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Lecture on Motional EMF, Eddy Currents, and Self Inductance, Slides of Electrical Engineering

Indira Gandhi Institute of Medical SciencesElectrical Engineering

A set of lecture notes covering the topics of motional emf, eddy currents, and self inductance. Formulas, examples, and explanations of these electrical engineering concepts. Students are introduced to the concept of motional emf, which is the emf induced by the motion of a conductor in a magnetic field. The document also covers eddy currents, which are currents induced in conductors when they are in changing magnetic fields, and self inductance, which is the property of a coil that opposes changes in current. An example problem on a solenoid within a coil, as well as explanations of energy conservation and the demonstration of eddy currents.

Typology: Slides

2012/2013

Uploaded on 08/20/2013

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1
LECTURE 17
Motional EMF
Eddy Currents
Self Inductance
3/5/12 2
Reminder: How to Change Magnetic Flux in a
Coil
1.
B changes: dΦm
dt =dB
dt
NA cos
B,
A
( )
2. A changes: dΦm
dt =NB dA
dt cos
B,
A
( )
3.
B,
A
( )
changes: dΦm
dt =NBA
dcos
B,
A
( )
dt
4. N changes (unlikely): dΦm
dt =dN
dt
BA cos
B,
A
( )
3/5/12 3
Example Problem: Solenoid within a Coil
120 turn coil of
radius 2.4 cm and
resistance 5.3 "
solenoid with
radius 1.6 cm and
n = 220 turns/cm
Initial current in the solenoid is 1.5 A.
Current is reduced to zero in 25 ms.
What is the current in the coil while the
current is being reduced?
3/5/12 4
Example Problem: Solenoid within a Coil
pf3
pf4
pf5

Partial preview of the text

Download Lecture on Motional EMF, Eddy Currents, and Self Inductance and more Slides Electrical Engineering in PDF only on Docsity!

LECTURE 17

• Motional EMF

• Eddy Currents

• Self Inductance

3/5/12 2

Reminder: How to Change Magnetic Flux in a

Coil

B changes: d Φ m dt = dB dt NA cos  B , 

(^ A )

  1. A changes: d Φ m dt = NB dA dt cos  B , 

(^ A )

B , 

(^ A ) changes:^

d Φ m dt = NBA d cos  B , 

⎡ ⎣ ( A )⎤ ⎦

dt

  1. N changes (unlikely): d Φ m dt = dN dt BA cos  B , 

(^ A )

3/5/12 3

Example Problem: Solenoid within a Coil

120 turn coil of radius 2.4 cm and resistance 5.3 " solenoid with radius 1.6 cm and n = 220 turns/cm Initial current in the solenoid is 1.5 A. Current is reduced to zero in 25 ms. What is the current in the coil while the current is being reduced? 3/5/12 4

Example Problem: Solenoid within a Coil

3/5/12 5

Motional EMF

Motional EMF is any emf induced by the motion of a conductor in a magnetic field. 3/5/12 6

Calculation

3/5/12 7

Energy Conservation

  • Energy is dissipated in circuit at rate P ’:
  • The induced current gives rise to a net magnetic force F in the loop which opposes the motion:
  • Rate of work by applied force: 3/5/12 8

Eddy Currents

*Relative motion between a B field and a conductor induces a current in the conductor. *The induced current give rises to a net magnetic force, FM , which opposes the motion.

3/5/12 13

Reduce Eddy Currents

Metal strips with insulating glue Cut slots into the metal. 3/5/12 14

Inductors & Inductance

Symbol for inductor *An inductor can be used to produce a desired B field. *Inductance: L = N Φ M i

Units of L: 1 Henry = 1 H = 1

Tm^2

A

3/5/12 15

Self Inductance

X X X X X X X X X X X X X X a b dI/dt An induced emf, L, appears in any coil in which the current is changing. Self-Induction: Changing current through a loop induces an opposing voltag in that same loop. 3/5/12 16

Self Inductance in a Coil

3/5/12 17

Magnetic Energy in an Inductor

power delivered by battery power delivered to inductor power dissipated by resistor Upon closing switch, S, apply Kirchoff’s loop rule:

ε − IR − L

dI

dt

Multiply through by I: ε I = I 2 R + LI dI dt 3/5/12 18

Magnetic Energy in an Inductor

2 m f I m m 0 m m m LI 2

U

U dU LI dI U LI dI dt dI LI dt dU IfU energyinthe inductor, f =

∫ ∫ energy stored in an inductor 3/5/12 19

Magnetic Energy in a Solenoid

B = μ 0 nII =

B

μ 0 n L = μ 0 n^2 Al Um =

LI^2 =

μ 0 n^2 Al

B

μ 0 n

2

B^2

2 μ 0 Al magnetic energy density um =

B^2

2 μ 0 electric energy density ue =

ε 0 E^2 Both of these are general results.