Board Work 1.If the magnetic field B intensifies, in what direction will a current be induced around the loop? B Which direction is the flux change? What.

Slides:

Advertisements

Similar presentations

Applications of Electromagnetism

Advertisements

Alternating Current Circuits and Electromagnetic Waves

Quiz 9 Fall For magnets, like poles repel each other and unlike poles A. also repel each other. B. attract each other. C. can attract or repel.

My Chapter 22 Lecture.

© 2012 Pearson Education, Inc. { Chapter 31 Alternating Current Circuits (cont.)

Alternating Current Circuits And Electromagnetic Waves Chapter 21.

Chapter 21 Alternating Current Circuits and Electromagnetic Waves 1. Alternating Current 2. Resistor in an AC circuit 3. Capacitor in an AC circuit 4.

Physics for Scientists and Engineers II, Summer Semester Lecture 20: July 10 th 2009 Physics for Scientists and Engineers II.

Characteristics of Light

L 28 Electricity and Magnetism [6] magnetism Faraday’s Law of Electromagnetic Induction –induced currents –electric generator –eddy currents Electromagnetic.

L 28 Electricity and Magnetism [6] magnetism Faraday’s Law of Electromagnetic Induction –induced currents –electric generator –eddy currents Electromagnetic.

Chapter 29 Continued-Chapter 31- Chapter EMF Induced in a Moving Conductor Example 29-8: Force on the rod. To make the rod move to the right.

Chapter 22: Electromagnetic Waves

CHEMISTRY 161 Chapter 7 Quantum Theory and Electronic Structure of the Atom

Phy 213: General Physics III Chapter 30: Induction & Inductance Lecture Notes.

Transformer. AC Source  Alternating current comes from generators, not batteries. Ideal sinusoidal sourceIdeal sinusoidal source  The symbol for an.

Electro-Magnetic Induction © David Hoult Magnetic flux © David Hoult 2009.

Eleanor Roosevelt High School Chin-Sung Lin Lesson 21.

Day 4: Transformers Definition of a Transformer Transformer Windings Transformer Operation using Faraday’s Law Step-up & Step-down Transformers Turns Ratio.

Principles of Physics Electromagnetic Induction. Changing magnetic fields can create a voltage (and thus cause current to flow) in a conductor A wire.

Electromagnetic Induction

Motion The base SI units for length, time, and mass are meters, seconds, and kilograms Movement in relation to a frame of reference is called relative.

Electromagnetism Chapter 8. Summary of Important Equations to understand for the HW: 1. V o N o --- = --- V i N i 2.v = c = λ · f 3.λ max = / T.

Lecture 11 Electromagnetic Waves Chapter 21.8  Outline Discovery and Studies of Electromagnetic Waves Properties of Electromagnetic Waves The Spectrum.

Exam 2 Thursday, March 24 8 problems on the test

Chapter 22: Electromagnetic Induction Essential Concepts and Summary.

Electromagnetic Induction Create electric current from changing magnetic fields.

Parts of a Wave. Physical Science EOCT Review Domain IV Waves, Electricity and Magnetism.

Motional EMF This is the emf induced in a conductor moving through a magnetic field. Examples on sheet 10 To change the magnetic flux we can change: 1.the.

MagnetismSection 3 Section 3: Electric Currents from Magnetism Preview Key Ideas Bellringer Electromagnetic Induction The Electromagnetic Force Transformers.

Chapter 21 Electromagnetic Waves. General Physics Exam II Curve: +30.

Activity B1-WA due by 4 pm Friday 03/28 Chapter 5 Mallard HW quiz – Due by 12 AM Thursday 03/27 Chapter 5 quiz in class on Thursday 03/27 Tuesday, March.

Copyright © by Holt, Rinehart and Winston. All rights reserved. ResourcesChapter menu Objectives Describe the conditions required for electromagnetic induction.

Magnetism Chapter 36. What is a Magnet? Material or object that produces a magnetic field. Two types:  Permanent  Electromagnet.

13.5 Transformers Different electrical devices require different amounts of electrical energy to operate. An electric stove requires a lot of electrical.

Magnetic Flux and Faraday’s Law of Induction

Magnetism Part 3: Electric Currents From Magnetism

Moving charges create magnetic fields. What do moving magnets do?

Unit 9: Part 2 Electromagnetic Induction and Waves.

Chapter 21: Alternating Current Circuits and EM Waves Resistors in an AC Circuits Homework assignment : 22,25,32,42,63  AC circuits An AC circuit consists.

REVISION ELECTROMAGNETISM. ELECTROMAGNETIC SPECTRUM (EMS)

Electromagnetic Induction. Motion of a magnet in a coil or loop creates (induces) voltage If coil is connected to complete circuit, current flows Relative.

© Houghton Mifflin Harcourt Publishing Company Preview Objectives Electromagnetic Induction Characteristics of Induced Current Sample Problem Chapter 20.

Physics 213 General Physics Lecture 14. Test 1 1. Click in!!

L 29 Electricity and Magnetism [6]

L 28 Electricity and Magnetism [6] magnetism Faraday’s Law of Electromagnetic Induction –induced currents –electric generator –eddy currents Electromagnetic.

Faraday’s Law of Induction Magnetic flux  = A B cos   B A A changing magnetic flux generates an induced voltage (emf = electromotive force) V = [emf]

Practice Problems A horizontal wire is moving vertically upwards in a horizontal magnetic field of strength tesla which is perpendicular to the.

Electromagnetism Faraday & Maxwell. Maxwell James Clerk Faraday ( ) was an Scottish scientist. He was a gifted mathematician and one of the first.

 Electromagnetic Induction – The production of an emf (the energy per unit charge supplied by a source of electric current) in a conducting circuit by.

Physics 213 General Physics Lecture Last Meeting: Electric Generators, Alternating Current Today: Electromagnetic Waves, Maxwell’s Equations.

Light, color, and frequency pg. 71. Objectives Describe a light wave. Understand qualitatively the relationship between color, frequency, and wavelength.

Transformer Objectives 1.Describe how a transformer works by watching a video clip. 2.Apply the transformer equations by solving problems.

L 28 Electricity and Magnetism [6] magnetism Faraday’s Law of Electromagnetic Induction –induced currents –electric generator –eddy currents Electromagnetic.

20 Overview current  magnetic field magnetic field  current

Chapter 20 Preview Objectives Electromagnetic Induction

Lecture 19 Electromagnetic Waves.

Electromagnetic Spectrum and EM Waves

General Physics L19_EMwaves Chapter 24

Transforming energy with magnetism

Electric Currents from Magnetism

25.1 The Electromagnetic Spectrum

25.1 The Electromagnetic Spectrum

P1H Smart Lesson 5.

Phys102 Lecture 20 Electromagnetic Waves * (skipped)

AC Transformers Source: OSHA.

Transforming energy with magnetism

Ch. 5 - Electrons in Atoms Waves & Particles.

SCI 340 L51 Light and color not really in your book

Warm-up Is it possible to create a circuit with wires, but no battery or other electrical power supply?

Presentation transcript:

Board Work 1.If the magnetic field B intensifies, in what direction will a current be induced around the loop? B Which direction is the flux change? What current would oppose it?

AC Transformers Source: OSHA

Objective Relate input and output power, voltage, current, and number of windings in an AC transformer.

Flux Change Creates Potential Rapidly changing field high induced potential unchanging field zero induced potential

How a Transformer Works Alternating current in the primary coil creates a changing magnetic field. The changing field induces an electric potential in the secondary coil.

Potential Proportional to Loops Same flux  and area A through both sets of windings Each loop adds potential Potentials V are proportional to the number of loops N V1V1 N1N1 V2V2 N2N2 =

Energy is Conserved Ideally: power in = power out V 1 I 1 = V 2 I 2 Realistic: power in > power out Efficiencies usually around 95%

Transformer Summary Power in  power out  loops  higher V, lower I  loops  lower V, higher I

Poll Question A “step-down” transformer converts input at 120 V to output at 20 V. If the input circuit has 1100 W, how much power is available at the output? A.200 W. B.660 W. C.1100 W. D.2400 W.

Board Work 2.A transformer with 1000 primary windings converts AC at 110 V (primary) to 220 V (secondary). a.Which is greater: the potential in the primary circuit or the potential in the secondary circuit? b.Where will the number of loops be greater: in the primary or in the secondary?

Board Work 2.A transformer with 1000 primary windings converts AC at 110 V (primary) to 220 V (secondary). c.What is the voltage ratio V 2 /V 1 ? d.What is the loops ratio N 2 /N 1 ? e.How many loops are in the secondary circuit (N 2 )?

Board Work 2.A transformer with 1000 primary windings converts AC at 110 V (primary) to 220 V (secondary). f.What is the current ratio I 2 / I 1 ?

Formulas for Transformers Power: V 1 I 1 = V 2 I 2 Current: I 2 = I 1 V1V1 V2V2 = I1= I1 N1N1 N2N2 Potential: V 2 = V 1 I1I1 I2I2 = V1= V1 N2N2 N1N1 Loops: V1V1 V2V2 N1N1 N2N2 =

Example A transformer with 5000 primary coils and 100 secondary coils has an input voltage of 50 kV. What is the output voltage? V out = V in N out /N in = (50 kV)(100/5000) = (50 kV)/50 = 1 kv = 1,000 V

Light Chapter 26

Objectives Describe the transverse “medium” of electromagnetic waves.

Thought experiment: charging parallel plates Last Piece of EM Theory A changing electric field acts as a current Charges accumulate on the plates A changing E field creates a B field! Maxwell’s pivotal insight I I +– E B The E field between the plates increases The changing E field is sort of a virtual current

Electromagnetic Fields Faraday’s law: a changing magnetic field creates an electric field BB EE Virtual Current: a changing electric field creates a magnetic field

What They Mean Faraday’s Law = Lorentz Force –A transversely-moving B field makes an E field –The electric field is proportional to the magnetic field strength BB

What They Mean Virtual current works the same way –A transversely-moving E field makes a B field –The magnetic field is proportional to the electric field strength (note the directions)

Electromagnetic Field Interplay A moving B field creates an E field –E direction = B  v direction B v E B v E v B E The fields are self-propagating –v direction = E  B direction A moving E field creates a B field –B direction = v  E direction

AC Creates Oscillating B Field Observe here

The End Result Electric and magnetic fields are perpendicular: to each other, and to the direction of propagation.

Poll Question Are electromagnetic waves transverse, longitudinal, or a combination of both? A.Transverse. B.Longitudinal. C.A combination of transverse and longitudinal.

Speed of Light c =  10 8 m/s (in vacuum)

Electromagnetic Wave Energy Non-classical result: E = hf E = energy f = frequency h = Planck constant =  J s

Electromagnetic Spectrum

Temp Influences Spectrum Higher T  greater power – P/A =  T 4 –  = 5.67  10 –8 W m –2 K –4 Higher T  higher peak frequency – max = b/T – b =  10 6 nm K Source: M. A. Seeds, Exploring the Universe

Poll Question How do “warm” colors (red, orange, yellow) and “cool” colors (green, blue) relate to temperature? A.At higher temperatures, more of the light emitted is “warm”-colored. B.At higher temperatures, more of the light emitted is “cool”-colored.

Something to Ponder Why do hotter objects emit a greater fraction of their energy at short wavelengths (high frequencies)?

Reading for Next Time Color –How we see color –Why things are colored