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Transcript
Chapter 30
Inductance, Electromagnetic
Oscillations, and AC Circuits
Copyright © 2009 Pearson Education, Inc.
Problem 2
2. (II) Determine the mutual inductance per
unit length between two long solenoids, one
inside the other, whose radii are r1 and r2 (r2
< r1 ) and whose turns per unit length are n1
and n2
30-2 Self-Inductance
A changing current in a coil will also induce an emf in
itself:
Here, L is called the self-inductance:
30-2 Self-Inductance
Example 30-3: Solenoid inductance.
(a) Determine a formula for the self-inductance L
of a tightly wrapped and long solenoid containing N
turns of wire in its length l and whose crosssectional area is A.
(b) Calculate the value of L if N = 100, l= 5.0 cm,
A = 0.30 cm2, and the solenoid is air filled.
Problem 8
8.(II) An air-filled cylindrical inductor has 2800
turns, and it is 2.5 cm in diameter and 21.7 cm
long. (a) What is its inductance? (b) How many
turns would you need to generate the same
inductance if the core were filled with iron of
magnetic permeability 1200 times that of free
space?
30-2 Self-Inductance
Example 30-5: Coaxial cable inductance.
Determine the inductance per unit length of
a coaxial cable whose inner conductor has a
radius r1 and the outer conductor has a
radius r2. Assume the conductors are thin
hollow tubes so there is no magnetic field
within the inner conductor, and the magnetic
field inside both thin conductors can be
ignored. The conductors carry equal
currents I in opposite directions.
30-3 Energy Stored in a
Magnetic Field
30-4 LR Circuits
A circuit consisting of an inductor
and a resistor will begin with most
of the voltage drop across the
inductor, as the current is
changing rapidly. With time, the
current will increase less and less,
until all the voltage is across the
resistor.
30-4 LR Circuits
The sum of potential differences around the loop
gives
Integrating gives the current as a function of
time:
.
The time constant of an LR circuit is
.
30-4 LR Circuits
If the circuit is then shorted across the
battery, the current will gradually decay away:
.
30-4 LR Circuits
Example 30-6: An LR circuit.
At t = 0, a 12.0-V battery is connected in
series with a 220-mH inductor and a total of
30-Ω resistance, as shown. (a) What is the
current at t = 0? (b) What is the time
constant? (c) What is the maximum current?
(d) How long will it take the current to reach
half its maximum possible value? (e) At this
instant, at what rate is energy being
delivered by the battery, and (f) at what
rate is energy being stored in the inductor’s
magnetic field?