Fisica Generale - Alan Giambattista, Betty McCarty Richardson Chapter 20: Electromagnetic Induction •Motional EMF •Electric Generators •Faraday’s Law •Lenz’s Law •Transformers •Eddy Currents •Induced Electric Fields •Mutual- and Self-Inductance •LR Circuits Copyright © 2008 – The McGraw-Hill Companies s.r.l. 1 Fisica Generale - Alan Giambattista, Betty McCarty Richardson §20.1 Motional EMF Consider a conductor in a B-field moving to the right. V Copyright © 2008 – The McGraw-Hill Companies s.r.l. 2 Fisica Generale - Alan Giambattista, Betty McCarty Richardson FB qv B An electron in the conductor experiences a force downward. eV The electrons in the bar will move toward the bottom of the bar. F This creates an electric field in the bar and results in a potential difference between the top and bottom of the bar. Copyright © 2008 – The McGraw-Hill Companies s.r.l. 3 Fisica Generale - Alan Giambattista, Betty McCarty Richardson What if the bar were placed across conducting rails (in red) so that there is a closed loop for the electrons to follow? V L In this circuit, the electrons flow clockwise; the current is counterclockwise. Copyright © 2008 – The McGraw-Hill Companies s.r.l. 4 Fisica Generale - Alan Giambattista, Betty McCarty Richardson The motional EMF is vBL where L is the separation between the rails. The current in the rod is V vBL I R R R where R is the resistance in the “wires”. Copyright © 2008 – The McGraw-Hill Companies s.r.l. 5 Fisica Generale - Alan Giambattista, Betty McCarty Richardson The rod has a current through it. What is the direction of the magnetic force on the rod due to the external magnetic field? F I L B The magnitude of the magnetic force on the rod is: vBL vB2 L2 F ILB sin 90 ILB LB R R Using the right hand rule, the force on the bar is directed to the left. Copyright © 2008 – The McGraw-Hill Companies s.r.l. 6 Fisica Generale - Alan Giambattista, Betty McCarty Richardson To maintain a constant EMF, the rod must be towed to the right with constant speed. An external agent must do work on the bar. (Energy conservation) Copyright © 2008 – The McGraw-Hill Companies s.r.l. 7 Fisica Generale - Alan Giambattista, Betty McCarty Richardson §20.2 Electric Generators A coil of wire is spun in a magnetic field. This produces an EMF and also a current; both vary with time. (ACalternating current) An energy source is needed to turn the wire coil. Examples include burning coal or natural gas to produce steam; falling water. Copyright © 2008 – The McGraw-Hill Companies s.r.l. 8 Fisica Generale - Alan Giambattista, Betty McCarty Richardson The EMF produced by an AC generator is: t 0 sin t In the United States and Canada 0 = 170 volts and f = /2 = 60 Hz. Copyright © 2008 – The McGraw-Hill Companies s.r.l. 9 Fisica Generale - Alan Giambattista, Betty McCarty Richardson §20.3 Faraday’s Law Moving a conductor through a B-field will generate an EMF. Another way to generate an EMF is to place a stationary conductor in a B-field that varies with time. Copyright © 2008 – The McGraw-Hill Companies s.r.l. 10 Fisica Generale - Alan Giambattista, Betty McCarty Richardson The magnetic flux is proportional to the number of B-field lines that cross a given area. The unit of magnetic flux is the weber: 1 Wb = 1 Tm2 B BA cos Loop of wire with area A Copyright © 2008 – The McGraw-Hill Companies s.r.l. 11 Fisica Generale - Alan Giambattista, Betty McCarty Richardson B Faraday’s Law: N t An induced EMF in a “coil” of N loops is due to a changing magnetic flux. Ways to induce an EMF: 1. Vary the magnetic field. 2. Vary the area of the coil. 3. Change the angle between B and A. Copyright © 2008 – The McGraw-Hill Companies s.r.l. 12 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Example: If the magnetic field in a region varies with time according to the graph shown below, find the magnitude of the induced EMF in a single loop of wire during the following time intervals: (a) 0-2.0 ms, (b) 2.0-4.0 ms, and (c) 4.0-8.0 ms. The loop has area 0.500 m2 and the plane of the loop is perpendicular to the B-field. B (T) 0.50 T t (ms) 2 4 8 Copyright © 2008 – The McGraw-Hill Companies s.r.l. 13 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Example continued: Using Faraday’s Law: B B A t t This is the slope of the given B versus time graph. Copyright © 2008 – The McGraw-Hill Companies s.r.l. 14 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Example continued: (a) In the interval 0.0-2.0 ms, B 2 0.50T-0.00T A 0.500 m 130 V. 3 t 2.0 10 s (b) In the interval 2.0-4.0 ms, B 2 0.50T-0.50T A 0.500 m 0 V. 3 t 2.0 10 s Copyright © 2008 – The McGraw-Hill Companies s.r.l. 15 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Example continued: (c) In the interval 4.0-8.0 ms, B 2 A 0.500 m t 0.00T-0.50T 63 V. 3 4.0 10 s Copyright © 2008 – The McGraw-Hill Companies s.r.l. 16 Fisica Generale - Alan Giambattista, Betty McCarty Richardson §20.4 Lenz’s Law The direction of induced EMFs and currents always oppose the change in flux that produced them. That is, the induced I (and thus induced B) tries to keep the total flux through the loop constant. Copyright © 2008 – The McGraw-Hill Companies s.r.l. 17 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Example: Towing the bar to the right produced an induced current that was CCW. What is the direction of the induced magnetic field? V L The induced B is out of the page to maintain the flux originally through the loop before the bar started to move to the right (the area of the loop is increasing). Copyright © 2008 – The McGraw-Hill Companies s.r.l. 18 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Example (text problem 20.12): A long straight wire carrying a steady current is in the plane of a circular loop of wire. (a) If the loop of wire is moved closer to the wire, what is the direction of the induced current in the wire loop? I Wire loop There is a magnetic field into the page at the location of the loop. As the loop gets closer to the wire there is an increase in flux. To negate this increase in flux, the induced B-field must point out of the page. This requires a CCW current. Copyright © 2008 – The McGraw-Hill Companies s.r.l. 19 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Example continued: (b) At one instant, the induced EMF in the loop is 3.5 mV. What is the rate of change of the magnetic flux through the loop in that instant? B 3.5 mV 3.5 10 3 Wb / s t Copyright © 2008 – The McGraw-Hill Companies s.r.l. 20 Fisica Generale - Alan Giambattista, Betty McCarty Richardson §20.5 Transformers Wrap an iron core with wire. Secondary coil Primary coil Apply a varying voltage to the primary coil. This causes a changing magnetic flux in the secondary coil. B 1 N1 t 2 N2 B t Copyright © 2008 – The McGraw-Hill Companies s.r.l. 21 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Since the flux through the coils is the same 1 N1 2 N2 The “turns ratio” gives the ratio of the EMFs. Depending on the turns ratio, a transformer can be used to step-up or step-down a voltage. The rate that power is supplied to both coils is the same 1 I 2 N1 2 I1 N 2 Copyright © 2008 – The McGraw-Hill Companies s.r.l. 22 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Example (text problem 20.25): A step-down transformer has a turns ratio of 1/100. An AC voltage of amplitude 170 V is applied to the primary. If the primary current is 1.0 mA, what is the secondary current? I 2 N1 I1 N 2 N1 100 I1 I 2 1.0 mA 0.1 A 1 N2 Copyright © 2008 – The McGraw-Hill Companies s.r.l. 23 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Example (text problem 20.27): The primary coil of a transformer has 250 turns and the secondary coil has 1000 turns. An AC voltage is sent through the primary. The EMF of the primary is 16.0 V. What is the EMF in the secondary? 1 N1 2 N2 N2 1000 2 1 16.0 V 64.0 V 250 N1 Copyright © 2008 – The McGraw-Hill Companies s.r.l. 24 Fisica Generale - Alan Giambattista, Betty McCarty Richardson §20.6 Eddy Currents If a conductor is subjected to a changing magnetic flux, a current will flow. (This includes sheets of metal, etc.) Copyright © 2008 – The McGraw-Hill Companies s.r.l. 25 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Consider a metal plate that swings through a magnetic field. pivot X An external magnetic field into the page created by a magnet. Copyright © 2008 – The McGraw-Hill Companies s.r.l. 26 Fisica Generale - Alan Giambattista, Betty McCarty Richardson As the plate swings through the region of magnetic field, some regions of the plate are entering the B-field (increasing flux), and other regions of the plate are leaving the B-field (decreasing flux). There will be induced currents in the conductor called eddy currents. The eddy currents dissipate energy (according to I2R); this results in the damping of the amplitude of the metal sheet. Copyright © 2008 – The McGraw-Hill Companies s.r.l. 27 Fisica Generale - Alan Giambattista, Betty McCarty Richardson §20.7 Induced Electric Fields When a stationary conductor sits in a changing magnetic field it is an induced electric field that causes the charges in the conductor to move. Copyright © 2008 – The McGraw-Hill Companies s.r.l. 28 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Copyright © 2008 – The McGraw-Hill Companies s.r.l. 29 Fisica Generale - Alan Giambattista, Betty McCarty Richardson §20.8 Mutual- and Self-Inductance A variable current I1 flows in coil 1. Coil 1 Coil 2 I1 then induces a current in coil 2. The flux (21) through coil 2 due to coil 1 is N 2 21 I1. Copyright © 2008 – The McGraw-Hill Companies s.r.l. 30 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Writing this as an equality, N221 MI1 Where M is the mutual inductance. It depends only on constants and geometrical factors. The unit of inductance is the Henry (1H = 1Vs/A). 21 I1 2 N2 M t t The induced EMF in the coils will be: 12 I 2 1 N1 M t t Copyright © 2008 – The McGraw-Hill Companies s.r.l. 31 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Self-inductance occurs when a current carrying coil induces an EMF in itself. The definition of self-inductance (L) is N LI . Copyright © 2008 – The McGraw-Hill Companies s.r.l. 32 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Example (text problem 20.41): The current in a 0.080 Henry solenoid increases from 20.0 mA to 160.0 mA in 7.0 s. Find the average EMF in the solenoid during that time interval. I N L t t 160 mA 20 mA 0.080 H 7.0 s 1.6 10 3 V Copyright © 2008 – The McGraw-Hill Companies s.r.l. 33 Fisica Generale - Alan Giambattista, Betty McCarty Richardson An inductor stores energy in its magnetic field according to: 1 2 U LI 2 The energy density in a magnetic field is: uB 1 20 B2 Copyright © 2008 – The McGraw-Hill Companies s.r.l. 34 Fisica Generale - Alan Giambattista, Betty McCarty Richardson §20.9 LR Circuits An inductor and resistor are connected in series to a battery. As with an RC circuit, the current in the circuit varies with time. Copyright © 2008 – The McGraw-Hill Companies s.r.l. 35 Fisica Generale - Alan Giambattista, Betty McCarty Richardson I . The voltage drop across an inductor is given by L L t When an inductor is “charging” (the energy stored is increasing) the current in the circuit is: I (t ) I f 1 et / Where = L/R is the time constant for the circuit and If = b/R maximum current in the circuit. Copyright © 2008 – The McGraw-Hill Companies s.r.l. 36 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Applying Kirchhoff’s loop rule to the circuit gives the EMF in the inductor as: L b IR b e t / Copyright © 2008 – The McGraw-Hill Companies s.r.l. 37 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Plots of L(t) and I(t) for this LR circuit: Copyright © 2008 – The McGraw-Hill Companies s.r.l. 38 Fisica Generale - Alan Giambattista, Betty McCarty Richardson For a “discharging” inductor, I (t ) I 0 e t / where I0 is the current in the inductor when t=0. The LR circuit time constant plays the same role as in an RC circuit. Copyright © 2008 – The McGraw-Hill Companies s.r.l. 39 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Example: A coil has an inductance of 0.15 H and a resistance of 33.0 . The coil is connected to a 6.0 V ideal battery. When the current reaches one-half the maximum value: (a) At what rate is the magnetic energy being stored in the inductor? I max Vmax Power P IV 2 2 Vmax= emf of the battery (b) = 6.0 Volts I max b R 0.18 Amps I max Vmax P 0.27 Watts 2 2 Copyright © 2008 – The McGraw-Hill Companies s.r.l. 40 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Example continued: (b) At what rate is energy being dissipated? Energy is dissipated in the resistor at a rate 2 I max 2 P I R R 2 2 0.18 Amps 33.0 0.27 Watts. 2 Copyright © 2008 – The McGraw-Hill Companies s.r.l. 41 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Example continued: (c) What is the total power the battery supplies? The battery must supply energy to the inductor and the resistor. Part a and b calculate the rate at which energy is delivered to the inductor and resistor respectively; the battery must supply the sum of these: Pbattery = 0.54 Watts. Copyright © 2008 – The McGraw-Hill Companies s.r.l. 42 Fisica Generale - Alan Giambattista, Betty McCarty Richardson Summary •Motional EMF •Faraday’s Law •Lenz’s Law •Transformers •Eddy Currents •Inductance and Inductors •LR Circuits Copyright © 2008 – The McGraw-Hill Companies s.r.l. 43