Chapter 29

Chapter 29 Electromagnetic Induction

Goals for Chapter 29 • To examine experimental evidence that a changing magnetic field induces an emf • To learn how Faraday’s law relates the induced emf to the change in flux • To determine the direction of an induced emf

Goals for Chapter 29 • To calculate the emf induced by a moving conductor • To learn how a changing magnetic flux generates an electric field • To study Maxwell’s Equations – the four fundamental equations that describe electricity and magnetism

Introduction • How is a credit card reader related to magnetism? • Energy conversion makes use of electromagnetic induction. • Faraday’s law and Lenz’s law tell us about induced currents.

Induced current • A changing magnetic flux causes an induced current. No change => NO induced current!

Induced current • A changing magnetic flux causes an induced current. The induced emf is the corresponding emf causing the current.

Magnetic flux through an area element

Faraday’s law • Flux depends on orientation of surface with respect to B field.

Faraday’s law • Faraday’s law: Induced emf in a closed loop equals negativeof time rate of change of magnetic flux through the loop  = –dB/dt In this case, if the flux changed from maximum to minimum in some time t, and loop was conducting, an EMF would be generated!

Faraday’s law • Faraday’s law: Induced emf in a closed loop equals negativeof time rate of change of magnetic flux through the loop  = –dB/dt [B ]= Tesla-m2 [d B/ dt] = Tesla-m2/sec and from F = qv x BTeslas = Newtons-sec/Coulomb-meters [N/C][sec/meters] [d B/ dt] = [N/C][sec/meter][m2/sec] = Nm/C = Joule/C = VOLT!

Emf and the current induced in a loop • Example 29.1: What is induced EMF & Current?

Emf and the current induced in a loop • Example 29.1: What is induced EMF & Current? df/dt = d(BA)/dt = (dB/dt) A = 0.020 T/s x 0.012 m2 = 0.24 mV I = E/R = 0.24 mV/5.0W = 0.048 mA

Direction of the induced emf • Direction of induced current from EMF creates B field to KEEP original flux constant!

Direction of the induced emf • Direction of induced current from EMF creates B field to KEEP original flux constant! Induced current generates B field flux opposing change

Lenz’s law Lenz’s law: The direction of any magnetic induction effect is such as to oppose the cause of the effect.

Magnitude and direction of an induced emf • Example 29.2 – 500 loop circular coil with radius 4.00 cm between poles of electromagnet. B field decreases at 0.200 T/second. What are magnitude and direction of induced EMF?

Magnitude and direction of an induced emf • Example 29.2 – 500 loop circular coil with radius 4.00 cm between poles of electromagnet. B field decreases at 0.200 T/second. What are magnitude and direction of induced EMF? Careful with flux ANGLE!f between A and B!  = –N dB/dt = [NdB/dt] x [A cos f] Direction? Since B decreases, EMF resists change…

A simple alternator – Example 29.3 • An alternator creates alternatingpositive and negative currents (AC) as a loop is rotated by an external torque while in a fixed magnetic field (or vice-versa!) Note – w comes from an external rotating force! • Water turning a turbine (hydroelectric) • Gasoline Motor turning a shaft (AC generator)

A simple alternator – Example 29.3 • An alternator creates alternatingpositive and negative currents (AC) as a loop rotates in a fixed magnetic field (or vice-versa!) Note – NO commutator to reverse current direction in the loop – so you will get ALTERNATING current

A simple alternator – Example 29.3 • An alternator creates alternatingpositive and negative currents (AC) as a loop rotates in a fixed magnetic field (or vice-versa!) For simple alternator rotating at angular rate of w, what is the induced EMF?

A simple alternator • Example 29.3: For simple alternator rotating at angular rate of w, what is induced EMF? • B is constant; A is constant • Flux B is NOT constant! • B = BAcos f • Angle f varies in time: f = wt • EMF = - d [B ]/dt = -d/dt [BAcos(wt)] • So EMF = wBAsin(wt)

A simple alternator • EMF = wBAsin(wt)

DC generator and back emf in a motor • Example 29.4: A DC generator creates ONLY one-directional (positive) current flow with EMF always the same “sign.” Slip rings DC generator AC alternator

DC generator and back emf in a motor • Example 29.4: A DC generator creates ONLY one-directional (positive) current flow with EMF always the same “sign.” Commutator AC alternator DC generator

DC generator and back emf in a motor • Commutator results in ONLY unidirectional (“direct”) current flow: EMF(DC gen) = | wBAsin(wt) |

DC generator and back emf in a motor • Example 29.4: A DC generator creates ONLY one-directional (positive) current flow with EMF always the same “sign.” “Back EMF” Generated from changing flux through the loop DC generator

DC generator and back emf in a motor • Average EMF generated = AVG( | wBAsin(wt) | )over Period T where T = 1/f = 2p/w

DC generator and back emf in a motor

DC generator and back emf in a motor • Example 29.4: 500 turn coil, with sides 10 cm long, rotating in B field of 0.200 T generates 112 V. What is w?

Lenz’s law and the direction of induced current

Slidewire generator – Example 29.5 • What is magnitude and direction of induced emf? Area A vector chosen to be into page

Slidewire generator – Example 29.5 • B is constant; A is INCREASING => flux increases!

Slidewire generator – Example 29.5 • Area A = Lx so dA/dt = L dx/dt = Lv Width x

Slidewire generator • EMF = - d [B ]/dt = -BdA/dt = -BLv Induced current creates B OUT of page

Work and power in the slidewire generator • Let resistance of wires be “R” • What is rate of energy dissipation in circuit and rate of work done to move the bar?

Work and power in the slidewire generator • EMF = -BLv • I = EMF/R = -BLv/R • Power = I2R = B2L2v2/R

Work and power in the slidewire generator • Work done = Force x Distance • Power applied = Work/Time = Force x velocity • Power = Fv = iLBv and I = EMF/R • Power = (BLv/R)LBv = B2L2v2/R

Motional electromotive force • The motional electromotive force across the ends of a rod moving perpendicular to a magnetic field is = vBL.

Motional electromotive force • The motional electromotive force across the ends of a rod moving perpendicular to a magnetic field is = vBL. • Across entire (stationary) conductor, E field will push current!

Chapter 29

Chapter 29

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Chapter 29

Chapter 29

Chapter 29

Chapter 29

Chapter 29

Chapter 29

Chapter 29

Chapter 29

Chapter 29

CHAPTER 29

Chapter 29

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Chapter 29