An Ideal Transformer Example: Difference between revisions

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<math>{Z_{th}} = \frac{e_{1}}{i_{1}}</math>
<math>{Z_{th}} = \frac{e_{1}}{i_{1}}</math>


Since this is an ideal transformer <math>{e_{1}}=\frac{N_{1}}{N_{2}}{e_{2}}</math> and <math>{i_{1}}=/frac{N_{2}}{N_{1}}{i_{2}}</math>
Since this is an ideal transformer <math>{e_{1}}=\frac{N_{1}}{N_{2}}{e_{2}}</math> and <math>{i_{1}}=\frac{N_{2}}{N_{1}}{i_{2}}</math>


So we can substitute, <math>=\frac{\frac{N_{1}}{N_{2}}{e_{2}}}{\frac{N_{2}}{N_{1}}{i_{2}}}</math>
So we can substitute, <math>{Z_{th}}=\frac{\frac{N_{1}}{N_{2}}{e_{2}}}{\frac{N_{2}}{N_{1}}{i_{2}}}</math>


<math>=(\frac{N_{1}}{N_{2}})^2{R_{L}}</math>
<math>=(\frac{N_{1}}{N_{2}})^2{Z_{L}}</math>


Now, plugging in the given values:
Now, substituting:


<math>\ {Z_{th}} = 3^2(5+j3)</math>
<math>\ {Z_{th}} = 3^2(5+j3)</math>


<math>\ =(45+j27)\Omega</math>
<math>\ =(45+j27)\Omega</math>

Since <math>{i_{1}}=\frac{e_{1}}{R_{th}}</math>,

<math>{i_{1}}=\frac{120\sqrt{2}}{45+j27} A</math>


Since this is an ideal transformer, it can be modeled by this simple circuit:
Since this is an ideal transformer, it can be modeled by this simple circuit:
[[Image: Ideal_Circuit.jpg]]
[[Image: Ideal_Circuit.jpg]]

Therefore, <math>{i_{1}}=\frac{e_{1}}{Z_{th}}</math>,

<math>{i_{1}}=\frac{120\sqrt{2}}{45+j27} A</math>


===Contributors===
===Contributors===
Line 40: Line 40:
===Reviwed By===
===Reviwed By===
Andrew Sell - Chris, everything looks fine, though I would do some extra formatting if possible to help make the problem flow a little smoother as you read it, and locate the picture a little higher to help bring the solution together.
Andrew Sell - Chris, everything looks fine, though I would do some extra formatting if possible to help make the problem flow a little smoother as you read it, and locate the picture a little higher to help bring the solution together.

Tyler Anderson - Looks good.


===Read By===
===Read By===

Latest revision as of 16:34, 24 January 2010

Consider a simple, transformer with two windings. Find the current provided by the voltage source.

  • Winding 1 has a sinusoidal voltage of ° applied to it at a frequency of 60Hz.
  • The combined load on winding 2 is

Solution

Given: and

Substituting ,

Therefore,

Now the Thevenin equivalent impedance, , is found through the following steps:

Since this is an ideal transformer and

So we can substitute,

Now, plugging in the given values:

Since this is an ideal transformer, it can be modeled by this simple circuit: Ideal Circuit.jpg

Therefore, ,

Contributors

Christopher Garrison Lau I

Reviwed By

Andrew Sell - Chris, everything looks fine, though I would do some extra formatting if possible to help make the problem flow a little smoother as you read it, and locate the picture a little higher to help bring the solution together.

Tyler Anderson - Looks good.

Read By

John Hawkins