent clean grease off clothes?
2. If you had a beaker of water, a beaker of rubbing alcohol, and a
beaker of vinegar, describe how you would construct a fair test
to determine which liquid was the best cleaner.
3. What is a pipeline “pig,” and how does it move?
4. Describe a technology that uses pressure to change the solubility
of gas.
5. Describe three uses of pumps.
6. What are two major uses of valves?
7. How does a bathyscaph work?
8. Identify one industry that uses the properties of fluids.

Focus SCIENCE AND TECHNOLOGY
On
Technological problems often lend themselves to more than one
solution. These solutions may involve different designs, materials,
and processes. Think back to what you learned in this section.
1. What examples did you encounter of multiple solutions to a
problem?
2. Was one solution better than the others?
3. How did you know when you had a solution that would work
in your own activities?

Many Technologies Are Based on the Properties of Fluids 73
 S C I E N C E W O R L D

C

y
a
se d
S t u

The Alberta Oil Sands Deposits
The Issue The oil sands contain an estimated 1.7 trillion
The oil sands have important benefits and potential barrels of oil—more oil than all the world’s known oil
costs to everyone living in Alberta. What do you think reserves combined. However, getting the oil out of
these benefits and costs are? Read the background the ground and refining it have not been easy.
information below and use the “Go Further”
suggestions in the next column to find out more.
Petroleum was once called “black gold” because
of both its dark colour and its high value. It made its
finders rich because of its importance as a source of
energy. Today, petroleum products flow into homes
as heating oil, into cars and trucks as gasoline and
diesel fuel, and onto roads as asphalt. Petroleum is
also used to make plastics.
The first commercial oil wells were developed in
the 1850s. Since then, people have been looking for
and finding this valuable fluid all over the world.
Only about 18% of the oil sands within 50 m of the surface can
Alberta has been a petroleum producer since the
be recovered with today’s technology. Even so, almost 20% of
1940s. It is also home to the largest oil sands Canada’s oil supply now comes from these sands.
deposits in the world.
Go Further
Fort Chipewyan Now it’s your turn. Look into the following resources
r
ve
to help you form your opinion:
Ri
a ce

Athabasca
Pe Look on the Web: Check out oil sands or synthetic
Peace River Fort
McMurray
Wabasca
oil on the Internet.
r
sca
Ri v e Oil sands Ask the Experts: Try to find an expert, such as a
ba

deposits in petrochemical engineer or an environmental impact
Atha

Edmonton
Alberta. The officer.
largest deposits
Calgary
are in the Look It Up in Newspapers and Magazines: Look for
0
100
200
300
400
500
Athabasca articles about the Alberta oil sands, synthetic oil, or
region. the environmental impact of the oil sands.

The oil sands deposits are unique because they
are a mechanical mixture. The sand particles are In Your Opinion
coated with a thick, tar-like substance called bitumen What are the benefits of developing the oil sands?
and small amounts of water. Unfortunately for the oil Based on the information you have, what do you
industry, bitumen isn’t useful for anything except think should be done with the oil sands?
paving roads. In the early 1900s, some Edmonton Which do you think is more important—the
streets were paved with oil sands. benefits or the costs?

74 Unit A: Mix and Flow of Matter
 U NIT SUMMARY: MIX AND FLOW OF M AT T E R
Key Concepts Section Summaries

1.0 1.0 Fluids are used in technological devices and everyday materials.

WHMIS symbols An understanding of the WHMIS symbols and safety procedures in your science class
properties of fluids is very important. Unsafe behaviour is dangerous to both you and your classmates.
Fluids make it easier to transport, process, and use different kinds of materials. Slurry
technology is an example of how fluids can be used to transport other materials. Glass
and steel are examples of the use of fluids as a stage in the production process of
materials. Toothpaste is an example of the use of fluids to make using other materials
easier.
Fluids have properties such as viscosity, density, buoyancy, and compressibility that
make them useful for meeting human needs.

2.0 2.0 The properties of mixtures and fluids can be explained by the particle model
of matter.
pure substances, mixtures,
Matter can be divided into pure substances and mixtures. Mixtures can further be
and solutions
divided into mechanical mixtures and solutions.
solute and solvent
concentration Solutions are made with a solute and a solvent. The more solute in the solvent, the
solubility and saturation more concentrated the solution. Concentration can be calculated in grams per millilitre
points (g/mL). The solubility of a solute in a solvent depends on the temperature of the
particle model of matter solution, the type of solute, and the type of solvent.
The particle model of matter provides a model for describing how particles behave in
the three states of matter and in mixtures.

3.0 3.0 The properties of gases and liquids can be explained by the particle model
of matter.
properties of fluids
Viscosity is a fluid’s internal resistance or friction that keeps it from flowing. As the
mass, volume, density
temperature increases in a liquid, the viscosity decreases.
viscosity and flow rate
buoyancy Density is the amount of mass in a given volume. It is calculated by dividing the mass
of a substance by its volume. The density of a substance increases as its temperature
decreases. Most substances have a greater density in their solid state than in their
liquid and gas states. The particle model of matter describes particles in a solid and
liquid being packed closer together than those in a gas. A gas has more space between
particles.
Less dense objects float on more dense substances. An object floats because the
buoyant force of the fluid acting on it is greater than the force of gravity acting on it.
Gases are compressible, but liquids are almost incompressible. Pressure is calculated
by dividing the force exerted by the area over which the force is applied. Pascal’s law
states that when a force is applied to a fluid, the pressure is transmitted equally
throughout the fluid.

4.0 4.0 Many technologies are based on the properties of fluids.

properties of fluids Many different technologies are based on the properties of fluids. Cleaners and
fluid technology cleaning solvents work because of the different solubilities of substances. Pumps move
applications fluids from one place to another. Valves control the flow of fluids. Hydraulic and
pneumatic systems use fluids to move objects and devices such as submarines.

Unit Summary 75
PROJECT

CREATING
DRINKIT
Getting Started
In this unit, you have developed
a variety of skills and an
understanding of the properties
of mixtures and fluids. You
learned how to make solutions,
calculate density, and describe
buoyancy. You will now use
these skills and this knowledge
to design a new drink. The
e-mail to the right contains the Steps to Success
information you need to get 1 Work with your group to design a procedure for completing your
started on your project. assigned task. After you design your procedure, show it to your
teacher for approval.
Your Goal
2 Collect the equipment you need and carry out your plan.
Your goal is to design and carry
3 Make modifications to your plan as necessary. Write down any
out a procedure that will allow
changes to your plan as you work through it.
you to determine the density of
a sugar solution that can 4 Record the tests you made and your observations of the results.
suspend a grape. 5 Verify your results by making a fresh solution based on the results
you recorded.
What You Need to Know
You will prepare a report to the How Did It Go?
president, F. Izzy, about your 6 Describe the procedure you used when you were trying to
procedure and what you determine the best sugar solution to use. Did you follow a specific
discovered. Your report should procedure or did you just keep trying until you found the answer?
include the following: 7 How did you determine the point where you had the appropriate
an outline of the procedure solution concentration?
you developed and any 8 Could you have improved on your method of finding the
modifications you made appropriate solution concentration? Suggest changes you would
the data you make if you were to repeat this activity.
collected during 9 In any investigation, errors result. For example, after you
Caution!
your investigation determined the mass of sugar to add, some of the sugar may have
Remember
the results of your spilled out before it was added to the beaker. What possible
not to taste
investigation sources of error could have occurred in this activity? Why is it
anything in
recommendations important to identify these sources of error when reporting your
the lab.
for further work results?

76 Unit A: Mix and Flow of Matter
UNIT REVIEW: MIX AND FLOW OF MATTER
Unit Vocabulary 2.0

1. Create a mind map that illustrates your 6. What is the difference between a pure
understanding of the following terms. substance, a mechanical mixture, and a
Use the word fluid as your starting word. solution? Give an example of each.
pure substance 7. a) What is meant by the concentration
mechanical mixture of a solution?
solution b) What units are usually used to
solute measure concentration?
solvent
8. What is the difference between a solute
concentration
and a solvent?
solubility
viscosity 9. What factors affect the rate of
density dissolving?
pressure 10. How does the particle model of matter
hydraulic explain the following statement? If you
pneumatic combine 25 mL of water with 25 mL of
rubbing alcohol, the total volume is only
49 mL.
Check Your Knowledge

1.0 3.0

2. Identify the WHMIS symbols listed 11. How does the particle model explain
below and explain what each one viscosity?
means.
12. What is the density of the following
substances?

Substance Mass (g) Volume (mL) Density
vegetable oil 92 100
iron 39 5
3. What should you do if a corrosive
gold 326 20
chemical spills on you?
4. Describe an example of a material being
prepared as a fluid to make it easier to 13. Why is hot water less dense than cold
transport or use. water?

5. What are some important properties of 14. Describe Pascal’s law, and give one
fluids? Give an example of a technology example of a device that uses this law to
that uses each property. function.

Unit Review 77
UNIT REVIEW: MIX AND FLOW OF MATTER

15. What is the pressure exerted on the 22. You have two samples of the same
inside of a can if the surface area of the liquid. One is at 50°C and one is at 30°C.
can is 0.2 m2 and the force is 10 N? a) What will happen if you pour the
same amount of each liquid down a
ramp? Which flow rate would be
4.0 faster? Use the particle model to
explain your answer.
16. Describe a technology that is based on b) If you poured the same amount of
the solubility of substances. this liquid at 70°C down the ramp,
17. Describe one example of how a pump what would happen?
moves a fluid from one place to another. 23. Some medicines are more effective if
18. How can a hydraulic system be used to they dissolve slowly. How would you
transfer a force or control a motion? design a pill that would take longer to
dissolve?
24. On the coast of British Columbia, a
Connect Your Understanding fishing boat loaded with fish sank when
19. When you open a can of cold soda pop, it entered the Fraser River from the
you hear a small noise. When you open Strait of Georgia. The strait is part of the
a can of warm soda pop, the noise is Pacific Ocean. Why do you think this
much louder. What does this tell you happened?
about the relationship between the 25. How can a 2000-kg vehicle be lifted with
amount of carbon dioxide dissolved in a small force?
the soda pop and the temperature of the
soda pop?
20. Which solution is more concentrated: Practise Your Skills
Solution A with 50 g of substance in 26. Plan an experiment that would test the
200 mL of water or Solution B with 12 g compressibility of three different fluids.
of the same substance in 40 mL of a) What materials would you need?
water? Explain your answer. Calculate b) What procedure would you use?
the concentration of each solution in c) What variables would you need to
g/100 mL. control?
21. The solubility of a substance at 20°C is
40 g/100 mL of water. A solution has
30 g of this substance dissolved in
100 mL of water at 20°C. Is this solution
saturated or unsaturated?

78 Unit A: Mix and Flow of Matter
27. A student dropped pennies one at a time 31. Why do you think the environment
into a known volume of water and should be considered when people use
measured the volume displaced. The fluid technologies?
table below shows the results.

Mass (g) Volume (mL)
Focus SCIENCE AND TECHNOLOGY
17 2 On
35 4
52 6 In this unit, you have investigated science
70 8
and technology related to fluids and
mixtures. Consider the following questions.
88 10
32. Reread the three questions on page 7
a) What is the density of a copper about the role of the properties of fluids
penny? in science and technology. Use a creative
b) Graph this data with mass on the way to demonstrate your understanding
vertical axis and volume on the of one of these questions.
horizontal axis. Find the slope of the 33. What examples demonstrated how fluid
line. How does this slope compare technology could provide solutions to a
with the density of pure copper at practical problem?
8.96?
34. Describe a situation where a
technological development involved trial
and error and the use of knowledge from
Self Assessment other scientific fields.
Think back to the work you did during this 35. Describe the process involved in
unit. designing a device to perform a specific
28. Describe one situation where you task. Was this a set step-by-step process
observed the contributions of science or did it require changes as you
and technology to the understanding of developed the device?
mixtures and fluids. 36. Sometimes technology developers want
29. Give an example of one person’s to design a technology that works well
contribution to the science and in certain locations. Describe a situation
technology of fluids and mixtures that where an understanding of local
you found interesting. conditions made this possible.
30. What is one idea or issue covered in this
unit that you would like to explore in
more detail?

Unit Review 79