m (Disambiguate terms by having problems within questions)
m (Used cursive instead of blackboard bold for MMF)
 
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A developed diagram approach is used, "unrolling" the machine such that increasing <math>\phi</math> (counterclockwise as drawn) is to the left.
 
A developed diagram approach is used, "unrolling" the machine such that increasing <math>\phi</math> (counterclockwise as drawn) is to the left.
  
Magnetomotive force (MMF) for a machine with '''concentrated''' windings may be found as <math>\mathbb{F} = \int_{\phi = 0}^{360^\circ} N(\phi) i \, d\phi</math>.
+
Magnetomotive force (MMF) for a machine with '''concentrated''' windings may be found as <math>\mathcal{F} = \int_{\phi = 0}^{360^\circ} N(\phi) i \, d\phi</math>.
  
 
It is given that <math>N_{as} = \mp 1</math> at an inferred position of <math>\phi_s = 0^\circ</math> and <math>\phi_s = 180^\circ</math>. The current is <math>i_{as} = 1 \, \textrm{A}</math>.
 
It is given that <math>N_{as} = \mp 1</math> at an inferred position of <math>\phi_s = 0^\circ</math> and <math>\phi_s = 180^\circ</math>. The current is <math>i_{as} = 1 \, \textrm{A}</math>.
  
Because <math>\oiint_S \vec{B} \cdot d\vec{S} = 0</math>, including on the interior surface of the stator and ends of the machine, the average value in the developed diagram of <math>B(\phi_s)</math> must be 0. The average value of MMF must also be 0 because the airgap is constant, meaning that <math>\mathbb{F}(\phi_s)</math> and <math>B(\phi_s)</math> are proportional to each other in the airgap from <math>B(\phi_s) = \frac{\mu_0 \mathbb{F}(\phi_s)}{g}</math>. Thus, the offset of -1.0 A is removed.
+
Because <math>\oiint_S \vec{B} \cdot d\vec{S} = 0</math>, including on the interior surface of the stator and ends of the machine, the average value in the developed diagram of <math>B(\phi_s)</math> must be 0. The average value of MMF must also be 0 because the airgap is constant, meaning that <math>\mathcal{F}(\phi_s)</math> and <math>B(\phi_s)</math> are proportional to each other in the airgap from <math>B(\phi_s) = \frac{\mu_0 \mathcal{F}(\phi_s)}{g}</math>. Thus, the offset of -1.0 A is removed.
  
 
[[Image:ECE QE ES1 2007 fig2.png|500x500px|left|MMF in Developed Diagram Format]]
 
[[Image:ECE QE ES1 2007 fig2.png|500x500px|left|MMF in Developed Diagram Format]]

Latest revision as of 17:28, 16 January 2018


Answers and Discussions for

ECE Ph.D. Qualifying Exam ES-1 August 2007



Problem 1, part b

A developed diagram approach is used, "unrolling" the machine such that increasing $ \phi $ (counterclockwise as drawn) is to the left.

Magnetomotive force (MMF) for a machine with concentrated windings may be found as $ \mathcal{F} = \int_{\phi = 0}^{360^\circ} N(\phi) i \, d\phi $.

It is given that $ N_{as} = \mp 1 $ at an inferred position of $ \phi_s = 0^\circ $ and $ \phi_s = 180^\circ $. The current is $ i_{as} = 1 \, \textrm{A} $.

Because $ \oiint_S \vec{B} \cdot d\vec{S} = 0 $, including on the interior surface of the stator and ends of the machine, the average value in the developed diagram of $ B(\phi_s) $ must be 0. The average value of MMF must also be 0 because the airgap is constant, meaning that $ \mathcal{F}(\phi_s) $ and $ B(\phi_s) $ are proportional to each other in the airgap from $ B(\phi_s) = \frac{\mu_0 \mathcal{F}(\phi_s)}{g} $. Thus, the offset of -1.0 A is removed.

MMF in Developed Diagram Format

Discussion



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