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Transcript
Lecture 16




Generators
Self Inductance
AC circuits
RLC circuits
Application – Tape
Recorder

A magnetic tape moves past
a recording and playback
head



The tape is a plastic ribbon
coated with iron oxide or
chromium oxide
To record, the sound is
converted to an electrical
signal which passes to an
electromagnet that
magnetizes the tape in a
particular pattern
To playback, the magnetized
pattern is converted back
into an induced current
driving a speaker
Fig. 20-19, p.672
Fig. 20-19a, p.672
Fig. 20-19b, p.672
Generators

Alternating Current (AC) generator



Converts mechanical energy to electrical
energy
Consists of a wire loop rotated by some
external means
There are a variety of sources that can
supply the energy to rotate the loop

These may include falling water, heat by burning
coal to produce steam
AC Generators, cont

Basic operation of the
generator




As the loop rotates, the
magnetic flux through it
changes with time
This induces an emf and a
current in the external circuit
The ends of the loop are
connected to slip rings that
rotate with the loop
Connections to the external
circuit are made by stationary
brushes in contact with the
slip rings
Fig. P20-30, p.688
AC Generators, final

The emf generated by
the rotating loop can be
found by
ε =2 B ℓ v=2 B ℓ sin θ

If the loop rotates with a
constant angular speed,
ω, and N turns
ε = N B A ω sin ω t


ε = εmax when loop is
parallel to the field
ε = 0 when when the
loop is perpendicular to
the field
AC Generators – Detail of
Rotating Loop



The magnetic force
on the charges in the
wires AB and CD is
perpendicular to the
length of the wires
An emf is generated
in wires BC and AD
The emf produced in
each of these wires is
ε= B ℓ v= B ℓ sin θ
DC Generators



Components are
essentially the same
as that of an ac
generator
The major difference
is the contacts to the
rotating loop are
made by a split ring,
or commutator
Demo1 Demo2
DC Generators, cont



The output voltage
always has the same
polarity
The current is a
pulsing current
To produce a steady
current, many loops
and commutators
around the axis of
rotation are used

The multiple outputs
are superimposed and
the output is almost
free of fluctuations
p.674
Motors

Motors are devices that convert
electrical energy into mechanical
energy


A motor is a generator run in reverse
A motor can perform useful
mechanical work when a shaft
connected to its rotating coil is
attached to some external device
Motors and Back emf



The phrase back emf
is used for an emf
that tends to reduce
the applied current
When a motor is
turned on, there is
no back emf initially
The current is very
large because it is
limited only by the
resistance of the coil
Motors and Back emf, cont



As the coil begins to rotate, the induced
back emf opposes the applied voltage
The current in the coil is reduced
The power requirements for starting a
motor and for running it under heavy
loads are greater than those for running
the motor under average loads
Self-inductance

Self-inductance occurs when the
changing flux through a circuit arises
from the circuit itself




As the current increases, the magnetic flux
through a loop due to this current also increases
The increasing flux induces an emf that opposes
the change in magnetic flux
As the magnitude of the current increases, the
rate of increase lessens and the induced emf
decreases
This opposing emf results in a gradual increase
of the current
Self-inductance cont

The self-induced emf must be
proportional to the time rate of change
of the current
I
  L
t


L is a proportionality constant called the
inductance of the device
The negative sign indicates that a changing
current induces an emf in opposition to that
change
Self-inductance, final


The inductance of a coil depends
on geometric factors
The SI unit of self-inductance is
the Henry


1 H = 1 (V · s) / A
You can determine an expression
for L
 B N  B
LN

I
I