Download Document

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

Document related concepts

Inertial frame of reference wikipedia , lookup

Fictitious force wikipedia , lookup

N-body problem wikipedia , lookup

Hunting oscillation wikipedia , lookup

Modified Newtonian dynamics wikipedia , lookup

Centrifugal force wikipedia , lookup

Centripetal force wikipedia , lookup

Classical mechanics wikipedia , lookup

Equations of motion wikipedia , lookup

Work (physics) wikipedia , lookup

Force wikipedia , lookup

Rigid body dynamics wikipedia , lookup

Classical central-force problem wikipedia , lookup

Newton's theorem of revolving orbits wikipedia , lookup

Inertia wikipedia , lookup

Newton's laws of motion wikipedia , lookup

Transcript
Newton’s Laws of
Motion
Lecture 6
Does this have anything to do with cookies?
 Nope, not fig newtons…Sir Isaac Newton
 A little bit stuffy, bad hair, but quite an
intelligent guy.
 He was a genius mathematician &
physician in the 1700’s.
 During his work, he came up with the
three basic ideas that are applied to the
physics of most motion.
 The ideas have been tested and proved
so many times over the years that are
now called Newton's Three Laws of
Motion.
 Check out BrainPop’s Sir Isaac Newton:
29. Newton’s 3 Laws of Motion-a
QuickTime™ and a
decompressor
are needed to see this picture.
http://www.youtube.com/watch?v=iH48Lc7wq0U&feature=related
Newton’s Law #1
 What does this mean?
 If nothing is happening to
you and nothing does happen
you will never go anywhere.
 If you're going in a specific
direction, unless something
happens to you, you will
always go in that direction.
 Forever.
 Things don’t move unless a
force is applied to them.
Examples
 A golf ball on a tee will
remain on the tee until
the club, the unbalanced
force, makes contact with
it.
QuickT ime™ and a
T IFF (Uncompressed) decompressor
are needed to see thi s picture.
Examples
 Think again of astronauts in
space.
 Have you ever noticed that
their tools float?
 They can just place them in
space and they stay in one
place.
 There are very few forces
acting on objects in space.
 When you put something in
one place, it will only move
very slowly when gravity
pulls it.
Examples
 Objects like to keep doing what they’re
doing!!!
Why don’t things keep on
moving forever?
 So, if an object in motion remains in motion
unless acted upon by another force and I
pushed my desk across the room, would it
keep moving forever?
 Of course not.
 It stops moving because an unbalanced force
acts on it.
 This unbalanced force is friction.
 This force is everywhere & affects our daily
life constantly.
Example
 A tractor trailer will
often jackknife on an
icy road when the
driver suddenly
applies the breaks.
 The breaks stop the
wheels and the front
of the rig stops.
 However, the back
half skids and keeps
moving in the
direction it was going
in.
Law #1 = Law of Inertia
 Newton’s first law is also called the “law
of inertia”
 Inertia is the property of an object to
resist change in motion.
 It is because of inertia that objects like to
remain at rest or why objects like to keep
moving.
Law of Inertia
 To understand inertia, imagine trying to move a
bowling ball and a golf ball.
 Which needs more force?
 Of course, the bowling ball needs more force to
get it moving at the same speed as the golf ball.
 The bowling ball also needs more force to stop.
 A bowling ball has more inertia than a golf ball.
 The greater an object’s inertia, the greater the
force needed to change its motion.
Inertia & Mass
 Inertia comes from mass.
 Objects with more mass have more inertia and
are more resistant to changes in their motion.
 Have you ever observed the behavior of your
mom’s coffee in a coffee cup filled to the rim
while starting a car from rest or while bringing
a car to rest from a state of motion?
 Coffee tends to "keep on doing what it is
doing.”
 Coffee in motion tends to stay in motion.
30. Eureka: Inertia & Mass
QuickTime™ and a
decompressor
are needed to see this picture.
http://www. youtube.com/watch?v=by-7kkAu2Pg&feature=re lated
Example
 Have you ever played the “Blob” game in
the car?
 Why is it that when the car turns right, your
body goes to the left and when the car
turns left, you blob to the right?
 You blob in the direction of the car’s
original motion.
 Your body wants to keep going straight,
even as the car is turning.
Example
 Imagine a dog sitting in the passenger seat of a
car.
 Suddenly, the brakes are slammed to avoid the
bozo driving in front.
 What happens to the sweet dog?
 She goes flying into the dashboard!
 Poor puppy experienced inertia!
 Even though the car was stopped by the force of
the brakes/friction, she kept going.
 A dog in motion remains in motion!
Example
 Or… what happens to your dog when you suddenly
slam on the gas pedal?
Why you must always wear a
seatbelt….
Look at that inertia!
31. Newton’s First Law of Motion
QuickTime™ and a
decompressor
are needed to see this picture.
You should now be able to explain why
the following occurs:
 blood rushes from your head to your feet
while quickly stopping when riding on a
descending elevator.
 to dislodge ketchup from the bottom of a
ketchup bottle, the bottle is often turned
upside down, thrust downward at a high
speed and then abruptly halted.
You should now be able to explain
why the following occurs:
 headrests are placed in cars to prevent
whiplash injuries during rear-end
collisions.
 while riding a skateboard, you fly
forward off the board when hitting a
curb, a rock or another object which
abruptly halts the motion of the
skateboard.
32. Newton’s First Law &
Roller Coasters
QuickTime™ and a
decompressor
are needed to see this picture.
Newton’s Third Law





We’re going to skip ahead to Newton’s 3rd law.
We’ll come back to Law #2 tomorrow.
Newton’s first law only applies to single objects.
This third law deals with pairs of objects.
This is because all forces come in pairs.
33. Newton’s 3rd law
QuickTime™ and a
decompressor
are needed to see this picture.
http://www.youtube.com/watch?v=cP0Bb3WXJ_k
Newton versus the Elephant
 Imagine a skateboard contest
between Newton & an elephant.
 They can only push against each
other, not against the ground.
 The fastest one wins.
 The elephant knows it is much
stronger & pushes off Newton
with a huge force, thinking he
will win.
 But will he?
Newton versus the Elephant
QuickT ime™ and a
TIFF (Uncompressed) decompressor
are needed to see this picture.
 The result of the giant push from the elephant is that
Newton flies away with a greater speed & the puzzled
elephant moves backwards with a smaller speed.
 Newton wins - and will always win, no matter how hard the
elephant pushes.
 In fact, Newton doesn’t have to push at all & he still wins.
 Why?
Newton versus the Elephant
QuickT ime™ and a
TIFF (Uncompressed) decompressor
are needed to see this picture.
 Newton wins because forces always come in pairs.
 The elephant pushes against Newton & that action pushes
Newton away.
 The elephant's force against Newton creates a reaction force
against the elephant.
 These forces are EQUAL in strength.
 BUT, these two are different in mass - Newton has a lot less
mass & inertia, so he moves more easily.
Newton’s Third law
 We’ve talked about this before.
 When you sit in your chair, your body exerts a
downward force on the chair and the chair exerts an
upward force on your body.
 There are two forces resulting from this interaction
— a force on the chair and a force on your body.
 It’s a pair of forces!
 Action and reaction!
Newton’s Third law






This is how sports work.
How do you hit a baseball?
A golf ball? A tennis ball?
How do you shoot a basketball?
How do you spike a volleyball?
All sports is related to forces & action/reaction
pairs.
Examples
 Think of how birds fly.
 The wings of a bird push air
downwards.
 In turn, the air reacts by pushing the
bird upwards.
 For every action, there is an equal (in
size) and opposite (in direction)
reaction.
 Action-reaction force pairs make it
possible for birds to fly.
Example
 When you swim…your hands and feet push on the water this is the action force.
 The reaction force is the water pushing equally (and in an
opposite direction) on your hands and feet.
 The reaction forces causes forward motion.
Why don’t the forces cancel?
 The reason is action & reaction forces
act on different objects.
 If the two forces canceled each other
out, there would be no motion.
 Think about throwing a ball.
 You apply the action to the ball,
creating the ball’s acceleration.
 The reaction is the ball pushing back
on your hand.
 You can only cancel forces acting on
the same object.
More examples…
More examples…
BrainPop: Laws of Motion
 Click here
 Log on: mms308 password: marshall