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http://www.nearingzero.net (nz014.jpg)
This relates (sort of) to a demo I’ll do later.
Today’s lecture is brought to you by…
Physics
Man
Sometimes he appears in a homework problem!
Not to be confused with…
Electro-Man
(http://www.thinkgeek.com)
.
Help available for students with test anxiety
February 18, 2016 by Peter Ehrhard
Do you know students struggling with test anxiety? Let
them know that counseling, disability support and student
wellness will present a three-session workshop to help
students manage their anxiety and perform better
academically.
The series will be held 3:30-4:30 p.m. Wednesdays, Feb.
24, March 2, and March 9. For the location and to reserve
your space, contact [email protected] or call 341-4211.
Space is limited and participation will be on a first-come,
first-served basis.
Today’s agenda:
Potential Changes Around a Circuit.
You must be able to calculate potential changes around a closed loop.
Emf, Terminal Voltage, and Internal Resistance.
You must be able to incorporate all of the above quantities in your circuit calculations.
Electric Power.
You must be able to calculate the electric power dissipated in circuit components, and
incorporate electric power in work-energy problems.
Examples.
circuit components in series
In lecture 7 (the first capacitors lecture) I suggested using
conservation of energy to show that the voltage drop across
circuit components in series is the sum of the individual voltage
drops:
Vab
a
C1
C2
C3
V1
V2
V3
+ V
Vab = V = V1 + V2 + V3
b
circuit components in series
In general, the voltage drop across resistors in series (or other
circuit components) is the sum of the individual voltage drops.
a
R1
R2
R3
b
V1
V2
V3
+ -
V
Here’s what your text means by Vab:
Vab=Va-Vb=Vba
Vab = V = V1 + V2 + V3
I “derived” this
in lecture 7.
You may use this in tomorrow’s homework. It “is”* on your
starting equations sheet, and is a consequence of conservation
of energy. Use this in combination with Ohm’s Law, V=IR.
* V = 0 around closed loop
Example: add the potential changes around the loop shown.
Start at point a (or any other point) and follow the current in a
clockwise path around the circuit and back to point a…
a
R1
R2
R3
b
V1
V2
V3
+ -
I
V
- V1 - V2 - V3 + V = 0
- IR1 - IR2 - IR3 + V = 0
For tomorrow’s homework, your path around the circuit should go in the same direction as your guessed current.
Example: add the potential changes around the loop shown.
Again, start at point a and follow the current in a clockwise path
around the circuit and back to point a…
a
R1
R2
b
V1
V2
- +
I
R3
VB
V3
+ -
VA
- V1 - V2 - V3 + VA - VB = 0
- IR1 - IR2 - IR3 + VA - VB = 0
For tomorrow’s homework, your path around the circuit should go in the same direction as your guessed current.
Example: calculate I, Vab, and Vba for the circuit shown.
To be worked at the blackboard in lecture.
5
b
10 
+ -
I
9V
a
Example: calculate I, Vab, and Vba for the circuit shown.
Graph the potential rises and drops in this circuit.
5
b
10 
+ -
I = 0.6 A
a
9V
5 I = 3V
b
 = 9V
10 I = 6V
a
Example: calculate I, Vab, and Vba for the circuit shown.
To be worked at the blackboard in lecture.
5
b
10 
I
- +
+-
6V
9V
a
Example: calculate I, Vab, and Vba for the circuit shown.
What if you guess the wrong current direction?
5
b
10 
I
- +
+-
6V
9V
a
DC Currents
In Physics 2135, whenever you work with currents in circuits,
you should assume (unless told otherwise) “direct current.”
Current in a dc circuit flows in one direction, from + to -.
We will not encounter ac circuits much in this course.
For any calculations involving household current, which is
ac, assuming dc will be “close enough” to give you “a feel”
for the physics.
If you need to learn about ac circuits, you’ll have courses
devoted to them.
The mathematical analysis is more complex. We have other
things to explore this semester.
Today’s agenda:
Potential Changes Around a Circuit.
You must be able to calculate potential changes around a closed loop.
Emf, Terminal Voltage, and Internal Resistance.
You must be able to incorporate all of the above quantities in your circuit calculations.
Electric Power.
You must be able to calculate the electric power dissipated in circuit components, and
incorporate electric power in work-energy problems.
Examples.
emf, terminal voltage, and internal resistance
We have been making calculations with voltages from batteries
without asking detailed questions about the batteries. Now it’s
time to look inside the batteries.
http://www.energizer.com
We introduce a new term – emf – in this section.
Any device which transforms a form of energy into electric
energy is called a “source of emf.”
“emf” is an abbreviation for “electromotive force,” but emf is
not a force!
The emf of a source is the voltage it produces when no current
is flowing.
The voltage you measure across the terminals of a battery (or
any source of emf) is less than the emf because of internal
resistance.
Here’s a battery with an emf. All batteries have an “internal
emf is the zero-current potential difference
resistance:”
a
+ -
b
The “battery” is everything
inside the green box.
Hook up a voltmeter to measure the emf:
emf
a
+ -
b
The “battery” is everything
inside the green box.
Getting ready to connect the
voltmeter (it’s not hooked up
yet).
Measuring the emf???
a
 (emf)
+ -
I
b
The “battery” is everything
inside the green box.
As soon as you connect the
voltmeter, current flows.
You can’t measure voltage without some (however
small) current flowing, so you can’t measure emf
directly.
You can only measure Vab.
Homework hint: an ideal voltmeter would be able to measure .
For example, problem 25.32.
We model a battery as producing an emf, , and having an
internal resistance r:
a
+ -

r
b
The “battery” is everything
inside the green box.

Vab
The terminal voltage, Vab, is the voltage you measure across
the battery terminals with current flowing. When a current I
flows through the battery, Vab is related to the emf  by
An extinct
starting
equation.
Vab = ε ± I r .
Not recommended for use by children under 6. Do
not continue use if you experience dizziness,
shortness of breath, or trouble sleeping. Do not
operate heavy machinery after using.
To model a battery, simply include an extra resistor to represent
the internal resistance, and label the voltage source* as an emf
instead of V (units are still volts):
+ -
a
r

b
If the internal resistance is negligible, simply don’t include it!
If you are asked to calculate the terminal voltage, it is just Vab = Va – Vb, calculated using the
techniques I am showing you today.
(Terminal voltage is usually expressed as a positive number, so it is better to take the absolute
value of Vab.)
*Remember, all sources of emf—not just batteries—have an internal resistance.
Summary of procedures for tomorrow’s homework:
Draw the current in a circuit so that it flows from – to +
through the battery. The sum of the potential changes
around a circuit loop is zero.
Potential decreases by IR when
current goes through a resistor.
Potential increases by  when
current passes through an emf in
the direction from the - to +
terminal.
I
V is loop
+
I
V is +
Treat a battery internal resistance like any other resistor. If I
flows through a battery + to -, potential decreases by .
Example: a battery is known to have an emf of 9 volts. If a 1
ohm resistor is connected to the battery, the terminal voltage is
measured to be 3 volts. What is the internal resistance of the
battery?
Because the voltmeter draws
“no” current, r and R are in
series with a current I flowing
through both.
ε - Ir - IR =0
IR, the potential drop across
the resistor R, is also the
potential difference Vab.
Vab = IR
R=1 
I
emf
+ -
a
internal resistance r
b
terminal voltage Vab
the voltmeter’s resistance is so
large that approximately zero
current flows through the voltmeter
ε - Ir - IR = 0
Ir = ε - IR
ε - IR
r=
I
ε
r= -R
I
r=
Vab = IR
Vab
I=
R
εR
-R
Vab
I
R=1 
emf
a
+ -
b
 ε

r = R
- 1
 Vab 
9 
r = 1  - 1  =  3 - 1  = 2
3 
A rather unrealistically large value for
the internal resistance of a 9V battery.
By the way, the experiment described in the previous example
is not a very good idea.
I=
I=
Vab
R
3
= 3A
1
I may do a demo on this some time.
Today’s agenda:
Potential Changes Around a Circuit.
You must be able to calculate potential changes around a closed loop.
Emf, Terminal Voltage, and Internal Resistance.
You must be able to incorporate all of the above quantities in your circuit calculations.
Electric Power.
You must be able to calculate the electric power dissipated in circuit components, and
incorporate electric power in work-energy problems.
Examples.
Electric Power
Last semester you defined power in terms of the work done by
a force.
dWF
PF 
dt
We’d better use the same definition this semester! So we will.
We focus here on the interpretation that power is energy
transformed per time, instead of work by a force per time.
energy transformed
P
time
The above equation doesn’t appear on your equation sheet, but
it should appear in your brain.
However, we begin with the work aspect. We know the work
done by the electric force in moving a charge q through a
potential difference:
Wif  Uif  qVif .
Using the above, the work done by the electric force in moving
an infinitesimal charge dq through a potential difference is:
dWif  dq Vif .
The instantaneous power, which is the work per time done by
the electric force, is
dWif
dq Vif
P

.
dt
dt
Let’s get lazy and drop the  in front of the V, but keep in the
back of our heads the understanding that we are talking about
potential difference. Then
dW
dq
P
  V.
dt
dt
But wait! We defined I = dQ/dt. So
P  IV.
And one more thing… the negative sign means energy is being
“lost.” So everybody writes
P  IV
and understands that P<0 means energy out, and P>0 means
energy in.
Also, using Ohm’s “law” V=IR, we can write P = I2R = V2/R.
I can’t believe it, but I got soft and put P = I2R = V2/R on
your starting equation sheet.
Truth in Advertising I. The V in P=IV is a potential
difference, or voltage drop. It is really a V.
Truth in Advertising II. Your power
company doesn’t sell you power. It sells
energy. Energy is power times time, so a
kilowatt-hour (what you buy from your
energy company) is an amount of energy.
Demo
(Remember the terminal voltage example?)
How your professor almost burned down
Mark Twain Elementary School
(on three different occasions).
(And Truman Elementary School another
time, just for good measure.)
Note: no equipment set-up is needed for this demo.
Example: an electric heater draws 15.0 A on a 120 V line. How
much power does it use and how much does it cost per 30 day
month if it operates 3.0 h per day and the electric company
charges 10.5 cents per kWh. For simplicity assume the current
flows steadily in one direction.
Skip to slide 34 for now.
What’s the meaning of this assumption about
the current direction?
The current in your household wiring doesn’t flow in one
direction, but because we haven’t talked about current other
than a steady flow of charge, we’ll make the assumption. Our
calculation will be a reasonable approximation to reality.
An electric heater draws 15.0 A on a 120 V line. How much
power does it use.
P  IV
P  15 A 120 V   1800 W = 1.8 kW
How much does it cost per 30 day month if it operates 3.0 h
per day and the electric company charges 10.5 cents per kWh.
 3 h   $0.105 
cos t  1.8 kW  30 days  


 day   kWh 
cos t  $17.00
How much energy is a kilowatt hour (kWh)?
1 kW1 h   1000 W3600 s 
J

 1000   3600 s 
s

= 3.6  106 J
So a kWh is a “funny” unit of energy. K (kilo) and h (hours) are
lowercase, and W (James Watt) is uppercase.
How much energy did the electric heater use?
Paverage 
Wdone by force
time
Energy Transformed

time
Energy Transformed   Paverage   time 
 3 h used   3600 s 
J

Energy Transformed  1800   30 days  


s
day
h





Energy Transformed  583, 200, 000 Joules used
Energy Transformed  583, 200, 000 Joules used
That’s a ton of joules! Good bargain for $17. That’s about
34,000,000 joules per dollar (or 0.0000029¢/joule).
OK, “used” is not an SI unit, but I stuck it in there to help me
understand. And joules don’t come by the ton.
One last quibble. You know from energy conservation that you
don’t “use up” energy. You just transform it from one form to
another.
Example: A 12 V battery with 2  internal resistance is
connected to a 4  resistor. Calculate (a) the rate at which
chemical energy is converted to electrical energy in the battery,
(b) the power dissipated internally in the battery, and (c) the
power output of the battery.
R=4
+-
I
r=2
 = 12 V
Calculate (a) the rate at which chemical energy is converted to
electrical energy in the battery.
R=4
+-
I
V  0
r=2
 = 12 V
around any closed circuit loop
Start at negative terminal of battery…
 - I R2 - I R4 = 0
I =  / (R2 + R4) = 12 V / 6  = 2 A
Energy is converted at the rate Pconverted=I=(2 A)(12 V)=24W.
Calculate (b) the power dissipated internally in the battery.
R=4
+-
I=2A
r=2
 = 12 V
Pdissipated = I2r = (2 A)2 (2 ) = 8 W.
Calculate (c) the power output of the battery.
Poutput = Pconverted - Pdissipated = 24 W - 8 W = 16W.
Calculate (c) the power output of the battery (double-check).
R=4
+-
I=2A
r=2
 = 12 V
The output power is delivered to (and dissipated by) the
resistor:
Poutput = Presistor = I2 R = (2 A)2 (4 ) = 16W.
Example: a 3 volt and 6 volt battery are connected in series,
along with a 6 ohm resistor. The batteries* are connected the
“wrong” way (+ to + or - to -). What is the power dissipated in
the resistor? In the 3 volt battery?
6
I
- +
+-
3V
6V
a
Starting at point a...
+6–3–6I=0
I = (6 – 3) / 6 = 0.5 A
*Assume zero internal resistance unless the problem suggests otherwise.
What is the power dissipated in the resistor?
6
I = 0.5 A
- +
+-
3V
6V
a
PR = I2R = (0.5)2 (6) = 1.5 W
What is the power dissipated in the 3 volt battery?
P3V = IV = (0.5) (3) = 1.5 W
Note:
P6V = IV = (0.5) (6) = 3 W = PR + P3V