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Faraday law of induction
Lenz’s rule
Induced currents and voltages
B field changes as we move permanent magnet
Area decreases as we stretch!
Induced current and voltages are generated when B field through
the loop or area of the loop in B field is changing.
Changes in magnetic flux Φ=ΒΑ is what controls the effect.
Concept of magnetic flux, I
Φ = ( B cos φ ) A;
Unit:
 
Φ = ( B ⋅ A)
Weber (Wb)
I Wb = 1T m2
Tesla
Wilhelm Weber, Germany
1804-1891
A
A
A
Example:
B
B
B



4
Concept of a vector for AREA of a
current loop

A
directed perpendicular to the
surface trough which the
current flows. Polarity of the
direction is according to the
“screw” rule – if you put a
screw into the surface, the
direction of its “penetration” is
the direction of vector A
5
Faraday’s law of induction
British physicist and chemist
(1791-1867)
∆Φ
E = −N
∆t
 
Φ = ( B ⋅ A) = for considered problems = BA
N=number of coil turns
A=area of the coils
Wb T ⋅ m 2
N
m 2 Nm
Units:
=
=
⋅
=
= Volt , b / c
s
s
C (m / s) s
C
N
V = E ⋅ d and Volt = m
C
Lenz’s rule
The induced emf has polarity that
leads to induced current whose
direction is to oppose the
original flux Φ change
Baltic German,
Worked at the U of
St. Petersburg, Russia
Motional emf
Em = L V B
Fq = qE = qE / L = q ⋅ vel ⋅ B ⇒ E = L ⋅ vel ⋅ B
Charge separation
Magnetic force
DC generator
Motional emf through Faraday’s law
of induction
Em = L V B
Em =
∆Φ
∆t
B∆A BL∆x
=
=LVB
=
∆t
∆t
∆X
V
L
B
Current should flow CW to
provide ∆B opposite to the
background B. Motional
emf should have plus
terminal at the bottom
Motional emf for tilted B field
Em = L V⊥ B
B∆A cos θ BL∆x cos θ
E=
=
=
= L V⊥ B
m
∆t
∆t
∆Φ
∆t
Current
Area
B field
θ
∆X
∆x
V
L
B
θ
V⊥
x
Sliding rod, magnetic
friction:
Acceleration
Deceleration and
stationary motion with constant velocity
Problem: Sliding rod
A conducting rod slides down between two frictionless vertical
copper tracks at a constant speed of 4 m/s perpendicular to a
0.5 T magnetic field. The resistance of the rod and tracks is
negligible. The rod maintains electrical contact at all times and
has a length of 1.3 m. A 0.75 ohm resistor is attached between
the tops of the tracks. What is the mass of the rod?
The rod is actually working as a DC generator. What is the
efficiency of mechanical energy conversion to electrical
energy?
η
2
electrical power delivered
I R
=
mechanical power supplied mgV
Solution,1
Solution,2
Induced effect:
polarity
Problem: Sliding coil
A rectangular coil has N=60 turns and resistance of R=0.02
ohms. When it is pulled downward, out of magnetic field at a
speed of 8 m/s, a current of I=0.2 A flows in this coil. 1) What is
the direction of induced current? 2) Determine the strength of
the magnetic field.
×
×
×
×
×
×
× ×
× ×
× ×
× B×
× ×
× ×
L2=8 cm
×
×
×
×
×
×
×
×
×
×
×
×
× L1=20 cm ×
×
×
×
×
V=8 m/s
×
×
×
×
×
×
×
×
×
×
×
×
×
×
×
×
×
×
×
×
×
×
×
×
Solution for
sliding coil
×
×
×
×
×
×
L2=8 cm
×
×
×
×
×
×
×
×
×
B×
×
×
×
×
×
×
×
×
×
×
×
×
×
×
L1=20 cm
V=8 m/s
Application: Induction stove
Water is boiled in the pot made of conducting ferromagnetic material b/c AC voltage
under the panel creates alternative magnetic field in nearby space including the
bottom of the pot. Induced voltage creates electric current that heats the pot
Discussion questions
Discussion questions
Discussion questions
Summary of equations
∆Φ
E = −N
∆t
Em = L V B
Φ = BA