Lecture 7 - heat transfer

advertisement
Announcements 1/21/11





Prayer
Lab 2 starts tomorrow
Homework solutions are being posted in
hallway around corner from where you turn in
the homework, right next to the CSR office.
I’ll be out of town on Monday. Class will be
taught by Dr. Stokes. I won’t have office
hours, but the Chris still will.
One person still doesn’t have his/her clicker
registered.
Quick Discussion:

Ralph's professor stated "If you add an ice
cube to a glass of water, the temperature of
the water does not necessarily decrease."
That seems bizarre to him, because ice is
obviously used to cool down water! Can you
help him understand how his professor’s
comment can be true?
Reading quiz (graded)

Which of the following is not a way heat can
be transferred?
a. conduction
b. convection
c. perpetuation
d. radiation
Reading quiz (graded)

Which of the following does not continuously
emit electromagnetic waves?
a. A light bulb which is turned on
b. A light bulb which is turned off
c. A star
d. A hot electric stove burner
e. None of the above
Blackbody Radiation

Hot objects glow!
a. That glow carries away
energy
heat energy
time


4
Plost  e ATobject
Surroundings also glow!
a. That glow adds energy
Pgained  e
4
ATsurroundings
Demo

Burning ants with magnifying glass
a. OK, not really
Color of emission
Chromaticity
diagram
You’ll learn/derive
the equation in
Phys 360, if you
take it.
Area ~ T4
More on Emissivity
“Fudge factor” between 0 and 1
 Different for different surfaces
a. 0.05 for “highly polished aluminum”
b. 0.8 for “anodized aluminum”
 Same as “absorptivity”
a. Why?
 Different for different wavelengths
a. Greenhouse effect

Thought question

A metal sphere is heated to 1200 K, and puts out
1000 W of radiation energy. If it is cooled to 600
K, it will put out ______ W of radiation energy.
(Don’t worry about heat absorbed from
surroundings. Assume emissivity is the same for the
two temperatures.)
a. 31.25
b. 62.5
c. 125
d. 250
e. 500
Reading quiz (graded)

The rate that heat is conducted
through a wall (temperature T1 on one
side, T2 on other side) is proportional
to…
a. T2-T1
b. (T2-T1)2
c. (T2-T1)1/2
d. log(T2-T1)
e. exp(T2-T1)
Thought Question

You put the end of a rod in a fire and the
other end in a tub of water. The rod that
would heat the water fastest will be:
a. short and fat
b. long and fat
c. short and thin
d. long and thin
Thermal Conduction
T2
hot
T1
cold
A
L
Q
 T2  T1 
P
 kA 

t
L


Really:
dQ
dT
 kA
dt
dx
Warning: what is
meant by time?
Thought question

If I heat the left end of an iron rod such that its
temperature is a constant 200 degrees C, and I
put the right end in ice water, what will the
temperature of the middle of the rod when the rod
approaches “steady state”?
a. 0 ºC
b. 50 ºC
c. 100 ºC
d. 150 ºC
e. 200 ºC
“Steady state” vs. “Thermal equilibrium”
What if left half of rod is iron, but the right half is copper?
Thermal Conductivity
Some Thermal Conductivities
(from your textbook)
Material
Copper
Aluminum
Iron
Glass
Wood
Air
k (J/s∙m∙C)
397
238
79.5
0.84
0.10
0.0234
What “feels” colder, a metal car or a wooden box?
Thought question:

If I heat one end of an iron rod to 150 degrees C and I
put the other end in ice water, I get a heat flow of 10 J/s
through it. If I do the same with a particular copper rod,
I get 25 J/s. If I stick the two of them together, side by
side, how much heat will flow through the combined rod?
a. 10 Watts or less
b. More than 10 but not greater than 25
c. More than 25 but less than 35
d. 35 Watts
e. More than 35 Watts
T2
hot
iron
Cu
T1
cold
Thought question:

I put an iron rod and a copper rod end-to-end to
form one long rod. The total heat flow through the
combined rod is 100 J/s. How does the heat flow
(J/s) through the iron compare to the heat flow
through the copper? (kiron = 79.5 W/mC; kCu = 397
W/mC)
a. Piron < Pcopper
b. Piron > Pcopper
c. Piron = Pcopper
T2
hot
T1
cold
iron
Cu
R-values
L
R
k
AT
P
R
Some R-values
(from your textbook)
Material
Brick, 4” thick
Styrofoam, 1” thick
Fiberglass insulation,
3.5” thick
Drywall, 0.5” thick
R (ft2 F hr/Btu)
4
5
Yuck!
10.9
0.45
Why useful: R values of wall materials add
Worked Problem

You foolishly decide to build the walls of your new
house out of solid aluminum (k = 238 W/mC), 5 cm
thick. As a result, in the wintertime heat leaks out like
a sieve. How much money will this cost you each day?
The inside temp is 70 F (21.1 C), the average
outside temperature is 25 F (-3.9 C). The surface
area is 280 m2. The gas company charges you $0.89
per “therm” (1.055  108 J). Only count heat loss
through conduction.
Class survey: guess the answer
Answer: $27,288
Quick Discussion
Material
Air
Fiberglass

k (J/s∙m∙C)
0.0234
0.045
If air is such a poor thermal conductor, why
is it beneficial to use fiberglass insulation in
your attic?
Convection

Demo: dye in tube
Download