Transcript Energy:

Energy:
The Capacity to Effect Change
Presentation 2003 R. McDermott
Energy is all Around Us:
It causes changes in velocity – kinetic energy
It causes rearrangement – potential energy
It stretches and compresses – elastic energy
It causes heating – dissipated energy
Energy is Energy!
Don’t be confused; all energy is the same, the
only difference is the change that energy
produces.
Energy is like water; pouring it into different
containers may make it look different, but it really
isn’t.
Kinetic Energy – Energy of Motion
Energy that causes motion is called
kinetic energy:
Translational: linear motion
Rotational:
spinning, tumbling
Vibrational:
back and forth
Translational KE = ½ MV2
Example:
What is the kinetic energy of a 2000kg car moving
at 40m/s?
Answer:
1,600,000 J
Comments:
Kinetic energy is directly proportional to mass;
doubling the mass doubles the KE
Kinetic energy is directly proportional to the
square of the velocity; doubling velocity
quadruples the KE
Velocity is a larger factor in determining KE than
is mass
Gravitational PE – Energy of Height
Energy stored in gravitational field
due to separation of mass and Earth
Changes the field geometry
We (erroneously) say that energy is
stored in the lifted object, but it is
actually in the field
Gravitational PE = MgH
Example:
How much potential energy is stored when a
100kg man climbs to the top of a 1000m
peak?
Answer:
981,000 J
Comments:
Gravitational potential energy is directly
proportional to mass and height; doubling either
one doubles the PE
Gravitational potential energy is also directly
proportional to the gravitational field strength;
traveling to a planet with a higher ‘g’ would
cause higher PE values for a given height.
Elastic Energy – Energy of a Spring
Stretch or Compression
Energy stored in spring
A type of potential energy
Spring PE = ½ kX2
Example:
How much elastic energy is stored in a spring
(k= 8 N/m) that is compressed by 0.05 m?
Answer:
0.01 J
Comments:
Elastic potential energy for a spring is directly
proportional to the spring strength (k); doubling k
doubles the PE
Elastic potential energy is also directly
proportional to the square of the stretch or
compression; doubling quadruples the PE
Stretch/compression is a larger factor in
determining PE than is the value of k
Dissipated Energy – “Lost” Energy
Non-isolated system
Energy dispersed into air, ground, etc.
Heat, sound, light, etc
Friction is a common cause
Collisions also lead to dissipated energy
Example:
A 2000 kg car moving at 20 m/s brakes to a stop.
How much heat is produced in the brakes?
Answer:
KElost = Heat
Heat = 400,000 J
Units
Working from PE = MgH, energy must have
units of kg-m2/s2
But using F = Ma, we see that this is must also
be equal to a N-m
However, energy is assigned a derived unit, the
Joule, which is equal to the units above
All SI energy units are given in Joules
Energy is a scalar
Energy is Constant – Isolated System
Under normal conditions, energy cannot be
created or destroyed
An isolated system/object (no outside
interactions) has a fixed amount of energy
Although the change that energy produces (the
“form of energy”) may change, the amount of
energy in the system does not
Conservation of Energy
In an isolated system, the total energy is constant
though it may change “form”
A falling object gradually “converts” PE to KE
Releasing a spring “converts” PE to KE
In a non-isolated system, total energy can include
dissipated energy to maintain a constant total
A braking car converts KE to heat
In these cases, total energy before = total energy after
Conservation
Energy and Position
Solving Conservation Problems:
Identify the system/object
Earth is always part of the system
Identify initial energy “forms”
Identify final energy “forms”
Set total initial energy equal to total final energy
Solve
Roller Coaster – Energy Conservation
As a coaster falls, PE is converted into KE
Total PE + KE (mechanical energy) is constant
PE lost = KE gained
MgH = ½ MV2
V = (2gH)
Example:
A 2000 kg roller coaster car
moves to the top of a 100m hill
and then falls. Assuming it
started at rest, how fast will it be
moving when it reaches the
bottom of the hill?
Answer:
MgH = ½ MV2
V = 44.3 m/s
Follow-up:
A 2000 kg roller coaster car
moves to the top of a 100m hill
and then falls. How fast will the
car be moving when it is halfway
down?
Answer:
31.3 m/s
It’s the KE that is half, not
the velocity!
Spring Example:
A 2.0 kg block falls 10 m in compressing
a spring (k = 10 N/m). What was the
compression of the spring?
Answer:
MgH = ½ kX2
X = 6.3 m
Acknowledgements
Animations courtesy of Tom Henderson,
Glenbrook South High School, Illinois
Artwork courtesy of Dr. Phil Dauber