Activity 1.3.3 Thermodynamics
Introduction
Think back to the last time someone complained about a door being left open. What did
you notice about the temperature within the room as a result of the open door? In Activity
1.3.3 you will investigate the effects of work, thermal energy, and energy on a system, as
in the case of the room with the door left open.
Procedure
Answer the following questions as your teacher discusses the Introduction
to Thermodynamics presentation.
1. Define thermodynamics.
The study of the effects of work,
thermal energy, and energy on a
system
2. List three examples of a thermodynamic system.
a. Nuclear power
b.
Electronic heat sink
c.
Rocket launch
3. Define thermal energy.
Kinetic energy in transit from one object
to another due to temperature difference
4. Define temperature.
The average kinetic energy of particles in
an object
Sc
al
e
Freezing point of water
Boiling point of water
Celsius
0°
C
10
0°
C
Fahrenheit
32
°F
21
2°F
Kelvin
27
3K
37
3K
5. Fill in the table below with the correct scale and unit.
6. Define absolute zero.
All kinetic energy is removed - 0 K
7.
Define thermal equilibrium.
Touching objects within a system reach
the same temperature
8.
Define the Zeroth Law of Thermodynamics.
If two systems are separately found to be
in thermal equilibrium with a third system,
the first two systems are in thermal
equilibrium with each other.
9. Define the First Law of Thermodynamics.
Thermal energy can change form and
location, but it cannot be created or
destroyed.
10. List two ways thermal energy can be increased in a system.
a. Adding thermal energy
b.
11.
Performing work on the system
Define the Second Law of
Thermodynamics.
Thermal energy
flows from hot to
cold.
12. Define entropy.
The measure of how evenly distributed
heat is within a system
13. Define convection.
The transfer of thermal energy by
movement of fluid (liquid or gas)
14. List two examples of convection.
a. Weather
b.
Boiler systems
15. Define conduction.
The transfer of thermal energy within an
object or between objects from
molecule to molecule
16. List two examples of conduction.
a. Metal spoon
b.
Heat through a wall
Conduction Equations:
17. Define the following variables.
Q = Energy transferred
m = Mass of material absorbing or releasing energy
c = Specific heat capacity of a material (J/kg °C)
P = Rate of energy transfer
Δ t = Change in time
k = Thermal conductivity
A = Area of thermal conductivity
L = Thickness of material
Δ T = Change in Temperature
(18–22) A 1 kg piece of aluminum metal at 90 °C is placed in 4 liters (= 4 kg) of wa- ter at
25 °C. Determine the final temperature (Tf).
18. List all known
values. mAl = 1.00
kg
mwater = 4.00 kg
TAl = 90.0 °C
Twater = 25.0 °C
Cp-Al = 900. J/kg °C
Cp-water = 4184 J/kg °C
19. List all unknown values.
Tfinal
20. Select equations.
21. Apply known values.
22. Solve.
(23–27) The top of a 3/16 inch thick acrylic testing box is covered with an unknown
½ inch insulation material (black). The dimensions of box are 10 inch x 10 inch on each
side. The sides and are wrapped with a control insulting material (blue) so that the almost
all heat loss is through the 10 inch x 10 inch unknown insulating material on the top of the
box (assume no heat is lost from the bottom or sides of the box).
Determine the thermal conductivity for the insulating material if a 25 W bulb is used to
heat the box. You may assume the only heat loss from the box occurs through the 10 x 10
test area. The bulb maintains the inside temperature at 10 ºC higher than the outside
temperature.
23. List all known values.
A = 10.0 in. x 10.0 in. = 0.254 m x 0.254 m =
0.064516 m
2
ΔT = 10.0
°C P =
25.0 W
L = 0.50 in. = 0.0127 m
24. List all unknown values.
k = Thermal conductivity
25. Select equations.
26.
Apply known values.
27.
Solve.
28. Define U-value.
Measure of a material’s ability to conduct
heat
29. Define R-value.
Measure of a material’s ability to resist
heat movement
(30–31) Use the provided R-value chart and illustration below to calculate the R-val- ue
of the wall cavity and the R-value at the stud location.
30. Wall cavity R-value
5/8 drywall = 0.56
Fiberglass batt = 11.00 (3.5 in. x 3.142)
Extruded polystyrene = 4.00
Wood bevel lap siding = 0.80
0.56 + 11.00 + 4.00 + 0.80 = R16.36
31. R-value at stud location
5/8 drywall
= 0.56 2 x4
stud = 4.38
Extruded polystyrene = 4.00
Wood bevel lap siding = 0.80
0.56 + 4.38 + 4.00 + 0.80 =
R9.74
32. Define radiation.
The process by which energy is
transmitted through a medium, including
empty space, as electromagnetic waves
33. List two examples of radiation.
a. Microwave oven
b.
Heat transfer from the human body
34. Define Stefan’s Law.
All objects lose and gain thermal energy
by electromagnetic radiation.
(35–39) A student travels on a school bus in the middle of winter from home to school.
The school bus temperature is 58 °F. The student’s skin temperature is 91.4
°F. Determine the net energy transfer from the student’s body during the 20 min ride to
school due to electromagnetic radiation. Note: Skin emissivity is 0.90, and the sur- face
area of the student is 1.50 m2.
35. List all known values.
A = 1.50
me=
2
0.90
ϭ = 5.6696 x 10-8 w/ m2 k 4
t = 20.00 min = 1200. s
Bus temperature = 58.0 °F = 287.60
K Skin temperature = 91.4 °F =
306.15 K
36. List all unknown values.
P = Rate of
energy transfer
Q = Energy
transfer
37.
Select equations.
38.
Apply known values to equations.
Solve for (T –T )
4
4
287.604 K = 6,841,566,093.34 K
306.154 K = 8,784,904,710.59 K
8,784,904,710.59 K - 6,841,566,093.34 K = 1,943,338,617.25 K
Pnet = (5.6696 x 10-8 w/ m2 k 4) x (1.50 m2) x (0.90) x (1,943,338,617.25 K)
= 148.74 W
Q = 148.74 W x 1200. s
39. Solve.
Q = 178,000 J
40. Define geothermal energy.
Energy generated from the thermal energy
stored beneath the Earth’s sur- face
RValue
Chart
Construction Material
R-Value
½ in. Drywall
0.4
5
5/8 in. Drywall
0.5
6
Particle Board – ½ in.
0.6
3
Particle Board – ¾ in.
0.9
4
Fiberboard ½ in.
1.3
2
Extruded Polystyrene 1 in.
4.0
0
Extruded Polystyrene 1 ½ in.
6.0
0
Foil-faced Polyisocyanurate 1 in.
7.2
0
2x4
4.3
8
2x6
6.8
8
Hardwood
0.9
0
Masonry
Systems
Brick 4 in. common
R-Value
0.8
0
Brick 4 in. face
0.4
4
Concrete Block – Normal wt. 12 in. empty core
1.2
3
Concrete Block – Light wt. 12 in. empty core
2.60–2.30
Cement Mortar
0.2
0
Sand and Gravel
0.6
0
Stucco
0.2
0
Roofing
R-Value
Asphalt Roll
0.1
5
Asphalt Shingle
0.4
4
Slate
0.0
5
Wood
0.9
4
Siding
R-Value
Wood Shingles
0.8
7
Wood Drop
0.7
9
Wood Bevel Lapped
0.8
0
Aluminum/Steel – Hollow
0.61
Aluminum/Steel – with 3/8 in. Backer
Insulation
1.82
R-Value per in.
Fiberglass Batt
3.14
2
Blankets – Rock Wool
3.0–
3.8
Loose Fill – Cellulose
2.8–
3.7
Loose Fill – Fiberglass 0.7 lb/cu.ft
2.2–
4.0
Loose Fill – Rock Wool
3.1
Loose Fill – Vermiculite
2.2
Extruded Polystyrene
4.00