Transcript 12.1 Forces
Forces
12.1 Pg 356-362
FORCE:
A push or a pull that acts on
an object
Can cause a resting object to
move, or it can accelerate a
moving object by changing
the object’s speed or
direction.
FORCE:
Unit of force: Newton (N)
1 Newton is the force that causes a
1 kg mass to accelerate at a rate of
1 m/s2
1 N = 1 kgm/s2
kg = mass and m/s2 = acceleration
so…
Force = mass x acceleration
Representing Force
Example: Measuring
force with a spring scale
at the grocery store
When the vegetables are
in the basket the force
pushes the basket down
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To represent force use
an arrow in the direction
of the force.
Vectors can be used to represent
force because force has magnitude
and direction
Combining forces
Forces CAN be combined (vector
addition)
3 people pushing a car out of gas
Forces in the SAME direction you ADD
Forces in the OPPOSITE direction you
SUBTRACT
NET FORCE: overall force acting on an
object after all the forces are combined
Balanced forces:
When the forces on an object are
balanced, the net force is ZERO and
there is no change in the object’s
motion
0
The forces are balanced when they are
equal in size and opposite in direction
THINK equal push and pull
Unbalanced force
When an unbalanced force acts on
an object, the object accelerates
THINK TUG OF WAR
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FRICTION:
A force that opposes the motion of
objects that touch as they move past
each other
Friction makes
Walking possible
Food stay on your fork
Tires on your car grip the road so the car moves
forward
A feather slow down as it falls
There are four main types of friction:
static friction, sliding friction, rolling
friction, and fluid friction
Static Friction
The friction force that acts on
objects that are not moving
Always acts in the direction
opposite to the applied force
Every time you take a step
and push off the ground you
are experiencing static
friction
It is not the same as static
electricity!!
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Sliding Friction
A force that opposes the direction of motion
of an object as it slides over a surface
Sliding friction is less than static friction,
therefore once you get something moving it is
easier to keep it moving
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Rolling Friction
The friction force that acts on
rolling objects, occurs when
the floor and object are bent
slightly out of shape
Rolling friction is is about 100
to 1000 times less than the
force of static or sliding friction
Ball bearings are often used to
reduce friction in machines
Friction is greatly reduced
because it changes sliding friction
to rolling friction
Think in-line skates and skate
boards
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Fluid Friction
The force that opposes
motion of an object as it
moves through a fluid
Fluids are liquids (like water)
or mixtures of gases (like air)
Fluid friction increases as as
the speed of the object
increases
Air resistance is fluid friction
acting on an object moving
through air
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GRAVITY:
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Force that acts
between any two
masses
Acts downward
toward the center of
Earth
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Falling objects
Gravity causes objects to
accelerate downward,
whereas air resistance
acts in the direction
opposite to the motion and
reduces acceleration
Air resistance acts in the
direction OPPOSITE to
the motion
Gravity
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Air Resistance
Terminal Velocity
Terminal velocity of a
skydiver is approximately
As speed increases air resistance
195 km/h (122 mph or 54
increases
m/s)
Gravity
If an object falls for a long time
the upward force of air resistance
becomes equal to the downward
force of gravity
Then the object continues to fall at a
constant velocity (or constant speed)
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Terminal velocity is the constant
velocity of a falling object when
the force of air resistance equals
the force of gravity
Air Resistance
Projectile Motion
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Both marbles fall at the
same rate even if one is
also moving forward
The motion of a falling object
after it is given an initial
forward velocity
The path of a projectile is
always a curve
Air resistance and gravity are
the only forces acting on a
projectile
The combination of an initial
forward velocity and the
downward force of gravity
causes the ball to follow a
curved path
Projectiles and Speed
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In the diagram the marbles
roll off the table and fall to the
floor
The marbles continue to
move forward while they fall
Therefore, as the marble’s
velocity increases the
distance away it travels will
increase
All marbles hit the ground at
the same time no matter how
fast they travel forward
Projectile Motion Problem
How fast would the person have to run in order to land in the water safely
(land 2m away)?
Given info:
Height of cliff = 9 m
Distance forward = 2.5 m
Gravity = 9.8 m/s2
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Find Velocity (v) and Time (t)
2.5m
First find time
t = √2(h)
t = √2(9m)
9.8m/s2
t = √18m
9.8m/s2
= √1.836734694s2 = 1.4s
9.8m/s2
Now find the velocity (speed)
v=d
t
v = 2.5m
v = 1.8 m/s
1.4s
So the person would have to run at a velocty of 1.8 m/s in order to land at
least 2.5 m away from the cliff. If not he could be seriously injured on the
rocks below.