Journal #51 1/6/2010
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Transcript of Journal #51 1/6/2010
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Journal #51 1/6/2010
Calculate the answers to the following problems. Use scientific notation and sig figs in your answers.
?101.41075.2 57
?1001.110881.7 75
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Journal #51 Solutions
?101.41075.2 57
?1001.110881.7 75
13101.1
21080.7
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Excerpts from Ch 10-11
Work, Power, and Energy
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Work
Work in the scientific sense: The work done on an object is equal to the product of the force exerted in the direction of motion, times the object’s displacement
Work is a vector quantity!Work = Force x distance
W F d
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More on Work…
• To lift an object requires work, but to hold an object without moving it (by definition) does not require work.• The unit of joule comes
from the name of a British physicist named James Prescott Joule.
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Work = Force|| x Distance
• Only the component of force parallel to the displacement does work• In this case, the distance is
the magnitude of the displacement.
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x
F
xxdFW
xF
yF
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Practice Problems - work
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Example Problem #2 Solution
JW
WFdW
4109.2
35825
?35825
WmdNFA.)
B.)
?351650
WmdNF
JW
WFdW
4108.5
351650
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Example Problem #3 Solution
JW
WdmgW
dFW g
2100.6
2.880.95.7
?2.8min305.7
Wmd
tkgm
A.)
B.)
JW
W
dFFW persongbackpackg
3109.5
2.8)64580.95.7(
)(
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Power• Power is equal to the amount of work
done per unit time.
• The unit for power is the Joule/second which is also called a Watt named after the Scottish inventor, James Watt
interval timedonework Power
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What is horsepower? 1 horsepower = 746
Watts The horsepower was
originally defined to compare the output of steam engines with the power of draft horses
Horsepower is not a recognized SI unit but is still widely used in many applications (such as cars).
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Homework – Work and PowerP. 278 at back of chapter 10
#52-59You must show left-hand line-up (aka -
define your terms!), formulas used, all of your work, then circle your final answers!
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Journal #52 1/7/10 Order the speed of the rollercoaster (from fastest to
slowest) at the positions labeled. If you believe the speed would be the same at two points, indicate that as well.
AB
C
F
E
D
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Journal #52 Solution Fastest to slowest: C, F, B, A & D same, then E is
slowest. What rule can we make up?
AB
C
F
E
D
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Making the graph
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Energy…the BIG picture
• The Universe is made up of matter and energy.
• Energy is the “mover” of matter. • There are many forms of energy.• Conversions from one form of energy
to another continually occur.• Energy cannot be created or
destroyed.
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Forms of energyThere are many forms of energy –
chemical, mechanical, thermal, solar, electrical, kinetic, potential…
All are measured in Joules, the same units as work!
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Potential energy (symbol PE) is stored chemical energy or energy of position.
Types of PE: elastic, gravitational and chemical.
Potential Energy
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Gravitational Potential
Gravitational Potential Energy can be found by multiplying the mass (in kilograms) of an object, by the acceleration due to gravity, and the height (in meters)
GPE = mgh
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Kinetic energy (symbol KE) is energy of motion. Kinetic energy depends on both mass and velocity
Kinetic Energy
KE 12mv 2
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Energy possessed by an object due to its motion or its stored energy of position.
It can be either potential energy or kinetic energy, or a combination of both
All forms of energy are measured in joules (J).
Mechanical Energy
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Mechanical Energy Conversions …total energy is constant
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Work-Energy Theorem• Relates chapter 10 Work and 11 Energy • Note that Kinetic Energy (KE) of a
moving object = the work an object can do while it is being brought to rest
• Work = change in KE; if no change in KE, no work is done
F d 12mv 2
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Calculate speed at positions B,C and D.
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More Energy Transfer High speed winds are used to
do work on the blades of a turbine at the so-called wind farm.
Mech. Energy from the air gives the air particles the ability to apply a force to the blades.
As the blades spin, their energy is subsequently converted into electrical energy (a non-mechanical form of energy) and supplied to homes and industries in order to run electrical appliances.
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Energy Transfer...This diagram
shows that the boys potential energy is changing. Explain what is happening, in other words how is the energy changing?
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Energy cannot be created or destroyed.
Energy can be transformed from one form to another, but the total amount of energy never changes.
Ex: We can go from PE to KE to PE and back again…think about coaster or pendulum
Law of Conservation of Energy
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What happens to energy?The energy we often think of as lost
is not truly lost but is just converted into forms that may no longer be useful to us – often transferred to thermal energy or heat…Ex: burning log in a fireplace; gasoline in an engine; electric light bulb