Example Problems with Transformers: Difference between revisions

Latest revision as of 17:03, 26 January 2010

Transformer Example

Kevin Starkey EMEC, Nick Christman, Aric Vyhmeister

Problem:

A step down transformer has a winding of $N_{1}=10{\text{ turns and }}N_{2}=2$ turns. (a) If the input voltage is 1200V, what is the resulting output voltage? (b) If the input and output currents are $5A{\mbox{ and }}20A$ , respectively, what is the current loss due to the leakage inductance, $i_{m}(t)$ .

Figure 1: Model for an ideal transformer.

Figure 2: Magnetic circuit of an ideal transformer.

Solution:

a) By modifying equation 5-39 (Mohan 5-22) we can obtain an equation for the output voltage. That is,

$e_{2}=\left({\frac {N_{2}}{N_{1}}}\right)e_{1}$ .

With the information provided we can now determine the output voltage:

$e_{2}=\left({\frac {N_{2}}{N_{1}}}\right)e_{1}=\left({\frac {2}{10}}\right)1200V=240V$

b) From the figure above, we need to find the true value of current (i.e. the current that is not lost by leakage inductance). To accomplish this we will use equation 5-40 (Mohan 5-23) to obtain the value of $i_{1}^{'}$ . That is,

$i_{1}^{'}=\left({\frac {N_{2}}{N_{1}}}\right)i_{2}=\left({\frac {2}{10}}\right)20A=4A$ .

Now from equation 5-42 (Mohan 5-23) we can obtain the current loss due to the leakage inductance, which is

$i_{m}=i_{1}-i_{1}^{'}=5A-4A=1A$ .

Therefore, the current loss in our transformer is $1A$ , which means this specific transformer is very "leaky."

@@ Line 1: / Line 1: @@
-==Problems 1-3==
+==Transformer Example==
-'''Kevin Starkey, Nick Christman, Aric Vyhmeister'''
+'''[[Kevin Starkey EMEC]], [[Nick Christman]], [[Aric Vyhmeister]]'''
-'''Problem 1.''' An ''ideal'' step down transformer has a winding of <math> N_1 = 10 \text{ turns and } N_2 = 2 </math> turns. If the input voltage is 1200V, what is the resulting output voltage?
+<u>'''Problem:'''</u>
-'''Solution''' Using the equation <math> e_2 = \frac{N_2}{N_1}e_1 </math> we get
-<math> e_2 = \frac{2}{10}1200 = 240V </math>
+A step down transformer has a winding of <math> N_1 = 10 \text{ turns and } N_2 = 2 </math> turns. (a) If the input voltage is 1200V, what is the resulting output voltage? (b) If the input and output currents are <math>5A \mbox{ and } 20A</math>, respectively, what is the current loss due to the leakage inductance, <math>i_{m}(t)</math>.
+<center>
+{|
+|[[Image:IdealTransformer1-nka.jpg|thumb|center|upright=2|Figure 1: Model for an ideal transformer.]]
+|[[Image:IdealTransformer2-nka.jpg|thumb|center|upright=2|Figure 2: Magnetic circuit of an ideal transformer.]]
+|}
+</center>
+<u>'''Solution:'''</u>
+a) By modifying equation 5-39 (Mohan 5-22) we can obtain an equation for the output voltage. That is,
+<br/>
+<div style="text-align:center">
+<math> e_2 = \left( \frac{N_2}{N_1} \right) e_1 </math>.
+</div>
+<br/>
+With the information provided we can now determine the output voltage:
+<br/>
+<div style="text-align:center">
+<math>  e_2 = \left( \frac{N_2}{N_1} \right) e_1 = \left( \frac{2}{10} \right) 1200V = 240V </math>
+</div>
+<br/>
+b) From the figure above, we need to find the true value of current (i.e. the current that is not lost by leakage inductance). To accomplish this we will use equation 5-40 (Mohan 5-23) to obtain the value of <math>i_{1}^{'}</math>. That is,
+<br/>
+<div style="text-align:center">
+<math>i_{1}^{'} = \left( \frac{N_2}{N_1} \right) i_{2} = \left( \frac{2}{10} \right) 20A = 4A</math>.
+</div>
+Now from equation 5-42 (Mohan 5-23) we can obtain the current loss due to the leakage inductance, which is
+<br/>
+<div style="text-align:center">
+<math>i_{m} = i_{1} - i_{1}^{'} = 5A - 4A = 1A</math>.
+</div>
+Therefore, the current loss in our transformer is <math>1A</math>, which means this specific transformer is very "leaky."

Example Problems with Transformers: Difference between revisions

Latest revision as of 17:03, 26 January 2010

Transformer Example

Navigation menu

Search