An Ideal Transformer Example: Difference between revisions

Revision as of 23:42, 18 January 2010

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

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

$\ {e_{1}}(t)={V_{1}}\cos(\omega t)$

$\ \omega =2\pi f$ , so $\ \omega =120\pi$

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

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

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

$={\frac {{\frac {N_{1}}{N_{2}}}{e_{2}}}{{\frac {N_{2}}{N_{1}}}{i_{2}}}}$

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

Now, substituting:

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

$\ =(45+j27)\Omega$

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

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

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

John Hawkins

@@ Line 8: / Line 8: @@
 <math>\ \omega=2\pi f</math>, so <math>\ \omega=120\pi</math>
-Therefore, <math>\ {e_{1}}(t)={V_{1}}\cos(120\pi t)</math>
+Therefore, <math>\ {e_{1}}(t)=120\sqrt{2}\cos(120\pi t)V</math>
 Now the Thevenin equivalent impedance, <math>\ {Z_{th}}</math>, is found through the following steps: