Summary of the last lecture

Slides:

Advertisements

Similar presentations

Chapter 11 Inductors.

Advertisements

ENERGY CONVERSION ONE (Course 25741) Chapter one Electromagnetic Circuits …continued.

MAGNETISM. The Earth Magnetic Poles North and South Geographic Poles North and South Earth is a giant magnet.

Electromagnetism and magnetic circuits.

Magnetic Circuits and Transformers

12: Electromagnetic Induction 12.2 Alternating Current.

Engr. Abbas Abbasi Behavior of Ferromagnetic Materials Saturation and Hysteresis.

Magnetism and Magnetic Circuits

Copyright © 2009 Pearson Education, Inc. Lecture 9 – Electromagnetic Induction.

Magnetic Field Basic Concepts: A current carrying wire produces a magnetic field in the area around it. A time changing magnetic field induces a voltage.

Mehran University Of Engineering And Technology ZAB Khairpur Campus Subject :- Theory Of EMF Lecturer:- Engr: Toqueer Jumani Department Of Electrical.

Magnetism & Electromagnetism

Lecture No. 15 By. Sajid Hussain Qazi.  Physical explanation of Hysteresis loss ▪ The magnetic core of transformer is made of ′ Cold Rolled Grain Oriented.

ELECTRICAL ENGINEERING: PRINCIPLES AND APPLICATIONS, Third Edition, by Allan R. Hambley, ©2005 Pearson Education, Inc. Chapter 15 Magnetic Circuits and.

ET 332a Dc Motors, Generators and Energy Conversion Devices Lesson 2: Magnetic Circuits- Quantities and Definitions 1.

Lesson 4: Solving Magnetic Circuits with Electrical Analogies ET 332a Dc Motors, Generators and Energy Conversion Devices 1.

Magnetic Field Basic Concepts:

Magnetic and Electromagnetic Fields

Chapter 29 Electromagnetic Induction and Faraday’s Law

Counter EMF (also known as Back EMF) When the current through an inductor changes, the magnetic field also changes. This changing magnetic field causes.

EEE107 Magnetism.

AP Physics C Montwood High School R. Casao

C H A P T E R 22 Electromagnetic Induction.

DC GENERATOR CHAPTER-9.

MUZAIDI BIN MARZUKI Chapter 4: Electromagnetic.

Chapter 16 DC Generators.

Elec467 Power Machines & Transformers

Chapter 1 MAGNETIC CIRCUIT.

Chapter 2 Electromagnetism Dr. Mohd Junaidi Abdul Aziz

Chapter 21 Electromagnetic Induction and Faraday’s Law.

ELECTRICAL BASICS (Chapter 8) Electrical terms Electricity & magnetism Electricity Circuits Magnetism Electrical units Electric potential or eletromotive.

Fundamentals of Electromagnetics and Electromechanics

Announcements For lectures 8 to 10 please be reading Chapter 3

Electric Machinery 王嘉帷 MA

ELECTRICAL ENGINEERING: PRINCIPLES AND APPLICATIONS, Fourth Edition, by Allan R. Hambley, ©2008 Pearson Education, Inc. Lecture 21 Magnetic Circuits, Materials.

Transformers Transformers are some of the most efficient machines that can be built, with efficiencies exceeding 99%. Only simple machines (levers, inclined.

CHAPTER 2 MAGNETIC MATERIALS AND CIRCUITS

Chapter 21 Electromagnetic Induction and Faraday’s Law.

Counter EMF (also known as Back EMF) When the current through an inductor changes, the magnetic field also changes. This changing magnetic field causes.

Tuesday April 19, PHYS , Dr. Andrew Brandt PHYS 1444 – Section 02 Lecture #18 Tuesday April 19, 2011 Dr. Andrew Brandt Chapter 29 Lenz Law.

3/17/2014 PHYS , Dr. Andrew Brandt 1 PHYS 1442 – Section 004 Lecture #15 Monday March 17, 2014 Dr. Andrew Brandt Chapter 21 Generator Transformer.

Lesson 3: Solving Magnetic Circuits

Lecture 4 by Moeen Ghiyas Chapter 11 – Magnetic Circuits 21/01/20161.

Hysteresis When we increased the current we observed, saturation. What would happen if I decrease the current after saturation? The flux for a given H.

Wednesday, April 11, PHYS , Spring 2007 Dr. Andrew Brandt PHYS 1444 – Section 004 Lecture #18 Wednesday, April Dr. Andrew Brandt.

POWER CIRCUIT & ELECTROMAGNETICS EET 221 Transformer.

Copyright © 2009 Pearson Education, Inc. Chapter 30 Inductance, Electromagnetic Oscillations, and AC Circuits HW8: Chapter 28:18,31,40 Chapter 29:3, 30,48.

L-8 MAGNETIC CIRCUITS ELE 1001: Basic Electrical Technology

Magnetic Circuits and Magnetic Materials

True-False Questions. A magnetic core material may exhibit hysteresis or saturation but not both.

DCMT PRESENTATION DEVANSH KHARE ( )

Lesson 8: Ideal Transformer Theory and Operation

True-False Questions.

Introduction to magnetic circuits

ECE 476 POWER SYSTEM ANALYSIS

Hansaba College of Engineering & Technology

Electric Machine Magnetic Circuit

ELECTRICAL TECHNOLOGY EET 103/4

Lecture 2: Electro-Mechanical Fundamentals

Transformers. Transformer An A.C. device used to change high voltage low current A.C. into low voltage high current A.C. and vice-versa without changing.

PHYS 1444 – Section 003 Lecture #18

TRANSFORMER JITANSHU SINGH 15/ICE/25.

Lesson 4: Solving Magnetic Circuits with Electrical Analogies

Energy Conversion and Transport George G. Karady & Keith Holbert

Chapter 1 Introduction to Machinery Principles

Electrical Machines (EELE 3351)

Unit-1 Transformer.

Presentation transcript:

Summary of the last lecture

Magnetic circuits Compare this formula with Ohm’s law in electric circuits:

Another useful formula in a series situation

Problem 1-8 Assume 4% increase in effective Cross-sectional area for fringing effect Calculate the flux density in each of the legs

Magnetic Behaviour of Ferromagnetic Materials We talked about Ferromagnetic materials, such as iron, steel, cobalt, nickel and some alloys. They have a high relative permeability (2000-6000). In magnetic circuit theory we assumed: where is a constant.

By this assumption we have assumed a linear relation, i.e.: This means in a coil if I increase the current to twice as much, the flux will be twice as much as well. This is what we call linear relation.

But the reality is different. These are typical curves But the reality is different. These are typical curves.We have saturation.

Typical B-H curve of steel

Typical ur-H curve of steel

Now, can we solve the problems knowing these curves ? In some problems, instead of giving the relative permeability, they produce the B-H curve. In these cases, the operating condition (Bo-Ho), should be known somehow. If it is known, there would be no problem.

Remember the example: Given : i=1 A, N=100, lc=40 cm, A= 100 cm2 r =5000 Calculate : F, H, B, , and

Now consider this example: Given : i=1 A, N=100, lc=40 cm, A= 100 cm2 given the above B-H curve Calculate : F, H, B, , and From the magnetizing curve:

Hysteresis When we increased the current we observed, saturation. What would happen if I decrease the current after saturation? The flux for a given H is higher when decreasing

Can we explain the hysteresis phenomena? All materials consist of small magnetic domains. When they are in a magnetic field the domains are intended to be in line with the field.

The domains after applying magnetic field The domains before applying magnetic field When the magnetic field is removed, not all domains are randomized again

Hysteresis loss Hysteresis is not a serious problem when we have DC excitation (the examples considered so far). It causes some loss when we have AC excitation, called hysteresis loss. If we have AC excitation, e.g. the current i is sinusoid, the hysteresis happens at each cycle. The hysteresis loss is proportional to the frequency and also depends on the area of the hysteresis loop.

Other losses - Copper loss: - Eddy Current loss: - Core losses:

Eddy Current Eddy current: As we saw, a flux induces a voltage on a coil. Q: Why not inducing a voltage on the core itself? A: It actually does. The result is eddy current. That is why the transformers core are laminated.