An Ideal Transformer Example: Difference between revisions

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

• Winding 1 has a sinusoidal voltage of ${\displaystyle 120{\sqrt {2}}\angle {0}}$° applied to it at a frequency of 60Hz.
• ${\displaystyle {\frac {N_{1}}{N_{2}}}=3}$
• The combined load on winding 2 is ${\displaystyle \ {Z_{L}}=(5+j3)\Omega }$

Solution

Given: ${\displaystyle \ {e_{1}}(t)={V_{1}}\cos(\omega t)}$ and ${\displaystyle \ \omega =2\pi f}$

Substituting ${\displaystyle \ f=60Hz}$, ${\displaystyle \ \omega =120\pi }$

Therefore, ${\displaystyle \ {e_{1}}(t)=120{\sqrt {2}}\cos(120\pi t)V}$

Now the Thevenin equivalent impedance, ${\displaystyle \ {Z_{th}}}$, is found through the following steps:

${\displaystyle {Z_{th}}={\frac {e_{1}}{i_{1}}}}$

Since this is an ideal transformer ${\displaystyle {e_{1}}={\frac {N_{1}}{N_{2}}}{e_{2}}}$ and ${\displaystyle {i_{1}}=/frac{N_{2}}{N_{1}}{i_{2}}}$

So we can substitute, ${\displaystyle ={\frac {{\frac {N_{1}}{N_{2}}}{e_{2}}}{{\frac {N_{2}}{N_{1}}}{i_{2}}}}}$

${\displaystyle =({\frac {N_{1}}{N_{2}}})^{2}{R_{L}}}$

Now, substituting:

${\displaystyle \ {Z_{th}}=3^{2}(5+j3)}$

${\displaystyle \ =(45+j27)\Omega }$

Since ${\displaystyle {i_{1}}={\frac {e_{1}}{R_{th}}}}$,

${\displaystyle {i_{1}}={\frac {120{\sqrt {2}}}{45+j27}}A}$

Since this is an ideal transformer, it can be modeled by this simple circuit:

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.

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John Hawkins