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W10D1: Inductance and Magnetic Field Energy Today’s Reading Assignment W10D1 Inductance & Magnetic Energy Course Notes: Sections 11.1-3 1 Announcements Math Review Week 10 Tuesday from 9-11 pm in 32-082 PS 7 due Week 10 Tuesday at 9 pm in boxes outside 32-082 or 26-152 Next Reading Assignment W10D2 DC Circuits & Kirchhoff’s Loop Rules Course Notes: Sections 7.1-7.5 Exam 3 Thursday April 18 7:30 pm –9:30 pm 2 Outline Faraday Law Problem Solving Faraday Law Demonstrations Mutual Inductance Self Inductance Energy in Inductors Transformers 3 Faraday’s Law of Induction If C is a stationary closed curve and S is a surface spanning C then d E × d s = òC dt B × d A òò S The changing magnetic flux through S induces a non-electrostatic electric field whose line integral around C is non-zero 4 Problem: Calculating Induced Electric Field d E×ds = B×dA ò òò dt open surface closed path Consider a uniform magnetic field which points into the page and is confined to a circular region with radius R. Suppose the magnitude increases with time, i.e. dB/dt > 0. Find the magnitude and direction of the induced electric field in the regions (i) r < R, and (ii) r > R. (iii) Plot the magnitude of the electric field as a function r. 5 Faraday’s Law Demonstrations 6 Demonstration: Electric Guitar H32 Pickups http://tsgphysics.mit.edu/front/?page=demo.php&letnum=H%2032&show=0 7 Electric Guitar 8 Demonstration: 32-082 Aluminum Plate between Pole Faces of a Magnet H 14 http://tsgphysics.mit.edu/front/?page=demo.php&letnum=H 14&show=0 26-152 Copper Pendulum Between Poles of a Magnet H13 http://tsgphysics.mit.edu/front/?page=demo.php&letnum=H 13&show=0 9 Eddy Current Braking What happened to kinetic energy of pendulum? 10 Eddy Current Braking The magnet induces currents in the metal that dissipate the energy through Joule heating: 1. Current is induced counter-clockwise (out from center) 2. Force is opposing motion (creates slowing torque) 11 Eddy Current Braking The magnet induces currents in the metal that dissipate the energy through Joule heating: 1. Current is induced clockwise (out from center) 2. Force is opposing motion (creates slowing torque) 3. EMF proportional to angular frequency 12 Demonstration: 26-152 Levitating Magnet H28 http://tsgphysics.mit.edu/front/?page=demo.php&letnum=H 28&show=0 32-082 Levitating Coil on an Aluminum Plate H15 http://tsgphysics.mit.edu/front/?page=demo.php&letnum=H 15&show=0 13 Mutual Inductance 14 Demonstration: Two Small Coils and Radio H31 http://tsgphysics.mit.edu/front/?page=demo.php&letnum=H 31&show=0 15 Mutual Inductance Current I2 in coil 2, induces magnetic flux F12 in coil 1. “Mutual inductance” M12: F12 º M12 I 2 M12 = M 21 = M Change current in coil 2? Induce EMF in coil 1: dI 2 e12 º - M12 dt 16 Group Problem: Mutual Inductance An infinite straight wire carrying current I is placed to the left of a rectangular loop of wire with width w and length l. What is the mutual inductance of the system? 17 Self Inductance 18 Self Inductance What if is the effect of putting current into coil 1? There is “self flux”: F B º LI Faraday’s Law e dI = -L dt 19 Calculating Self Inductance L Unit: Henry 1. 2. 3. 4. F total B,self I V s 1H=1 A Assume a current I is flowing in your device Calculate the B field due to that I Calculate the flux due to that B field Calculate the self inductance (divide out I) 20 Worked Example: Solenoid Calculate the selfinductance L of a solenoid (n turns per meter, length , radius R) L F total B,self I 21 Solenoid Inductance ò B×ds = B = m0 I enc = m0 ( n ) I B 0 nI F B,turn = òò B × d A = BA = m0 nIp R L N F B,turn I 2 N 0 n R 0 n R l 2 2 2 22 Concept Question: Solenoid A very long solenoid consisting of N turns has radius R and length d, (d>>R). Suppose the number of turns is halved keeping all the other parameters fixed. The self inductance 1. remains the same. 2. doubles. 3. is halved. 4. is four times as large. 5. is four times as small. 6. None of the above. 23 Concept Q. Ans.: Solenoid Solution 5. The self-induction of the solenoid is equal to the total flux through the object which is the product of the number of turns time the flux through each turn. The flux through each turn is proportional to the magnitude of magnetic field which is proportional to the number of turns per unit length or hence proportional to the number of turns. Hence the selfinduction of the solenoid is proportional to the square of the number of turns. If the number of turns is halved keeping all the other parameters fixed then he self inductance is four times as small. 24 Group Problem: Toroid Calculate the selfinductance L of a toroid with a square cross section with inner radius a, outer radius b = a+h, (height h) and N square windings . L F total B,self I REMEMBER 1. Assume a current I is flowing in your device 2. Calculate the B field due to that I 3. Calculate the flux due to that B field 4. Calculate the self inductance (divide out I) 25 Energy in Inductors 26 Inductor Behavior L I dI L dt Inductor with constant current does nothing 27 Back EMF dI L dt dI L dt I dI 0 dt L 0 I dI 0 L 0 dt 28 Demos: 26-152 Back “emf” in Large http://tsgphysics.mit.edu/front/?page=demo.php&letnum=H 17&show=0 Inductor H17 32-082 Marconi Coil H12 http://tsgphysics.mit.edu/front/?page=demo.php&letnum=H 12&show=0 29 Marconi Coil: On the Titanic Another ship Same era Titanic Marconi Telegraph 30 Marconi Coil: Titanic Replica 31 The Point: Big EMF Big L Big dI Small dt dI L dt Huge EMF 32 Energy To “Charge” Inductor 1. Start with “uncharged” inductor 2. Gradually increase current. Must do work: dI dW = Pdt = e I dt = L I dt = LI dI dt 3. Integrate up to find total work done: W dW I LI dI L I 1 2 2 I 0 33 Energy Stored in Inductor UL L I 1 2 2 But where is energy stored? 34 Example: Solenoid Ideal solenoid, length l, radius R, n turns/length, current I: B 0 nI L o n R l 2 2 U B = LI = ( mo n p R l)I 1 2 2 1 2 2 2 2 B2 2 UB R l 2 o Energy Density Volume 35 Energy Density Energy is stored in the magnetic field 2 B uB 2o Magnetic Energy Density Energy is stored in the electric field o E uE 2 2 Electric Energy Density 36 Worked Example: Energy Stored in Toroid Consider a toroid with a square cross section with inner radius a, outer radius b = a+h, (height h) and N square windings with current I. Calculate the energy stored in the magnetic field of the torus. 37 Solution: Energy Stored in Toroid The magnetic field in the torus is given by 0 NI B 2 r The stored energy is then U mag 1 2 0 B 2 dVvol all space 2 1 2 0 h0 N 2 I 2 h 0 NI r dr 0 a 2 r 4 b b 2 B h2 r dr a 2 2 dr h0 N I b ln r 4 a a b The self-inductance is L 2U mag I2 0 N 2 b h ln 2 a 38 Group Problem: Coaxial Cable Inner wire: r = a Outer wire: r = b I X I 1. How much energy is stored per unit length? 2. What is inductance per unit length? HINTS: This does require an integral The EASIEST way to do (2) is to use (1) 39 Transformer Step-up transformer Flux F through each turn same: ep dF = Np ; dt dF e s = Ns dt es Ns = ep Np Ns > Np: step-up transformer Ns < Np: step-down transformer 40 Demonstrations: 26-152 One Turn Secondary: Nail H10 http://tsgphysics.mit.edu/front/?page=demo.php&letnum=H 10&show=0 26-152 Many Turn Secondary: Jacob’s Ladder H11 http://tsgphysics.mit.edu/front/?page=demo.php&letnum=H 11&show=0 32-082 Variable Turns Around a Primary Coil H9 http://tsgphysics.mit.edu/front/?page=demo.php&letnum=H 9&show=0 41 Concept Question: Residential Transformer If the transformer in the can looks like the picture, how is it connected? 1. House=Left, Line=Right 2. Line=Left, House=Right 3. I don’t know 42 Answer: Residential Transformer Answer: 1. House on left, line on right The house needs a lower voltage, so we step down to the house (fewer turns on house side) 43 Transmission of Electric Power Power loss can be greatly reduced if transmitted at high voltage 44 Electrical Power Power is change in energy per unit time So power to move current through circuit elements: d d dq P U qV V dt dt dt P I V 45 Power - Resistor Moving across a resistor in the direction of current decreases your potential. Resistors always dissipate power V Pdissipated I V I R R 2 2 46 Example: Transmission lines An average of 120 kW of electric power is sent from a power plant. The transmission lines have a total resistance of 0.40 W. Calculate the power loss if the power is sent at (a) 240 V, and (b) 24,000 V. (a) P 1.2 105W I 500A 2 V 2.4 10 V 83% loss!! PL I 2 R (500A)2 (0.40W) 100kW 5 P 1.2 10 W (b) I 5.0 A 4 V 2.4 10 V PL I 2 R (5.0A)2 (0.40W) 10W 0.0083% loss 47 Transmission lines We just calculated that I2R is smaller for bigger voltages. What about V2/R? Isn’t that bigger? Why doesn’t that matter? 48